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REJ09B0392-0064
16
M16C/64 Group
Hardware Manual
RENESAS MCU M16C FAMILY / M16C/60 SERIES
PRELIMINARY
M16C/64 Group Hardware Manual
All information contained in these materials, including products and product specifications, represents information on the product at the time of publication and is subject to change by Renesas Technology Corp. without notice. Please review the latest information published by Renesas Technology Corp. through various means, including the Renesas Technology Corp. website (http://www.renesas.com).
Rev.0.64 Revision Date: Oct 12, 2007
www.renesas.com
Notes regarding these materials
1. This document is provided for reference purposes only so that Renesas customers may select the appropriate Renesas products for their use. Renesas neither makes warranties or representations with respect to the accuracy or completeness of the information contained in this document nor grants any license to any intellectual property rights or any other rights of Renesas or any third party with respect to the information in this document. 2. Renesas shall have no liability for damages or infringement of any intellectual property or other rights arising out of the use of any information in this document, including, but not limited to, product data, diagrams, charts, programs, algorithms, and application circuit examples. 3. You should not use the products or the technology described in this document for the purpose of military applications such as the development of weapons of mass destruction or for the purpose of any other military use. When exporting the products or technology described herein, you should follow the applicable export control laws and regulations, and procedures required by such laws and regulations. 4. All information included in this document such as product data, diagrams, charts, programs, algorithms, and application circuit examples, is current as of the date this document is issued. Such information, however, is subject to change without any prior notice. Before purchasing or using any Renesas products listed in this document, please confirm the latest product information with a Renesas sales office. Also, please pay regular and careful attention to additional and different information to be disclosed by Renesas such as that disclosed through our website. (http://www.renesas.com ) 5. Renesas has used reasonable care in compiling the information included in this document, but Renesas assumes no liability whatsoever for any damages incurred as a result of errors or omissions in the information included in this document. 6. When using or otherwise relying on the information in this document, you should evaluate the information in light of the total system before deciding about the applicability of such information to the intended application. Renesas makes no representations, warranties or guaranties regarding the suitability of its products for any particular application and specifically disclaims any liability arising out of the application and use of the information in this document or Renesas products. 7. With the exception of products specified by Renesas as suitable for automobile applications, Renesas products are not designed, manufactured or tested for applications or otherwise in systems the failure or malfunction of which may cause a direct threat to human life or create a risk of human injury or which require especially high quality and reliability such as safety systems, or equipment or systems for transportation and traffic, healthcare, combustion control, aerospace and aeronautics, nuclear power, or undersea communication transmission. If you are considering the use of our products for such purposes, please contact a Renesas sales office beforehand. Renesas shall have no liability for damages arising out of the uses set forth above. 8. Notwithstanding the preceding paragraph, you should not use Renesas products for the purposes listed below: (1) artificial life support devices or systems (2) surgical implantations (3) healthcare intervention (e.g., excision, administration of medication, etc.) (4) any other purposes that pose a direct threat to human life Renesas shall have no liability for damages arising out of the uses set forth in the above and purchasers who elect to use Renesas products in any of the foregoing applications shall indemnify and hold harmless Renesas Technology Corp., its affiliated companies and their officers, directors, and employees against any and all damages arising out of such applications. 9. You should use the products described herein within the range specified by Renesas, especially with respect to the maximum rating, operating supply voltage range, movement power voltage range, heat radiation characteristics, installation and other product characteristics. Renesas shall have no liability for malfunctions or damages arising out of the use of Renesas products beyond such specified ranges. 10. Although Renesas endeavors to improve the quality and reliability of its products, IC products have specific characteristics such as the occurrence of failure at a certain rate and malfunctions under certain use conditions. Please be sure to implement safety measures to guard against the possibility of physical injury, and injury or damage caused by fire in the event of the failure of a Renesas product, such as safety design for hardware and software including but not limited to redundancy, fire control and malfunction prevention, appropriate treatment for aging degradation or any other applicable measures. Among others, since the evaluation of microcomputer software alone is very difficult, please evaluate the safety of the final products or system manufactured by you. 11. In case Renesas products listed in this document are detached from the products to which the Renesas products are attached or affixed, the risk of accident such as swallowing by infants and small children is very high. You should implement safety measures so that Renesas products may not be easily detached from your products. Renesas shall have no liability for damages arising out of such detachment. 12. This document may not be reproduced or duplicated, in any form, in whole or in part, without prior written approval from Renesas. 13. Please contact a Renesas sales office if you have any questions regarding the information contained in this document, Renesas semiconductor products, or if you have any other inquiries.
General Precautions in the Handling of MPU/MCU Products
The following usage notes are applicable to all MPU/MCU products from Renesas. For detailed usage notes on the products covered by this manual, refer to the relevant sections of the manual. If the descriptions under General Precautions in the Handling of MPU/MCU Products and in the body of the manual differ from each other, the description in the body of the manual takes precedence. 1. Handling of Unused Pins Handle unused pins in accord with the directions given under Handling of Unused Pins in the manual. The input pins of CMOS products are generally in the high-impedance state. In operation with an unused pin in the open-circuit state, extra electromagnetic noise is induced in the vicinity of LSI, an associated shoot-through current flows internally, and malfunctions occur due to the false recognition of the pin state as an input signal become possible. Unused pins should be handled as described under Handling of Unused Pins in the manual. 2. Processing at Power-on The state of the product is undefined at the moment when power is supplied. The states of internal circuits in the LSI are indeterminate and the states of register settings and pins are undefined at the moment when power is supplied. In a finished product where the reset signal is applied to the external reset pin, the states of pins are not guaranteed from the moment when power is supplied until the reset process is completed. In a similar way, the states of pins in a product that is reset by an on-chip power-on reset function are not guaranteed from the moment when power is supplied until the power reaches the level at which resetting has been specified. 3. Prohibition of Access to Reserved Addresses Access to reserved addresses is prohibited. The reserved addresses are provided for the possible future expansion of functions. Do not access these addresses; the correct operation of LSI is not guaranteed if they are accessed. 4. Clock Signals After applying a reset, only release the reset line after the operating clock signal has become stable. When switching the clock signal during program execution, wait until the target clock signal has stabilized. When the clock signal is generated with an external resonator (or from an external oscillator) during a reset, ensure that the reset line is only released after full stabilization of the clock signal. Moreover, when switching to a clock signal produced with an external resonator (or by an external oscillator) while program execution is in progress, wait until the target clock signal is stable. 5. Differences between Products Before changing from one product to another, i.e. to one with a different part number, confirm that the change will not lead to problems. The characteristics of MPU/MCU in the same group but having different part numbers may differ because of the differences in internal memory capacity and layout pattern. When changing to products of different part numbers, implement a system-evaluation test for each of the products.
HOW TO USE THIS MANUAL
1. Purpose and Target Readers
This manual is designed to provide the user with an understanding of the hardware functions and electrical characteristics of the MCU. It is intended for users designing application systems incorporating the MCU. A basic knowledge of electric circuits, logical circuits, and MCUs is necessary in order to use this manual. The manual comprises an overview of the product; descriptions of the CPU, system control functions, peripheral functions, and electrical characteristics; and usage notes. Particular attention should be paid to the precautionary notes when using the manual. These notes occur within the body of the text, at the end of each section, and in the Usage Notes section.
The revision history summarizes the locations of revisions and additions. It does not list all revisions. Refer to the text of the manual for details. The following documents apply to the M16C/64 Group. Make sure to refer to the latest versions of these documents. The newest versions of the documents listed may be obtained from the Renesas Technology Web site. Description Document Title Document No. Hardware overview and electrical characteristics M16C/64 Group REJ03B0216 Datasheet This hardware Hardware manual Hardware specifications (pin assignments, mem- M16C/64 Group Hardware Manual manual ory maps, peripheral function specifications, electrical characteristics, timing charts) and operation description Note: Refer to the application notes for details on using peripheral functions. Available from Renesas TechnolApplication note Information on using peripheral functions and ogy Web site. application examples Sample programs Information on writing programs in assembly language and C Renesas Product specifications, updates on documents, technical update etc. Document Type Datasheet
2.
Notation of Numbers and Symbols
The notation conventions for register names, bit names, numbers, and symbols used in this manual are described below. (1) Register Names, Bit Names, and Pin Names Registers, bits, and pins are referred to in the text by symbols. The symbol is accompanied by the word "register," "bit," or "pin" to distinguish the three categories. Examples the PM03 bit in the PM0 register P3_5 pin, VCC pin (2) Notation of Numbers The indication "b" is appended to numeric values given in binary format. However, nothing is appended to the values of single bits. The indication "h" is appended to numeric values given in hexadecimal format. Nothing is appended to numeric values given in decimal format. Examples Binary: 11b Hexadecimal: EFA0h Decimal: 1234
3.
Register Notation
The symbols and terms used in register diagrams are described below.
XXX Register
b7 b6 b5 b4 b3 b2 b1 b0
*1
Symbol XXX Address XXX After Reset 00h
0
Bit Symbol
XXX0
Bit Name
XXX bits
b1 b0
Function
1 0: XXX 0 1: XXX 1 0: Do not set. 1 1: XXX
RW RW RW
*2
XXX1
(b2)
Nothing is assigned. If necessary, set to 0. When read, the content is undefined.
*3
RW
(b3)
Reserved bits
Set to 0. Function varies according to the operating mode.
*4
XXX4
XXX bits
RW
XXX5
WO
XXX6 XXX bit 0: XXX 1: XXX
RW
XXX7
RO
*1 Blank: Set to 0 or 1 according to the application. 0: Set to 0. 1: Set to 1. X: Nothing is assigned. *2 RW: Read and write. RO: Read only. WO: Write only. -: Nothing is assigned. *3 * Reserved bit Reserved bit. Set to specified value. *4 * Nothing is assigned Nothing is assigned to the bit. As the bit may be used for future functions, if necessary, set to 0. * Do not set to a value Operation is not guaranteed when a value is set. * Function varies according to the operating mode. The function of the bit varies with the peripheral function mode. Refer to the register diagram for information on the individual modes.
4.
List of Abbreviations and Acronyms
Full Form Asynchronous Communication Interface Adapter bits per second Cyclic Redundancy Check Direct Memory Access Direct Memory Access Controller Global System for Mobile Communications High Impedance Inter Equipment bus Input/Output Infrared Data Association Least Significant Bit Most Significant Bit Non-Connection Phase Locked Loop Pulse Width Modulation Special Function Registers Subscriber Identity Module Universal Asynchronous Receiver/Transmitter Voltage Controlled Oscillator
Abbreviation ACIA bps CRC DMA DMAC GSM Hi-Z IEBus I/O IrDA LSB MSB NC PLL PWM SFR SIM UART VCO
All trademarks and registered trademarks are the property of their respective owners. IEBus is a registered trademark of NEC Electronics Corporation.
SFR Page Reference
Address 0000h 0001h 0002h 0003h 0004h 0005h 0006h 0007h 0008h 0009h 000Ah 000Bh 000Ch 000Dh 000Eh 000Fh 0010h 0011h 0012h 0013h 0014h 0015h 0016h 0017h 0018h 0019h 001Ah 001Bh 001Ch 001Dh 001Eh 001Fh 0020h 0021h 0022h 0023h 0024h 0025h 0026h 0027h 0028h 0029h 002Ah 002Bh 002Ch 002Dh 002Eh 002Fh 0030h 0031h 0032h 0033h 0034h 0035h 0036h 0037h 0038h 0039h 003Ah 003Bh 003Ch 003Dh 003Eh 003Fh 0040h 0041h NOTE: 1. Blank columns are all reserved space. No access is allowed. Voltage Monitor 0 Circuit Control Register VW0C 40 Processor Mode Register 2 Low Voltage Detection Interrupt Register PM2 D4INT 79 39 Reset Source Determine Flag Voltage Detection 2 Circuit Flag Register Voltage Detection Circuit Operation Enable Register Chip Select Expansion Control Register PLL Control Register 0 RSTFR VCR1 VCR2 CSE PLC0 46 38 38 62 80 Clock Prescaler Reset Flag CPSRF 141 Peripheral Clock Select Register PCLKR 79 Program 2 Area Control Register PRG2C 50 Protect Register Data Bank Register Oscillation Stop Detection Register PRCR DBR CM2 98 67 78 Processor Mode Register 0 Processor Mode Register 1 System Clock Control Register 0 System Clock Control Register 1 Chip Select Control Register PM0 PM1 CM0 CM1 CSR 48 49 76 77 55 0047h 0048h 0049h 004Ah 004Bh 004Ch 004Dh 004Eh 004Fh 0050h 0051h 0052h 0053h 0054h 0055h 0056h 0057h 0058h 0059h 005Ah 005Bh 005Ch 005Dh 005Eh 005Fh 0060h 0061h 0062h 0063h 0064h 0065h 0066h 0067h 0068h 0069h 006Ah 006Bh 006Ch 006Dh 006Eh 006Fh 0070h 0071h 0072h 0073h 0074h 0075h 0076h 0077h 0078h 0079h 007Ah 007Bh 007Ch 007Dh 007Eh 007Fh D080h to D17Fh DMA2 Interrupt Control Register DMA3 Interrupt Control Register UART5 BUS Collision Detection Interrupt Control Register UART5 Transmit Interrupt Control Register UART5 Receive Interrupt Control Register UART6 BUS Collision Detection Interrupt Control Register UART6 Transmit Interrupt Control Register UART6 Receive Interrupt Control Register UART7 BUS Collision Detection Interrupt Control Register UART7 Transmit Interrupt Control Register UART7 Receive Interrupt Control Register DM2IC DM3IC U5BCNIC S5TIC S5RIC U6BCNIC S6TIC S6RIC U7BCNIC S7TIC S7RIC 105 105 105 105 105 105 105 105 105 105 105 Register Symbol Page Address 0042h 0043h 0044h 0045h 0046h Register INT7 Interrupt Control Register INT6 Interrupt Control Register INT3 Interrupt Control Register Timer B5 Interrupt Control Register Timer B4 Interrupt Control Register, UART1 BUS Collision Detection Interrupt Control Register Timer B3 Interrupt Control Register, UART0 BUS Collision Detection Interrupt Control Register SI/O4 Interrupt Control Register, INT5 Interrupt Control Register SI/O3 Interrupt Control Register, INT4 Interrupt Control Register UART2 BUS Collision Detection Interrupt Control Register DMA0 Interrupt Control Register DMA1 Interrupt Control Register Key Input Interrupt Control Register A/D Conversion Interrupt Control Register UART2 Transmit Interrupt Control Register UART2 Receive Interrupt Control Register UART0 Transmit Interrupt Control Register UART0 Receive Interrupt Control Register UART1 Transmit Interrupt Control Register UART1 Receive Interrupt Control Register Timer A0 Interrupt Control Register Timer A1 Interrupt Control Register Timer A2 Interrupt Control Register Timer A3 Interrupt Control Register Timer A4 Interrupt Control Register Timer B0 Interrupt Control Register Timer B1 Interrupt Control Register Timer B2 Interrupt Control Register INT0 Interrupt Control Register INT1 Interrupt Control Register INT2 Interrupt Control Register Symbol INT7IC INT6IC INT3IC TB5IC TB4IC, U1BCNIC TB3IC, U0BCNIC S4IC, INT5IC S3IC, INT4IC BCNIC DM0IC DM1IC KUPIC ADIC S2TIC S2RIC S0TIC S0RIC S1TIC S1RIC TA0IC TA1IC TA2IC TA3IC TA4IC TB0IC TB1IC TB2IC INT0IC INT1IC INT2IC Page 106 106 106 105 105
105 106 106 106 105 105 105 105 105 105 105 105 105 105 105 105 105 105 105 105 105 105 106 106 106
B-1
Address 0180h 0181h 0182h 0183h 0184h 0185h 0186h 0187h 0188h 0189h 018Ah 018Bh 018Ch 018Dh 018Eh 018Fh 0190h 0191h 0192h 0193h 0194h 0195h 0196h 0197h 0198h 0199h 019Ah 019Bh 019Ch 019Dh 019Eh 019Fh 01A0h 01A1h 01A2h 01A3h 01A4h 01A5h 01A6h 01A7h 01A8h 01A9h 01AAh 01ABh 01ACh 01ADh 01AEh 01AFh 01B0h 01B1h 01B2h 01B3h 01B4h 01B5h 01B6h 01B7h 01B8h 01B9h 01BAh 01BBh 01BCh 01BDh 01BEh 01BFh 01C0h 01C1h 01C2h
Register DMA0 Source Pointer
Symbol SAR0
Page 128
Address 01C3h 01C4h 01C5h 01C6h
Register
Symbol
Page
DMA0 Destination Pointer
DAR0
128
01C7h 01C8h 01C9h 01CAh Timer B Count Source Select Register 0 Timer B Count Source Select Register 1 TBCS0 TBCS1 157 157
DMA0 Transfer Counter
TCR0
128
01CBh 01CCh 01CDh 01CEh
DMA0 Control Register
DM0CON
128
01CFh 01D0h 01D1h 01D2h Timer A Count Source Select Register 0 Timer A Count Source Select Register 1 Timer A Count Source Select Register 2 TACS0 TACS1 TACS2 141 141 142
DMA1 Source Pointer
SAR1
128
01D3h 01D4h 01D5h Timer A Waveform Output Function Select Register TAPOFS 142
DMA1 Destination Pointer
DAR1
128
01D6h 01D7h 01D8h 01D9h 01DAh 01DBh 01DEh 01DCh
DMA1 Transfer Counter
TCR1
128
DMA1 Control Register
DM1CON
127
01DDh 01DFh 01E0h 01E1h 01E2h 01E3h 01E4h 01E5h
DMA2 Source Pointer
SAR2
128
DMA2 Destination Pointer
DAR2
128
01E6h 01E7h 01E8h 01E9h Timer B Count Source Select Register 2 Timer B Count Source Select Register 3 TBCS2 TBCS3 157 157
DMA2 Transfer Counter
TCR2
128
01EAh 01EBh 01ECh 01EDh 01EEh 01EFh 01F0h 01F1h
DMA2 Control Register
DM2CON
127
DMA3 Source Pointer
SAR3
128
01F2h 01F3h 01F4h 01F5h 01F6h 01F7h 01F8h 01F9h
DMA3 Destination Pointer
DAR3
128
DMA3 Transfer Counter
TCR3
128
01FAh 01FBh 01FCh 01FDh 01FEh 01FFh 0200h 0201h 0202h 0203h 0204h NOTE: 1. Blank columns are all reserved space. No access is allowed.
DMA3 Control Register
DM3CON
128
B-2
Address 0205h 0206h 0207h 0208h 0209h 020Ah 020Bh 020Ch 020Dh 020Eh 020Fh 0210h 0211h 0212h 0213h 0214h 0215h 0216h 0217h 0218h 0219h 021Ah 021Bh 021Ch 021Dh 021Eh 021Fh 0220h 0221h 0222h 0223h 0224h 0225h 0226h 0227h 0228h 0229h 022Ah 022Bh 022Ch 022Dh 022Eh 022Fh 0230h 0231h 0232h 0233h 0234h 0235h 0236h 0237h 0238h 0239h 023Ah 023Bh 023Ch 023Dh 023Eh 023Fh 0240h 0241h 0242h 0243h 0244h 0245h 0246h 0247h 0248h
Register Interrupt Source Select Register 3 Interrupt Source Select Register 2 Interrupt Source Select Register
Symbol IFSR3A IFSR2A IFSR
Page 114 114 113
Address 0249h 024Ah 024Bh 024Ch 024Dh 024Eh 024Fh 0250h
Register UART0 Bit Rate Register UART0 Transmit Buffer Register UART0 Transmit/Receive Control Register 0 UART0 Transmit/Receive Control Register 1 UART0 Receive Buffer Register
Symbol U0BRG U0TB U0C0 U0C1 U0RB
Page 180 179 181 182 179
UART Transmit/Receive Control Register 2
UCON
183
Address Match Interrupt Enable Register Address Match Interrupt Enable Register 2 Address Match Interrupt Register 0
AIER AIER2 RMAD0
117 117 117
0251h 0252h 0253h 0254h 0255h 0256h 0257h 0258h 0259h 025Ah 025Bh 025Ch 025Dh 025Eh 025Fh 0260h 0261h 0262h 0263h 0264h 0265h 0266h 0267h 0268h 0269h 026Ah 026Bh 026Ch 026Dh 026Eh 026Fh 0270h 0271h 0272h SI/O3 Control Register SI/O3 Bit Rate Register SI/O4 Transmit/Receive Register SI/O4 Control Register SI/O4 Bit Rate Register SI/O34 Control Register 2 S3C S3BRG S4TRR S4C S4BRG S34C2 224 224 224 224 224 225 0273h 0274h 0275h 0276h 0277h 0278h 0279h 027Ah 027Bh 027Ch 027Dh 027Eh 027Fh 0280h 0281h 0282h 0283h 0284h 0285h 0286h 0287h 0288h 0289h UART5 Special Mode Register 4 UART5 Special Mode Register 3 UART5 Special Mode Register 2 UART5 Special Mode Register UART5 Transmit/Receive Mode Register UART5 Bit Rate Register U5SMR4 U5SMR3 U5SMR2 U5SMR U5MR U5BRG 185 184 184 183 180 180 SI/O3 Transmit/Receive Register S3TRR UART2 Transmit/Receive Control Register 0 UART2 Transmit/Receive Control Register 1 UART2 Receive Buffer Register U2C0 U2C1 U2RB UART2 Special Mode Register 4 UART2 Special Mode Register 3 UART2 Special Mode Register 2 UART2 Special Mode Register UART2 Transmit/Receive Mode Register UART2 Bit Rate Register UART2 Transmit Buffer Register U2SMR4 U2SMR3 U2SMR2 U2SMR U2MR U2BRG U2TB 185 184 184 183 180 180 170 181 182 179 224 UART1 Transmit/Receive Control Register 0 UART1 Transmit/Receive Control Register 1 UART1 Receive Buffer Register U1C0 U1C1 U1RB UART1 Special Mode Register 4 UART1 Special Mode Register 3 UART1 Special Mode Register 2 UART1 Special Mode Register UART1 Transmit/Receive Mode Register UART1 Bit Rate Register UART1 Transmit Buffer Register U1SMR4 U1SMR3 U1SMR2 U1SMR U1MR U1BRG U1TB 185 184 184 183 180 180 170 180 182 170
Address Match Interrupt Register 1
RMAD1
117
Address Match Interrupt Register 2
RMAD2
117
Address Match Interrupt Register 3
RMAD3
117
Flash Memory Control Register 0 Flash Memory Control Register 1 Flash Memory Control Register 2
FMR0 FMR1 FMR2
272 273 274
Flash Memory Control Register 6
FMR6
275
UART0 Special Mode Register 4 UART0 Special Mode Register 3 UART0 Special Mode Register 2 UART0 Special Mode Register UART0 Transmit/Receive Mode Register
U0SMR4 U0SMR3 U0SMR2 U0SMR U0MR
185 184 184 183 180
NOTE: 1. Blank columns are all reserved space. No access is allowed.
B-3
Address 028Ah 028Bh 028Ch 028Dh 028Eh 028Fh 0290h 0291h 0292h 0293h 0294h 0295h 0296h 0297h 0298h 0299h 029Ah 029Bh 029Ch 029Dh 029Eh 029Fh 02A0h 02A1h 02A2h 02A3h 02A4h 02A5h 02A6h 02A7h 02A8h 02A9h 02AAh 02ABh 02ACh 02ADh 02AEh 02AFh 02B0h to 02FFh 0300h 0301h 0302h 0303h 0304h 0305h 0306h 0307h 0308h 0309h 030Ah 030Bh 030Ch 030Dh 030Eh 030Fh 0310h 0311h 0312h 0313h 0314h 0315h 0316h 0317h 0318h 0319h
Register UART5 Transmit Buffer Register UART5 Transmit/Receive Control Register 0 UART5 Transmit/Receive Control Register 1 UART5 Receive Buffer Register
Symbol U5TB U5C0 U5C1 U5RB
Page 179 181 182 170
Address 031Ah 031Bh 031Ch 031Dh 031Eh 031Fh 0320h 0321h 0322h 0323h Count Start Flag
Register Timer B3 Mode Register Timer B4 Mode Register Timer B5 Mode Register
Symbol TB3MR TB4MR TB5MR
Page 155 155 155
TABSR ONSF TRGSR UDF TA0 TA1 TA2 TA3 TA4 TB0 TB1 TB2 TA0MR TA1MR TA2MR TA3MR TA4MR TB0MR TB1MR TB2MR TB2SC
156 140 140 139 152 152 152 152 152 155 155 155 138 138 138 138 138 155 155 155 170
One-Shot Start Flag Trigger Select Register Up/Down Flag Timer A0 Register Timer A1 Register Timer A2 Register Timer A3 Register Timer A4 Register Timer B0 Register Timer B1 Register Timer B2 Register Timer A0 Mode Register Timer A1 Mode Register Timer A2 Mode Register Timer A3 Mode Register Timer A4 Mode Register Timer B0 Mode Register Timer B1 Mode Register Timer B2 Mode Register Timer B2 Special Mode Register
UART6 Special Mode Register 4 UART6 Special Mode Register 3 UART6 Special Mode Register 2 UART6 Special Mode Register UART6 Transmit/Receive Mode Register UART6 Bit Rate Register UART6 Transmit Buffer Register UART6 Transmit/Receive Control Register 0 UART6 Transmit/Receive Control Register 1 UART6 Receive Buffer Register
U6SMR4 U6SMR3 U6SMR2 U6SMR U6MR U6BRG U6TB U6C0 U6C1 U6RB
185 184 184 183 180 180 179 181 182 179
0324h 0325h 0326h 0327h 0328h 0329h 032Ah 032Bh 032Ch 032Dh 032Eh 032Fh 0330h 0331h 0332h 0333h
UART7 Special Mode Register 4 UART7 Special Mode Register 3 UART7 Special Mode Register 2 UART7 Special Mode Register UART7 Transmit/Receive Mode Register UART7 Bit Rate Register UART7 Transmit Buffer Register UART7 Transmit/Receive Control Register 0 UART7 Transmit/Receive Control Register 1 UART7 Receive Buffer Register
U7SMR4 U7SMR3 U7SMR2 U7SMR U7MR U7BRG U7TB U7C0 U7C1 U7RB
185 184 184 183 180 180 179 181 182 179
0334h 0335h 0336h 0337h 0338h 0339h 033Ah 033Bh 033Ch 033Dh 033Eh 033Fh 0340h 0341h 0342h
Timer B3,4,5 Count Start Flag Timer A1-1 Register Timer A2-1 Register Timer A4-1 Register Three-Phase PWM Control Register 0 Three-Phase PWM Control Register 1 Three-Phase Output Buffer Register 0 Three-Phase Output Buffer Register 1 Dead Time Timer Timer B2 Interrupt Generation Frequency Set Counter
TBSR TA11 TA21 TA41 INVC0 INVC1 IDB0 IDB1 DTT ICTB2
156 170 170 170 167 168 169 169 169 169
0343h 0344h 0345h 0346h 0347h 0348h 0349h 034Ah 034Bh 034Ch 034Dh 034Eh 034Fh 0350h 0351h 0352h 0353h 0354h 0355h 0356h 0357h 0358h 0359h 035Ah 035Bh NOTE: 1. Blank columns are all reserved space. No access is allowed.
Timer B3 Register Timer B4 Register Timer B5 Register
TB3 TB4 TB5
155 155 155
B-4
Address 035Ch 035Dh 035Eh 035Fh 0360h 0361h 0362h 0363h 0364h 0365h 0366h 0367h 0368h 0369h 036Ah 036Bh 036Ch 036Dh 036Eh 036Fh 0370h 0371h 0372h 0373h 0374h 0375h 0376h 0377h 0378h 0379h 037Ah 037Bh 037Ch 037Dh 037Eh 037Fh 0380h 0381h 0382h 0383h 0384h 0385h 0386h 0387h 0388h 0389h 038Ah 038Bh 038Ch 038Dh 038Eh 038Fh 0390h 0391h 0392h 0393h 0394h 0395h 0396h 0397h 0398h 0399h 039Ah 039Bh 039Ch 039Dh 039Eh 039Fh
Register
Symbol
Page
Address 03A0h 03A1h 03A2h 03A3h
Register
Symbol
Page
Pull-Up Control Register 0 Pull-Up Control Register 1 Pull-Up Control Register 2
PUR0 PUR1 PUR2
258 258 259
03A4h 03A5h 03A6h 03A7h 03A8h 03A9h
Port Control Register
PCR
259
03AAh 03ABh 03ACh 03ADh 03AEh 03AFh 03B0h 03B1h 03B2h 03B3h 03B4h 03B5h 03B6h 03B7h 03B8h 03B9h 03BAh 03BBh 03BCh 03BDh 03BEh 03BFh CRC Input Register A/D Register 0 A/D Register 1 A/D Register 2 A/D Register 3 A/D Register 4 A/D Register 5 A/D Register 6 A/D Register 7 CRCIN AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7 248 233 233 233 233 233 233 233 233 CRC Data Register CRCD 248
Count Source Protection Mode Register Watchdog Timer Reset Register Watchdog Timer Start Register Watchdog Timer Control Register
CSPR WDTR WDTS WDC
120 119 119 119
03C0h 03C1h 03C2h 03C3h 03C4h 03C5h 03C6h 03C7h 03C8h 03C9h 03CAh 03CBh 03CCh 03CDh 03CEh 03CFh 03D0h 03D1h 03D2h 03D3h
DMA2 Source Select Register DMA3 Source Select Register
DM2SL DM3SL
125 125
03D4h 03D5h 03D6h 03D7h 03D8h 03D9h 03DAh 03DBh
A/D Control Register 2 A/D Control Register 0 A/D Control Register 1 D/A0 Register D/A1 Register D/A Control Register
ADCON2 ADCON0 ADCON1 DA0 DA1 DACON
233 232 232 247 247 247
DMA0 Source Select Register DMA1 Source Select Register
DM0SL DM1SL
125 125
03DCh 03DDh 03DEh 03DFh 03E0h 03E1h 03E2h 03E3h
Port P0 Register Port P1 Register Port P0 Direction Register Port P1 Direction Register
P0 P1 PD0 PD1
257 257 256 256
NOTE: 1. Blank columns are all reserved space. No access is allowed.
B-5
Address 03E4h 03E5h 03E6h 03E7h 03E8h 03E9h 03EAh 03EBh 03ECh 03EDh 03EEh 03EFh 03F0h 03F1h 03F2h 03F3h 03F4h 03F5h 03F6h 03F7h 03F8h 03F9h 03FAh 03FBh 03FCh 03FDh 03FEh 03FFh D000h to D7FFh
Register Port P2 Register Port P3 Register Port P2 Direction Register Port P3 Direction Register Port P4 Register Port P5 Register Port P4 Direction Register Port P5 Direction Register Port P6 Register Port P7 Register Port P6 Direction Register Port P7 Direction Register Port P8 Register Port P9 Register Port P8 Direction Register Port P9 Direction Register Port P10 Register Port P10 Direction Register P2 P3
Symbol
Page 257 257 256 256 257 257 256 256 257 257 256 256 257 257 256 256 257 256
PD2 PD3 P4 P5 PD4 PD5 P6 P7 PD6 PD7 P8 P9 PD8 PD9 P10 PD10
OFS1
Optional Feature Select Address
OFS1
269
NOTE: 1. Blank columns are all reserved space. No access is allowed.
B-6
TABLE OF CONTENTS
SFR Page Reference .......................................................................................................B-1
1.
Overview .................................................................................................. 1
1.1 1.2 1.3 1.4 1.5 1.6 Features .............................................................................................................. 1 Applications .................................................................................................. 1 Product List ........................................................................................................ 4 Block Diagram ..................................................................................................... 6 Pin Assignments.................................................................................................. 7 Pin Functions..................................................................................................... 11 Specifications ...................................................................................................... 2 1.1.1
2.
Central Processing Unit (CPU)............................................................... 14
2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Data Registers (R0, R1, R2 and R3)................................................................. 14 Address Registers (A0 and A1)......................................................................... 15 Frame Base Registers (FB)............................................................................... 15 Interrupt Table Register (INTB) ......................................................................... 15 Program Counter (PC) ...................................................................................... 15 User Stack Pointer (USP) and Interrupt Stack Pointer (ISP) ............................. 15 Static Base Register (SB).................................................................................. 15 Flag Register (FLG)........................................................................................... 15 Carry Flag (C Flag)..................................................................................... 15 Debug Flag (D Flag) ................................................................................... 15 Zero Flag (Z Flag)....................................................................................... 15 Sign Flag (S Flag)....................................................................................... 15 Register Bank Select Flag (B Flag) ............................................................ 15 Overflow Flag (O Flag) ............................................................................... 15 Interrupt Enable Flag (I Flag)...................................................................... 15 Stack Pointer Select Flag (U Flag) ............................................................. 16 Processor Interrupt Priority Level (IPL) ...................................................... 16 Reserved Space ......................................................................................... 16
2.8.1 2.8.2 2.8.3 2.8.4 2.8.5 2.8.6 2.8.7 2.8.8 2.8.9 2.8.10
1- 1
3. 4. 5.
Memory .................................................................................................. 17 Special Function Registers (SFRs) ........................................................ 18 Reset ...................................................................................................... 32
5.1 Hardware Reset 1 ............................................................................................. 32 Reset on a Stable Supply Voltage .............................................................. 32 Power-on Reset.......................................................................................... 32 5.1.1 5.1.2 5.2 5.3 5.4 5.5 5.6
Brown-out Reset................................................................................................ 35 Software Reset.................................................................................................. 35 Watchdog Timer Reset...................................................................................... 35 Oscillation Stop Detection Reset ....................................................................... 35 Internal Space ................................................................................................... 36
6.
Voltage Detection Circuit ........................................................................ 37
6.1 6.2 6.3 6.4 6.5 Brown-out Reset................................................................................................ 41 Low Voltage Detection Interrupt ........................................................................ 42 Limitations on Exiting Stop Mode ...................................................................... 44 Limitations on Exiting Wait Mode ...................................................................... 44 Cold Start-up / Warm Start-up Discrimination.................................................... 45
7.
Processor Mode ..................................................................................... 47
7.1 7.2 7.3 Types of Processor Mode.................................................................................. 47 Setting Processor Modes .................................................................................. 47 Internal Memory ................................................................................................ 51
8.
Bus ......................................................................................................... 53
8.1 Bus Mode .......................................................................................................... 53 Separate Bus.............................................................................................. 53 Multiplexed Bus .......................................................................................... 53 Address Bus ............................................................................................... 54 Data Bus..................................................................................................... 54 Chip Select Signal ...................................................................................... 54 Read and Write Signals.............................................................................. 57 ALE Signal.................................................................................................. 57 RDY Signal ................................................................................................. 58
1- 2
8.1.1 8.1.2 8.2 8.2.1 8.2.2 8.2.3 8.2.4 8.2.5 8.2.6
Bus Control........................................................................................................ 54
8.2.7 8.2.8 8.2.9 8.2.10
HOLD Signal............................................................................................... 59 BCLK Output .............................................................................................. 59 External Bus Status When Internal Area IS Accessed ............................... 61 Software Wait ............................................................................................. 61
9.
Memory Space Expansion Function ....................................................... 66
9.2 4-Mbyte Mode ................................................................................................... 66 Addresses 04000h to 3FFFFh, C0000h to FFFFFh ................................... 66 Addresses 40000h to BFFFFh ................................................................... 66 9.2.1 9.2.2
10. Clock Generation Circuit ........................................................................ 74
10.1 Type of the Clock Generation Circuit................................................................. 74 Main Clock.................................................................................................. 81 Sub Clock ................................................................................................... 82 125 kHz On-Chip Oscillator Clock (fOCO-S).............................................. 83 PLL Clock ................................................................................................... 83 CPU Clock and BCLK................................................................................. 86 Peripheral Function Clock (f1, fC32) .......................................................... 87 10.1.1 10.1.2 10.1.3 10.1.4 10.2 10.2.1 10.2.2 10.3 10.4
CPU Clock and Peripheral Function Clock........................................................ 86
Clock Output Function....................................................................................... 87 Power Control.................................................................................................... 88 Normal Operating Mode ............................................................................. 88 Wait Mode .................................................................................................. 90 Stop Mode .................................................................................................. 92
10.4.1 10.4.2 10.4.3 10.5 10.6
System Clock Protection Function .................................................................... 95 Oscillation Stop and Re-Oscillation Detect Function ......................................... 96 Operation When CM27 bit = 0 (Oscillation Stop Detection Reset) ............. 96 Operation When CM27 bit = 1 (Oscillation Stop and Re-oscillation Detect Interrupt) ................................................................... 96 How to Use Oscillation Stop and Re-Oscillation Detect Function............... 97
10.6.1 10.6.2 10.6.3
11. Protection ............................................................................................... 98 12. Interrupt .................................................................................................. 99
12.1 12.2 Type of Interrupts .............................................................................................. 99 Software Interrupts .......................................................................................... 100 Undefined Instruction Interrupt ................................................................. 100
1- 3
12.2.1
12.2.2 12.2.4 12.3 12.3.1 12.3.2 12.4 12.4.1 12.4.2 12.5 12.5.1 12.5.2 12.5.3 12.5.4 12.5.5 12.5.6 12.5.7 12.5.8 12.5.9 12.6 12.7 12.8 12.9
Overflow Interrupt ..................................................................................... 100 INT Instruction Interrupt............................................................................ 100 Special Interrupts...................................................................................... 101 Peripheral Function Interrupts .................................................................. 101 Fixed Vector Tables .................................................................................. 102 Relocatable Vector Tables ........................................................................ 103 I Flag......................................................................................................... 107 IR Bit......................................................................................................... 107 Bits ILVL2 to ILVL0 and IPL ...................................................................... 107 Interrupt Sequence ................................................................................... 108 Interrupt Response Time .......................................................................... 109 Variation of IPL when Interrupt Request IS Accepted .............................. 109 Saving Registers ...................................................................................... 110 Returning from an Interrupt Routine ..........................................................111 Interrupt Priority .........................................................................................111
Hardware Interrupts......................................................................................... 101
Interrupts and Interrupt Vector......................................................................... 102
Interrupt Control .............................................................................................. 105
12.5.10 Interrupt Priority Level Select Circuit .........................................................111 INT Interrupt .................................................................................................... 113 NMI Interrupt ................................................................................................... 115 Key Input Interrupt........................................................................................... 115 Address Match Interrupt .................................................................................. 116
13. Watchdog Timer ................................................................................... 118
13.1 13.2 Count Source Protection Mode Disabled ........................................................ 121 Count Source Protection Mode Enabled ......................................................... 122
14. DMAC................................................................................................... 123
14.1 Transfer Cycles ............................................................................................... 129 Effect of Source and Destination Addresses ............................................ 129 Effect of BYTE Pin Level .......................................................................... 129 Effect of Software Wait ............................................................................. 129 Effect of RDY Signal................................................................................. 129 14.1.1 14.1.2 14.1.3 14.1.4 14.2 14.3
DMA Transfer Cycles ...................................................................................... 131 DMA Enabled .................................................................................................. 132
1- 4
14.4 14.5
DMA Request .................................................................................................. 132 Channel Priority and DMA Transfer Timing..................................................... 133
15. Timers.................................................................................................. 134
15.1 Timer A ............................................................................................................ 137 Timer Mode .............................................................................................. 143 Event Counter Mode................................................................................. 144 One-Shot Timer Mode .............................................................................. 149 Pulse Width Modulation (PWM) Mode...................................................... 151 Timer Mode .............................................................................................. 158 Event Counter Mode................................................................................. 160 Pulse Period and Pulse Width Measurement Modes ............................... 162 15.1.1 15.1.2 15.1.3 15.1.4 15.2 15.2.1 15.2.2 15.2.3
Timer B ............................................................................................................ 154
16. Three-Phase Motor Control Timer Function ......................................... 165 17. Serial Interface ..................................................................................... 175
17.1 UARTi (i = 0 to 2, 5 to 7).................................................................................. 175 Clock Synchronous Serial I/O Mode......................................................... 186 Clock Asynchronous Serial I/O (UART) Mode.......................................... 194 Special Mode 1 (I2C mode) ...................................................................... 202 Special Mode 2 ......................................................................................... 212 Special Mode 3 (IE mode) ........................................................................ 216 Special Mode 4 (SIM Mode) (UART2) ...................................................... 218 SI/Oi Operation Timing ............................................................................. 227 CLK Polarity Selection.............................................................................. 227 Functions for Setting an SOUTi Initial Value............................................. 228 Functions for Selecting SOUTi State after Transmission.......................... 229 17.1.1 17.1.2 17.1.3 17.1.4 17.1.5 17.1.6 17.2 17.2.1 17.2.2 17.2.3 17.2.4
SI/O3 and SI/O4 .............................................................................................. 223
18. A/D Converter....................................................................................... 230
18.1 Mode Description ............................................................................................ 234 One-Shot Mode ........................................................................................ 234 Repeat Mode ............................................................................................ 236 Single Sweep Mode.................................................................................. 238 Repeat Sweep Mode 0 ............................................................................. 240 Repeat Sweep Mode 1 ............................................................................. 242
1- 5
18.1.1 18.1.2 18.1.3 18.1.4 18.1.5
18.2 18.3 18.4 18.5
Conversion Rate.............................................................................................. 244 Extended Analog Input Pins ............................................................................ 244 Current Consumption Reducing Function ....................................................... 244 Output Impedance of Sensor under A/D Conversion ...................................... 245
19. D/A Converter....................................................................................... 246
19.1 Summary ......................................................................................................... 246
20. CRC Operation..................................................................................... 248 21. Programmable I/O Ports....................................................................... 250
21.1 21.2 21.3 21.4 Port Pi Direction Register (PDi Register, i = 0 to 10)....................................... 250 Port Pi Register (Pi Register, i = 0 to 10) ........................................................ 250 Pull-up Control Register 0 to Pull-up Control Register 2 (Registers PUR0 to PUR2) ............................................................................................... 250 Port Control Register (PCR Register) ............................................................. 250
22. Flash Memory Version.......................................................................... 263
22.1 Memory Map ................................................................................................... 264 Boot Mode ................................................................................................ 265 User Boot Function................................................................................... 265 ROM Code Protect Function .................................................................... 267 ID Code Check Function .......................................................................... 267 Forced Erase Function ............................................................................. 268 Standard Serial I/O Mode Disable Function ............................................. 268 EW0 Mode................................................................................................ 271 EW1 Mode................................................................................................ 271 Flash Memory Control Register (Registers FMR0, FMR1, FMR2 and FMR6)....................................................................................................... 271 Precautions on CPU Rewrite Mode.......................................................... 282 Software Commands ................................................................................ 284 Data Protect Function............................................................................... 290 Status Register ......................................................................................... 290 Full Status Check...................................................................................... 292 22.1.1 22.1.2 22.2 22.2.1 22.2.2 22.2.3 22.2.4 22.3 22.3.1 22.3.2 22.3.3 22.3.4 22.3.5 22.3.6 22.3.7 22.3.8 22.4
Functions to Prevent Flash Memory from Rewriting ....................................... 267
CPU Rewrite Mode.......................................................................................... 270
Standard Serial I/O Mode ................................................................................ 294
1- 6
22.4.1 22.4.2 22.5 22.5.1
ID Code Check Function .......................................................................... 294 Example of Circuit Application in the Standard Serial I/O Mode............... 298 ROM Code Protect Function .................................................................... 300
Parallel I/O Mode............................................................................................. 300
23. Electrical Characteristics ...................................................................... 301
23.1 Electrical Characteristics ................................................................................. 301
24. Precautions .......................................................................................... 341
24.1 24.2 SFR ................................................................................................................. 341 Register Settings ...................................................................................... 341 VCC1 ........................................................................................................ 342 CNVSS ..................................................................................................... 342 Reset ............................................................................................................... 342 24.1.1 24.2.1 24.2.2 24.3 24.4 24.5 24.6 24.7
Bus .................................................................................................................. 343 PLL Frequency Synthesizer ............................................................................ 344 Power Control.................................................................................................. 345 Protect ............................................................................................................. 347 Interrupt ........................................................................................................... 348 Reading address 00000h ......................................................................... 348 SP Setting................................................................................................. 348 NMI Interrupt............................................................................................. 348 Changing an Interrupt Generate Factor.................................................... 349 INT Interrupt ............................................................................................. 349 Rewriting the Interrupt Control Register ................................................... 350 Watchdog Timer Interrupt ......................................................................... 351 Write to the DMAE Bit in the DMiCON Register (i = 0 to 3)...................... 352 Timer A ..................................................................................................... 353 Timer B ..................................................................................................... 357
24.7.1 24.7.2 24.7.3 24.7.4 24.7.5 24.7.6 24.7.7 24.8 24.9 24.8.1 24.9.1 24.9.2
DMAC.............................................................................................................. 352 Timers ............................................................................................................. 353
24.10 Serial Interface ................................................................................................ 360 24.10.1 Clock Synchronous Serial I/O................................................................... 360 24.10.2 UART (Clock Asynchronous Serial I/O) Mode.......................................... 362 24.10.3 Special Mode 1 (I2C Mode) ...................................................................... 362 24.10.4 Special Mode 4 (SIM Mode) ..................................................................... 362
1- 7
24.10.5 SI/O3, SI/O4 ............................................................................................. 363 24.11 A/D Converter.................................................................................................. 364 24.12 Programmable I/O Ports.................................................................................. 366 24.13 Flash Memory Version..................................................................................... 367 24.13.1 Functions to Inhibit Rewriting Flash Memory............................................ 367 24.13.2 Stop Mode ................................................................................................ 367 24.13.3 Wait Mode ................................................................................................ 367 24.13.4 Low Power Consumption Mode, On-Chip Oscillator Low Power Consumption Mode ................................. 367 24.13.5 Writing Command and Data ..................................................................... 367 24.13.6 Program Command .................................................................................. 367 24.13.7 Lock Bit Program Command .................................................................... 367 24.13.8 Operation Speed....................................................................................... 368 24.13.9 Instructions Inhibited against Use............................................................. 368 24.13.10 Interrupts .................................................................................................. 368 24.13.11 How to Access.......................................................................................... 368 24.13.12 Writing in the User ROM Area .................................................................. 368 24.13.13 DMA transfer ............................................................................................ 368 24.13.14 Programming / Erasing Endurance and Execution Time.......................... 369 24.14 Noise ............................................................................................................... 370
Appendix 1.Package Dimensions ................................................................ 371 Register Index Appendix 1-372
1- 8
PRELIMINARY
M16C/64 Group
RENESAS MCU
1.
1.1
Overview
Features
The M16C/64 Group MCUs incorporate the M16C/60 Series CPU core and flash memory, employing sophisticated instructions for a high level of efficiency. With 1 Mbyte of address space (expandable to 4 Mbyte), this MCU is capable of executing instructions at high speed. In addiditon, the CPU core boasts a multiplier for high-speed operation processing. Power consumption is low, and the M16C/64 Group supports operating modes that allow additional power control. The MCU also uses an anti-noise configuration to reduce emissions of electromagnetic noise and is designed to withstand EMI. Integration of many peripheral functions, including multifunction timer and serial interface, reduces the number of system components.
1.1.1
Applications
Audio, cameras, television, home appliance, office equipment, communication equipment, portable equipment, industrial equipment, etc.
REJ09B0392-0064 Rev.0.64 Page 1 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
1.2
Specifications
Tables 1.1 and 1.2 list Specifications Outline. Table 1.1
Item CPU
Specifications (1)
Function Central processing unit Specification M16C/60 core (multiplier: 16-bit x 16-bit ! 32 bits, multiply and accumulate instruction: 16 x 16 + 32 !32 bits) * Number of basic instructions: 91 * Minimum instruction execution time: 40.0 ns ( f(BCLK) = 25 MHz, VCC1 = VCC2 = 2.7 to 5.5 V) * Operating modes: Single-chip, memory expansion, and microprocessor See Table 1.3 Product List. Low-voltage detection unit * 4 circuits: Main clock, sub clock, on-chip oscillator (125 kHz), PLL * Oscillation stop detection: Main clock oscillation stop detection and reoscillation detection function * Frequency divider circuit: Divide ratio selectable from 1, 2, 4, 8 and 16 * Low-power consumption modes: Wait mode, stop mode * Address space: 1 Mbyte * External bus interface: 0 to 3 waits states, chip select 4 outputs, memory area expansion function (up to 4 Mbytes), 3 V, 5 V interface * Bus format: Separate bus or multiplexed bus selectable, data bus width selectable (8 or 16 bits), number of address buses selectable (12, 16, or 20 buses) * CMOS I/O ports: 85, selectable pull-up resistor * Nch open drain ports: 3 * Interrupt vectors: 70 * External interrupt input: 13 (NMI, INT x 8, key input x 4) * Interrupt priority levels: 7 15 bits x 1 (with prescaler) Automatic reset start function selectable * 4 channels, cycle steal mode * Trigger sources: 43 * Transfer modes: 2 (single transfer, repeat transfer) 16-bit timer x 5 Timer mode, event counter mode, one shot timer mode, pulse width modulation (PWM) mode Event counter two-phase pulse signal processing (two-phase encoder input) x 3 channels 16-bit timer x 6 Timer mode, event counter mode, pulse period measurement mode, pulse width measurement mode Three-phase inverter control (timer A1, timer A2, timer A4, timer B2), On-chip dead time timer Clock synchronous/asynchronous x 6 channels I2C-bus, IEBus (1), special mode 2, SIM (UART2) Clock synchronization only x 2 channels
Memory Voltage Detection Clock
ROM, RAM, data flash Voltage detection circuit Clock generation circuit
External Bus Bus and memory expansion Expansion
I/O Ports Interrupts
Programmable I/O ports
Watchdog Timer DMA DMAC
Timer
Timer A
Timer B
Timer functions for threephase motor control Serial Interface UART0 to UART2, UART5 to UART7 SI/O3, SI/O4
NOTE: 1. IEBus is a registered trademark of NEC Electronics Corporation.
REJ09B0392-0064 Rev.0.64 Page 2 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
Table 1.2
Item A/D Converter D/A Converter
Specifications (2)
Function Specification 10-bit resolution x 26 channels, including sample and hold function, Conversion time: 1.72 s 8-bit resolution x 2 CRC-CCITT (X16 + X12 + X5 + 1) compliant Programming and erasure power supply voltage: 2.7 V to 5.5 V Programming and erasure endurance: 100 times Program security: ROM code protect, ID code check Functions on-chip debug, on-board flash rewrite function, address match x 4 25 MHz/VCC1 = VCC2 = 2.7 to 5.5 V 20 mA (25 MHz/VCC1 = VCC2 = 3 V) 3.0 A(VCC1 = VCC2 = 3 V, in stop mode) -20C to 85C, -40C to 85C 100-pin QFP: PRQP0100JD-B (Previous package code: 100P6F-A) 100-pin LQFP: PLQP0100KB-A (Previous package code: 100P6Q-A)
CRC Calculation Circuit Flash Memory
Debug Function Operation Frequency/Supply Voltage Power Consumption Operating Temperature Package
REJ09B0392-0064 Rev.0.64 Page 3 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
1.3
Product List
Table 1.3 lists product information. Figure 1.1 shows part numbers, memory sizes, and packages. Table 1.3 Product List ROM Capacity Part No. R5F36406NFA R5F36406NFB R5F3640DNFA R5F3640DNFB R5F3640MNFA R5F3640MNFB R5F36406DFA R5F36406DFB R5F3640DDFA R5F3640DDFB R5F3640MDFA R5F3640MDFB Program ROM 1 RAM Program Data Flash Capacity ROM 2 Package Code Remarks
(D) 128 Kbytes 16 Kbytes 4 Kbytes 12 Kbytes PRQP0100JD-B Operating x 2 blocks (D) PLQP0100KB-A temperature -20C to 85C (D) 256 Kbytes 16 Kbytes 4 Kbytes 16 Kbytes PRQP0100JD-B x 2 blocks (D) PLQP0100KB-A (D) 512 Kbytes 16 Kbytes 4 Kbytes 31 Kbytes PRQP0100JD-B x 2 blocks (D) PLQP0100KB-A (D) 128 Kbytes 16 Kbytes 4 Kbytes 12 Kbytes PRQP0100JD-B Operating x 2 blocks (D) PLQP0100KB-A temperature -40C to 85C (D) 256 Kbytes 16 Kbytes 4 Kbytes 16 Kbytes PRQP0100JD-B x 2 blocks (D) PLQP0100KB-A (D) 512 Kbytes 16 Kbytes 4 Kbytes 31 Kbytes PRQP0100JD-B x 2 blocks (D) PLQP0100KB-A
(D) : Under development NOTE: 1. Previous package codes are as follows. PRQP0100JD-B: 100P6F-A, PLQP0100KB-A: 100P6Q-A
Part No. R 5 F 3
640
6
D
FA
Package type: FA: Package PRQP0100JD-B (100P6F-A) FB: Package PLQP0100KB-A (100P6Q-A) Property Code N: Operating temperature -20C to 85C D: Operating temperature -40C to 85C Memory capacity Program ROM 1 / RAM 6: 128 Kbytes / 12 Kbytes D: 256 Kbytes / 16 Kbytes M: 512 Kbytes / 31 Kbytes M16C / 64 Group 16-bit microcomputer Memory type: F: Flash memory Renesas microcomputer Renesas semiconductor
Figure 1.1
Correspondence of Part No., with Memory Size and Package
REJ09B0392-0064 Rev.0.64 Page 4 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
M1 6 C R 5 F 3 6 4 0 6 DF A XXXXXXX
Part No. (See Figure 1.1 Correspondence of Part No., with Memory Size and Package ) Date code seven digits
Figure 1.2
Marking Diagram of Flash Memory Version (Top View)
REJ09B0392-0064 Rev.0.64 Page 5 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
1.4
Block Diagram
Figure 1.3 is a M16C/64 Group Block Diagram.
8
8
8
8
8
8
Port P0
Port P1
Port P2
Port P3
Port P4
Port P5
VCC2 ports
Internal peripheral functions
Timer (16-bit) Outputs (Timer A): 5 Inputs (Timer B): 6
Three-phase motor control circuit
UART or clock synchronous serial I/O (6 channels) Clock synchronous serial I/O
(8 bits x 2 channels)
Clock generation circuits
XIN-XOUT XCIN-XCOUT
PLL frequency synthesizer On-chip oscillator (125 kHz) DMAC (4 channels)
CRC calculation circuit (CCITT) (Polynomial X16 + X12 + X5 + 1)
Watchdog timer (15 bits) A/D converter (10 bits x 26 channels) D/A converter (8 bits x 2 channels)
M16C/60 Series CPU core
R0H R1H R2 R3 A0 A1 FB R0L R1L SB USP ISP INTB PC FLG
Memory ROM (1) RAM (2)
Multiplier
VCC1 ports
Port P10 8
Port P9 8
Port P8 8
Port P7 8
Port P6 8
NOTES : 1. ROM size depends on MCU type. 2. RAM size depends on MCU type.
Figure 1.3
Block Diagram
REJ09B0392-0064 Rev.0.64 Page 6 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
1.5
Pin Assignments
Figures 1.4 and 1.5 show pin assignments (top view).
(3) P1_0/CTS6/RTS6/D8 P1_1/CLK6/D9 P1_2/RXD6/SCL6/D10 P1_3/TXD6/SDA6/D11 P1_4/D12 P1_5/INT3/D13 P1_6/INT4/D14 P1_7/INT5/D15 P2_0/AN2_0/A0, [A0/D0], A0 P2_1/AN2_1/A1, [A1/D1], [A1/D0] P2_2/AN2_2/A2, [A2/D2], [A2/D1] P2_3/AN2_3/A3, [A3/D3], [A3/D2] P2_4/INT6/AN2_4/A4, [A4/D4], [A4/D3] P2_5/INT7/AN2_5/A5, [A5/D5], [A5/D4] P2_6/AN2_6/A6, [A6/D6], [A6/D5] P2_7/AN2_7/A7, [A7/D7], [A7/D6] VSS P3_0/A8 [A8/D7] VCC2 P3_1/A9 P3_2/A10 P3_3/A11 P3_4/A12 P3_5/A13 P3_6/A14 P3_7/A15 P4_0/A16 P4_1/A17 P4_2/A18 P4_3/A19
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51
P0_7/AN0_7/D7 P0_6/AN0_6/D6 P0_5/AN0_5/D5 P0_4/AN0_4/D4 P0_3/AN0_3/D3 P0_2/AN0_2/D2 P0_1/AN0_1/D1 P0_0/AN0_0/D0 P10_7/AN7/KI3 P10_6/AN6/KI2 P10_5/AN5/KI1 P10_4/AN4/KI0 P10_3/AN3 P10_2/AN2 P10_1/AN1 AVSS P10_0/AN0 VREF AVCC P9_7/ADTRG/SIN4
81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 9 10 11 1 2 3 4 5 6 7 8
VCC2 ports
50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 19 20 21 22 23 24 25 26 27 28 29 30
M16C/64 Group
PRQP0100JD-B (100P6F-A) (top view)
VCC1 ports
12 13 14 15 16 17 18
P4_4/CTS7/RTS7/CS0 P4_5/CLK7/CS1 P4_6/RXD7/SCL7/CS2 P4_7/TXD7/SDA7/CS3 P5_0/WRL/WR P5_1/WRH/BHE P5_2/RD P5_3/BCLK P5_4/HLDA P5_5/HOLD P5_6/ALE P5_7/RDY/CLKOUT P6_0/CTS0/RTS0 P6_1/CLK0 P6_2/RXD0/SCL0 P6_3/TXD0/SDA0 P6_4/CTS1/RTS1/CTS0/CLKS1 P6_5/CLK1 P6_6/RXD1/SCL1 P6_7/TXD1/SDA1
NOTES: 1. N-channel open-drain output. 2. Check the position of Pin 1 by referring to appendix 1, Package Dimensions. 3. Symbols in brackets [ ] represent a functional signal as a whole.
Figure 1.4
Pin Assignment (Top View)
REJ09B0392-0064 Rev.0.64 Page 7 of 373
P9_6/ANEX1/SOUT4 P9_5/ANEX0/CLK4 P9_4/DA1/TB4IN P9_3/DA0/TB3IN P9_2/TB2IN/SOUT3 P9_1/TB1IN/SIN3 P9_0/TB0IN/CLK3 BYTE CNVSS P8_7/XCIN P8_6/XCOUT RESET XOUT VSS XIN VCC1 P8_5/NMI/SD(1) P8_4/INT2/ZP P8_3/INT1 P8_2/INT0 P8_1/TA4IN/U/CTS5/RTS5 P8_0/TA4OUT/U/RXD5/SCL5 P7_7/TA3IN/CLK5 P7_6/TA3OUT/TXD5/SDA5 P7_5/TA2IN/W P7_4/TA2OUT/W P7_3/CTS2/RTS2/TA1IN/V P7_2/CLK2/TA1OUT/V P7_1/RXD2/SCL2/TA0IN/TB5IN(1) P7_0/TXD2/SDA2/TA0OUT(1)
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
(3) P1_3/TXD6/SDA6/D11 P1_4/D12 P1_5/INT3/D13 P1_6/INT4/D14 P1_7/INT5/D15 P2_0/AN2_0/A0, [A0/D0], A0 P2_1/AN2_1/A1, [A1/D1], [A1/D0] P2_2/AN2_2/A2, [A2/D2], [A2/D1] P2_3/AN2_3/A3, [A3/D3], [A3/D2] P2_4/INT6/AN2_4/A4, [A4/D4], [A4/D3] P2_5/INT7/AN2_5/A5, [A5/D5], [A5/D4] P2_6/AN2_6/A6, [A6/D6], [A6/D5] P2_7/AN2_7/A7, [A7/D7], [A7/D6] VSS P3_0/A8 [A8/D7] VCC2 P3_1/A9 P3_2/A10 P3_3/A11 P3_4/A12 P3_5/A13 P3_6/A14 P3_7/A15 P4_0/A16 P4_1/A17
75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59
P1_2/RXD6/SCL6/D10 P1_1/CLK6/D9 P1_0/CTS6/RTS6/D8 P0_7/AN0_7/D7 P0_6/AN0_6/D6 P0_5/AN0_5/D5 P0_4/AN0_4/D4 P0_3/AN0_3/D3 P0_2/AN0_2/D2 P0_1/AN0_1/D1 P0_0/AN0_0/D0 P10_7/AN7/KI3 P10_6/AN6/KI2 P10_5/AN5/KI1 P10_4/AN4/KI0 P10_3/AN3 P10_2/AN2 P10_1/AN1 AVSS P10_0/AN0 VREF AVCC P9_7/ADTRG/SIN4 P9_6/ANEX1/SOUT4 P9_5/ANEX0/CLK4
76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100
58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30
VCC2 ports
M16C/64 Group
PLQP0100KB-A (100P6Q-A) (top view)
VCC1 ports
29 28 27 26
P4_2/A18 P4_3/A19 P4_4/CTS7/RTS7/CS0 P4_5/CLK7/CS1 P4_6/RXD7/SCL7/CS2 P4_7/TXD7/SDA7/CS3 P5_0/WRL/WR P5_1/WRH/BHE P5_2/RD P5_3/BCLK P5_4/HLDA P5_5/HOLD P5_6/ALE P5_7/RDY/CLKOUT P6_0/CTS0/RTS0 P6_1/CLK0 P6_2/RXD0/SCL0 P6_3/TXD0/SDA0 P6_4/CTS1/RTS1/CTS0/CLKS1 P6_5/CLK1 P6_6/RXD1/SCL1 P6_7/TXD1/SDA1 P7_0/TXD2/SDA2/TA0OUT(1) P7_1/RXD2/SCL2/TA0IN/TB5IN(1) P7_2/CLK2/TA1OUT/V
6 7 8 9 10 11 12 13 14 15 16 17 18 19
NOTES: 1. N-channel open-drain output. 2. Check the position of Pin 1 by referring to appendix 1, Package Dimensions. 3. Symbols in brackets [ ] represent a functional signal as a whole.
Figure 1.5
Pin Assignment (Top View)
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P9_4/DA1/TB4IN P9_3/DA0/TB3IN P9_2/TB2IN/SOUT3 P9_1/TB1IN/SIN3 P9_0/TB0IN/CLK3 BYTE CNVSS P8_7/XCIN P8_6/XCOUT RESET XOUT VSS XIN VCC1 P8_5/NMI/SD(1) P8_4/INT2/ZP P8_3/INT1 P8_2/INT0 P8_1/TA4IN/U/CTS5/RTS5 P8_0/TA4OUT/U/RXD5/SCL5 P7_7/TA3IN/CLK5 P7_6/TA3OUT/TXD5/SDA5 P7_5/TA2IN/W P7_4/TA2OUT/W P7_3/CTS2/RTS2/TA1IN/V
Oct 12, 2007
20 21 22 23 24 25
1
2 3
4 5
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
Table 1.4
Pin No. FA FB 1 99 2 100 3 1 4 2 5 3 6 4 7 5 8 6 9 7 10 8 11 9 12 10 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48
Pin Names, for 100-Pin Package(1)
Control Pin Port P9_6 P9_5 P9_4 P9_3 P9_2 P9_1 P9_0 BYTE CNVSS XCIN XCOUT
RESET XOUT VSS XIN VCC1
Interrupt Pin
Timer Pin
UART Pin SOUT4 CLK4
Analog Pin ANEX1 ANEX0 DA1 DA0
Bus Control Pin
TB4IN TB3IN TB2IN TB1IN TB0IN
SOUT3 SIN3 CLK3
P8_7 P8_6
P8_5 P8_4 P8_3 P8_2 P8_1 P8_0 P7_7 P7_6 P7_5 P7_4 P7_3 P7_2 P7_1 P7_0 P6_7 P6_6 P6_5 P6_4 P6_3 P6_2 P6_1 P6_0 P5_7 P5_6 P5_5 P5_4 P5_3 P5_2 P5_1 P5_0 P4_7 P4_6 P4_5 P4_4
NMI INT2 INT1 INT0
SD ZP
TA4IN/U TA4OUT/U TA3IN TA3OUT TA2IN/W TA2OUT/W TA1IN/V TA1OUT/V TA0IN/TB5IN TA0OUT
CTS5/RTS5 RXD5/SCL5 CLK5 TXD5/SDA5
CTS2/RTS2 CLK2 RXD2/SCL2 TXD2/SDA2 TXD1/SDA1 RXD1/SCL1 CLK1 CTS1/RTS1/CTS0/ CLKS1 TXD0/SDA0 RXD0/SCL0 CLK0 CTS0/RTS0 RDY/CLKOUT ALE HOLD HLDA BCLK RD WRH/BHE WRL/WR
TXD7/SDA7 RXD7/SCL7 CLK7
CTS7/RTS7
CS3 CS2 CS1 CS0
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
Table 1.5
Pin Names for 100-Pin Package(2)
Port P4_3 P4_2 P4_1 P4_0 P3_7 P3_6 P3_5 P3_4 P3_3 P3_2 P3_1 P3_0 P2_7 P2_6 P2_5 P2_4 P2_3 P2_2 P2_1 P2_0 P1_7 P1_6 P1_5 P1_4 P1_3 P1_2 P1_1 P1_0 P0_7 P0_6 P0_5 P0_4 P0_3 P0_2 P0_1 P0_0 P10_7 KI3 P10_6 KI2 P10_5 KI1 P10_4 KI0 P10_3 P10_2 P10_1 AVSS P10_0 VREF AVCC P9_7 SIN4
ADTRG
Pin No. Control FA FB Pin 51 49 52 50 53 51 54 52 55 53 56 54 57 55 58 56 59 57 60 58 61 59 62 60 VCC2 63 61 64 62 VSS 65 63 66 64 67 65 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98
Interrupt Pin
Timer Pin
UART Pin
Analog Pin
Bus Control Pin A19 A18 A17 A16 A15 A14 A13 A12 A11 A10 A9 A8, [A8/D7]
INT7 INT6
AN2_7 AN2_6 AN2_5 AN2_4 AN2_3 AN2_2 AN2_1 AN2_0
A7, [A7/D7], [A7/D6] A6, [A6/D6], [A6/D5] A5, [A5/D5], [A5/D4] A4, [A4/D4], [A4/D3] A3, [A3/D3], [A3/D2] A2, [A2/D2], [A2/D1] A1, [A1/D1], [A1/D0] A0, [A0/D0], A0 D15 D14 D13 D12 D11 D10 D9 D8
INT5 INT4 INT3
TXD6/SDA6 RXD6/SCL6 CLK6
CTS6/RTS6
AN0_7 AN0_6 AN0_5 AN0_4 AN0_3 AN0_2 AN0_1 AN0_0 AN7 AN6 AN5 AN4 AN3 AN2 AN1 AN0
D7 D6 D5 D4 D3 D2 D1 D0
REJ09B0392-0064 Rev.0.64 Page 10 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
1.6
Pin Functions
Pin Functions (1)
Pin Name VCC1 VCC2 VSS AVCC AVSS
RESET
Table 1.6
Power supply input Analog power supply input Reset input CNVSS
Signal Name
I/O I
Power Supply -
Description Apply 2.7 to 5.5 V to pins VCC1 and VCC2 (VCC1 =VCC2) and 0 V to the VSS pin (1) Apply the power supply for the A/D converter. Connect the AVCC pin to VCC1. Connect the AVSS pin to VSS. Low active input pin. Driving this pin Low resets the MCU. Input pin to switch processor mode. To start up in single-chip mode after a reset, connect the CNVSS pin to VSS via resister. To start up in microprocessor mode, connect the CNVSS pin to VSS1. Input pin to select the data bus of the external memory area. The data bus is 16-bit when it is Low and 8-bit when it is High. This pin must be fixed either High or Low. Connect the BYTE pin to VSS in single-chip mode Inputs or outputs data (D0 to D7) while accessing an external memory area with separate bus Inputs or outputs data (D8 to D15) while accessing an external memory area with 16-bit separate bus Outputs address bits A0 to A19 Inputs or outputs data (D0 to D7) and outputs address bits (A0 to A7) by timesharing, while accessing an external memory area with 8-bit multiplexed bus Inputs or outputs data (D0 to D7) and outputs address bits (A1 to A8) by timesharing, while accessing an external memory area with 16-bit multiplexed bus Outputs chip-select signals CS0 to CS3 to specify an external memory area Low active output pins. Outputs WRL, WRH, (WR, BHE), RD signals. WRL and WRH can be switched with or BHE and WR can be selected by a program. WRL, WRH and RD selected If the external data bus is 16-bit, data is written to an even address in external memory area when WRL is driven low. Data is written to an odd address when WRH is driven low. Data is read when RD is driven low. WR, BHE and RD are selected Data is written to external memory area when WR is driven low. Data in external memory area is read when RD is driven low. An odd address is accessed when BHE is driven low. Select WR, BHE, and RD for external 8-bit data bus Output ALE signal to latch address. Low active input pin. The MCU is placed in hold state while the HOLD pin is driven low. Low active output pin. In a hold state, HLDA outputs a lowlevel signal. Low active input pin. The MCU is placed in wait state while the RDY pin is driven low.
I I I
VCC1 VCC1 VCC1
CNVSS
External data bus width select input Bus control pins
BYTE
I
VCC1
D0 to D7 D8 to D15 A0 to A19 A0/D0 to A7/D7 A1/D0 to A8/D7
CS0 to CS3 WRL/WR WRH/BHE RD
I/O I/O O I/O
VCC2 VCC2 VCC2 VCC2
I/O
VCC2
O O
VCC2 VCC2
ALE
HOLD HLDA RDY
O I O I
VCC2 VCC2 VCC2 VCC2
Power supply: VCC2 is used to supply power to external bus related pins. NOTE: 1. VCC1 is hereinafter referred to as VCC unless otherwise noted.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
Table 1.7
Pin Functions (2)
Pin Name XIN XOUT XCIN XCOUT BCLK CLKOUT
INT0 to INT2 INT3 to INT7 NMI KI0 to KI3
Signal Name Main clock input Main clock output Sub clock input Sub clock output BCLK output Clock output
INT interrupt input NMI interrupt input
I/O I O I O O O I I I I I/O I I I O I I I O O I/O I/O I I O O O
Power Supply VCC1 VCC1 VCC1 VCC1 VCC2 VCC2 VCC1 VCC2 VCC1 VCC1 VCC1 VCC1 VCC1 VCC1 VCC1 VCC1 VCC1 VCC2 VCC1 VCC2 VCC1 VCC2 VCC1 VCC2 VCC1 VCC2 VCC1 Serial data input pins
Description I/O pins for the main clock oscillation circuit. Connect a ceramic resonator or crystal oscillator between XIN and XOUT(1). To apply an external clock, connect it to XIN and leave XOUT open. I/O pins for a sub clock oscillation circuit. Connect a crystal oscillator between XCIN and XCOUT (1). To apply an external clock, connect it to XCIN and leave XCOUT open Output pin for BCLK signal This pin outputs the clock having the same frequency as fC, f8, or f32 Low active input pins for INT interrupt Low active input pin for NMI interrupt Low active input pins for key input interrupt Timer A0 to A4 I/O pins (TA0OUT as an output pin is N-channel open drain output) Timer A0 to A4 input pins Input pin for Z-phase Timer B0 to B5 input pins Output pins for three-phase motor control timer output
Key input interrupt input Timer A
TA0OUT to TA4OUT TA0IN to TA4IN ZP
Timer B Three-phase motor control timer Serial interface UART0 to UART2, UART5 to UART7
TB0IN to TB5IN U, U, V, V, W, W
SD CTS0 to CTS2, CTS5 CTS6, CTS7 RTS0 to RTS2, RTS5 RTS6, RTS7 CLK0 to CLK2, CLK5
Input pin for three-phase motor control timer input
Input pins to control data transmission
Output pins to control data reception
Transfer clock I/O pins
CLK6, CLK7
RXD0 to RXD2, RXD5
RXD6, RXD7
TXD0 to TXD2, TXD5
Serial data output pins(2) Output pin for transfer clock multiple-pin output function
TXD6, TXD7 CLKS1
NOTES: 1. Consult the oscillator manufacturer regarding the oscillation characteristics. 2. TXD2, SDA2, and SCL2 are N-channel open-drain output pins. TXDi (i = 0, 1, 5 to 7), SDAi, and SCLi can be selected as CMOS output pins or N-channel open-drain output pins by a program.
REJ09B0392-0064 Rev.0.64 Page 12 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
1. Overview
Table 1.8
Signal Name UART0 to UART2, UART5 to UART7 I2C mode
Pin Functions (3)
Pin Name SDA0 to SDA2, SDA5 SDA6, SDA7 SCL0 to SCL2, SCL5 SCL6, SCL7 CLKS3, CLKS4 SIN3, SIN4 SOUT3, SOUT4 I/O I/O I/O I/O I/O I/O I O I I I I I O I/O Power Supply VCC1 VCC2 VCC1 VCC2 VCC1 VCC1 VCC1 VCC1 VCC1 VCC2 VCC1 VCC1 VCC1 VCC2 Input pin for an external A/D trigger Extended analog input pin for the A/D converter Output pin for the D/A converter 8-bit CMOS I/O ports. A direction register determines whether each pin is used as an input port or an output port. A pull-up resistor may be enabled or disabled for input ports in 4-bit units. Transfer clock I/O pins Serial data input pins Serial data output pins Reference voltage input pins for the A/D converter and D/A converter. Connect to VCC1. Analog input pins for the A/D converter Transfer clock I/O pins (1) Serial data I/O pins (1) Description
Serial interface SI/03, SI/04
Reference VREF voltage input A/D converter AN0 to AN7 AN0_0 to AN0_7 AN2_0 to AN2_7
ADTRG
ANEX0, ANEX1 D/A converter I/O port DA0, DA1 P0_0 to P0_7 P1_0 to P1_7 P2_0 to P2_7 P3_0 to P3_7 P4_0 to P4_7 P5_0 to P5_7 P6_0 to P6_7 P7_0 to P7_7 P8_0 to P8_7 P9_0 to P9_7 P10_0 to P10_7
I/O
VCC1
8-bit I/O ports having equivalent functions to P0. However, P7_0, P7_1, and P8_5 are N-channel open-drain output ports. No pull-up resistor is provided. P8_5 is an input port for verifying the NMI pin level and shares a pin with NMI.
NOTE: 1. TXD2, SDA2, and SCL2 are N-channel open drain output pins. TXDi (i = 0, 1, 5 to 7), SDAi, SCLi can be selected as CMOS output pin or N-channel open drain output pin by program.
REJ09B0392-0064 Rev.0.64 Page 13 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
2. Central Processing Unit (CPU)
2.
Central Processing Unit (CPU)
Figure 2.1 shows the CPU registers. Seven registers (R0, R1, R2, R3, A0, A1, and FB) out of thirteen registers configure a register bank. There are two sets of register banks.
b31
b15
b8 b7
b0
R2 R3
R0H(high order bits of R0) R0L (loworder bits of R0) R1H(high order bits of R1) R1L (loworder bits of R1)
R2 R3 A0 A1 FB
b19
Data registers (1)
Address registers (1) Frame base registers (1)
b0
b15
INTBH
INTBL
Interrupt table register
INTBH is 4 high-order bits of INTB register and INTBL is 16 low-order bits of INTB register
b19 b0
PC
b15 b0
Program counter
USP ISP SB
b15 b0
User stack pointer Interrupt stack pointer Static base register
FLG
b15 b8 b7 b0
Flag register
IPL
UI
OB S Z DC
Carry flag Debug flag Zero flag Sign flag Register bank select flag Overflow flag Interrupt enable flag Stack pointer select flag Reserved area Processor interrupt priority level Reserved area
NOTE: 1. These registers comprise a register bank. There are two sets of register banks.
Figure 2.1
Central Processing Unit Register
2.1
Data Registers (R0, R1, R2 and R3)
The R0, R1, R2, and R3 are 16-bit registers used for transfer, arithmetic and logic operations. R0 and R1 can be split into high-order (R0H/R1H) and low-order bits (R0L/R1L) to be used separately as 8-bit data registers. R0 can be combined with R2 and used as a 32-bit data register (R2R0). The same applies to R3R1.
REJ09B0392-0064 Rev.0.64 Page 14 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
2. Central Processing Unit (CPU)
2.2
Address Registers (A0 and A1)
A0 and A1 are 16-bit registers used for A0-/A1-indirect addressing, A0-/A1-relative addressing, transfer, arithmetic and logic operations. A0 can be combined with A1 and used as a 32-bit address register (A1A0).
2.3
Frame Base Registers (FB)
FB is configured with 16 bits, and is used for FB relative addressing.
2.4
Interrupt Table Register (INTB)
INTB is a 20-bit register indicating the start address of an relocatable interrupt vector table.
2.5
Program Counter (PC)
PC is 20 bits wide and indicates the address of the next instruction to be executed.
2.6
User Stack Pointer (USP) and Interrupt Stack Pointer (ISP)
The stack pointers (SP), as USP and ISP, are each 16 bits wide. The U flag is used to switch between USP and ISP.
2.7
Static Base Register (SB)
SB is a 16-bit register used for SB-relative addressing.
2.8
Flag Register (FLG)
FLG is a 11-bit register indicating the CPU state.
2.8.1
Carry Flag (C Flag)
The C flag retains a carry, borrow, or shift-out bit that has been generated by the arithmetic/logic unit.
2.8.2
Debug Flag (D Flag)
The D flag is for debugging purpose only. Set it to 0.
2.8.3
Zero Flag (Z Flag)
The Z flag is set to 1 when an arithmetic operation results in 0; otherwise to 0.
2.8.4
Sign Flag (S Flag)
The S flag is set to 1 when an arithmetic operation results in a negative value; otherwise to 0.
2.8.5
Register Bank Select Flag (B Flag)
Register bank 0 is selected when the B flag is set to 0. Register bank 1 is selected when this flag is set to 1.
2.8.6
Overflow Flag (O Flag)
The O flag is set to 1 when an arithmetic operation results in an overflow; otherwise to 0.
2.8.7
Interrupt Enable Flag (I Flag)
The I flag enables maskable interrupts. Maskable interrupts are disabled when the I flag is set to 0, and enabled when it is set to 1. The I flag is set to 0 when an interrupt request is acknowledged.
REJ09B0392-0064 Rev.0.64 Page 15 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
2. Central Processing Unit (CPU)
2.8.8
Stack Pointer Select Flag (U Flag)
ISP is selected when the U flag is set to 0; USP is selected when the U flag is set to 1. The U flag is set to 0 when a hardware interrupt request is acknowledged or the INT instruction of software interrupt number 0 to 31 is executed.
2.8.9
Processor Interrupt Priority Level (IPL)
IPL is 3 bits wide and assigns processor interrupt priority levels from level 0 to level 7. If a requested interrupt has higher priority than IPL, the interrupt is enabled.
2.8.10
Reserved Space
Only write 0 to bits assigned as reserved bits. The read value is undefined.
REJ09B0392-0064 Rev.0.64 Page 16 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
3. Memory
3.
Memory
Figure 3.1 is a memory map of the M16C/64 Group. The M16C/64 Group has 1 Mbyte address space from address 00000h to FFFFFh. The internal ROM is flash memory. Program ROM 1 is allocated from address FFFFFh to lower. For example, a 64-Kbyte program ROM 1 is addressed from F0000h to FFFFFh. An 8-Kbyte data flash is addressed from 0E000h to 0FFFFh. This data flash space is used not only for data storage but also for program storage. Program ROM 2 is allocated addresses 10000h to 13FFFh. The user boot code area is assigned addresses 13FF0h to 13FFFh in the program ROM 2. The fixed interrupt vectors are addressed from FFFDCh to FFFFFh. They store the starting address of each interrupt routine. The internal RAM is allocated from address 00400h to higher. For example, a 10-Kbyte internal RAM is addressed from 00400h to 02BFFh. The internal RAM is used not only for data storage but also for stack area when subroutines are called or when interrupt request are acknowledged. SFRs are allocated from address 00000h to 003FFh and from 0D000h to 0D7FFh. Peripheral function control registers are located here. All blank spaces within SFRs are reserved and cannot be accessed by users. The special page vectors are addressed from FFE00h to FFFD7h. They are used for the JMPS instruction and JSRS instruction. Refer to the M16C/60, M16C/20 Series Software Manual for details. In memory expansion mode or microprocessor mode, some spaces are reserved and cannot be accessed by users.
00000h SFR 00400h Internal RAM XXXXXh 0D000h Reserved area 13FF0h SFR 0D800h External area 0E000h 10000h 14000h 27000h 28000h Internal RAM Size Address XXXXXh 12 Kbytes 16 Kbytes 31 Kbytes 033FFh 043FFh 07FFFh Internal ROM Size 128 Kbytes 256 Kbytes 512 Kbytes Address YYYYYh E0000h C0000h 80000h FFFFFh External area 80000h YYYYYh Internal ROM (program ROM 1) FFFFFh Reserved area (2) Internal ROM (data flash) Internal ROM (program ROM 2) External area Reserved area FFE00h FFFD8h FFFDCh 13FFFh User boot code area
Special page vector table Reserved area Undefined instruction Overflow BRK instruction Address match Single step Watchdog timer DBC NMI Reset
NOTES:
1. This memory map is based on the case that the PM10 bit in the PM1 register is 1, the PM13 bit in the PM1 register is 1, and the PRG2C0 bit in the PRG2C register is 0. 2. Available as external area in microprocessor mode.
Figure 3.1
Memory Map
REJ09B0392-0064 Rev.0.64 Page 17 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
4.
Special Function Registers (SFRs)
An SFR (Special Function Register) is a control register for a peripheral function. Tables 4.1 to 4.14 list SFR information.
Table 4.1
Address
0000h 0001h 0002h 0003h 0004h 0005h 0006h 0007h 0008h 0009h 000Ah 000Bh 000Ch 000Dh 000Eh 000Fh 0010h 0011h 0012h 0013h 0014h 0015h 0016h 0017h 0018h 0019h 001Ah 001Bh 001Ch 001Dh 001Eh 001Fh 0020h 0021h 0022h 0023h 0024h 0025h 0026h 0027h 0028h 0029h 002Ah 002Bh 002Ch 002Dh 002Eh 002Fh NOTES: X: Undefined 1. The blank areas are reserved and cannot be accessed by users. 2. Software reset, watchdog timer reset, and oscillation stop detection reset do not affect bits PM01 and PM00 in the PM0 register, and registers VCR1, VCR2, and VW0C. 3. Oscillation stop detection reset do not affect bits CM20, CM21, and CM27. 4. The CWR bit in the RSTFR register is set to 0 after brown-out reset. This bit does not change by any other reset.
SFR Information (1) (1)
Register Symbol After Reset
Processor Mode Register 0 Processor Mode Register 1 System Clock Control Register 0 System Clock Control Register 1 Chip Select Control Register Protect Register Data Bank Register Oscillation Stop Detection Register
PM0 PM1 CM0 CM1 CSR PRCR DBR CM2
00000000b (CNVSS pin is "L") 00000011b(CNVSS pin is "H") (2) 00001000b 01001000b 00100000b 00000001b 00h 00h 0X000010b (3)
Program 2 Area Control Register Peripheral Clock Select Register
PRG2C PCLKR
XXXXXXX0b 00000011b
Clock Prescaler Reset Flag
CPSRF
0XXXXXXXb
Reset Source Determine Flag Voltage Detection 2 Circuit Flag Register Voltage Detection Circuit Operation Enable Register Chip Select Expansion Control Register PLL Control Register 0 Processor Mode Register 2 Low Voltage Detection Interrupt Register
RSTFR VCR1 VCR2 CSE PLC0 PM2 D4INT
0XXXXXXXb (4) 00001000b (2) 000X0000b (Hardware reset 1) 001X0000b (Brown-out reset) (2) 00h 0X01X010b XXX00X01b (2) 00h
Voltage Monitor 0 Circuit Control Register
VW0C
10001X10b (Hardware Reset 1) 11001X11b (Brown-out reset) (2)
REJ09B0392-0064 Rev.0.64 Page 18 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.2
Address
0030h 0031h 0032h 0033h 0034h 0035h 0036h 0037h 0038h 0039h 003Ah 003Bh 003Ch 003Dh 003Eh 003Fh 0040h 0041h 0042h 0043h 0044h 0045h 0046h 0047h 0048h 0049h 004Ah 004Bh 004Ch 004Dh 004Eh 004Fh 0050h 0051h 0052h 0053h 0054h 0055h 0056h 0057h 0058h 0059h 005Ah 005Bh 005Ch 005Dh 005Eh 005Fh NOTE: 1.
SFR Information (2) (1)
Register Symbol After Reset
INT7 Interrupt Control Register INT6 Interrupt Control Register INT3 Interrupt Control Register Timer B5 Interrupt Control Register Timer B4 Interrupt Control Register, UART1 BUS Collision Detection Interrupt Control Register Timer B3 Interrupt Control Register, UART0 BUS Collision Detection Interrupt Control Register SI/O4 Interrupt Control Register, INT5 Interrupt Control Register SI/O3 Interrupt Control Register, INT4 Interrupt Control Register UART2 BUS Collision Detection Interrupt Control Register DMA0 Interrupt Control Register DMA1 Interrupt Control Register Key Input Interrupt Control Register A/D Conversion Interrupt Control Register UART2 Transmit Interrupt Control Register UART2 Receive Interrupt Control Register UART0 Transmit Interrupt Control Register UART0 Receive Interrupt Control Register UART1 Transmit Interrupt Control Register UART1 Receive Interrupt Control Register Timer A0 Interrupt Control Register Timer A1 Interrupt Control Register Timer A2 Interrupt Control Register Timer A3 Interrupt Control Register Timer A4 Interrupt Control Register Timer B0 Interrupt Control Register Timer B1 Interrupt Control Register Timer B2 Interrupt Control Register INT0 Interrupt Control Register INT1 Interrupt Control Register INT2 Interrupt Control Register The blank areas are reserved and cannot be accessed by users.
INT7IC INT6IC INT3IC TB5IC TB4IC, U1BCNIC TB3IC, U0BCNIC S4IC, INT5IC S3IC, INT4IC BCNIC DM0IC DM1IC KUPIC ADIC S2TIC S2RIC S0TIC S0RIC S1TIC S1RIC TA0IC TA1IC TA2IC TA3IC TA4IC TB0IC TB1IC TB2IC INT0IC INT1IC INT2IC
XX00X000b XX00X000b XX00X000b XXXXX000b XXXXX000b XXXXX000b XX00X000b XX00X000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XX00X000b XX00X000b XX00X000b X: Undefined
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.3
Address
0060h 0061h 0062h 0063h 0064h 0065h 0066h 0067h 0068h 0069h 006Ah 006Bh 006Ch 006Dh 006Eh 006Fh 0070h 0071h 0072h 0073h 0074h 0075h 0076h 0077h 0078h 0079h 007Ah 007Bh 007Ch 007Dh 007Eh 007Fh 0080h 0081h 0082h 0083h 0084h 0085h 0086h 0087h 0088h 0089h 008Ah 008Bh 008Ch 008Dh 008Eh 008Fh 0090h 0091h 0092h 0093h 0094h 0095h 0096h 0097h 0098h 0099h 009Ah 009Bh 009Ch 009Dh 009Eh 009Fh to 015Fh NOTE: 1.
SFR Information (3) (1)
Register Symbol After Reset
DMA2 Interrupt Control Register DMA3 Interrupt Control Register UART5 BUS Collision Detection Interrupt Control Register UART5 Transmit Interrupt Control Register UART5 Receive Interrupt Control Register UART6 BUS Collision Detection Interrupt Control Register UART6 Transmit Interrupt Control Register UART6 Receive Interrupt Control Register UART7 BUS Collision Detection Interrupt Control Register UART7 Transmit Interrupt Control Register UART7 Receive Interrupt Control Register
DM2IC DM3IC U5BCNIC S5TIC S5RIC U6BCNIC S6TIC S6RIC U7BCNIC S7TIC S7RIC
XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b
X: Undefined The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.4
Address
0160h 0161h 0162h 0163h 0164h 0165h 0166h 0167h 0168h 0169h 016Ah 016Bh 016Ch 016Dh 016Eh 016Fh 0170h 0171h 0172h 0173h 0174h 0175h 0176h 0177h 0178h 0179h 017Ah 017Bh 017Ch 017Dh 017Eh 017Fh 0180h 0181h 0182h 0183h 0184h 0185h 0186h 0187h 0188h 0189h 018Ah 018Bh 018Ch 018Dh 018Eh 018Fh 0190h 0191h 0192h 0193h 0194h 0195h 0196h 0197h 0198h 0199h 019Ah 019Bh 019Ch 019Dh 019Eh 019Fh NOTE: 1.
SFR Information (4) (1)
Register Symbol After Reset
DMA0 Source Pointer
SAR0
XXh XXh 0Xh XXh XXh 0Xh XXh XXh
DMA0 Destination Pointer
DAR0
DMA0 Transfer Counter
TCR0
DMA0 Control Register
DM0CON
00000X00b
DMA1 Source Pointer
SAR1
XXh XXh 0Xh XXh XXh 0Xh XXh XXh
DMA1 Destination Pointer
DAR1
DMA1 Transfer Counter
TCR1
DMA1 Control Register
DM1CON
00000X00b
X: Undefined The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.5
Address
01A0h 01A1h 01A2h 01A3h 01A4h 01A5h 01A6h 01A7h 01A8h 01A9h 01AAh 01ABh 01ACh 01ADh 01AEh 01AFh 01B0h 01B1h 01B2h 01B3h 01B4h 01B5h 01B6h 01B7h 01B8h 01B9h 01BAh 01BBh 01BCh 01BDh 01BEh 01BFh 01C0h 01C1h 01C2h 01C3h 01C4h 01C5h 01C6h 01C7h 01C8h 01C9h 01CAh 01CBh 01CCh 01CDh 01CEh 01CFh 01D0h 01D1h 01D2h 01D3h 01D4h 01D5h 01D6h 01D7h 01D8h 01D9h 01DAh 01DBh 01DCh 01DDh 01DEh 01DFh NOTE: 1.
SFR Information (5) (1)
Register
DMA2 Source Pointer
Symbol
SAR2 XXh XXh 0Xh XXh XXh 0Xh XXh XXh
After Reset
DMA2 Destination Pointer
DAR2
DMA2 Transfer Counter
TCR2
DMA2 Control Register
DM2CON
00000X00b
DMA3 Source Pointer
SAR3
XXh XXh 0Xh XXh XXh 0Xh XXh XXh
DMA3 Destination Pointer
DAR3
DMA3 Transfer Counter
TCR3
DMA3 Control Register
DM3CON
00000X00b
Timer B Count Source Select Register 0 Timer B Count Source Select Register 1
TBCS0 TBCS1
00h X0h
Timer A Count Source Select Register 0 Timer A Count Source Select Register 1 Timer A Count Source Select Register 2
TACS0 TACS1 TACS2
00h 00h X0h
Timer A Waveform Output Function Select Register
TAPOFS
XXX00000b
X: Undefined The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.6
Address
01E0h 01E1h 01E2h 01E3h 01E4h 01E5h 01E6h 01E7h 01E8h 01E9h 01EAh 01EBh 01ECh 01EDh 01EEh 01EFh 01F0h 01F1h 01F2h 01F3h 01F4h 01F5h 01F6h 01F7h 01F8h 01F9h 01FAh 01FBh 01FCh 01FDh 01FEh 01FFh 0200h 0201h 0202h 0203h 0204h 0205h 0206h 0207h 0208h 0209h 020Ah 020Bh 020Ch 020Dh 020Eh 020Fh 0210h 0211h 0212h 0213h 0214h 0215h 0216h 0217h 0218h 0219h 021Ah 021Bh 021Ch 021Dh 021Eh 021Fh NOTE: 1.
SFR Information (6) (1)
Register Symbol After Reset
Timer B Count Source Select Register 2 Timer B Count Source Select Register 3
TBCS2 TBCS3
00h X0h
Interrupt Source Select Register 3 Interrupt Source Select Register 2 Interrupt Source Select Register
IFSR3A IFSR2A IFSR
00h 00h 00h
Address Match Interrupt Enable Register Address Match Interrupt Enable Register 2 Address Match Interrupt Register 0
AIER AIER2 RMAD0
XXXXXX00b XXXXXX00b 00h 00h X0h 00h 00h X0h 00h 00h X0h 00h 00h X0h X: Undefined
Address Match Interrupt Register 1
RMAD1
Address Match Interrupt Register 2
RMAD2
Address Match Interrupt Register 3
RMAD3
The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.7
Address
0220h 0221h 0222h 0223h 0224h 0225h 0226h 0227h 0228h 0229h 022Ah 022Bh 022Ch 022Dh 022Eh 022Fh 0230h 0231h 0232h 0233h 0234h 0235h 0236h 0237h 0238h 0239h 023Ah 023Bh 023Ch 023Dh 023Eh 023Fh 0240h 0241h 0242h 0243h 0244h 0245h 0246h 0247h 0248h 0249h 024Ah 024Bh 024Ch 024Dh 024Eh 024Fh 0250h 0251h 0252h 0253h 0254h 0255h 0256h 0257h 0258h 0259h 025Ah 025Bh 025Ch 025Dh 025Eh 025Fh NOTE: 1.
SFR Information (7) (1)
Register
Flash Memory Control Register 0 Flash Memory Control Register 1 Flash Memory Control Register 2
Symbol
FMR0 FMR1 FMR2
After Reset
00000001b 00X0XX0Xb XXXX0000b
Flash Memory Control Register 6
FMR6
XX0XXX00b
UART0 Special Mode Register 4 UART0 Special Mode Register 3 UART0 Special Mode Register 2 UART0 Special Mode Register UART0 Transmit/Receive Mode Register UART0 Bit Rate Register UART0 Transmit Buffer Register UART0 Transmit/Receive Control Register 0 UART0 Transmit/Receive Control Register 1 UART0 Receive Buffer Register UART Transmit/Receive Control Register 2
U0SMR4 U0SMR3 U0SMR2 U0SMR U0MR U0BRG U0TB U0C0 U0C1 U0RB UCON
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00XX0010b XXh XXh X0000000b
UART1 Special Mode Register 4 UART1 Special Mode Register 3 UART1 Special Mode Register 2 UART1 Special Mode Register UART1 Transmit/Receive Mode Register UART1 Bit Rate Register UART1 Transmit Buffer Register UART1 Transmit/Receive Control Register 0 UART1 Transmit/Receive Control Register 1 UART1 Receive Buffer Register
U1SMR4 U1SMR3 U1SMR2 U1SMR U1MR U1BRG U1TB U1C0 U1C1 U1RB
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00XX0010b XXh XXh X: Undefined
The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.8
Address
0260h 0261h 0262h 0263h 0264h 0265h 0266h 0267h 0268h 0269h 026Ah 026Bh 026Ch 026Dh 026Eh 026Fh 0270h 0271h 0272h 0273h 0274h 0275h 0276h 0277h 0278h 0279h 027Ah 027Bh 027Ch 027Dh 027Eh 027Fh 0280h 0281h 0282h 0283h 0284h 0285h 0286h 0287h 0288h 0289h 028Ah 028Bh 028Ch 028Dh 028Eh 028Fh 0290h 0291h 0292h 0293h 0294h 0295h 0296h 0297h 0298h 0299h 029Ah 029Bh 029Ch 029Dh 029Eh 029Fh NOTE: 1.
SFR Information (8) (1)
Register Symbol After Reset
UART2 Special Mode Register 4 UART2 Special Mode Register 3 UART2 Special Mode Register 2 UART2 Special Mode Register UART2 Transmit/Receive Mode Register UART2 Bit Rate Register UART2 Transmit Buffer Register UART2 Transmit/Receive Control Register 0 UART2 Transmit/Receive Control Register 1 UART2 Receive Buffer Register SI/O3 Transmit/Receive Register SI/O3 Control Register SI/O3 Bit Rate Register SI/O4 Transmit/Receive Register SI/O4 Control Register SI/O4 Bit Rate Register SI/O34 Control Register 2
U2SMR4 U2SMR3 U2SMR2 U2SMR U2MR U2BRG U2TB U2C0 U2C1 U2RB S3TRR S3C S3BRG S4TRR S4C S4BRG S34C2
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00000010b XXh XXh XXh 01000000b XXh XXh 01000000b XXh 00XXX0X0b
UART5 Special Mode Register 4 UART5 Special Mode Register 3 UART5 Special Mode Register 2 UART5 Special Mode Register UART5 Transmit/Receive Mode Register UART5 Bit Rate Register UART5 Transmit Buffer Register UART5 Transmit/Receive Control Register 0 UART5 Transmit/Receive Control Register 1 UART5 Receive Buffer Register
U5SMR4 U5SMR3 U5SMR2 U5SMR U5MR U5BRG U5TB U5C0 U5C1 U5RB
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00000010b XXh XXh
UART6 Special Mode Register 4 UART6 Special Mode Register 3 UART6 Special Mode Register 2 UART6 Special Mode Register UART6 Transmit/Receive Mode Register UART6 Bit Rate Register UART6 Transmit Buffer Register UART6 Transmit/Receive Control Register 0 UART6 Transmit/Receive Control Register 1 UART6 Receive Buffer Register
U6SMR4 U6SMR3 U6SMR2 U6SMR U6MR U6BRG U6TB U6C0 U6C1 U6RB
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00000010b XXh XXh X: Undefined
The blank areas are reserved and cannot be accessed by users.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.9
Address
02A0h 02A1h 02A2h 02A3h 02A4h 02A5h 02A6h 02A7h 02A8h 02A9h 02AAh 02ABh 02ACh 02ADh 02AEh 02AFh 02B0h 02B1h 02B2h 02B3h 02B4h 02B5h 02B6h 02B7h 02B8h 02B9h 02BAh 02BBh 02BCh 02BDh 02BEh 02BFh 02C0h 02C1h 02C2h 02C3h 02C4h 02C5h 02C6h 02C7h 02C8h 02C9h 02CAh 02CBh 02CCh 02CDh 02CEh 02CFh 02D0h 02D1h 02D2h 02D3h 02D4h 02D5h 02D6h 02D7h 02D8h 02D9h 02DAh 02DBh 02DCh 02DDh 02DEh 02DFh NOTE: 1.
SFR Information (9) (1)
Register Symbol After Reset
UART7 Special Mode Register 4 UART7 Special Mode Register 3 UART7 Special Mode Register 2 UART7 Special Mode Register UART7 Transmit/Receive Mode Register UART7 Bit Rate Register UART7 Transmit Buffer Register UART7 Transmit/Receive Control Register 0 UART7 Transmit/Receive Control Register 1 UART7 Receive Buffer Register
U7SMR4 U7SMR3 U7SMR2 U7SMR U7MR U7BRG U7TB U7C0 U7C1 U7RB
00h 000X0X0Xb X0000000b X0000000b 00h XXh XXh XXh 00001000b 00000010b XXh XXh
X: Undefined The blank areas are reserved and cannot be accessed by users.
REJ09B0392-0064 Rev.0.64 Page 26 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.10
Address
02E0h 02E1h 02E2h 02E3h 02E4h 02E5h 02E6h 02E7h 02E8h 02E9h 02EAh 02EBh 02ECh 02EDh 02EEh 02EFh 02F0h 02F1h 02F2h 02F3h 02F4h 02F5h 02F6h 02F7h 02F8h 02F9h 02FAh 02FBh 02FCh 02FDh 02FEh 02FFh 0300h 0301h 0302h 0303h 0304h 0305h 0306h 0307h 0308h 0309h 030Ah 030Bh 030Ch 030Dh 030Eh 030Fh 0310h 0311h 0312h 0313h 0314h 0315h 0316h 0317h 0318h 0319h 031Ah 031Bh 031Ch 031Dh 031Eh 031Fh NOTE: 1.
SFR Information (10) (1)
Register Symbol After Reset
Timer B3,4,5 Count Start Flag Timer A1-1 Register Timer A2-1 Register Timer A4-1 Register Three-Phase PWM Control Register 0 Three-Phase PWM Control Register 1 Three-Phase Output Buffer Register 0 Three-Phase Output Buffer Register 1 Dead Time Timer Timer B2 Interrupt Generation Frequency Set Counter
TBSR TA11 TA21 TA41 INVC0 INVC1 IDB0 IDB1 DTT ICTB2
000XXXXXb XXh XXh XXh XXh XXh XXh 00h 00h XX111111b XX111111b XXh XXh
Timer B3 Register Timer B4 Register Timer B5 Register
TB3 TB4 TB5
XXh XXh XXh XXh XXh XXh
Timer B3 Mode Register Timer B4 Mode Register Timer B5 Mode Register
TB3MR TB4MR TB5MR
00XX0000b 00XX0000b 00XX0000b
X: Undefined The blank areas are reserved and cannot be accessed by users.
REJ09B0392-0064 Rev.0.64 Page 27 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.11
Address
0320h 0321h 0322h 0323h 0324h 0325h 0326h 0327h 0328h 0329h 032Ah 032Bh 032Ch 032Dh 032Eh 032Fh 0330h 0331h 0332h 0333h 0334h 0335h 0336h 0337h 0338h 0339h 033Ah 033Bh 033Ch 033Dh 033Eh 033Fh 0340h 0341h 0342h 0343h 0344h 0345h 0346h 0347h 0348h 0349h 034Ah 034Bh 034Ch 034Dh 034Eh 034Fh 0350h 0351h 0352h 0353h 0354h 0355h 0356h 0357h 0358h 0359h 035Ah 035Bh 035Ch 035Dh 035Eh 035Fh NOTE: 1.
SFR Information (11) (1)
Register
Count Start Flag One-Shot Start Flag Trigger Select Register Up/Down Flag Timer A0 Register Timer A1 Register Timer A2 Register Timer A3 Register Timer A4 Register Timer B0 Register Timer B1 Register Timer B2 Register Timer A0 Mode Register Timer A1 Mode Register Timer A2 Mode Register Timer A3 Mode Register Timer A4 Mode Register Timer B0 Mode Register Timer B1 Mode Register Timer B2 Mode Register Timer B2 Special Mode Register
Symbol
TABSR ONSF TRGSR UDF TA0 TA1 TA2 TA3 TA4 TB0 TB1 TB2 TA0MR TA1MR TA2MR TA3MR TA4MR TB0MR TB1MR TB2MR TB2SC 00h 00h 00h 00h
After Reset
XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh XXh 00h 00h 00h 00h 00h 00XX0000b 00XX0000b 00XX0000b XXXXXX00b
X: Undefined The blank areas are reserved and cannot be accessed by users.
REJ09B0392-0064 Rev.0.64 Page 28 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.12
Address
0360h 0361h 0362h 0363h 0364h 0365h 0366h 0367h 0368h 0369h 036Ah 036Bh 036Ch 036Dh 036Eh 036Fh 0370h 0371h 0372h 0373h 0374h 0375h 0376h 0377h 0378h 0379h 037Ah 037Bh 037Ch 037Dh 037Eh 037Fh 0380h 0381h 0382h 0383h 0384h 0385h 0386h 0387h 0388h 0389h 038Ah 038Bh 038Ch 038Dh 038Eh 038Fh
SFR Information (12) (1)
Register Symbol
PUR0 PUR1 PUR2 00h 00000000b (2) 00000010b 00h
After Reset
Pull-Up Control Register 0 Pull-Up Control Register 1 Pull-Up Control Register 2
Port Control Register
PCR
00000XX0bh
Count Source Protection Mode Register Watchdog Timer Reset Register Watchdog Timer Start Register Watchdog Timer Control Register
CSPR WDTR WDTS WDC
00h (3) XXh XXh 00XXXXXXb
NOTES: X: Undefined 1. The blank areas are reserved and cannot be accessed by users. 2. Values after hardware reset 1 or brown-out reset are as follows: * 00000000b when "L" is input to the CNVSS pin * 00000010b when "H" is input to the CNVSS pin Values after software reset, watchdog timer reset, and oscillation stop detection reset are as follows: * 00000000b when bits PM01 and PM00 in the PM0 register are set to 00b (single-chip mode). * 00000010b when bits PM01 and PM00 in the PM0 register are set to 01b (memory expansion mode) or 11b (microprocessor mode). 3. When the CSPROINT bit in the OFS1 address is set to 0, value after reset is 10000000b
REJ09B0392-0064 Rev.0.64 Page 29 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.13
Address
0390h 0391h 0392h 0393h 0394h 0395h 0396h 0397h 0398h 0399h 039Ah 039Bh 039Ch 039Dh 039Eh 039Fh 03A0h 03A1h 03A2h 03A3h 03A4h 03A5h 03A6h 03A7h 03A8h 03A9h 03AAh 03ABh 03ACh 03ADh 03AEh 03AFh 03B0h 03B1h 03B2h 03B3h 03B4h 03B5h 03B6h 03B7h 03B8h 03B9h 03BAh 03BBh 03BCh 03BDh 03BEh 03BFh 03C0h 03C1h 03C2h 03C3h 03C4h 03C5h 03C6h 03C7h 03C8h 03C9h NOTE: 1.
SFR Information (13) (1)
Register Symbol
DM2SL DM3SL 00h 00h
After Reset
DMA2 Source Select Register DMA3 Source Select Register
DMA0 Source Select Register DMA1 Source Select Register
DM0SL DM1SL
00h 00h
CRC Data Register CRC Input Register A/D Register 0 A/D Register 1 A/D Register 2 A/D Register 3 A/D Register 4
CRCD CRCIN AD0 AD1 AD2 AD3 AD4
XXh XXh XXh XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb X: Undefined
The blank areas are reserved and cannot be accessed by users.
REJ09B0392-0064 Rev.0.64 Page 30 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
4. Special Function Registers (SFRs)
Table 4.14
Address
03CAh 03CBh 03CCh 03CDh 03CEh 03CFh 03D0h 03D1h 03D2h 03D3h 03D4h 03D5h 03D6h 03D7h 03D8h 03D9h 03DAh 03DBh 03DCh 03DDh 03DEh 03DFh 03E0h 03E1h 03E2h 03E3h 03E4h 03E5h 03E6h 03E7h 03E8h 03E9h 03EAh 03EBh 03ECh 03EDh 03EEh 03EFh 03F0h 03F1h 03F2h 03F3h 03F4h 03F5h 03F6h 03F7h 03F8h 03F9h 03FAh 03FBh 03FCh 03FDh 03FEh 03FFh D000h to D7FFh NOTE: 1.
SFR Information (14) (1)
Register Symbol
AD5 AD6 AD7
After Reset
XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb XXXXXXXXb 000000XXb
A/D Register 5 A/D Register 6 A/D Register 7
A/D Control Register 2 A/D Control Register 0 A/D Control Register 1 D/A0 Register D/A1 Register D/A Control Register
ADCON2 ADCON0 ADCON1 DA0 DA1 DACON
0000X00Xb 00000XXXb 0000X000b 00h 00h 00h
Port P0 Register Port P1 Register Port P0 Direction Register Port P1 Direction Register Port P2 Register Port P3 Register Port P2 Direction Register Port P3 Direction Register Port P4 Register Port P5 Register Port P4 Direction Register Port P5 Direction Register Port P6 Register Port P7 Register Port P6 Direction Register Port P7 Direction Register Port P8 Register Port P9 Register Port P8 Direction Register Port P9 Direction Register Port P10 Register Port P10 Direction Register
P0 P1 PD0 PD1 P2 P3 PD2 PD3 P4 P5 PD4 PD5 P6 P7 PD6 PD7 P8 P9 PD8 PD9 P10 PD10
XXh XXh 00h 00h XXh XXh 00h 00h XXh XXh 00h 00h XXh XXh 00h 00h XXh XXh 00h 00h XXh 00h
X: Undefined The blank areas are reserved and cannot be accessed by users.
REJ09B0392-0064 Rev.0.64 Page 31 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
5. Reset
5.
Reset
Hardware reset 1, brown-out reset, software reset, watchdog timer reset and oscillation stop detection reset are available to reset the microcomputer.
5.1
Hardware Reset 1
The microcomputer resets pins, the CPU, and SFR by setting the RESET pin. If the supply voltage meets the recommended operating conditions, the microcomputer resets all pins, the CPU, and SFR when an "L" signal is applied to the RESET pin (see Table 5.1 "Pin Status When RESET Pin Level is "L""). When the signal applied to the RESET pin changes low ("L") to high ("H"), the microcomputer executes the program in an address indicated by the reset vector. The 125 kHz on-chip oscillator clock divided by 8 is automatically selected as a CPU clock after reset. Refer to 4. "Special Function Registers (SFRs)" for SFR states after reset. The internal RAM is not reset. When an "L" signal is applied to the RESET pin while writing data to the internal RAM, the internal RAM is in an indeterminate state. Figure 5.1 shows an Example Reset Circuit. Figure 5.2 shows a Reset Sequence. Table 5.1 lists Pin Status When RESET Pin Level is "L".
5.1.1
Reset on a Stable Supply Voltage
(1) Apply "L" to the RESET pin (2) Wait for 1/fOCO-S x 20 (3) Apply an "H" signal to the RESET pin
5.1.2
(1) (2) (3) (4) (5)
Power-on Reset
Apply "L" to the RESET pin Raise the supply voltage to the recommended operating level Insert td(P-R) ms as wait time for the internal voltage to stabilize Wait for 1/fOCO-S x 20 Apply "H" to the RESET pin
Recommended operation VCC1 voltage 0V RESET VCC1 RESET 0.2 VCC1 or below 0V td (P-R)+ 0.2 VCC1 or below 1 x 20 or above fOCO - S
Figure 5.1
Example Reset Circuit
REJ09B0392-0064 Rev.0.64 Page 32 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
5. Reset
VCC1, VCC2
XIN
Microprocessor mode BYTE = "H" RESET
td(P-R)
More than 20 cycles of fOCO-S are necessary. BCLK 48 cycles (fOCO-S divided by 8 x 48)
BCLK
Address
FFFFCh
FFFFDh
FFFFEh
Content of reset vector
RD
WR
CS0 Microprocessor mode BYTE = "L" Address
FFFFCh FFFFEh
Content of reset vector
RD
WR
CS0
Single-chip mode Address
FFFFCh FFFFEh
Content of reset vector
Figure 5.2
Reset Sequence
REJ09B0392-0064 Rev.0.64 Page 33 of 373
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5. Reset
Table 5.1
Pin Status When RESET Pin Level is "L"
Status Pin Name P0 P1 P4_4 P4_5 to P4_7 P5_0 P5_1 P5_2 P5_3 P5_4 CNVSS = VSS Input port Input port Input port Input port Input port Input port Input port Input port Input port CNVSS = VCC1 (1) BYTE = VSS Data input Data input Address output (undefined)
CS0 output ("H" is output)
BYTE = VCC1 Data input Input port Address output (undefined)
CS0 output ("H" is output)
P2, P3, P4_0 to P4_3 Input port
Input port (pulled high)
WR output ("H" is output) BHE output (undefined) RD output ("H" is output)
Input port (pulled high)
WR output ("H" is output) BHE output (undefined) RD output ("H" is output)
BCLK output
HLDA output (The output value depends on the input to the HOLD pin) HOLD input (2)
BCLK output
HLDA output (The output value depends on the input to the HOLD pin) HOLD input (2)
P5_5 P5_6 P5_7 P6, P7, P8, P9, P10
Input port Input port Input port Input port
ALE output ("L" is output)
RDY input
ALE output ("L" is output)
RDY input
Input port
Input port
NOTE: 1. Shown here is the valid pin state when the internal power supply voltage has stabilized after power on. When CNVSS = VCC1, the pin state is indeterminate until the internal power supply voltage stabilizes. 2. Apply a "H" signal.
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M16C/64 Group
5. Reset
5.2
Brown-out Reset
The microcomputer resets pins, the CPU, or SFRs by setting the built-in voltage detection 0 circuit. The voltage detection 0 circuit monitors the voltage applied to the VCC1 pin (Vdet0). The microcomputer resets pins, the CPU, and SFR as soon as the voltage that is applied to the VCC1 pin drops to Vdet0 or below. Then, 125 kHz on-chip oscillator clock starts counting when the voltage that is applied to the VCC1 pin goes up to Vdet0 or above. The internal reset signal becomes "H" after the 125 kHz on-chip oscillator clock is counted 32 times, and then reset sequence starts (see Figure 5.2). The 125 kHz on-chip oscillator clock divided by 8 is automatically selected as a CPU clock after reset. Refer to 4. "Special Function Registers (SFRs)" for the SFR status after brown-out reset. The internal RAM is not reset. When the voltage that is applied to the VCC1 pin drops to Vdet0 or below while writing data to the internal RAM, the internal RAM is in an indeterminate state. Refer to 6. "Voltage Detection Circuit" for details of the voltage detection 0 circuit.
5.3
Software Reset
The microcomputer resets pins, the CPU, and SFRs when the PM03 bit in the PM0 register is set to 1 (microcomputer reset). Then the microcomputer executes the program in an address determined by the reset vector. The 125 kHz on-chip oscillator clock divided by 8 is automatically selected as a CPU clock after reset. In the software reset, the microcomputer does not reset a part of the SFRs. Refer to 4. "Special Function Registers (SFRs)" for details. The internal RAM is not reset.
5.4
Watchdog Timer Reset
The microcomputer resets pins, the CPU, and SFRs when the PM12 bit in the PM1 register is set to 1 (reset when watchdog timer underflows) and the watchdog timer underflows. Then the microcomputer executes the program in an address determined by the reset vector. The 125 kHz on-chip oscillator clock divided by 8 is automatically selected as a CPU clock after reset. In the watchdog timer reset, the microcomputer does not reset a part of the SFRs. Refer to 4. "Special Function Registers (SFRs)" for details. The internal RAM is not reset. When the watchdog timer underflows while writing data to the internal RAM, the internal RAM is in an indeterminate state. Refer to 13. "Watchdog Timer" for details.
5.5
Oscillation Stop Detection Reset
The microcomputer resets and stops pins, the CPU, and SFRs when the CM27 bit in the CM2 register is 0 (reset when oscillation stop detected), if it detects main clock oscillation circuit stop. Refer to 10.6 "Oscillation Stop and Re-Oscillation Detect Function" for details. In the oscillation stop detection reset, the microcomputer does not reset a part of the SFRs. Refer to 4. "Special Function Registers (SFRs)" for details. Processor mode remains unchanged since bits PM01 to PM00 in the PM0 register are not reset.
REJ09B0392-0064 Rev.0.64 Page 35 of 373
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M16C/64 Group
5. Reset
5.6
Internal Space
Figure 5.3 shows CPU Register Status After Reset. Refer to 4. "Special Function Registers (SFRs)" for SFR states after reset.
b15
b0
0000h 0000h 0000h 0000h 0000h 0000h 0000h
b19
Data register (R0) Data register (R1) Data register (R2) Data register (R3) Address register (A0) Address register (A1) Frame base register (FB)
b0
00000h Content of addresses FFFFEh to FFFFCh
b15 b0
Interrupt table register (INTB) Program counter (PC) User stack pointer (USP) Interrupt stack pointer (ISP) Static base register (SB)
b0
0000h 0000h 0000h
b15
0000h
b15 b8 b7 b0
Flag register (FLG)
IPL
UI
OB S Z DC
Figure 5.3
CPU Register Status After Reset
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M16C/64 Group
6. Voltage Detection Circuit
6.
Voltage Detection Circuit
The voltage detection circuit consists of the voltage detection 0 circuit and the low voltage detection circuit. The voltage detection 0 circuit monitors the voltage applied to the VCC1 pin. The microcomputer is reset if the voltage detection 0 circuit detects VCC1 is Vdet0 or below. The low voltage detection circuit also monitors the voltage applied to the VCC1 pin. The low voltage detection signal is generated when the low voltage detection circuit detects that VCC1 passes through Vdet2. This signal generates the low voltage detection interrupt. The VC13 bit in the VCR1 register determines whether VCC1 is Vdet2 and above or below Vdet2. The voltage detection circuit is available when VCC1 = 5 V. Figure 6.1 shows a Voltage Detection Circuit Block Diagram.
Low voltage detection circuit VCC1
VC27
+
Internal reference voltage
Noise filter
Low voltage detection interrupt signal
-
Vdet2
VCR1 register
b3
VC25 Voltage detection 0 circuit
+ -
VC13 bit
Voltage detection 0 signal
Vdet0
Figure 6.1
Voltage Detection Circuit Block Diagram
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M16C/64 Group
6. Voltage Detection Circuit
Voltage Detection 2 Circuit Flag Register
b7 b6 b5 b4 b3 b2 b1 b0
0000
000
Symbol VCR1
Address 0019h
After Reset (2) 00001000b
Bit Symbol -- (b2-b0) VC13 -- (b7-b4)
Bit Name Reserved bits Low voltage monitor flag (1) Reserved bits Set to 0
Function
RW RW RO RW
0 : VCC1 < Vdet2 1 : VCC1 Vdet2 Set to 0
NOTES : 1. The VC13 bit is enabled when the VC27 bit in the VCR2 register is set to 1 (low voltage detection circuit enabled). The VC13 bit is always 1 (VCC1 Vdet2) when the VC27 bit is set to 0 (low voltage detection circuit disabled). 2. This register dose not change at software reset, watchdog timer reset, and oscillation stop detection reset.
Voltage Detection Circuit Operation Enable Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
0
0000
Symbol VCR2 Bit Symbol -- (b3-b0) -- (b4) VC25 -- (b6) VC27
Address 001Ah Bit Name Reserved bits Set to 0
After Reset (4) 000X0000b (Hardware reset 1) 001X0000b (Brown-out reset) Function RW RW -- RW RW RW
No register bit. If necessary, set to 0. Read as undefined value Voltage detection 0 enable bit 0 : Disable voltage detection 0 circuit (2, 5) 1 : Enable voltage detection 0 circuit Reserved bit Low voltage monitor bit (3, 5) Set to 0 0 : Disable low voltage detection circuit 1 : Enable low voltage detection circuit
NOTES : 1. Write to this register after setting the PRC3 bit in the PRCR register to 1 (write enabled). 2. To use brown-out reset, set the VC25 bit to 1 (voltage detection 0 circuit enabled). 3. When the VC13 bit in the VCR1 register and D42 bit in the D4INT register are used or the D40 bit is set to 1 (low voltage detection interrupt enabled), set the VC27 bit to 1 (low voltage detection circuit enabled). 4. This register does not change at software reset, watchdog timer reset, and oscillation stop detection reset. 5. The detection circuit does not start operation until td(E-A) elapses after the VC25 bit or VC27 bit is set to 1.
Figure 6.2
Registers VCR1 and VCR2
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M16C/64 Group
6. Voltage Detection Circuit
Low Voltage Detection Interrupt Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol D4INT Bit Symbol D40
Address 001Fh Bit Name Low voltage detection interrupt enable bit (5) 0 : Disabled 1 : Enabled
After Reset 00h Function RW RW
D41
STOP mode deactivation control bit (4, 6)
0 : Disabled (the low voltage detection interrupt is not used for recovery from stop mode) 1 : Enabled (the low voltage detection interrupt is used for recovery from stop mode) 0 : Not detected 1 : Vdet2 passing detection 0 : Not detected 1 : Detected
b5 b4
RW
D42 D43 DF0
Voltage change detection flag (2) WDT overflow detect flag
RW (3) RW (3)
Sampling clock select bit DF1 -- (b7-b6)
0 0 1 1
0 : D4INT clock divided by 8 1 : D4INT clock divided by 16 0 : D4INT clock divided by 32 1 : D4INT clock divided by 64
RW RW --
No register bits. If necessary, set to 0. Read as undefined value.
NOTES : 1. Write to this register after setting the PRC3 bit in the PRCR register to 1 (write enabled). 2. This flag is enabled when the VC27 bit in the VCR2 register is set to 1 (low voltage detection circuit enabled). If the VC27 bit is set to 0 (low voltage detection circuit disabled), the D42 bit is set to 0 (not detected). 3. This bit is set to 0 by writing a 0 in a program. (writing a 1 has no effect.) 4. If the low voltage detection interrupt needs to be used to get out of stop mode again after once used for that purpose, reset the D41 bit by writing a 0 and then a 1. 5. The D40 bit is effective when the VC27 bit in the VCR2 register = 1. To set the D40 bit to 1, set bits in the following order. (a) Set the VC27 bit to 1. (b) Wait for td(E-A) until the detection circuit is actuated. (c) Wait for the sampling time. (See Table 6.3 Sampling Period.) (d) Set the D40 bit to 1. 6. This bit is used for wait mode exiting control when the CM02 bit in the CM0 register is 1 (stop peripheral function clock f1 in wait mode).
Figure 6.3
D4INT Register
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6. Voltage Detection Circuit
Voltage Monitor 0 Circuit Control Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
11
0
Symbol VW0C Bit Symbol VW0C0 VW0C1 -- (b2) -- (b3) VW0F0
Address 002Ah Bit Name Brown-out reset enable bit (3)
After Reset (2) 10001X10b (Hardware reset 1) 11001X11b (Brown-out reset) Function 0 : Disabled 1 : Enabled RW RW RW RW RO
Voltage monitor 0 digital filter 0 : Enable digital filter disable mode select bit 1 : Disable digital filter Reserved bit Reserved bit Set to 0. Read as undefined value Read as undefined value
b5 b4
Sampling clock select bit VW0F1 -- (b7-b6) Reserved bits
0 0 1 1
0 : fOCO-S divided by 1 1 : fOCO-S divided by 2 0 : fOCO-S divided by 4 1 : fOCO-S divided by 8
RW
Set to 1
RW
NOTES : 1. Set the PRC3 bit in the PRCR register to 1 (write enabled) to rewrite the VW0C register. 2. The value of this register remain unchanged after software reset, watchdog timer reset, or oscillation stop detection reset. 3. Set the VC25 bit in the VCR2 register to 1 (voltage detection 0 circuit enabled) to enable the VW0C0 bit. Set the VW0C0 bit to 0 (disabled) when the VC25 bit is set to 0 (voltage detection 0 circuit disabled).
Figure 6.4
VW0C Register
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M16C/64 Group
6. Voltage Detection Circuit
6.1
Brown-out Reset
Figure 6.5 is a block diagram illustrating brown-out reset generation circuit. Table 6.1 shows a setting procedure of the bits for brown-out reset. Figure 6.6 provides an example of brown-out reset operation. When using brown-out resetbrown-out reset to exit stop mode, set the VW0C1 bit in the VW0C register to 1 (digital filter disabled).
Table 6.1 Setting Procedures of the Bits for Brown-out Reset
Procedure 1 2 3
4 5 6 7
When using the digital filter When not using the digital filter Set the VC25 bit in the VCR2 register to 1 (voltage detection 0 circuit enabled) Wait for td (E-A) Use bits VW0F0 to VW0F1 in the VW0C regis- Set the VW0C1 bit in the VW0C register to 1 ter to select the digital filter sampling clock. Set (digital filter disabled), and bits 6 and 7 to 1 the VW0C1 bit to 0 (digital filter enabled), bits 6 and 7 to 1 Set bit 2 in the VW0C register to 0 (setting bit 2 to 0 once again after procedure 3 is necessary) Set the CM14 bit in the CM1 register to 0 (125 kHz on-chip oscillator oscillates) Wait for digital filter sampling clock x 4 cycles - (no wait time) Set the VW0C0 bit in the VW0C register to 1 (brown-out reset enabled)
Brown-out reset generation circuit VW0F1 to VW0F0 = 00b = 01b Voltage detection 0 circuit fOCO-S VC25 VW0C1 VCC1 Internal reference voltage
+ -
= 10b
1/2
1/2
1/2 = 11b
Voltage detection 0 signal When the VC25 bit is set to 0 (disabled), the voltage detection 0 signal becomes "H."
Digital filter
Brown-out reset signal VW0C1 VW0C0
1
1
VW0C0 to VW0C1, VW0F0 to VW0F1 = the bits in the VW0C register VC25 = the bit in the VC2 register
Figure 6.5
Brown-out Reset Generation Circuit
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M16C/64 Group
6. Voltage Detection Circuit
VCC Vdet0
Digital filter sampling clock
x4 cycles
1 fOCO-S
x32
When the VW0C1 bit is 0 (digital filter enabled)
Internal reset signal
1 fOCO-S
x32
When the VW0C1 bit is 1 (digital filter disabled)
Internal reset signal
VW0C1 = the bit in the VW0C register The above diagram shows an instance in which the following conditions are all met. *The VC25 bit in the VCR2 register = 1 (voltage detection 0 circuit enabled) *The VW0C0 bit in the VW0C register = 1 (brown-out reset enabled) Pins, the CPU, and SFRs are initialized when the internal reset signal becomes low. The microcomputer executes the program in an address indicated by the reset vector when the internal reset signal changes low to high. Refer to 4. SFRs for the SFR status after reset.
Figure 6.6
Brown-out Reset Operation Example
6.2
Low Voltage Detection Interrupt
If the D40 bit in the D4INT register is set to 1 (low voltage detection interrupt enabled), the low voltage detection interrupt request is generated when the voltage applied to the VCC1 pin is above or below Vdet2. The low voltage detection interrupt shares the same interrupt vector with the watchdog timer interrupt, oscillation stop, and re-oscillation detection interrupt. Set the D41 bit in the D4INT register to 1 (enabled) to use the low voltage detection interrupt to exit stop mode. The D42 bit in the D4INT register is set to 1 as soon as the voltage applied to the VCC1 pin reaches Vdet2 due to the voltage rise and voltage drop. When the D42 bit changes 0 to 1, the low voltage detection interrupt request is generated. Set the D42 bit to 0 by program. However, when the D41 bit is set to 1 and the microcomputer is in stop mode, the low voltage detection interrupt request is generated regardless of the D42 bit state if the voltage applied to the VCC1 pin is detected to be above Vdet2. The microcomputer then exits stop mode. Table 6.2 shows Low Voltage Detection Interrupt Request Generation Conditions. Bits DF1 to DF0 in the D4INT register determine the sampling period that detects the voltage applied to the VCC1 pin reaches Vdet2. Table 6.3 shows the Sampling Periods.
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6. Voltage Detection Circuit
Table 6.2
Low Voltage Detection Interrupt Request Generation Conditions
Operating Mode Normal Operating Mode Wait Mode (2)
(1)
VC27 Bit
D40 Bit
D41 Bit -
D42 Bit 0 to 1 0 to 1 -
CM02 Bit 0 1 0
VC13 Bit 0 to 1 (3) 1 to 0 (3) 0 to 1 (3) 1 to 0 (3) 0 to 1 0 to 1
1
1
1
Stop Mode (2)
- indicates either 0 or 1 is settable. NOTE: 1. The status except wait mode and stop mode is handled as normal mode. (Refer to 10. "Clock Generation Circuit") 2. Refer to 6.3 "Limitations on Exiting Stop Mode" and 6.4 "Limitations on Exiting Wait Mode". 3. An interrupt request for voltage reduction is generated after the value of the VC13 bit changes and a sampling time elapses. See Figure 6.8 "Low Voltage Detection Interrupt Generation Circuit Operation Example" for details.
Table 6.3 Sampling Periods
CPU Clock (D4INT clock) (MHz) 16
Sampling Clock (s) DF1 to DF0 = 00 DF1 to DF0 = 01 DF1 to DF0 = 10 DF1 to DF0 = 11 (CPU clock divided by 8) (CPU clock divided by 16) (CPU clock divided by 32) (CPU clock divided by 64) 3.0 6.0 12.0 24.0
Low voltage detection interrupt generation circuit
DF1, DF0
00b
Low voltage detection circuit
01b 10b
D4INT clock (the clock with which it operates also in wait mode)
VC27
1/8
1/2
1/2
1/2
11b
The D42 bit is set to 0 (not detected) by program. When the VC27 bit is set to 0 (low voltage detection circuit disabled), the D42 bit is set to 0.
VC13
VCC1 VREF
D42
Noise rejection circuit Digital filter
Watchdog timer interrupt signal
+ -
Noise rejection
(Rejection range : 200 ns)
Low voltage detection signal
The low voltage detection signal becomes "H" when the VC27 bit is set to 0 (disabled). CM10
D41
Low voltage detection interrupt signal Oscillation stop, re-oscillation detection interrupt signal
Non-maskable interrupt sognal
CM02 WAIT instruction (wait mode) Watchdog timer block
D43 D40
Watchdog timer underflow signal
This bit is set to 0 (not detected) by program.
Figure 6.7
Low Voltage detection Interrupt Generation Block Diagram
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6. Voltage Detection Circuit
VCC1
VC13 bit
Sampling
Sampling
Sampling
Sampling
No low voltage detection interrupt signals are generated when the D42 bit is "H." Output of the digital filter
(2)
D42 bit Set the D42 bit to 0 (not detected) by program.
Low voltage detection interrupt signal
NOTES : 1. The D40 bit is set to 1 (low voltage detection interrupt enabled). 2. Output of the digital filter is shown in Figure 6.7.
Figure 6.8
Low Voltage Detection Interrupt Generation Circuit Operation Example
6.3
Limitations on Exiting Stop Mode
The low voltage detection interrupt is immediately generated and the microcomputer exits stop mode if the CM10 bit in the CM1 register is set to 1 (stop mode) under the conditions below. * the VC27 bit in the VCR2 register is set to 1 (low voltage detection circuit enabled) * the D40 bit in the D4INT register is set to 1 (low voltage detection interrupt enabled) * the D41 bit in the D4INT register is set to 1 (low voltage detection interrupt is used to exit stop mode) * the voltage applied to the VCC1 pin is higher than Vdet2 (the VC13 bit in the VCR1 register is 1) If the microcomputer is set to enter stop mode when the voltage applied to the VCC1 pin drops below Vdet2 and to exit stop mode when the voltage applied rises to Vdet2 or above, set the CM10 bit to 1 when VC13 bit is 0 (VCC1 < Vdet2).
6.4
Limitations on Exiting Wait Mode
The low voltage detection interrupt is immediately generated and the microcomputer exits wait mode If WAIT instruction is executed under the conditions below. * the CM02 bit in the CM0 register is set to 1 (stop peripheral function clock) * the VC27 bit in the VCR2 register is set to 1 (low voltage detection circuit enabled) * the D40 bit in the D4INT register is set to 1 (low voltage detection interrupt enabled) * the D41 bit in the D4INT register is set to 1 (low voltage detection interrupt is used to exit wait mode) * the voltage applied to the VCC1 pin is higher than Vdet2 (the VC13 bit in the VCR1 register is 1) If the microcomputer is set to enter wait mode when the voltage applied to the VCC1 pin drops below Vdet2 and to exit wait mode when the voltage applied rises to Vdet2 or above, perform WAIT instruction when the VC13 bit is 0 (VCC1 < Vdet2).
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6. Voltage Detection Circuit
6.5
Cold Start-up / Warm Start-up Discrimination
As for the cold start-up / warm start-up discrimination, the CWR bit in the RSTFR register determines either cold start-up (reset process) when power-on or warm start-up (reset process) when reset signal is applied during the microcomputer running. The value of the CWR bit is 0 when power is applied. The CWR bit is also set to 0 after brown-out reset. The CWR bit is set to 1 by writing a 1 in a program and does not change at hardware reset 1, software reset, watchdog timer reset, and oscillation stop detection reset. Use brown-out reset for cold start-up / warm start-up discrimination. Follow Table 6.1 Setting Procedures of the Bits for Brown-out Reset to set the bits for brown-out reset. Figure 6.9 shows Cold Start-up / Warm Start-up Discrimination Example. Figure 6.10 shows RSTFR Register.
5V
VCC1
Vdet0 0V
Set to 1 by program Set to 1 by program
CWR bit Brown-out reset
The above diagram shows an instance in which the digital filter is not used.
Figure 6.9 Cold Start-up / Warm Start-up Discrimination Example
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6. Voltage Detection Circuit
Reset Source Determine Flag
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol RSTFR
Address 0018h
After Reset 0XXXXXXXb (1)
Bit Symbol CWR -- (b5-b1) -- (b7-b6)
Bit Name Cold start-up / warm start determine flag (2, 3) Reserved bits Reserved bits 0 : Cold start-up 1 : Warm start-up
Function
RW RW RO RW
Read as undefined value Set to 0
NOTES : 1. The CWR bit is set to 0 (cold start-up) after power activation or brown-out reset. The CWR bit remains unchanged after hardware reset 1, software reset, watchdog timer reset, or oscillation stop detection reset. 2. The CWR bit is set to 1 by writing a 1 in a program (writing a 0 has no effect). 3. The CWR bit is undefined when the VW0C0 bit in the VW0C register is set to 0 (brown-out reset disabled).
Figure 6.10
RSTFR Register
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7. Processor Mode
7.
7.1
Processor Mode
Types of Processor Mode
Three processor modes are available to choose from: single-chip mode, memory expansion mode, and microprocessor mode. Table 7.1 shows the Features of Processor Modes.
Table 7.1 Features of Processor Modes Processor Modes Access Space Single-chip mode SFR, internal RAM, internal ROM
Memory expansion mode Microprocessor mode
SFR, internal RAM, internal ROM, external area (1) SFR, internal RAM, external area (1) Some pins serve as bus control pins (1)
Pins Which Are Assigned I/O Ports All pins are I/O ports or peripheral function I/ O pins Some pins serve as bus control pins (1)
NOTE: 1. Refer to 8. "Bus" for details.
7.2
Setting Processor Modes
Processor mode is set by using the CNVSS pin and bits PM01 to PM00 in the PM0 register. Table 7.2 shows the Processor Mode After Hardware Reset. Table 7.3 shows Bits PM01 to PM00 Set Values and Processor Modes
Table 7.2 Processor Mode After Hardware Reset
CNVSS Pin Input Level VSS VCC1 (1, 2) Single-chip mode Microprocessor mode
Processor Modes
NOTES: 1. If the microcomputer is reset in hardware by applying VCC1 to the CNVSS pin (hardware reset 1 or brown-out reset), the internal ROM cannot be accessed regardless of the status of bits PM10 to PM00. 2. The multiplexed bus cannot be assigned to the entire CS space.
Table 7.3 Bits PM01 to PM00 Set Values and Processor Modes
Bits PM01 to PM00 00b 01b 10b 11b
Processor Modes Single-chip mode Memory expansion mode Do not set Microprocessor mode
Rewriting bits PM01 to PM00 places the microcomputer in the corresponding processor mode regardless of whether the input level on the CNVSS pin is "H" or "L". Note, however, that bits PM01 to PM00 cannot be rewritten to 01b (memory expansion mode) or 11b (microprocessor mode) at the same time bits PM07 to PM02 are rewritten. Note also that these bits cannot be rewritten to enter microprocessor mode in the internal ROM, nor can they be rewritten to exit microprocessor mode in areas overlapping the internal ROM. If the microcomputer is reset in hardware by applying VCC1 to the CNVSS pin (hardware reset 1 or brown-out reset), the internal ROM cannot be accessed regardless of bits PM01 to PM00. Figures 7.1 to 7.3 show the PM0 Register and PM1 Register. Figure 7.4 show the Memory Map in SingleChip Mode.
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7. Processor Mode
Processor Mode Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PM0
Address 0004h
After Reset (4) 00000000b (CNVSS pin = "L") 00000011b (CNVSS pin = "H") Function
b1
Bit Symbol PM00
Bit Name 0 0 1 1
b0
RW RW RW
Processor mode bit PM01
(4)
0 : Single-chip mode 1 : Memory expansion mode 0 : Do not set 1 : Microprocessor mode
PM02
R/W mode select bit (2)
0 : RD, BHE, WR 1 : RD, WRH, WRL Setting this bit to 1 resets the microcomputer. Read as 0
b5 b4
RW
PM03
Software reset bit
RW
PM04 Multiplexed bus space select bit (2) PM05
0 0 1 1
0 : Multiplexed bus is unused (separate bus in the entire CS space) 1 : Allocated to CS2 space 0 : Allocated to CS1 space 1 : Allocated to the entire CS space (3)
RW
RW
PM06
Port P4_0 to P4_3 function select bit (2)
0 : Address output 1 : Port function (address is not output) 0 : BCLK is output 1 : BCLK is not output (pin is left high-impedance)
RW
PM07
BCLK output disable bit (2)
RW
NOTES : 1. Write to this register after setting the PRC1 bit in the PRCR register to 1 (write enabled). 2. Bits PM02, and PM04 to PM07 are effective when bits PM01 and PM00 are set to 01b (memory expansion mode) or 11b (microprocessor mode). 3. To set bits PM01 and PM00 to 01b and bits PM05 and PM04 to 11b (multiplexed bus assigned to the entire CS space), apply an "H" signal to the BYTE pin (external data bus is 8 bits wide). While the CNVSS pin is held "H" (= VCC1), do not rewrite the PM05 and PM04 bits to 11b after reset. If bits PM05 and PM04 are set to 11b during memory expansion mode, P3_1 to P3_7 and P4_0 to P4_3 become I/O ports, in which case the accessible area for each CS is 256 bytes. 4. Bits PM01 and PM00 do not change at software reset, watchdog timer reset, and oscillation stop detection reset.
Figure 7.1
PM0 Register
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
7. Processor Mode
Processor Mode Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol PM1
Address 0005h
After Reset 00001000b
Bit Symbol PM10 PM11 PM12 PM13
Bit Name CS2 area switch bit (data flash enable bit) (2) Port P3_7 to P3_4 function select bit (3)
Function 0 : CS2 (0E000h to 0FFFFh ) 1 : Data flash (0E000h to 0FFFFh) 0 : Address output 1 : Port function
RW RW RW RW RW
Watchdog timer function select 0 : Watchdog timer interrupt bit (4) 1 : Watchdog timer reset Internal reserved area expansion bit (2, 6) (NOTE 6)
b5 b4
PM14 Memory area expansion bit PM15 -- (b6) PM17 Reserved bit Wait bit (5)
(3)
0 0 1 1
0 : 1-Mbyte mode (no expansion) 1 : Do not set 0 : Do not set 1 : 4-Mbyte mode
RW
RW
Set to 0 0 : No wait state 1 : Wait state (1 wait)
RW RW
NOTES : 1. Write to this register after setting the PRC1 bit in the PRCR register to 1 (write enabled). 2. Bits PM10 and PM13 are automatically set to 1 while the FMR01 bit in the FMR0 register is set to 1 (CPU rewrite mode). 3. Bits PM11, PM14, and PM 15 are effective when bits PM01 and PM00 are set to 01b (memory expansion mode) or 11b (microprocessor mode). 4. The PM12 bit is set to 1 by writing a 1 in a program (writing a 0 has no effect). The PM12 bit is automatically set to 1 when the CSPRO bit in the CSPR register is 1 (count source protection mode enabled). 5. When the PM17 bit is set to 1 (wait state), one wait state is inserted when accessing the internal RAM or internal ROM. When the PM17 bit is set to 1 and accesses an external area, set the CSiW bit in the CSR register (i = 0 to 3) to 0 (wait state). 6. The access area is changed by the PM13 bit as listed in the table below. Access Area Internal RAM Program ROM 1 External PM13 = 0 PM13 = 1
Up to Addresses 00400h to 03FFFh (15 Kbytes) The entire area is usable Up to Addresses D0000h to FFFFFh (192 Kbytes) The entire area is usable
Address 04000h to 0CFFFh are usable Address 04000h to 0CFFFh are reserved Address 80000h to CFFFFh are usable Address 80000h to CFFFFh are reserved Note that 08000h to 0CFFFh are reserved when (in memory expansion mode) PM10 is set to 1 during microprocessor mode.
Figure 7.2
PM1 Register
REJ09B0392-0064 Rev.0.64 Page 49 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
7. Processor Mode
Program 2 Area Control Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol PRG2C(1)
Address 0010h
After Reset XXXXXXX0h
Bit Symbol PRG2C -- (b1) -- (b7-b2)
Bit Name Program ROM 2 disable bit Reserved bit
Function 0 : Enable program ROM 2 1 : Disable program ROM 2 Set to 0
RW RW RW --
No register bits. If necessary, set to 0. Read as undefined value
NOTE : 1. Write to this register after setting the PRC6 bit in the PRCR register to 1 (write enabled).
Figure 7.3
PRG2C Register
REJ09B0392-0064 Rev.0.64 Page 50 of 373
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M16C/64 Group
7. Processor Mode
7.3
Internal Memory
The internal RAM can be used in all processor modes. The range of the internal RAM depends on the setting of the PM 13 bit in the PM1 register. The internal ROM is used in single-chip mode and memory expansion mode. Three internal ROMs are available: data flash, program ROM 2, and program ROM 1. Data flash includes block A (addresses 0E000h to 0EFFFh) and block B (addresses 0F000h to 0FFFFh). When data flash is selected by the setting of the PM10 bit in the PM1 register, both block A and block B can be used. Table 7.4 shows Data Flash (addresses 0E000h to 0FFFFh).
Table 7.4 Data Flash (addresses 0E000h to 0FFFFh)
PM10 Bit in PM1 Register Processor Modes Single-chip mode Memory expansion mode Microprocessor mode
0 Unusable External area External area
1 Data flash Data flash Reserved area
Set the PRG2C0 bit in the PRG2C register to select program ROM 2. Table 7.5 shows Program ROM 2 (addresses 10000h to 13FFFh). Do not use the last 16 bytes (addresses 13FF0h to 13FFFh) when using program ROM 2 in single-chip mode or memory expansion mode. These bytes are assigned as the user boot code area (refer to 22.1.2 "User Boot Function").
Table 7.5 Program ROM 2 (addresses 10000h to 13FFFh)
PRG2C0 bit in PRG2C Register Processor Modes Single-chip mode Memory expansion mode Microprocessor mode
0 Program ROM 2 Program ROM 2 Reserved area
1 Unusable External area External area
The range of program ROM 1 depends on the setting of the PM13 bit in the PM1 register. Figure 7.4 indicates the Memory Map in Single-Chip Mode.
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M16C/64 Group
7. Processor Mode
Single-chip Mode 00000h 00400h Internal RAM XXXXXh Unusable 0D000h 0D800h 0E000h 10000h 14000h YYYYYh
Internal ROM (program ROM 1)
SFR
SFR Unusable Internal ROM (2)
(data flash)
PM13 = 0 Internal RAM Address XXXXXh Size 12 Kbytes 033FFh 16 Kbytes 03FFFh (1) 31 Kbytes 03FFFh (1)
Internal ROM Address YYYYYh Size 128 Kbytes E0000h 256 Kbytes D0000h (1) 512 Kbytes D0000h (1)
Internal ROM (3) (program ROM 2) Unusable
PM13 = 1 Internal RAM Address XXXXXh Size 12 Kbytes 033FFh 16 Kbytes 043FFh 31 Kbytes 07FFFh
Internal ROM Address YYYYYh Size 128 Kbytes E0000h 256 Kbytes C0000h 512 Kbytes 80000h
FFFFFh NOTES : 1. If the PM13 bit is set to 0, 15 Kbytes of the internal RAM and 192 Kbytes of the internal ROM can be used. 2. Data flash can be used when the PM10 bit in the PM1 register is 1 (0E000h to 0FFFFh = data flash). 3. Program ROM 2 can be used when the PRG2C0 bit in the PRG2C register is 0 (program ROM 2 enabled).
Figure 7.4
Memory Map in Single-Chip Mode
REJ09B0392-0064 Rev.0.64 Page 52 of 373
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M16C/64 Group
8. Bus
8.
Bus
During memory expansion or microprocessor mode, some pins serve as the bus control pins to perform data input /output to and from external devices. These bus control pins include A0 to A19, D0 to D15, CS0 to CS3, RD, WRL /WR, WRH / BHE, ALE, RDY, HOLD, HLDA, and BCLK.
8.1
Bus Mode
Bus mode, either multiplexed or separate, can be selected using bits PM05 and PM04 in the PM0 register. Table 8.1 shows the Difference between Separate Bus and Multiplexed Bus.
8.1.1
Separate Bus
In this bus mode, data and address are separate.
8.1.2
Multiplexed Bus
In this bus mode, data and address are multiplexed.
8.1.2.1
When the Input Level on BYTE Pin is High (8-Bit Data Bus)
D0 to D7 and A0 to A7 are multiplexed.
8.1.2.2
When the Input Level on BYTE Pin is Low (16-Bit Data Bus)
D0 to D7 and A1 to A8 are multiplexed. D8 to D15 are not multiplexed. Do not use D8 to D15. External devices connecting to a multiplexed bus are allocated to only the even addresses of the microcomputer. Odd addresses cannot be accessed.
Table 8.1 Difference between Separate Bus and Multiplexed Bus
Pin Name (1) P0_0 to P0_7 / D0 to D7 P1_0 to P1_7 / D8 to D15 P2_0 / A0 (/ D0 / -) P2_1 to P2_7 / A1 to A7 (/ D1 to D7 / D0 to D6) P3_0 / A8 (/ - / D7)
Separate Bus D0 to D7 D8 to D15 A0 A1 to A7 A8
Multiplexed Bus BYTE = "H" BYTE = "L" (NOTE 2) I/O port P1_0 to P1_7 A0 D0 (NOTE 2) (NOTE 2) A0 A1 to A7 D0 to D6 A8 D7
A1 to A7 D1 to D7 A8
NOTES: 1. See Table 8.6 "Pin Functions for Each Processor Mode" for bus control signals other than the above. 2. It changes with a setting of PM05 and PM04, and area to access. See Table 8.6 "Pin Functions for Each Processor Mode" for details.
REJ09B0392-0064 Rev.0.64 Page 53 of 373
Oct 12, 2007
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M16C/64 Group
8. Bus
8.2
Bus Control
The following describes the signals needed for accessing external devices and the functionality of software wait.
8.2.1
Address Bus
The address bus consists of 20 lines: A0 to A19. The address bus width can be chosen to be 12, 16, or 20 bits by using the PM06 bit in the PM0 register and the PM11 bit in the PM1 register. Table 8.2 shows the Set Value of Bits PM06 and PM11, and Address Bus Width.
Table 8.2 Set Value of Bits PM06 and PM11, and Address Bus Width
Bits Set Value (1) PM11 = 1 PM06 = 1 PM11 = 0 PM06 = 1 PM11 = 0 PM06 = 0
Pin Function P3_4 to P3_7 P4_0 to P4_3 A12 to A15 P4_0 to P4_3 A12 to A15 A16 to A19
Address Bus Width 12 bits 16 bits 20 bits
NOTE: 1. No values other than those shown above can be set. When processor mode is changed from single-chip mode to memory expansion mode, the address bus is indeterminate until any external area is accessed.
8.2.2
Data Bus
When input on the BYTE pin is high (data bus is 8 bits wide), 8 lines D0 to D7 comprise the data bus; when input on the BYTE pin is low (data bus is 16 bits wide), 16 lines D0 to D15 comprise the data bus. Do not change the input level on the BYTE pin while in operation.
8.2.3
Chip Select Signal
The chip select (hereafter referred to as the CS) signals are output from the CSi (i = 0 to 3) pins. These pins can be chosen to function as I/O ports or as CS by using the CSi bit in the CSR register. Figure 8.1 shows the CSR Register. During 1-Mbyte mode, the external area can be separated into up to 4 by the CSi signal which is output from the CSi pin. During 4-Mbyte mode, CSi signal or bank number is output from the CSi pin. Refer to 9. "Memory Space Expansion Function". Figure 8.2 shows Examples of Address Bus and CSi Signal Output in 1-Mbyte mode.
REJ09B0392-0064 Rev.0.64 Page 54 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
8. Bus
Chip Select Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol CSR
Address 0008h
After Reset 01h
Bit Symbol CS0 CS1 CS2 CS3 CS0W CS1W CS2W CS3W
Bit Name CS0 output enable bit CS1 output enable bit CS2 output enable bit CS3 output enable bit CS0 wait bit CS1 wait bit CS2 wait bit CS3 wait bit
Function 0 : Disable chip select output (functions as I/O port) 1 : Enable chip select output
RW RW RW RW RW
0 : Wait state 1 : No wait state (1, 2, 3)
RW RW RW RW
NOTES : 1. When the RDY signal is used in the area indicated by CSi (i = 0 to 3) or the multiplex bus is used, set the CSiW bit to 0 (wait state). 2. When the PM17 bit in the PM1 register is set to 1 (wait state), set the CSiW bit to 0 (wait state). 3. When the CSiW bit = 0 (wait state), the number of wait states can be selected using bits CSEi1W to CSEi0W in the CSE register.
Figure 8.1
CSR Register
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M16C/64 Group
8. Bus
Example 1 To access the external area indicated by CSj in the next cycle after accessing the external area indicated by CSi The address bus and chip select signal both change state between these two cycles.
Example 2 To access the internal ROM or internal RAM in the next cycle after accessing the external area indicated by CSi The chip select signal changes state but the address bus does not change state
Access to the external area indicated by CSi
Access to the external area indicated by CSj
Access to the external area indicated by CSi
Access to the internal ROM or internal RAM
BCLK Read signal Data bus Address bus CSi CSj Data Data
BCLK Read signal Data bus Address bus CSi Data Address
Address Address
Example 3 To access the external area indicated by CSi in the next cycle after accessing the external area indicated by the same CSi The address bus changes state but the chip select signal does not change state
Example 4
Not to access any area (nor instruction prefetch generated) in the next cycle after accessing the external area indicated by CSi Neither the address bus nor the chip select signal changes state between these two cycles
Access to the external area indicated by CSi
Access to the same external area
Access to the external area indicated by CSi
No access
BCLK Read signal Data bus Address bus CSi Data Data
BCLK Read signal Data bus Address bus CSi Data Address
Address Address
NOTE : 1. These examples show the address bus and chip select signal when accessing areas in two successive cycles. The chip select bus cycle may be extended more than two cycles depending on a combination of these examples.
Shown above is the case where separate bus is selected and the area is accessed for read without wait states. i = 0 to 3, j = 0 to 3 (not including i, however)
Figure 8.2
Examples of Address Bus and CSi Signal Output in 1-Mbyte Mode
REJ09B0392-0064 Rev.0.64 Page 56 of 373
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M16C/64 Group
8. Bus
8.2.4
Read and Write Signals
When the data bus is 16 bits wide, the read and write signals can be chosen to be a combination of RD, BHE, and, WR or a combination of RD, WRL, and WRH by using the PM02 bit in the PM0 register. When the data bus is 8 bits wide, use a combination of RD, WR, and BHE. Table 8.3 shows the Operation of RD, WRL, and WRH Signals. Table 8.4 shows the Operation of RD, WR, and BHE Signals.
Table 8.3 Operation of RD, WRL, and WRH Signals RD WRL WRH
Data Bus Width 16-bit (BYTE pin input = "L") L H H H
Status of External Data Bus Read data Write 1 byte of data to an even address Write 1 byte of data to an odd address Write data to both even and odd addresses
H L H L
H H L L
Table 8.4
Operation of RD, WR, and BHE Signals RD WR BHE
Data Bus Width 16-bit (BYTE pin input = "L")
A0 H H L L L L
Status of External Data Bus
H L H L H L H L
L H L H L H L H
L L H H L L
- (1) - (1)
8-bit (BYTE pin input = "H") NOTE: 1. Do not use.
Write 1 byte of data to an odd address Read 1 byte of data from an odd address Write 1 byte of data to an even address Read 1 byte of data from an even address Write data to both even and odd addresses Read data from both even and odd addresses H or L Write 1 byte of data H or L Read 1 byte of data
8.2.5
ALE Signal
The ALE signal latches the address when accessing the multiplexed bus space. Latch the address when the ALE signal falls.
When BYTE pin input = "H" ALE A0/D0 to A7/D7 Address Data When BYTE pin input = "L" ALE A0 Address
A8 to A19
Address (1)
A1/D0 to A8/D7
Address
Data
A9 to A19
Address
NOTE : 1. If
the entire CS space is assigned a multiplexed bus, these pins function as I/O ports.
Figure 8.3
ALE Signal, Address Bus, Data Bus
REJ09B0392-0064 Rev.0.64 Page 57 of 373
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M16C/64 Group
8. Bus
8.2.6
RDY Signal
This signal is provided for accessing external devices which need to be accessed at low speed. If input on the RDY pin is low at the last falling edge of BCLK of the bus cycle, one wait state is inserted in the bus cycle. While in a wait state, the following signals retain the state in which they were when the RDY signal was acknowledged. A0 to A19, D0 to D15, CS0 to CS3, RD, WRL, WRH, WR, BHE, ALE, HLDA Then, when the input on the RDY pin is detected high at the falling edge of BCLK, the remaining bus cycle is executed. Figure 8.4 shows Examples in which the Wait State was Inserted into Read Cycle by RDY Signal. To use the RDY signal, set the corresponding bit (bits CS3W to CS0W) in the CSR register to 0 (with wait state). When not using the RDY signal, the RDY pin need to be pulled-up.
In an instance of separate bus
BCLK RD CSi
(i = 0 to 3)
RDY
tsu (RDY-BCLK)
Accept timing of RDY signal
In an instance of multiplexed bus
BCLK
RD CSi
(i = 0 to 3)
RDY
tsu (RDY-BCLK)
Accept timing of RDY signal
: Wait using RDY signal : Wait using software
tsu (RDY - BCLK) :
Duration for RDY input setup
Shown above is the case where bits CSEi1W to CSEi0W (i = 0 to 3) in the CSE register are 00b (one wait state).
Figure 8.4
Examples in Which Wait State Was Inserted into Read Cycle by RDY Signal
REJ09B0392-0064 Rev.0.64 Page 58 of 373
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M16C/64 Group
8. Bus
8.2.7
HOLD Signal
This signal is used to transfer control of the bus from the CPU or DMAC to an external circuit. When the input on the HOLD pin is pulled low, the microcomputer is placed in a hold state after the bus access at that time finishes. The microcomputer remains in the hold state while the HOLD pin is held low, during which time the HLDA pin outputs a low-level signal. Table 8.5 shows the Microcomputer Status in Hold State. Bus-using priorities are given to HOLD, DMAC, and CPU in descending order. However, if the CPU is accessing an odd address in word units, the DMAC cannot gain control of the bus during two separate accesses.
HOLD > DMAC > CPU
Figure 8.5 Bus-Using Priorities
Table 8.5
Microcomputer Status in Hold State
Item BCLK A0 to A19, D0 to D15, CS0 to CS3, RD, WRL,WRH, WR, BHE I/O ports
HLDA
Status Output High-impedance High-impedance Maintains status when HOLD signal is received Output "L" On (but watchdog timer stops) (2) Undefined
P0, P1, P3, P4 (1) P6 to P10
Internal Peripheral Circuits ALE
NOTES: 1. When I/O port function is selected. 2. The watchdog timer does not stop when the CSPRO bit in the CSPR register is set to 1 (count source protection mode enabled).
8.2.8
BCLK Output
If the PM07 bit in the PM0 register is set to 0 (output enabled), a clock with the same frequency as that of the CPU clock is output as BCLK from the BCLK pin. Refer to 10.2 "CPU Clock and Peripheral Function Clock".
REJ09B0392-0064 Rev.0.64 Page 59 of 373
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M16C/64 Group
8. Bus
Table 8.6
Pin Functions for Each Processor Mode
Memory Expansion Mode or Microprocessor Mode 00b (separate bus) Memory Expansion Mode
Processor Mode Bits PM05 and PM04
01b (CS2 is for multiplexed bus and 11b (multiplexed bus for the others are for separate bus) 10b (CS1 is for multiplexed bus and the entire space) (1) the others are for separate bus) 8 bits "H" D0 to D7 (4) I/O ports A0/D0
(2)
Data Bus Width BYTE Pin P0_0 to P0_7 P1_0 to P1_7 P2_0 P2_1 to P2_7 P3_0 P3_1 to P3_3 P3_4 to P3_7 P4_0 to P4_3 P4_4 P4_5 P4_6 P4_7 P5_0 P5_1 P5_2 P5_3 P5_4 P5_5 P5_6 P5_7 PM11 = 0 PM11 = 1 PM06 = 0 PM06 = 1 CS0 = 0 CS0 = 1 CS1 = 0 CS1 = 1 CS2 = 0 CS2 = 1 CS3 = 0 CS3 = 1 PM02 = 0 PM02 = 1 PM02 = 0 PM02 = 1
8 bits "H" D0 to D7 I/O ports A0 A1 to A7 A8 A9 to A11 A12 to A15 I/O ports A16 to A19 I/O ports I/O ports
CS0
16 bits "L" D0 to D7 D8 to D15 A0 A1 to A7 A8
16 bits "L" D0 to D7 (4) D8 to A0 A1 to A7 /D0 to D6 (2) A8/D7 (2) D15(4)
8 bits "H" I/O ports I/O ports A0/D0 A1 to A7 /D1 to D7 A8 I/O ports I/O ports I/O ports
A1 to A7 /D1 to D7 (2) A8
I/O ports
CS1
I/O ports
CS2
I/O ports
CS3 WR
- (3)
BHE - (3) RD
WRL WRH
- (3) - (3)
WRL WRH
- (3) - (3)
BCLK
HLDA HOLD
ALE
RDY
I/O ports : Function as I/O ports or peripheral function I/O pins.
NOTES: 1. When bits PM01 and PM00 are set to 01b (memory expansion mode) and bits PM05 and PM04 are set to 11b (multiplexed bus assigned to the entire CS space), apply "H" to the BYTE pin (external data bus 8 bits wide). While the CNVSS pin is held "H" (= VCC1), do not rewrite bits PM05 and PM04 to 11b after reset. If bits PM05 and PM04 are set to 11b during memory expansion mode, P3_1 to P3_7 and P4_0 to P4_3 become I/O ports, in which case the accessible area for each CS is 256 bytes. 2. In separate bus mode, these pins serve as the address bus. 3. If the data bus is 8 bits wide, make sure the PM02 bit is set to 0 (RD, BHE, WR). 4. When accessing the area that uses a multiplexed bus, these pins output an indeterminate value during a write. REJ09B0392-0064 Rev.0.64 Page 60 of 373 Oct 12, 2007
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M16C/64 Group
8. Bus
8.2.9
External Bus Status When Internal Area IS Accessed
Table 8.7 shows the External Bus Status When Internal Area Accessed.
Table 8.7 External Bus Status When Internal Area Accessed
Item A0 to A19 D0 to D15 When Read When Write
RD, WR, WRL, WRH
SFR Accessed Address output High-impedance Output data
RD, WR, WRL, WRH output BHE output
Internal ROM, RAM Accessed Maintain the last accessed address of external area or SFR High-impedance Undefined Output "H" Maintain the last accessed status of external area or SFR Output "H" Output "L"
BHE
CS0 to CS3
Output "H" Output "L"
ALE
8.2.10
Software Wait
The PM17 bit in the PM1 register, which is a software-wait-related bit, has an influence over the internal memory and the external area. The SFR area is accessed in 2 BCLK or 3 BCLK cycles as determined by the PM20 bit in the PM2 register. Data flash, one of the internal ROMs, is affected by the PM17 bit and the FMR17 bit in the FMR1 register. See Table 8.8 "Bits and Bus Cycles Related to Software Wait (SFR, Internal Memory)" for details. Software waits can be inserted to the external area by setting the PM17 bit or setting the CSiW bit in the CSR register or bits CSEi1W to CSEi0W in the CSE register for each CSi (i = 0 to 3). To use the RDY signal, set the corresponding CSiW bit to 0 (with wait state). Refer to Table 8.9 "Bits and Bus Cycles Related to Software Wait (External Area)" for details. Table 8.8 shows the Bits and Bus Cycles Related to Software Wait (SFR, Internal Memory), Figure 8.6 shows the CSE register, and Table 8.9 shows the Bits and Bus Cycles Related to Software Wait (External Area).
Table 8.8 Bits and Bus Cycles Related to Software Wait (SFR, Internal Memory)
Area
Setting of Software-Wait-related Bits PM2 Register FMR1 Register PM1 Register FMR17 Bit PM17 Bit PM20 Bit (1) 1 0 Program ROM 1 Program ROM 2
Software Wait 1 wait
Bus cycle
SFR Internal RAM Internal ROM
0 1
0 1 0 1 0 1
2 waits No wait 1 BCLK cycle(3) 1 wait 2 BCLK cycles No wait 1 BCLK cycle(3) 1 wait 1 wait 2 BCLK cycles
2 BCLK cycles(3) 3 BCLK cycles
Data Flash (2)
-
2 BCLK cycles(3) No wait 1 BCLK cycle 1 wait 2 BCLK cycle
- indicates that either 0 or 1 can be set.
NOTES: 1. The PM 20 bit is valid when the PLC07 bit in the PLC0 register is set to 1 (PLL operation). 2. When 2.7 V VCC1 3.0 V and f (BCLK) 16 MHz, or when 3.0 V < VCC1 5.5 V and f (BCLK) 20 MHz, 1 wait is necessary to read data flash. Use the PM17 bit or the FMR 17 bit to set 1 wait. 3. Status after reset. REJ09B0392-0064 Rev.0.64 Page 61 of 373 Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
8. Bus
Chip Select Expansion Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol CSE
Address 001Bh
After Reset 00h
Bit Symbol CSE00W
Bit Name
b1
Function 0 0 1 1
b0
RW RW RW RW RW RW RW RW RW
CS0 wait expansion bit (1) CSE01W CSE10W CS1 wait expansion bit (1) CSE11W CSE20W CS2 wait expansion bit (1) CSE21W CSE30W CS3 wait expansion bit (1) CSE31W
0 : 1 wait 1 : 2 waits 0 : 3 waits 1 : Do not set
b3
0 0 1 1
b2
0 : 1 wait 1 : 2 waits 0 : 3 waits 1 : Do not set
b5
0 0 1 1
b4
0 : 1 wait 1 : 2 waits 0 : 3 waits 1 : Do not set
b7
0 0 1 1
b6
0 : 1 wait 1 : 2 waits 0 : 3 waits 1 : Do not set
NOTE : 1. Set the CSiW bit (i = 0 to 3) in the CSR register to 0 (wait state) before writing to bits CSEi1W to CSEi0W. If the CSiW bit needs to be set to 1 (no wait state), set bits CSEi1W and CSEi0W to 00b before setting it.
Figure 8.6
CSE Register
REJ09B0392-0064 Rev.0.64 Page 62 of 373
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M16C/64 Group
8. Bus
Table 8.9
Bits and Bus Cycles Related to Software Wait (External Area)
Area
Bus Mode
External Area
Separate Bus
Setting of Software-Wait-related Bits Software Wait CSE Register PM1 Regis- CSR Register Bits CSEi1W to ter PM17 Bit CSiW Bit (1) CSEi0W 0 1 00b No wait
Bus Cycle
1 BCLK cycle (Read) 2 BCLK cycles (Write) 2 BCLK cycles (4) 3 BCLK cycles 4 BCLK cycles 2 BCLK cycles 3 BCLK cycles 3 BCLK cycles 4 BCLK cycles 3 BCLK cycles
1 Multiplexed Bus 1
0 0 0 0 (3) 0 (2) 0
(2)
00b 01b 10b 00b 00b 01b 10b 00b
1 wait 2 waits 3 waits 1 wait 1 wait 2 waits 3 waits 1 wait
0 (2) 0 (2, 3)
i = 0 to 3 - indicates that either 0 or 1 can be set. NOTES: 1. To use the RDY signal, set the CSiW bit to 0 (with wait state). 2. To access in multiplexed bus mode, set the CSiW bit to 0 (with wait state). 3. When the PM17 bit is set to 1 and accesses an external area, set the CSiW bit to 0 (with wait state). 4. After reset, the PM17 bit is set to 0 (without wait state), bits CS0W to CS3W are set to 0 (with wait state), and the CSE register is set to 00h (one wait state for CS0 to CS3). Therefore, all external areas are accessed with one wait state.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
8. Bus
(1) Separate Bus, No Wait Setting Bus cycle (1) Bus cycle (1)
BCLK Write signal Read signal Data bus Address bus CS
Output
Input
Address
Address
(2) Separate Bus, 1-Wait Setting Bus cycle (1) BCLK Write signal Read signal Data bus Address bus CS
Output
Input
Bus cycle (1)
Address
Address
(3) Separate Bus, 2-Wait Setting
Bus cycle (1)
Bus cycle (1)
BCLK Write signal Read signal Data bus Address bus CS
Output
Input
Address
Address
NOTE : 1. These example timing charts indicate bus cycle length. After this bus cycle sometimes come read and write cycles in succession.
Figure 8.7
Typical Bus Timings Using Software Wait (1)
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
8. Bus
(1) Separate Bus, 3-Wait Setting Bus cycle (1) BCLK Write signal Read signal Data bus Address bus CS Output Address Address
Input
Bus cycle (1)
(2) Multiplexed Bus, 1- or 2-Wait Setting Bus cycle (1) BCLK Write signal Read signal ALE Address bus Address bus/ Data bus CS Address Address Data output Address Address
Input
Bus cycle (1)
(3) Multiplexed Bus, 3-Wait Setting Bus cycle (1) BCLK Write signal Read signal ALE Address bus Address bus/ Data bus CS Address Address Data output Address Address
Input
Bus cycle (1)
NOTE : 1. These example timing charts indicate bus cycle length. After this bus cycle sometimes come read and write cycles in succession.
Figure 8.8
Typical Bus Timings Using Software Wait (2)
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
9. Memory Space Expansion Function
9.
Memory Space Expansion Function
The following describes a memory space expansion function. During memory expansion or microprocessor mode, the memory space expansion function allows the access space to be expanded using the appropriate register bits. Table 9.1 shows Setting of Memory Space Expansion Function, Memory Space.
Table 9.1 Setting of Memory Space Expansion Function, Memory Space
Memory Space Expansion Function 1-Mbyte Mode 4-Mbyte Mode
Setting (PM15 to PM14) 00b 11b
Memory Space 1 Mbyte (no expansion) 4 Mbytes
9.1
1-Mbyte Mode
In this mode, the memory space is 1 Mbyte. In 1-Mbyte mode, the external area to be accessed is specified using the CSi (i = 0 to 3) signals (hereafter referred to as the CSi area). Figures 9.2 and 9.3 show the Memory Mapping and CS Area in 1-Mbyte mode.
9.2
4-Mbyte Mode
In this mode, the memory space is 4 Mbytes. Figure 9.1 shows the DBR Register. Bits BSR2 to BSR0 in the DBR register select a bank number which is to be accessed to read or write data. Setting the OFS bit to 1 (with offset) allows the accessed address to be offset by 40000h. In 4-Mbyte mode, the CSi (i = 0 to 3) pin function differs depending on an area to be accessed.
9.2.1
Addresses 04000h to 3FFFFh, C0000h to FFFFFh
* The CSi signal is output from the CSi pin (same operation as 1-Mbyte mode; however, the last address of the CS1 area is 3FFFFh).
9.2.2
Addresses 40000h to BFFFFh
* The CS0 pin outputs "L" * Pins CS1 to CS3 output the setting values of bits BSR2 to BSR0 (bank number)
Figures 9.4 and 9.5 show the Memory Mapping and CS Area in 4-Mbyte mode. Note that banks 0 to 6 are data-only areas. Locate the program in bank 7 or the CSi area.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
9. Memory Space Expansion Function
Data Bank Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol DBR Bit Symbol -- (b1-b0) OFS BSR0 BSR1 BSR2 -- (b7-b6)
Address 000Bh Bit Name
After Reset 00h Function RW -- RW RW
No register bits. If necessary, set to 0. Read as 0 Offset bit 0 : Not offset 1 : Offset
Bank selection bits
b5 b4 b3 0 0 0 : Bank 0 0 1 0 : Bank 2 1 0 0 : Bank 4 1 1 0 : Bank 6
b5 b4 b3 0 0 1 : Bank 1 0 1 1 : Bank 3 1 0 1 : Bank 5 1 1 1 : Bank 7
RW RW
No register bits. If necessary, set to 0. Read as 0
--
NOTE : 1. Effective when bits PM01 and PM00 in the PM0 register are set to 01b (memory expansion mode) or 11b (microprocessor mode).
Figure 9.1
DBR Register
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M16C/64 Group
9. Memory Space Expansion Function
Memory expansion mode 00000h 00400h XXXXXh 04000h 08000h 0D000h 0D800h 0E000h 10000h 14000h 27000h 28000h 30000h External area Reserved area SFR Internal RAM Reserved area
Microprocessor mode SFR Internal RAM Reserved area
CS3 (16 Kbytes)
External area SFR Data flash
(3)
CS2 (20 Kbytes) CS2 CS2 CS2 CS2
(2 Kbytes) (8 Kbytes) (16 Kbytes) (76 Kbytes)
SFR
Reserved, external area Reserved, external area
(2) (5)
Prpgram ROM 2 (4)
CS2 (102 Kbytes )
Reserved area
CS1 (32 Kbytes)
External area
CS0 (memory expansion mode : 640 Kbytes )
D0000h YYYYYh Internal ROM FFFFFh PM13 = 0 Internal RAM Capacity Address XXXXXh 12 Kbytes 033FFh 16 Kbytes 03FFFh (1) 31 Kbytes 03FFFh (1)
Reserved area
CS0 (microprocessor mode : 832 Kbytes)
Internal ROM Capacity Address YYYYYh 128 Kbytes E0000h 256 Kbytes D0000h (1) 512 Kbytes D0000h (1)
CS0 Memory expansion mode 30000h to CFFFFh Microprocessor mode 30000h to FFFFFh
External Area CS1 28000h to 2FFFFh
CS2
CS3
08000h to 0CFFFh 04000h to 0D800h to 26FFFh Note that this applies to the 07FFFh following areas only in the conditions described below. In memory expansion mode or when PM10 = 0, 08000h to 0CFFFh When PM10 = 0, 0E000h to 0FFFFh When PRG2C0 = 1 10000h to 13FFFh
NOTES : 1. When the PM13 bit in the PM1 register is set to 0, 15 Kbytes of the internal RAM and 192 Kbytes of the internal ROM can be used. 2. When the PM10 bit is set to 0, this area is used as external area; when 1, reserved area. 3. When the PM10 bit is set to 0, this area is used as external area; when 1, internal ROM (data flash). 4. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, internal ROM (program ROM 2). 5. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, reserved area.
Figure 9.2
Memory Mapping and CS Area in 1-Mbyte Mode (PM13 = 0)
Memory expansion mode 00000h 00400h XXXXXh SFR Internal RAM
Microprocessor mode SFR Internal RAM
08000h 0D000h 0D800h 0E000h 10000h 14000h 27000h 28000h 30000h
Reserved area SFR Data flash
(1) (2)
Reserved area SFR
Reserved, external area Reserved, external area
(3) (4)
Program ROM 2
CS2 CS2 CS2 CS2
(2 Kbytes) (8 Kbytes) (16 Kbytes) (76 Kbytes)
CS2 (102 Kbytes)
Reserved area
Reserved area
CS1 (32 Kbytes)
External area External area
CS0 (memory expansion mode : 320 Kbytes)
80000h YYYYYh Internal ROM FFFFFh PM13 = 1 Internal RAM Internal ROM Capacity Address XXXXXh Capacity Address YYYYYh CS0 128 Kbytes E0000h 12 Kbytes 033FFh Memory expansion mode 30000h to 7FFFFh 256 Kbytes C0000h 16 Kbytes 043FFh Microprocessor mode 30000h to FFFFFh
Reserved area
CS0 (misropocessor mode : 832 Kbytes)
External area CS1 CS2 0D800h to 26FFFh 28000h to Note that this applies to the 2FFFFh following areas only in the
When PM10 = 0, 0E000h to 0FFFFh When PRG2C0 = 1, 10000h to 13FFFh
CS3 No area
conditions described below.
NOTES : 1. When the PM10 bit is set to 0, this area is used as external area; when 1, internal ROM (data flash). 2. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, internal ROM (program ROM 2). 3. When the PM10 bit is set to 0, this area is used as external area; when 1, reserved area. 4. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, reserved area.
Figure 9.3
Memory Mapping and CS Area in 1-Mbyte Mode (PM13 = 1)
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
9. Memory Space Expansion Function
Memory expansion mode 00000h 00400h XXXXXh 04000h 08000h 0D000h 0D800h 0E000h 10000h 14000h 27000h 28000h 40000h External area Reserved area SFR Internal RAM Reserved area
Microprocessor mode SFR Internal RAM Reserved area
CS3 (16 Kbytes)
External area SFR Data flash
(4) (5)
CS2 (20 Kbytes) CS2 CS2 CS2 CS2
(2 Kbytes) (8 Kbytes) (16 Kbytes) (76 Kbytes)
SFR
Reserved, external area
(3)
Program ROM 2
Reserved, external area (6)
CS2 (102 Kbytes)
Reserved area
CS1 (96 Kbytes)
External area Other than the CS area (512 Kbytes x 8 banks)
C0000h D0000h YYYYYh Internal ROM FFFFFh PM13 = 0 Reserved area
CS0 (memory expansion mode : 64 Kbytes) CS0 (misropocessor mode : 256 Kbytes)
Internal RAM Internal ROM Capacity Address XXXXXh Capacity Address YYYYYh CS0 12 Kbytes 033FFh 128 Kbytes E0000h Memory expansion mode C0000h to CFFFFh 256 Kbytes D0000h (2) 03FFFh (2) 16 Kbytes 512 Kbytes D0000h (2) 31 Kbytes 03FFFh (2) Microprocessor mode C0000h to FFFFFh
CS1 28000h to 3FFFFh
External area CS2
08000h to 0CFFFh 0D800h to 26FFFh Note that this applies to the following areas only in the conditions described below. Inmemory expansion mode or when PM10 = 0, 08000h to 0CFFFh When PM10 = 0, 0E000h to 0FFFFh: When PRG2C0 = 1, 10000h to 13FFFh
CS3 04000h to 07FFFh
Other than the CS area (1)
40000h to BFFFFh
NOTES : 1. The CS0 pin outputs a low signal, and pins CS1 to CS3 output a bank number. 2. When the PM13 bit is set to 0, 15 Kbytes of the internal RAM and 192 Kbytes of the internal ROM can be used. 3. When the PM10 bit is set to 0, this area is used as external area; when 1, reserved area. 4. When the PM10 bit is set to 0, this area is used as external area; when 1, internal ROM (data flash). 5. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, internal ROM (program ROM 2). 6. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, reserved area.
Figure 9.4
Memory Mapping and CS Area in 4-Mbyte Mode (PM13 = 0)
Memory expansion mode Microprocessor mode SFR Internal RAM
00000h 00400h XXXXXh
SFR Internal RAM
08000h 0D000h 0D800h 0E000h 10000h 14000h 27000h 28000h 40000h
Reserved area SFR Data flash (2) Program ROM 2 (3)
Reserved area SFR
Reserved, external area
(4)
Reserved, external area (5)
CS2 CS2 CS2 CS2
(2 Kbytes) (8 Kbytes) (16 Kbytes) (76 Kbytes)
CS2 (102 Kbytes)
Reserved area
Reserved area
CS1 (96 Kbytes)
External area External area Other than the CS area (memory expansion mode: 256 Kbytes x 8 banks) * Change offset to use 256 Kbytes x 8 banks x2 Other than the CS area (microprocessor mode: 512 Kbytes x 8 banks) Reserved area
80000h C0000h YYYYYh FFFFFh
CS0 (misropocessor mode: 256 Kbytes)
Internal ROM
PM13 = 1 Internal RAM Internal ROM Capacity Address XXXXXh Capacity Address YYYYYh CS0 12 Kbytes 033FFh 128 Kbytes E0000h Microprocessor mode 16 Kbytes 256 Kbytes C0000h C0000h to FFFFFh 043FFh 31 Kbytes 07FFFh 512 Kbytes 80000h
CS1 28000h to 3FFFFh
External Area CS2
0D800h to 26FFFh Note that this applies to the following areas only in the conditions described below. When PM10 = 0, 0E000h to 0FFFFh When PRG2C0 = 1, 10000h to 13FFFh
CS3 No area
Other than the CS area (1)
Memory expansion mode 40000h to 7FFFFh Microprocessor mode 40000h to BFFFFh
NOTES : 1. The CS0 pin outputs a low signal, and pins CS1 to CS3 output a bank number. 2. When the PM10 bit is set to 0, this area is used as external area; when 1, internal ROM (data flash). 3. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, internal ROM (program ROM 2). 4. When the PM10 bit is set to 0, this area is used as external area; when 1, reserved area. 5. When the PRG2C0 bit in the PRG2C register is set to 1, this area is used as external area; when 0, reserved area.
Figure 9.5
Memory Mapping and CS Area in 4-Mbyte Mode (PM13 = 1)
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
9. Memory Space Expansion Function
Figure 9.6 shows the External Memory Connect Example in 4-Mbyte Mode. In this example, the CS pin of 4-Mbyte ROM is connected to the CS0 pin of the microcomputer. The 4Mbyte ROM address input pins AD21, AD20, and AD19 are connected to pins CS3, CS2, and CS1 of the microcomputer, respectively. The address input AD18 pin is connected to the A19 pin of microcomputer. Figures 9.7 to 9.9 show the relationship of addresses between the 4-Mbyte ROM and the microcomputer for the case of a connection example in Figure 9.6. In microprocessor mode or in memory expansion mode where the PM13 bit in the PM1 register is 0, banks are located every 512 Kbytes. Setting the OFS bit in the DBR register to 1 (offset) allows the accessed address to be offset by 40000h, so that even the data overlapping at a bank boundary can be accessed in succession. In memory expansion mode where the PM13 bit is 1, each 512-Kbyte bank can be accessed in 256 Kbyte units by switching them over with the OFS bit. Because the SRAM can be accessed on condition that the chip select signals S2 = "H" and S1 = "L", CS0 and CS2 can be connected to S2 and S1, respectively. If the SRAM does not have the input pins which accept "H" active and "L" active chip select signals (S1, S2), CS0 and CS2 should be decoded external to the chip.
D0 to D7 A0 to A16 A17 A19 CS1 CS2 CS3 RD CS0 WR
8 17
DQ0 to DQ7 AD0 to AD16 AD18 AD19 AD20 AD21 OE CS DQ0 to DQ7 AD0 to AD16 OE S2 S1 (1) W
Microcomputer
NOTE : 1. If only one chip select pin (S1 or S2) is present, using an external circuit is required for decode.
Figure 9.6
External Memory Connect Example in 4-Mbyte Mode
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128-Kbyte SRAM
4-Mbyte ROM
AD17
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
9. Memory Space Expansion Function
Memory expansion mode where PM13 = 0
ROM address Microcomputer address
OFS bit in DBR register = 0
000000h 040000h 080000h 40000h
OFS bit in DBR register = 1
Bank Number
OFS
Access Area
Output from the Microcomputer Pins CS Output CS3 CS2 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 CS1 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 1 1 A19 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 0 1 1 1 1 Address Output A18 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 1 0 0 1 1 A17 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 0 A16 A15 to A0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 0 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh
0
40000h
40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h 7FFFFh 80000h BFFFFh C0000h CFFFFh D0000h DFFFFh D0000h DFFFFh
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
000000h 07FFFFh 040000h 0BFFFFh 080000h 0FFFFFh 0C0000h 13FFFFh 100000h 17FFFFh 140000h 1BFFFFh 180000h 1FFFFFh 1C0000h 23FFFFh 200000h 27FFFFh 240000h 2BFFFFh 280000h 2FFFFFh 2C0000h 33FFFFh 300000h 37FFFFh 340000h 3BFFFFh 380000h 3BFFFFh 3C0000h 3FFFFFh 3C0000h 3CFFFFh
Internal ROM access Internal ROM access Internal ROM access Internal ROM access
bank 0 (512 Kbytes)
BFFFFh 40000h
0 1 0 1 1 0 2 1 0 3 1 0 4 1 0 5 1 0 6 1
bank 0 (512 Kbytes)
BFFFFh 40000h
0C0000h 100000h 140000h 180000h
bank 1 (512 Kbytes)
BFFFFh 40000h
bank 1 (512 Kbytes)
BFFFFh 40000h
bank 2 (512 Kbytes)
BFFFFh 40000h
bank 2 (512 Kbytes)
BFFFFh 40000h
Data only
1C0000h
bank 3 (512 Kbytes)
BFFFFh 40000h
200000h 240000h 280000h
bank 3 (512 Kbytes)
BFFFFh 40000h
bank 4 (512 Kbytes)
BFFFFh 40000h
bank 4 (512 Kbytes)
BFFFFh 40000h
2C0000h 300000h
bank 5 (512 Kbytes)
BFFFFh 40000h
bank 5 (512 Kbytes)
BFFFFh 40000h (512 Kbytes) BFFFFh
340000h 380000h 3C0000h 3FFFFFh
bank 6 (512 Kbytes)
BFFFFh 40000h
bank 6
Program or data Program or data
bank 7 (512 Kbytes)
BFFFFh
7
0
A21
A20
A19
A18
N.C.
A17
A16 A15 to A0
Address input for 4-Mbyte ROM
4-Mbyte ROM access area
Figure 9.7
Relationship Between Addresses on 4-Mbyte ROM and Those on Microcomputer (1)
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M16C/64 Group
9. Memory Space Expansion Function
Memory expansion mode where PM13 = 1
ROM address Microcomputer address
OFS bit in DBR register = 0
000000h 040000h 080000h
OFS bit in DBR register = 1
Bank Number
OFS
Access Area
Output from the Microcomputer Pins CS Output CS3 CS2 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 CS1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 A19 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 Address Output A18 A17 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 A16 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 A15 to A0 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh
bank 0 40000h
(256 Kbytes) 7FFFFh
0 bank 0
40000h
40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 40000h 7FFFFh 80000h FFFFFh 40000h
000000h 03FFFFh 040000h 07FFFFh 080000h 0BFFFFh 0C0000h 0FFFFFh 100000h 13FFFFh 140000h 17FFFFh 180000h 1BFFFFh 1C0000h 1FFFFFh 200000h 23FFFFh 240000h 27FFFFh 280000h 2BFFFFh 2C0000h 2FFFFFh 300000h 33FFFFh 340000h 37FFFFh 380000h 3BFFFFh
Internal ROM access Internal ROM access
0 1 0
(256 Kbytes) 7FFFFh
bank 1 40000h
(256 Kbytes) 7FFFFh
0C0000h 100000h 140000h 180000h
bank 1 bank 2 40000h
40000h (256 Kbytes) 7FFFFh
1 1 0
(256 Kbytes) 7FFFFh
bank 2 bank 3 40000h
40000h (256 Kbytes) 7FFFFh
2 1 0
Data only
(256 Kbytes) 7FFFFh
1C0000h
bank 3 bank 4 40000h
40000h (256 Kbytes) 7FFFFh
3 1 0
200000h 240000h 280000h
(256 Kbytes) 7FFFFh
bank 4 bank 5 40000h
40000h
4 1 0
(256 Kbytes) 7FFFFh
(256 Kbytes) 7FFFFh
2C0000h 300000h
bank 5 bank 6 40000h
40000h (256 Kbytes) 7FFFFh
5 1 0
(256 Kbytes) 7FFFFh
340000h 380000h 3C0000h 3FFFFFh
bank 6 bank 7 40000h
40000h
6 1
(256 Kbytes) 7FFFFh
Program or data Data only
(256 Kbytes) 7FFFFh
bank 7
40000h
7
0
(256 Kbytes) 7FFFFh
1 1
1 1
1 1
1 1
0 0
0 1
0 1
0000h FFFFh
3C0000h 3FFFFFh
Internal ROM access Internal ROM access
7
1
7FFFFh 80000h FFFFFh
A21
A20
A19
A18
N.C.
A17
A16 A15 to A0
Address input for 4-Mbyte ROM
4-Mbyte ROM access area
Figure 9.8
Relationship Between Addresses on 4-Mbyte ROM and Those on Microcomputer (2)
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M16C/64 Group
9. Memory Space Expansion Function
Microprocessor mode
ROM address Microcomputer address
OFS bit in DBR register = 0
000000h 40000h
Output from the Microcomputer Pins Bank Number OFS Access Area CS Output CS3 CS2 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 A20 CS1 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 1 1 A19 A19 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 0 1 1 1 1 A18 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 A21 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 1 0 0 1 1 N.C. Address Output A18 A17 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 A17 A16 A15 to A0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh 0000h FFFFh
OFS bit in DBR register = 1
bank 0
040000h 080000h (512 Kbytes) BFFFFh 40000h
0
40000h (512 Kbytes) BFFFFh 40000h
40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h BFFFFh 40000h 7FFFFh 80000h BFFFFh C0000h FFFFFh
000000h 07FFFFh 040000h 0BFFFFh 080000h 0FFFFFh 0C0000h 13FFFFh 100000h 17FFFFh 140000h 1BFFFFh 180000h 1FFFFFh 1C0000h 23FFFFh 200000h 27FFFFh 240000h 2BFFFFh 280000h 2FFFFFh 2C0000h 33FFFFh 300000h 37FFFFh 340000h 3BFFFFh 380000h 3BFFFFh 3C0000h 3FFFFFh 3C0000h 3FFFFFh
4-Mbyte ROM access area
0 1 0 1 1 0 2 1 0 3 1 0 4 1 0 5 1 0 6 1
bank 0
bank 1
0C0000h 100000h 140000h 180000h (512 Kbytes) BFFFFh 40000h (512 Kbytes) BFFFFh 40000h (512 Kbytes) BFFFFh 40000h
bank 1
(512 Kbytes) BFFFFh 40000h
bank 2
bank 2
(512 Kbytes) BFFFFh 40000h
Data only
1C0000h
bank 3
bank 3
(512 Kbytes) BFFFFh 40000h (512 Kbytes) BFFFFh 40000h (512 Kbytes) BFFFFh 40000h
200000h 240000h 280000h
(512 Kbytes) BFFFFh 40000h
bank 4
bank 4
2C0000h 300000h
bank 5
(512 Kbytes) BFFFFh 40000h
bank 5
bank 6
340000h 380000h 3C0000h 3FFFFFh (512 Kbytes) BFFFFh bank 7 40000h (512 Kbytes) 7FFFFh C0000h FFFFFh
bank 6
(512 Kbytes) BFFFFh
Program or data Program or data
7
0
A16 A15 to A0
Address input for 4-Mbyte ROM
Figure 9.9
Relationship Between Addresses on 4-Mbyte ROM and Those on Microcomputer (3)
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Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
10. Clock Generation Circuit
10. Clock Generation Circuit
10.1 Type of the Clock Generation Circuit
4 circuits are incorporated to generate the system clock signal: * Main clock oscillation circuit * Sub clock oscillation circuit * 125 kHz on-chip oscillator * PLL frequency synthesizer Table 10.1 lists the Clock Generation Circuit Specifications. Figure 10.1 shows the System Clock Generation Circuit. Figures 10.2 to 10.6 show the clock-related registers.
Table 10.1 Clock Generation Circuit Specifications
Item Use of Clock
Main Clock Oscillation Circuit CPU clock source Peripheral function clock source
Sub Clock Oscillation Circuit CPU clock source Clock source of timer A and B.
Clock Frequency Usable Oscillator Pins to Connect Oscillator Oscillation Stop, Restart Function Oscillator Status After Reset Other
0 to 20 MHz Ceramic oscillator Crystal oscillator XIN, XOUT Presence Oscillating
32.768 kHz Crystal oscillator XCIN, XCOUT Presence Stopped
125 kHz On-Chip Oscillator CPU clock source Peripheral function clock source CPU and peripheral function clock sources when the main clock stops oscillating About 125 kHz Presence Oscillating -
PLL Frequency Synthesizer CPU clock source Peripheral function clock source
10 to 25 MHz - (1) - (1) Presence Stopped - (1)
Externally derived clock can be input
NOTE: 1. The PLL frequency synthesizer uses the main clock oscillation circuit as a reference clock source. The items above are based on those of the main clock oscillation circuit.
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M16C/64 Group
10. Clock Generation Circuit
Subclock oscillation circuit XCIN CM04 Subclock XCOUT
I/O ports
CM01 to CM00 = 00b PM01 to PM00 = 00b, CM01 to CM00 = 01b PM01 to PM00 = 00b, CM01 to CM00 = 10b 1/32
fC32
CLKOUT PM01 to PM00 = 00b, CM01 to CM00 = 11b
fC
CM14
125 kHz on-chip oscillator Oscillation stop, re-oscillation detection circuit
125 kHz on-chip oscillator clock fOCO-S
f8
f32
f1
CM10 = 1 (stop mode)
SQ XIN R Main clock CM05 Main clock oscillation circuit XOUT
PLL frequency synthesizer PLL clock 1
0 CM11
PM25
bc
CM21=1
a
Divider
d
fC
CM07=0
D4INT clock CPU clock BCLK
CM21=0
CM07=1
CM02 S WAIT instruction R Q
b
RESET Software reset NMI PM24 Interrupt request level judgement output Brown-out reset Watchdog timer reset Oscillation stop detect reset CM02, CM04, CM05, CM06, CM07 : bits in the CM0 register CM10, CM11, CM14, CM16, CM17 : bits in the CM1 register PCLK0, PCLK1 : bits in the PCLKR register CM21, CM27 : bits in the CM2 register CM06 = 0 CM17 to CM16 = 10b CM06 = 1
c
1/2 1/2 1/16
CM06 = 0 CM17 to CM16 = 11b
a
1/2 1/2
1/2 1/4
1/2 1/8
1/32
d
CM06 = 0 CM17 to CM16 = 01b CM06 = 0 CM17 to CM16 = 00b
Details of the Divider
Oscillation Stop, Re-Oscillation Detection Circuit
Main clock
Pulse generation circuit for clock edge detection and charge / discharge control
CM27 = 0
Charge / discharge circuit
Reset generating circuit Oscillation stop, re-oscillation detection interrupt generating circuit
Oscillation stop detection reset Oscillation stop, re-oscillation detection interrupt signal CM21 switch signal
CM27 = 1
PLL Frequency Synthesizer
1/32 Phase comparator Main clock Reference clock divider Charge pump Voltage control oscillator (VCO)
Divider
PLL clock
Internal lowpass filter
Figure 10.1
System Clock Generation Circuit
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M16C/64 Group
10. Clock Generation Circuit
System Clock Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol CM0
Bit Symbol
Address 0006h Bit Name
b1 b0
After Reset 01001000b Function RW
CM00 CM01
Clock output function select bit 0 0 (valid only in single-chip 1 mode) 1 WAIT mode peripheral function clock stop bit (10)
0 : I/O port P5_7 1 : Output fC 0 : Output f8 1 : Output f32
RW
CM02
0 : Peripheral function clock f1 does not stop in wait mode 1 : Peripheral function clock f1 stops in wait mode (8)
RW
CM03 CM04 CM05 CM06
XCIN-XCOUT drive capacity select 0 : Low bit (2) 1 : High Port XC select bit (2) Main clock stop bit
(3, 4, 10, 12, 13)
RW RW RW RW
0 : I/O ports P8_6, P8_7 1 : XCIN-XCOUT oscillation function (9) 0 : On 1 : Off (5) 0 : CM16 and CM17 enabled 1 : Division-by-8 mode 0 : Main clock, PLL clock, or 125 kHz onchip oscillator clock 1 : Sub clock
Main clock division select bit 0 (7, 13, 14) System clock select bit
(6, 10, 11, 12)
CM07
RW
NOTES : 1. Rewrite this register after setting the PRC0 bit in the PRCR register to 1 (write enabled). 2. The CM03 bit is set to 1 (high) while the CM04 bit is set to 0 (I/O port) or when entering stop mode. 3. This bit is provided to stop the main clock when the low power consumption mode or 125 kHz on-chip oscillator low power dissipation mode is selected. This bit cannot be used for detection as to whether the main clock stops or not. To stop the main clock, set bits as follows: (a) Set the CM07 bit to 1 (sub clock selected) with the sub-clock stably oscillates, or set the CM21 bit in the CM2 register to 1 (125 kHz on-chip oscillator selected). (b) Set the CM20 bit in the CM2 register to 0 (oscillation stop, re-oscillation detection function disabled). (c) Set the CM05 bit to 1 (stop). 4. During external clock input, set the CM05 bit to 0 (oscillate). 5. When the CM05 bit is set to 1, the XOUT pin is held "H". Because the internal feedback resistor remains connected, the XIN pin is pulled "H" to the same level as XOUT via the feedback resistor. 6. After setting the CM04 bit to 1 (XCIN-XCOUT oscillator function), wait until the sub-clock oscillates stably before switching the CM07 bit from 0 to 1 (sub clock). 7. When entering stop mode, the CM06 bit is set to 1 (divide-by-8 mode). 8. The fC32 and fOCO-S clock do not stop. 9. To use a sub-clock, set this bit to 1. Also make sure ports P8_6 and P8_7 are directed for input, with no pullups. 10. When the PM21 bit in the PM2 register is set to 1 (disable clock modification), this bit remains unchanged even if writing to bits CM02, CM05, and CM07. 11. When setting the PM21 bit to 1, set the CM07 bit to 0 (main clock) before setting the PM21 bit to 1. 12. To use the main clock as the clock source for the CPU clock, set bits as follows. (a) Set the CM05 bit to 0 (oscillate). (b) Wait the main clock oscillation stabilizes. (c) Set bits CM11, CM21, and CM07 to 0. 13. When the CM07 bit is set to 1 (sub clock) and the CM05 bit is set to 1 (main clock stops), the CM06 bit is fixed to 1 (divide-by-8 mode) and the CM15 bit is fixed to 1 (drive capacity high). 14. To return from 125 kHz on-chip oscillator mode to high-speed or middle-speed mode, set bits CM06 and CM15 to 1.
Figure 10.2
CM0 Register
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M16C/64 Group
10. Clock Generation Circuit
System Clock Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol CM1
Bit Symbol
Address 0007h Bit Name All clock stop control bit
(4, 6)
After Reset 00100000b Function RW RW RW RW RW RW
CM10 CM11 -- (b3-b2) CM14 CM15 CM16
0 : Clock on 1 : All clocks off (stop mode) 0 : Main clock 1 : PLL clock (5) Set to 0
System clock select bit 1 Reserved bits
(6, 7)
125 kHz on-chip oscillator stop 0 : 125 kHz on-chip oscillator on bit (8, 9) 1 : 125 kHz on-chip oscillator off XIN-XOUT drive capacity select bit (2) 0 : Low 1 : High b7 b6 0 0 : No division mode 0 1 : Divide-by-2 mode 1 0 : Divide-by-4 mode 1 1 : Divide-by-16 mode
Main clock division select bit 1
(3)
RW
CM17
NOTES : 1. Rewrite this register after setting the PRC0 bit in the PRCR register to 1 (write enabled). 2. When entering stop mode or the CM05 bit is set to 1 (main clock stops) in low speed mode, the CM15 bit is set to 1 (drive capacity high). 3. This bit is valid when the CM06 bit is set to 0 (bits CM16 and CM17 enabled). 4. If the CM10 bit is set to 1 (stop mode), XOUT is held "H" and the internal feedback resistor is disconnected. Pins XCIN and XCOUT are in high-impedance state. When the CM11 bit is set to 1 (PLL clock), or the CM20 bit in the CM2 register is set to 1 (oscillation stop detection function enabled), do not set the CM10 bit to 1. 5. After setting the PLC07 bit in the PLC0 register to 1 (PLL operation), wait tsu (PLL) elapses before setting the CM11 bit to 1 (PLL clock). 6. When the PM21 bit in the PM2 register is set to 1 (disable clock modification), this bit remains unchanged even if writing to bits CM10 and CM11. When the CSPRO bit in the CSPR register is set to 1 (count source protection mode), this bit remains unchanged even if writing to the CM10 bit. 7. The CM11 bit is valid when bits CM07 and CM21 are set to 0. 8. The CM14 bit can be set to 1 (125 kHz on-chip oscillator off) when the CM21 bit is set to 0 (main clock or PLL clock). When the CM21 bit is set to 1 (125 kHz on-chip oscillator clock), the CM14 bit is set to 0 (125 kHz on-chip oscillator on) and remains unchanged even if writing 1 to this bit. 9. When the CSPRO bit in the CSPR register is set to 1 (count source protection mode), the CM14 bit is automatically set to 0 (125 kHz on-chip oscillator on) and remains unchanged even if writing a 1 to this bit (125 kHz on-chip oscillator does not stop).
Figure 10.3
CM1 Register
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M16C/64 Group
10. Clock Generation Circuit
Oscillation Stop Detection Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol CM2
Bit Symbol
Address 000Ch Bit Name Function
After Reset 0X000010b (11) RW
CM20
0: Oscillation stop and re-oscillation Oscillation stop and detection function disabled re-oscillation detection enable 1: Oscillation stop and re-oscillation bit (7, 9, 10,11) detection function enabled System clock select bit 2
(2, 3, 6, 8, 11, 12)
RW
CM21
0: Main clock or PLL clock 1: 125 kHz on-chip oscillator clock 0: Main clock stops and re-oscillation not detected 1: Main clock stops and re-oscillation detected 0: Main clock oscillates 1: Main clock stops Set to 0
RW
CM22
Oscillation stop and re-oscillation detection flag (4) XIN monitor flag (5) Reserved bits
RW
CM23 -- (b5-b4) -- (b6) CM27
RO RW -- RW
No register bit. If necessary, set to 0. Read as undefined value Operation select bit 0: Oscillation stop detection reset (when an oscillation stops and 1: Oscillation stop, re-oscillation detection re-oscillation is detected) (11) interrupt
NOTES : 1. Rewrite this register after setting the PRC0 bit in the PRCR register to 1 (write enabled). 2. When the CM20 bit is set to 1 (oscillation stop and re-oscillation detection function enabled), the CM27 bit is set to 1 (oscillation stop and re-oscillation detection interrupt), and the CPU clock source is the main clock, the CM21 bit is set to 1 (125 kHz on-chip oscillator clock) if the main clock stop is detected. 3. If the CM20 bit is set to 1 and the CM23 bit is set to 1 (main clock stops), do not set the CM21 bit to 0. 4. This bit is set to 1 when the main clock stop is detected and the main clock re-oscillation is detected. When this flag changes state from 0 to 1, an oscillation stop or a re-oscillation detection interrupt is generated. Use this bit in an interrupt routine to determine the factors of interrupts between the oscillation stop, re-oscillation etection interrupt and the watchdog timer interrupt. This bit is set to 0 by writing 0 in a program. (This bit remains unchanged even if a 1 is written. Nor is it set to 0 when an oscillation stop or a re-oscillation detection interrupt request is acknowledged.) When the CM22 bit is set to 1 and an oscillation stop or a reoscillation is detected, an oscillation stop or a re-oscillation detection interrupt is not generated. 5. Determine the main clock status by reading the CM23 bit several times in an oscillation stop or a re-oscillation detection interrupt routine. 6. This bit is valid when the CM07 bit in the CM0 register is set to 0. 7. When the PM21 bit in the PM2 register is set to 1 (disable clock modification), this bit remains unchanged even if writing to the CM20 bit. 8. When the CM20 bit is set to 1 (oscillation stop and re-oscillation detection function enabled), the CM27 bit is 1 (oscillation stop and re-oscillation detection interrupt), and the CM11 bit is set to 1 (PLL clock is selected as the CPU clock source), the CM21 bit remains unchanged even if a main clock stop is detected. When the CM22 bit is set to 0 under these conditions, an oscillation stop, a re-oscillation detection interrupt request is generated at main clock stop detection. Set the CM21 bit to 1 (125 kHz on-chip oscillator clock) in the interrupt routine. 9. Set the CM20 bit to 0 (disabled) before entering stop mode. Exit stop mode before setting the CM20 bit back to 1 (enabled). 10. Set the CM20 bit in the CM2 register to 0 (disabled) before setting the CM05 bit in the CM0 register to 1 (main clock stops). 11. Bits CM20, CM21, and CM27 remain unchanged at the oscillation stop detection reset. 12. When the CM21 bit is set to 0 (main clock or PLL clock) and the CM05 bit is set to 1 (main clock stops), the CM06 bit is fixed to 1 (divide-by-8 mode) and the CM15 bit is fixed to 1 (drive capacity high).
Figure 10.4
CM2 Register
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M16C/64 Group
10. Clock Generation Circuit
Peripheral Clock Select Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
000000
Symbol PCLKR Bit Symbol PCLK0 Bit Name
Address 0012h Function 0 : f2TIMAB 1 : f1TIMAB
After Reset 00000011b RW RW
Timers A and B clock select bit (clock source for Timers A , B, and the dead time timer)
PCLK1
SI/O clock select bit 0 : f2SIO (clock source for UART0 to UART2, UART5 to UART7, SI/ 1 : f1SIO O3, and SI/O4) Reserved bits Set to 0. Read as undefined value
RW
-- (b7-b2)
RW
NOTE : 1. Write to this register after setting the PRC0 bit in the PRCR register to 1 (write enabled).
Processor Mode Register 2 (1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol PM2
Bit Symbol
Address 001Eh Bit Name Specifying wait when accessing SFR at PLL operation (2) System clock protection bit
(3, 4)
After Reset XX000X01b Function RW RW
PM20
0 : 2 waits 1 : 1 wait 0 : Clock is protected by PRCR register 1 : Clock modification disabled
PM21 -- (b2) -- (b3) PM24
RW
No register bit. If necessary, set to 0. Read as undefined value
--
Reserved bit
Set to 0 0 : Port P8_5 function 1 : NMI function 0 : provide enabled 1 : provide disabled
RW
P8_5 / NMI function select bit (3) D4INT clock provide enable bit
(5)
RW
PM25 -- (b7-b6)
RW
No register bits. If necessary, set to 0. Read as undefined value
--
NOTES : 1. Write to this register after setting the PRC1 bit in the PRCR register to 1 (write enabled). 2. The PM20 bit becomes effective when the PLC07 bit in the PLC0 register is set to 1 (PLL on). Change the PM20 bit when the PLC07 bit is set to 0 (PLL off). 3. Once this bit is set to 1, it cannot be cleared to 0 in a program. 4. If the PM21 bit is set to 1, writing to the following bits has no effect: CM02 bit in CM0 register CM05 bit in CM0 register (main clock does not stop) CM07 bit in CM0 register (clock source for the CPU clock does not change) CM10 bit in CM1 register (stop mode is not entered) CM11 bit in CM1 register (clock source for the CPU clock does not change) CM20 bit in CM2 register (oscillation stop and re-oscillation detection function settings do not change) All bits in PLC0 register (PLL frequency synthesizer settings do not change) Be aware that the WAIT instruction cannot be executed when the PM21 bit = 1. 5. When using low voltage detection interrupt, set the PM25 bit to 1 (provide enabled).
Figure 10.5
PCLKR Register and PM2 Register
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M16C/64 Group
10. Clock Generation Circuit
PLL Control Register 0 (1, 2)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PLC0
Bit Symbol
Address 001Ch Bit Name
b2 b1 b0
After Reset 0X01X010b Function RW RW
PLC00 PLL multiplying factor select bit (3)
PLC01
PLC02 -- (b3) PLC04 Reference frequency counter set bit (3) PLC05 -- (b6) PLC07
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 : Do not set 1 : Multiply by 2 0 : Multiply by 4 1 : Multiply by 6 0 : Multiply by 8 1: 0: Do not set 1:
RW
RW
Reserved bit
Read as undefined value
b5 b4
RO RW
0 0 1 1
0 : No division 1 : Divide-by-2 0 : Divide-by-4 1 : Do not set
RW -- RW
No register bit. If necessary, set to 0. Read as undefined value Operation enable bit (4) 0 : PLL off 1 : PLL on
NOTES : 1. Write to this register after setting the PRC0 bit in the PRCR register to 1 (write enabled). 2. When the PM21 bit in the PM2 register is 1 (clock modification disabled), writing to this register has no effect. 3. Bits PLC00 to PLC02, PLC04, and PLC5 can only be modified when the PLC07 bit = 0 (PLL turned off). The value once written to this bit cannot be modified. 4. Before setting the PLC07 bit to 1, set the CM05 bit to 0 (main clock oscillation).
Figure 10.6
PLC0 Register
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M16C/64 Group The following describes the clocks generated by the clock generation circuit.
10. Clock Generation Circuit
10.1.1
Main Clock
This clock is provided by the main clock oscillation circuit and used as the clock source for the CPU and peripheral function clocks. The main clock oscillation circuit is configured by connecting a resonator between pins XIN and XOUT. The main clock oscillation circuit contains a feedback resistor, which is disconnected from the oscillation circuit during stop mode in order to reduce the amount of power consumed in the chip. The main clock oscillation circuit may also be configured by feeding an externally generated clock to the XIN pin. Figure 10.7 shows the Examples of Main Clock Connection Circuit. The power consumption in the chip can be reduced by setting the CM05 bit in the CM0 register to 1 (main clock oscillation circuit turned off) after switching the clock source for the CPU clock to a sub clock or 125 kHz on-chip oscillation clock. In this case, XOUT goes "H". Furthermore, because the internal feedback resistor remains on, XIN is pulled "H" to XOUT via the feedback resistor. During stop mode, all clocks including the main clock are turned off. Refer to 10.4 "Power Control" for details.
(Built-in feedback resistor) CIN XIN Oscillator XOUT Rd VSS
(1)
Microcomputer
(Built-in feedback resistor) XIN
Microcomputer
External clock
VCC1 VSS
COUT XOUT Open
NOTE : 1. Place a damping resistor if required. The resistance will vary depending on the oscillator and the oscillation drive capacity setting. Use the value recommended by each oscillator manufacturer. When the oscillation drive capacity is set to low, check if oscillation is stable at low. Also, place a feedback resistor between XIN and XOUT if the oscillator manufacturer recommends placing the resistor externally.
Figure 10.7
Examples of Main Clock Connection Circuit
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10. Clock Generation Circuit
10.1.2
Sub Clock
The sub clock is generated by the sub clock oscillation circuit. This clock is used as the clock source for the CPU clock, as well as the timer A and timer B count sources. In addition, an fC clock with the same frequency as that of the sub clock can be output from the CLKOUT pin. The sub clock oscillation circuit is configured by connecting a crystal resonator between pins XCIN and XCOUT. The sub clock oscillation circuit contains a feedback resistor, which is disconnected from the oscillation circuit during stop mode in order to reduce the amount of power consumed in the chip. The sub clock oscillation circuit may also be configured by feeding an externally generated clock to the XCIN pin. Figure 10.8 shows the Examples of Sub Clock Connection Circuit. After reset, the sub clock is turned off. At this time, the feedback resistor is disconnected from the oscillation circuit. To use the sub clock for the CPU clock, set the CM07 bit in the CM0 register to 1 (sub clock) after the sub clock becomes oscillating stably. During stop mode, all clocks including the sub clock are turned off. Refer to 10.4 "Power Control" for details.
(Built-in feedback resistor) CCIN XCIN Oscillator XCOUT RCd (1) VSS CCOUT
Microcomputer
(Built-in feedback resistor) XCIN
Microcomputer
External clock
VCC1 VSS
XCOUT Open
NOTE : 1. Place a damping resistor if required. The resistance will vary depending on the oscillator and the oscillation drive capacity setting. Use the value recommended by each oscillator manufacturer. When the oscillation drive capacity is set to low, check if oscillation is stable at low. Also, place a feedback resistor between XCIN and XCOUT if the oscillator manufacturer recommends placing the resistor externally.
Figure 10.8
Examples of Sub Clock Connection Circuit
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M16C/64 Group
10. Clock Generation Circuit
10.1.3
125 kHz On-Chip Oscillator Clock (fOCO-S)
This clock, approximately 125 kHz, is supplied by 125 kHz on-chip oscillator. This clock is used as the clock source for the CPU and peripheral function clocks. In addition, if the CSPRO bit in the CSPR register is 1 (count source protection mode enabled), this clock is used as the count source for the watchdog timer (Refer to 13.2 "Count Source Protection Mode Enabled"). After reset, the 125 kHz on-chip oscillator divided by 8 provides the CPU clock. It stops when the CM14 bit in the CM1 register is set to 0 (125 kHz on-chip oscillator stops). If the main clock stops oscillating when the CM20 bit in the CM2 register is 1 (oscillation stop, re-oscillation detection function enabled) and the CM27 bit is 1 (oscillation stop, re-oscillation detection interrupt), the 125 kHz on-chip oscillator automatically starts operating and supplying the necessary clock for the microcomputer.
10.1.4
PLL Clock
The PLL clock is generated by the PLL frequency synthesizer. This clock is used as the clock source for the CPU and peripheral function clocks. After reset, the PLL frequency synthesizer is turned off. The PLL frequency synthesizer is activated by setting the PLC07 bit to 1 (PLL operation). When the PLL clock is used as the clock source for the CPU clock, wait for tsu (PLL) until the PLL clock to be stable, and then set the CM11 bit in the CM1 register to 1. Before entering wait mode or stop mode, be sure to set the CM11 bit to 0 (CPU clock source is the main clock). Furthermore, before entering stop mode, be sure to set the PLC07 bit in the PLC0 register to 0 (PLL stops). Figure 10.10 shows the Procedure to Use PLL Clock as CPU Clock Source. The PLL clock is the main clock divided by the selected values of bits PLC05 and PLC04 in the PLC0 register, and then multiplied by the selected values of bits PLC02 to PLC00. Set bits PLC05 and PLC04 to fit divided frequency between 2 MHz and 5 MHz. Figure 10.9 shows the Relation between the Main Clock and the PLL Clock.
Main clock n m
Divided by n
(1)
Multiplied by m
(2)
PLL clock
: 1, 2, 4 (selected by bits PLC05 and PLC04 in the PLC0 register) : 2, 4, 6, 8 (selected by bits PLC02 to PLC00 in the PLC0 register)
NOTES : 1. Set the frequency divided by n between 2 MHz and 5 MHz. 2. Set 10 MHz PLL clock frequency 25 MHz
Figure 10.9
Relation between the Main Clock and the PLL Clock
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10. Clock Generation Circuit
Bits PLC05 and PLC04 and bits PLC02 to PLC00 can be set only once after reset. Table 10.2 shows the Example for Setting PLL Clock Frequencies.
Table 10.2 Example for Setting PLL Clock Frequencies
Main Clock 10 MHz 5 MHz 12 MHz 6 MHz
Setting Value Bits PLC05 and PLC04 Bits PLC02 to PLC00 01b (divided by 2) 010b (multiplied by 4) 00b (not divided) 010b (multiplied by 4) 10b (divided by 4) 100b (multiplied by 8) 01b (divided by 2) 100b (multiplied by 8)
PLL Clock 20 MHz 24 MHz
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10. Clock Generation Circuit
Using the PLL clock as the clock source for the CPU
Set the CM07 bit to 0 (main clock)
Set bits PLC05 and PLC04 (reference clock divided). Set bits PLC02 to PLC00 (multiplying factor)
Set the PLC07 bit to 1 (PLL operation)
Wait until the PLL clock becomes stable (tsu(PLL))
Set the CM11 bit to 1 (PLL clock for the CPU clock source)
END
Figure 10.10 Procedure to Use PLL Clock as CPU Clock Source
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10. Clock Generation Circuit
10.2
CPU Clock and Peripheral Function Clock
Two types of clock exists: CPU clock to operate the CPU Peripheral function clocks to operate the peripheral functions.
10.2.1
CPU Clock and BCLK
These are operating clocks for the CPU and watchdog timer. The main clock, sub clock, 125 kHz on-chip oscillator clock, or the PLL clock can be selected as the clock source for the CPU clock. When the main clock, PLL clock, or 125 kHz on-chip oscillator clock is selected as the clock source for the CPU clock, the selected clock source can be divided by 1 (undivided), 2, 4, 8 or 16 to produce the CPU clock. Use the CM06 bit in the CM0 register and bits CM17 and CM16 in the CM1 register to select a divide-by-n value. After reset, the 125 kHz on-chip oscillator clock divided by 8 provides the CPU clock. During memory expansion or microprocessor mode, a BCLK signal with the same frequency as the CPU clock can be output from the BCLK pin by setting the PM07 bit in the PM0 register to 0 (output enabled). Note that when entering stop mode or when the CM05 bit in the CM0 register is set to 1 (stop) in lowspeed mode, the CM06 bit in the CM0 register is set to 1 (divide-by-8 mode).
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10. Clock Generation Circuit
10.2.2
Peripheral Function Clock (f1, fC32)
These are operating clocks for the peripheral functions. f1 is produced from the main clock, the PLL clock, or the 125 kHz on-chip oscillator clock, and is used for timers A and B, UART0 to UART2, UART5 to UART7, SI/O3, SI/O4, and A/D converter. When the WAIT instruction is executed after setting the CM02 bit in the CM0 register to 1 (peripheral function clock f1 turned off during wait mode), or when the microcomputer is in low power consumption mode, the f1 clock is turned off. The fC32 clock is produced from the sub clock, and is used for timers A and B. This clock can be used when the sub clock is on. fOCO-S is used for timers A and B. fOCO-S can be used when the CM14 bit in the CM1 register is set to 0 (125 kHz on-chip oscillator oscillates). Figure 10.11 shows the Peripheral Function Clock.
fC fOCO-S
1/32
fC32 fOCO-S
Timer A, Timer B
CM11 = 0 Main clock PLL clock CM11 = 1
CM21 = 1 f1 CM02 CM21 = 0
UART0 to UART2
SI/O3, SI/O4
UART5 to UART7
A/D converter
Figure 10.11 Peripheral Function Clock
10.3
Clock Output Function
During single-chip mode, the f8, f32, or fC clock can be output from the CLKOUT pin. Use bits CM01 and CM00 in the CM0 register to select.
REJ09B0392-0064 Rev.0.64 Page 87 of 373
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M16C/64 Group
10. Clock Generation Circuit
10.4
Power Control
Normal operating mode, wait mode, and stop mode are provided as the power consumption control. All mode states, except wait mode and stop mode, are called normal operating mode in this document.
10.4.1
Normal Operating Mode
Normal operating mode is further classified into seven modes. In normal operating mode, because the CPU clock and the peripheral function clocks both are on, the CPU and the peripheral functions are operating. Power control is exercised by controlling the CPU clock frequency. The higher the CPU clock frequency, the greater the processing capability. The lower the CPU clock frequency, the smaller the power consumption in the chip. If the unnecessary oscillator circuits are turned off, the power consumption is further reduced. Before the clock sources for the CPU clock can be switched over, the new clock source to which switched must be oscillating stably. If the new clock source is the main clock, sub clock, or PLL clock, allow a sufficient wait time in a program until it becomes oscillating stably. When the CPU clock source is changed from the 125 kHz on-chip oscillator to the main clock, change the operating mode to the medium speed mode (divided by 8 mode) after the clock was divided by 8 (the CM06 bit in the CM0 register was set to 1) in the 125 kHz on-chip oscillator mode.
10.4.1.1
High-speed Mode
The main clock divided by 1 provides the CPU clock. If the sub clock is on, fC32 can be used as the count source for timers A and B.
10.4.1.2
PLL Operating Mode
The PLL clock serves as the CPU clock. If the sub clock is on, fC32 can be used as the count source for timers A and B. If fOCO-S is oscillating, fOCO-S can be used as the count source for timers A and B. PLL operating mode can be entered from high-speed mode or medium-speed mode. If PLL operating mode is to be changed to wait or stop mode, first go to high-speed mode or medium-speed mode before changing.
10.4.1.3
Medium-Speed Mode
The main clock divided by 2, 4, 8, or 16 provides the CPU clock. If the sub clock is on, fC32 can be used as the count source for timers A and B. If fOCO-S is oscillating, fOCO-S can be used as the count source for timers A and B.
10.4.1.4
Low-Speed Mode
The sub clock provides the CPU clock. The main clock is used as the clock source for the peripheral function clock when the CM21 bit in the CM2 register is set to 0 (main clock or PLL clock), and the 125 kHz on-chip oscillator clock is used when the CM21 bit is set to 1 (125 kHz on-chip oscillator clock). The fC32 clock can be used as the count source for timers A and B.
10.4.1.5
Low Power Consumption Mode
In this mode, the main clock is turned off after being placed in low speed mode. The sub clock provides the CPU clock. The fC32 clock can be used as the count source for timers A and B. If fOCO-S is oscillating, fOCO-S can be used as the count source for timers A and B. Simultaneously when this mode is selected, the CM06 bit in the CM0 register becomes 1 (divided by 8 mode). In the low power consumption mode, do not change the CM06 bit. Consequently, the medium-speed (divided by 8) mode is to be selected when the main clock is operated next.
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10. Clock Generation Circuit
10.4.1.6
125 kHz On-Chip Oscillator Mode
The 125 kHz on-chip oscillator clock divided by 1 (undivided), 2, 4, 8, or 16 provides the CPU clock. The 125 kHz on-chip oscillator clock is also the clock source for the peripheral function clocks. If the sub clock is on, fC32 can be used as the count source for timers A and B. When the operating mode is returned to the high- and medium-speed modes, set the CM06 bit in the CM0 register to 1 (divided by 8 mode).
10.4.1.7
125 kHz On-Chip Oscillator Low Power Consumption Mode
The main clock is turned off after being placed in 125 kHz on-chip oscillator mode. The CPU clock can be selected as in the 125 kHz on-chip oscillator mode. The 125 kHz on-chip oscillator clock is the clock source for the peripheral function clocks. If the sub clock is on, fC32 can be used as the count source for timers A and B.
Table 10.3 Setting Clock Related Bit and Modes
CM2 RegisMode ter CM21 PLL divided by 1 0 Operating divided by 2 0 Mode divided by 4 0 divided by 8 0 divided by 16 0 High-Speed Mode 0 Mediumdivided by 2 0 Speed Mode divided by 4 0 divided by 8 0 divided by 16 0 Low-Speed Mode Low Power Consumption 0 Mode 125 kHz divided by 1 1 On-chip divided by 2 1 Oscillator divided by 4 1 Mode divided by 8 1 divided by 16 1 125 kHz On-Chip Oscillator 1 Low Power Consumption Mode - indicates that either 0 or 1 is set.
CM1 Register CM11 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 CM14 0 0 0 0 0 0 CM17, CM16 00b 01b 10b 11b 00b 01b 10b 11b 00b 01b 10b 11b (2) CM07 0 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 0
CM0 Register CM06 0 0 0 1 0 0 0 0 1 0 1 (1) 0 0 0 1 0 (2) CM05 0 0 0 0 0 0 0 0 0 0 0 1 (1) 0 0 0 0 0 1 CM04 1 1 -
NOTES: 1. When the CM05 bit is set to 1 (main clock turned off) in low-speed mode, the mode goes to low power consumption mode and the CM06 bit is set to 1 (divided by 8 mode) simultaneously. 2. The divide-by-n value can be selected the same way as in 125 kHz on-chip oscillator mode.
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10. Clock Generation Circuit
10.4.2
Wait Mode
In wait mode, the CPU clock is turned off, so are the CPU and the watchdog timer because they are operated by the CPU clock. However, if the CSPRO bit in the CSPR register is 1 (count source protection enabled), the watchdog timer remains active. Because the main clock, sub clock, and 125 kHz onchip oscillator clock all are on, the peripheral functions using these clocks keep operating.
10.4.2.1
Peripheral Function Clock Stop Function
If the CM02 bit in the CM0 register is 1 (peripheral function clock f1 turned off during wait mode), the f1 clock is turned off while in wait mode, with the power consumption reduced that much. However, fC32 and fOCO-S (clock source of Timers A and B) remain on for the CM02 bit.
10.4.2.2
Entering Wait Mode
The microcomputer is placed into wait mode by executing the WAIT instruction. When the CM11 bit = 1 (CPU clock source is the PLL clock), be sure to clear the CM11 bit in the CM1 register to 0 (CPU clock source is the main clock) before going to wait mode. The power consumption of the chip can be reduced by clearing the PLC07 bit in the PLC0 register to 0 (PLL stops).
10.4.2.3
Pin Status during Wait Mode
Table 10.4 lists Pin Status during Wait Mode.
Table 10.4 Pin Status during Wait Mode
Pin A0 to A19, D0 to D15, CS0 to CS3, BHE
RD, WR, WRL, WRH HLDA, BCLK
Memory Expansion Mode Microprocessor Mode
Single-Chip Mode
Retains status just prior to enter- Cannot be used as a bus control pin ing wait mode "H" "H" "L" Retains status just prior to enter- Retains status before wait mode ing wait mode
ALE I/O ports CLKOUT When fC selected When f8, f32 selected
Cannot be used as a CLKOUT pin
Does not stop Does not stop when the CM02 bit is 0. When the CM02 bit is 1, the status immediately prior to entering wait mode is maintained
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10. Clock Generation Circuit
10.4.2.4
Exiting Wait Mode
The microcomputer is moved out of wait mode by a hardware reset, NMI interrupt, low voltage detection interrupt or peripheral function interrupt. If the microcomputer is to exit wait mode by a hardware reset, NMI interrupt, or low voltage detection interrupt, set the peripheral function interrupt bits ILVL2 to ILVL0 to 000b (interrupts disabled) before executing the WAIT instruction. The peripheral function interrupts are affected by the CM02 bit. If the CM02 bit is 0 (peripheral function clocks not turned off during wait mode), peripheral function interrupts can be used to exit wait mode. If the CM02 bit is 1 (peripheral function clocks turned off during wait mode), the peripheral functions using the peripheral function clocks stop operating, so that only the peripheral functions activated by external signals can be used to exit wait mode.
Table 10.5 NMI Interrupt Resets and Interrupts to Exit Wait Mode and Use Conditions
Reset, Interrupt Usable
CM02 = 0 Usable
CM02 = 1 Usable when operating with external clock Usable
Serial Interface Interrupt Usable when operating with internal or external clock Key Input Interrupt A/D Conversion Interrupt Timer A Interrupt Timer B Interrupt
INT Interrupt
Usable
Usable in one-shot mode or single sweep Do not use mode Usable in all modes Usable Usable Usable Usable (See 6.1 Brown-out Reset) Usable when count source protection mode is enabled (CSPRO = 1) Usable in event counter mode or when the count source is fC32 Usable Usable
Low Voltage Detection Interrupt Hardware Reset 1 Brown-out Reset Watchdog Timer Reset
Table 10.5 lists the Resets and Interrupts to Exit Wait Mode and Use Conditions. If the microcomputer is to be moved out of wait mode by a peripheral function interrupt, set up the following before executing the WAIT instruction. (1) Set bits ILVL2 to ILVL0 in the interrupt control register, for peripheral function interrupts used to exit wait mode. Bits ILVL2 to ILVL0 in all other interrupt control registers, for peripheral function interrupts not used to exit wait mode, are set to 000b (interrupt disabled). (2) Set the I flag to 1. (3) Start operating the peripheral functions used to exit wait mode. When the peripheral function interrupt is used, an interrupt routine is performed after an interrupt request is generated and then the CPU clock is supplied again. When the microcomputer exits wait mode by the peripheral function interrupt, the CPU clock is the same clock as the CPU clock executing the WAIT instruction.
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10. Clock Generation Circuit
10.4.3
Stop Mode
In stop mode, all oscillator circuits are turned off, so are the CPU clock and the peripheral function clocks. Therefore, the CPU and the peripheral functions clocked by these clocks stop operating. The least amount of power is consumed in this mode. If the voltage applied to pins VCC1 and VCC2 is VRAM or greater, the internal RAM is retained. When applying 2.7 or less voltage to pins VCC1 and VCC2, make sure VCC1 = VCC2 VRAM. However, the peripheral functions activated by external signals keep operating. The following resets and interrupts can be used to exit stop mode. Table 10.6 lists Resets and Interrupts to Stop Mode and Use Conditions
Table 10.6 NMI Interrupt Resets and Interrupts to Stop Mode and Use Conditions
Reset, Interrupt Usable Usable Usable Key Input Interrupt
INT Interrupt
Condition
Timer A Interrupt Timer B Interrupt Serial Interface Interrupt Low Voltage Detection Interrupt Hardware Reset 1 Brown-out Reset
Usable when counting external pulses in event counter mode Usable when external clock is selected Usable (See 6.2 Low Voltage Detection Interrupt) Usable Usable when digital filter is disabled (VW0C = 1)
10.4.3.1
Entering Stop Mode
The microcomputer is placed into stop mode by setting the CM10 bit in the CM1 register to 1 (all clocks turned off). At the same time, the CM06 bit in the CM0 register is set to 1 (divide-by-8 mode) and the CM15 bit in the CM1 register is set to 1 (main clock oscillator circuit drive capability high). Before entering stop mode, set the CM20 bit in the CM2 register to 0 (oscillation stop, re-oscillation detection function disabled). Also, if the CM11 bit in the CM1 register is 1 (PLL clock for the CPU clock source), set the CM11 bit to 0 (main clock for the CPU clock source) and the PLC07 bit in the PLC0 register to 0 (PLL turned off) before entering stop mode.
10.4.3.2
Pin Status in Stop Mode
Table 10.7 lists Pin Status in Stop Mode.
Table 10.7 Pin Status in Stop Mode
Pin A0 to A19, D0 to D15, CS0 to CS3, BHE
RD, WR, WRL, WRH HLDA, BCLK
Memory Expansion Mode Microprocessor Mode
Single-Chip Mode
Retains status just prior to stop mode Cannot be used as a bus control pin
"H" "H" indeterminate
Retains status just prior to stop mode Retains status just prior to stop mode
ALE I/O ports CLKOUT
Cannot be used as a CLKOUT pin
"H"
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10. Clock Generation Circuit
10.4.3.3
Exiting Stop Mode
Stop mode is exited by a hardware reset, NMI interrupt, low voltage detection interrupt, or peripheral function interrupt. When the hardware reset, NMI interrupt, or low voltage detection interrupt is used to exit stop mode, set bits ILVL2 to ILVL0 in the interrupt control registers for the peripheral function interrupt to 000b (interrupt disabled) before setting the CM10 bit to 1. When the peripheral function interrupt is used to exit stop mode, set the CM10 bit to 1 after the following settings are completed. (1) Set bits ILVL2 to ILVL0 in the interrupt control registers to decide the peripheral priority level of the peripheral function interrupt. Set the interrupt priority levels of the interrupts, not being used to exit stop mode, to 0 by setting bits ILVL2 to ILVL0 to 000b (interrupt disabled). (2) Set the I flag to 1. (3) Start operation of peripheral function being used to exit stop mode. When exiting stop mode by the peripheral function interrupt, the interrupt routine is performed after an interrupt request is generated and then the CPU clock is supplied again. When stop mode is exited by the peripheral function interrupt, low voltage detection interrupt, or NMI interrupt, the CPU clock source is as follows, in accordance with the CPU clock source setting before the microcomputer had entered stop mode. * When the sub clock is the CPU clock before entering stop mode: sub clock * When the main clock is the CPU clock source before entering stop mode: main clock divided by 8 * When the 125 kHz on-chip oscillator clock is the CPU clock source before entering stop mode: 125 kHz on-chip oscillator clock divided by 8
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M16C/64 Group Figure 10.12 shows the power Control Transition
10. Clock Generation Circuit
Power Control Mode State Transition
Reset Normal Operation Mode
125 kHz on-chip oscillator mode
CM07 = 0, CM21 = 1 CM14 = 0, CM05 = 0
CM14 = 0 CM21 = 1
125 kHz on-chip oscillator low power consumption mode
CM05 = 1, CM07 = 0 CM14 = 0, CM21 = 1
CM04 = 1 CM07 = 1
CM21 = 0
CM07 = 0 CM14 = 0 CM21 = 1
PLL operation mode
CM05 = 0 CM07 = 0 CM11 = 1 CM21 = 0 PLC07 = 1
PLC07 = 0 CM11 = 0
High-speed mode, medium-speed mode
CM05 = 0 CM07 = 0 CM11 = 0 CM21 = 0
CM04 = 1 CM07 = 1
Low-speed mode
CM04 = 1, CM05 = 0, CM07 = 1
Low power consumption mode
CM07 = 0 CM21 = 0 CM04 = 1, CM05 = 1 CM07 = 1
CM11 = 1 PLC07 = 1
Interrupt
WAIT instruction
Interrupt
CM10 = 1
Wait mode CPU operation stopped CM04, CM05, CM06, CM07: bits in the CM0 register CM11, CM14, CM16, CM17: bits in the CM1 register CM21: bits in the CM2 register
Stop mode All the oscillations stopped
Figure 10.12 Power Control Transition
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10. Clock Generation Circuit
10.5
System Clock Protection Function
The system clock protection function prohibits the CPU clock from changing clock sources when the main clock is selected as the CPU clock source. This is to prevent the CPU clock from stopping by an unexpected program operation. When the PM21 bit in the PM2 register is set to 1 (clock change disabled), the following bits cannot be written to: * Bits CM02, CM05, and CM07 in the CM0 register * Bits CM10 and CM11 in the CM1 register * The CM20 bit in the CM2 register * All bits in the PLC0 register When using the system clock protection function, set the CM05 bit in the CM0 register to 0 (main clock oscillation) and CM07 bit to 0 (main clock as CPU clock source) and follow the procedure below. (1) Set the PRC1 bit in the PRCR register to 1 (write to the PM2 register enabled). (2) Set the PM21 bit in the PM2 register to 1 (clock change disabled). (3) Set the PRC1 bit in the PRCR register to 0 (write to the PM2 register disabled). When the PM21 bit is set to 1, do not execute the WAIT instruction.
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10. Clock Generation Circuit
10.6
Oscillation Stop and Re-Oscillation Detect Function
The oscillation stop and re-oscillation detect function is such that main clock oscillation circuit stop and reoscillation are detected. At oscillation stop or re-oscillation detection, reset oscillation stop or re-oscillation detection interrupt are generated. Which is to be generated can be selected using the CM27 bit in the CM2 register. The oscillation stop and re-oscillation detect function can be enabled and disabled by the CM20 bit in the CM2 register. Table 10.8 lists a Specification Overview of Oscillation Stop and Re-Oscillation Detect Function.
Table 10.8 Specification Overview of Oscillation Stop and Re-Oscillation Detect Function
Item Oscillation Stop Detectable Clock and Frequency Bandwidth Enabling Condition for Oscillation Stop, Re-Oscillation Detect Function Operation at Oscillation Stop, Re-Oscillation Detection
Specification f(XIN) 2 MHz Set CM20 bit to 1 (enabled) Reset occurs (when CM27 bit = 0) Oscillation stop, re-oscillation detection interrupt generated (when CM27 bit = 1)
10.6.1
Operation When CM27 bit = 0 (Oscillation Stop Detection Reset)
When main clock stop is detected when the CM20 bit is 1 (oscillation stop, re-oscillation detection function enabled), the microcomputer is initialized, coming to a halt (oscillation stop reset. Refer to 4. "Special Function Registers (SFRs)", 5. "Reset"). This status is reset with hardware reset 1 or brown-out reset. Also, even when re-oscillation is detected, the microcomputer can be initialized and stopped; it is, however, necessary to avoid such usage (During main clock stop, do not set the CM20 bit to 1 and the CM27 bit to 0).
10.6.2
Operation When CM27 bit = 1 (Oscillation Stop and Re-oscillation Detect Interrupt)
When the main clock corresponds to the CPU clock source and the CM20 bit is 1 (oscillation stop and re-oscillation detect function enabled), the system is placed in the following state if the main clock comes to a halt. * Oscillation stop and re-oscillation detect interrupt request occurs. * CM14 bit = 0 (125 kHz on-chip oscillator clock oscillates) * CM21 bit = 1 (125 kHz on-chip oscillator clock for CPU clock source and clock source of peripheral function.) * CM22 bit = 1 (main clock stop detected) * CM23 bit = 1 (main clock stopped) When the PLL clock corresponds to the CPU clock source and the CM20 bit is 1, the system is placed in the following state if the main clock comes to a halt. Since the CM21 bit remains unchanged, set it to 1 (125 kHz on-chip oscillator clock) inside the interrupt routine. * Oscillation stop and re-oscillation detect interrupt request occurs. * CM14 bit = 0 (125 kHz on-chip oscillator clock oscillates) * CM22 bit = 1 (main clock stop detected) * CM23 bit = 1 (main clock stopped) * CM21 bit remains unchanged When the CM20 bit is 1, the system is placed in the following state if the main clock re-oscillates from the stop condition. * Oscillation stop and re-oscillation detect interrupt request occurs. * CM14 bit = 0 (125 kHz on-chip oscillator clock oscillates) * CM22 bit = 1 (main clock re-oscillation detected) * CM23 bit = 0 (main clock oscillation) * CM21 bit remains unchanged REJ09B0392-0064 Rev.0.64 Page 96 of 373 Oct 12, 2007
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10. Clock Generation Circuit
10.6.3
How to Use Oscillation Stop and Re-Oscillation Detect Function
* The oscillation stop and re-oscillation detect interrupt shares the vector with the watchdog timer interrupt and low voltage detection interrupt. If the oscillation stop, re-oscillation detection and watchdog timer interrupts both are used, read the CM22 bit in an interrupt routine to determine which interrupt source is requesting the interrupt. * When the main clock re-oscillated after oscillation stop, the clock source for the CPU clock and peripheral functions must be switched to the main clock in a program. Figure 10.13 shows the Procedure to Switch Clock Source from 125 kHz On-chip Oscillator to Main Clock. * Simultaneously with oscillation stop and re-oscillation detection interrupt occurrence, the CM22 bit becomes 1. When the CM22 bit is set to 1, oscillation stop and re-oscillation detection interrupt are disabled. By setting the CM22 bit to 0 in a program, oscillation stop and re-oscillation detection interrupt are enabled. * If the main clock stops during low speed mode where the CM20 bit is 1, an oscillation stop and reoscillation detection interrupt request is generated. At the same time, the 125 kHz on-chip oscillator starts oscillating. In this case, although the CPU clock is derived from the sub clock as it was before the interrupt occurred, the peripheral function clocks now are derived from the 125 kHz onchip oscillator clock. * To enter wait mode while using the oscillation stop and re-oscillation detection function, set the CM02 bit to 0 (peripheral function clocks not turned off during wait mode). * Since the oscillation stop and re-oscillation detection function is provided in preparation for main clock stop due to external factors, set the CM20 bit to 0 (oscillation stop and re-oscillation detection function disabled) where the main clock is stopped or oscillated in a program, that is where the stop mode is selected or the CM05 bit is altered. * This function cannot be used if the main clock frequency is 2 MHz or less. In that case, set the CM20 bit to 0.
Switch the main clock
NO
Determine several times whether the CM23 bit is set to 0 (main clock oscillates)
YES Set the CM06 bit to 1 (divide-by-8)
Set the CM22 bit to 0 (main clock stop, re-oscillation not detected)
Set the CM21 bit to 0 (main clock or PLL clock)
End
Bits CM21 to CM23: bits in the CM2 register
Figure 10.13 Procedure to Switch Clock Source From 125 kHz On-chip Oscillator to Main Clock
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11. Protection
11. Protection
In the event that a program runs out of control, this function protects the important registers so that they will not be rewritten easily. Figure 11.1 shows the PRCR Register. The following lists the registers protected by the PRCR register. * The PRC0 bit protects registers CM0, CM1, CM2, PLC0, and PCLKR. * The PRC1 bit protects registers PM0, PM1, PM2, TB2SC, INVC0, and INVC1. * The PRC2 bit protects registers PD9, S3C, and S4C. * The PRC3 bit protects registers VCR2, D4INT, and VW0C. * The PRC6 bit protects the PRG2C register. Set the PRC2 bit to 1 (write enabled) and then write to given SFR address, and the PRC2 bit will be cleared to 0 (write protected). The registers protected by the PRC2 bit should be changed in the next instruction after setting the PRC2 bit to 1. Make sure no interrupts or DMA transfers will occur between the instruction in which the PRC2 bit is set to 1 and the next instruction. Bits PRC0, PRC1, PRC3, and PRC6 are not automatically cleared to 0 by writing to given SFR address. They can only be cleared in a program.
Protect Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PRCR
Bit Symbol
Address 000Ah Bit Name Function
0
00
After Reset 00h RW
PRC0
Protect bit 0
PRC1
Protect bit 1
PRC2
Protect bit 2
PRC3
Protect bit 3
Enable write to registers CM0, CM1, CM2, PLC0 and PCLKR 0 : Write protected 1 : Write enabled Enable write to registers PM0, PM1, PM2, TB2SC, INVC0, and INVC1 0 : Write protected 1 : Write enabled Enable write to registers PD9, S3C, and S4C 0 : Write protected 1 : Write enabled Enable write to registers VCR2, D4INT, and VW0C 0 : Write protected 1 : Write enabled Set to 0 Enable write to the PRG2C register 0 : Write protected 1 : Write enabled Set to 0
RW
RW
RW
RW
-- (b5-b4) PRC6 -- (b7)
Reserved bits
RW
Protect bit 6
RW
Reserved bit
RW
NOTE : 1. The PRC2 bit is set to 0 by writing to given SFR address after setting it to 1. Other bits are not set to 0 automatically by the same token. Therefore, set them to 0 in a program.
Figure 11.1
PRCR Register
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12. Interrupt
12. Interrupt
12.1 Type of Interrupts
Figure 12.1 shows Type of Interrupts.
Software (non-maskable interrupt)
Undefined instruction (UND instruction) Overflow (INTO instruction) BRK instruction INT instruction
Interrupt Special (non-maskable interrupt) Hardware Peripheral function (1) (maskable interrupt)
NMI DBC (2) Watchdog timer Oscillation stop and re-oscillation detection Low voltage detection Single step (2) Address match
NOTES : 1. The peripheral functions in the microcomputer are used to generate the peripheral interrupt. 2. Do not normally use this interrupt because it is provided exclusively for use by development tools.
Figure 12.1
Type of Interrupts
* Maskable Interrupt
* Non-Maskable Interrupt
: The interrupt priority can be changed by enabling (disabling) an interrupt with the interrupt enable flag (I flag) or by using interrupt priority levels. : The interrupt priority cannot be changed by enabling (disabling) an interrupt with the interrupt enable flag (I flag) or by using interrupt priority levels.
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12. Interrupt
12.2
Software Interrupts
A software interrupt occurs when executing certain instructions. Software interrupts are non-maskable interrupts.
12.2.1
Undefined Instruction Interrupt
An undefined instruction interrupt occurs when executing the UND instruction.
12.2.2
Overflow Interrupt
An overflow interrupt occurs when executing the INTO instruction with the O flag in the FLG register set to 1 (the operation resulted in an overflow). The followings are instructions whose O flag changes by arithmetic: ABS, ADC, ADCF, ADD, CMP, DIV, DIVU, DIVX, NEG, RMPA, SBB, SHA, SUB
12.2.3
BRK Interrupt
A BRK interrupt occurs when executing the BRK instruction.
12.2.4
INT Instruction Interrupt
An INT instruction interrupt occurs when executing the INT instruction. Software interrupt Nos. 0 to 63 can be specified for the INT instruction. Because software interrupt Nos. 2 to 31 and 41 to 51 are assigned to peripheral function interrupts, the same interrupt routine as for peripheral function interrupts can be executed by executing the INT instruction. In software interrupt Nos. 0 to 31, the U flag is saved to the stack during instruction execution and is cleared to 0 (ISP selected) before executing an interrupt sequence. The U flag is restored from the stack when returning from the interrupt routine. In software interrupt Nos. 32 to 63, the U flag does not change state during instruction execution, and the SP selected at the time is used.
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12. Interrupt
12.3
Hardware Interrupts
Hardware interrupts are classified into two types: special interrupts and peripheral function interrupts.
12.3.1
Special Interrupts NMI Interrupt
Special interrupts are non-maskable interrupts.
12.3.1.1
An NMI interrupt is generated when input on the NMI pin changes state from high to low. For details about the NMI interrupt, refer to 12.7 "NMI Interrupt".
12.3.1.2
DBC Interrupt
Do not normally use this interrupt because it is provided exclusively for use by development tools.
12.3.1.3
Watchdog Timer Interrupt
Generated by the watchdog timer. Once a watchdog timer interrupt is generated, be sure to initialize the watchdog timer. For details about the watchdog timer, refer to 13. "Watchdog Timer".
12.3.1.4
Oscillation Stop and Re-Oscillation Detection Interrupt
Generated by the oscillation stop and re-oscillation detection function. For details about the oscillation stop and re-oscillation detection function, refer to 10. "Clock Generation Circuit".
12.3.1.5
Low Voltage Detection Interrupt
Generated by the voltage detection circuit. For details about the voltage detection circuit, refer to 6. "Voltage Detection Circuit".
12.3.1.6
Single-Step Interrupt
Do not normally use this interrupt because it is provided exclusively for use by development tools.
12.3.1.7
Address Match Interrupt
An address match interrupt is generated immediately before executing the instruction at the address indicated by registers RMAD0 to RMAD3 that correspond to one of the AIER0 or AIER1 bit in the AIER register or the AIER20 or AIER21 bit in the AIER2 register which is 1 (address match interrupt enabled). For details about the address match interrupt, refer to 12.9 "Address Match Interrupt".
12.3.2
Peripheral Function Interrupts
The peripheral function interrupt occurs when a request from the peripheral functions in the microcomputer is acknowledged. The peripheral function interrupt is a maskable interrupt. See Tables 12.2 and 12.3 Relocatable Vector Tables. Refer to the descriptions of each function for details about how the peripheral function interrupt occurs.
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12. Interrupt
12.4
Interrupts and Interrupt Vector
One interrupt vector consists of 4 bytes. Set the start address of each interrupt routine in the respective interrupt vectors. When an interrupt request is accepted, the CPU branches to the address set in the corresponding interrupt vector. Figure 12.2 shows the Interrupt Vector.
MSB Vector address (L)
LSB
Low-order address Middle-order address 0000 High-order address 0000
Vector address (H)
0000
Figure 12.2
Interrupt Vector
12.4.1
Fixed Vector Tables
The fixed vector tables are allocated to the addresses from FFFDCh to FFFFFh. Table 12.1 lists the Fixed Vector Table. In the flash memory version of microcomputer, the vector addresses (H) of fixed vectors are used by the ID code check function. For details, refer to 22.2 "Functions to Prevent Flash Memory from Rewriting".
Table 12.1 Fixed Vector Table
Interrupt Source Undefined Instruction (UND instruction) Overflow (INTO instruction) BRK Instruction (2) Address Match Single Step (1)
Vector Table Addresses Address (L) to Address (H) FFFDCh to FFFDFh FFFE0h to FFFE3h FFFE4h to FFFE7h FFFE8h to FFFEBh FFFECh to FFFEFh
Reference M16C/60, M16C/20 series software manual
12.9 "Address Match Interrupt"
13. "Watchdog Timer" 10. "Clock Generation Circuit" 6. "Voltage Detection Circuit"
Watchdog Timer, FFFF0h to FFFF3h Oscillation Stop and Re-Oscillation Detection, Low Voltage Detection
DBC (1) NMI
FFFF4h to FFFF7h FFFF8h to FFFFBh FFFFCh to FFFFFh
12.7 "NMI Interrupt" 5. "Reset"
Reset
NOTES: 1. Do not normally use this interrupt because it is provided exclusively for use by development tools. 2. If the contents of address FFFE7h is FFh, program execution starts from the address shown by the vector in the relocatable vector table.
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12. Interrupt
12.4.2
Relocatable Vector Tables
The 256 bytes beginning with the start address set in the INTB register comprise a relocatable vector table area. Tables 12.3 and 12.3 list the Relocatable Vector Tables. Setting an even address in the INTB register results in the interrupt sequence being executed faster than setting an odd address.
Table 12.2 Relocatable Vector Table (1)
Interrupt Source BRK Instruction (5)
- (Reserved) INT7 INT6 INT3
Vector Address (1) Address (L) to Address (H) +0 to +3 (0000h to 0003h) +8 to +11 (0008h to 000Bh) +12 to +15 (000Ch to 000Fh) +16 to +19 (0010h to 0013h) +20 to +23 (0014h to 0017h) 0 1 2 3 4 5 6 7 8 9
Software Interrupt Number
Reference M16C/60, M16C/20 series software manual
12.6 "INT Interrupt"
Timer B5
(4, 6)
15. "Timers" 15. "Timers" 17. "Serial Interface"
Timer B4, UART1 Bus Collision Detect +24 to +27 (0018h to 001Bh) Timer B3, UART0 Bus Collision Detect +28 to +31 (001Ch to 001Fh)
(4, 6)
SI/O4, INT5 (2) SI/O3, INT4 DMA0 DMA1 Key Input Interrupt A/D UART2 Transmit, NACK2 (3) UART2 Receive, ACK2 (3) UART0 Transmit, NACK0 UART0 Receive, ACK0
(3) (3) (2) (6)
+32 to +35 (0020h to 0023h) +36 to +39 (0024h to 0027h) +40 to +43 (0028h to 002Bh) +44 to +47 (002Ch to 002Fh) +48 to +51 (0030h to 0033h) +52 to +55 (0034h to 0037h) +56 to +59 (0038h to 003Bh) +60 to +63 (003Ch to 003Fh) +64 to +67 (0040h to 0043h) +68 to +71 (0044h to 0047h) +72 to +75 (0048h to 004Bh) +76 to +79 (004Ch to 004Fh) +80 to +83 (0050h to 0053h) +84 to +87 (0054h to 0057h) +88 to +91 (0058h to 005Bh) +92 to +95 (005Ch to 005Fh) +96 to +99 (0060h to 0063h) +100 to +103 (0064h to 0067h) +104 to +107 (0068h to 006Bh) +108 to +111 (006Ch to 006Fh) +112 to +115 (0070h to 0073h)
12.6 "INT Interrupt" 17. "Serial Interface" 17. "Serial Interface" 14. "DMAC" 12.8 "Key Input Interrupt" 18. "A/D Converter" 17. "Serial Interface"
UART2 Bus Collision Detection
10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28
UART1 Transmit, NACK1 (3) UART1 Receive, ACK1 (3) Timer A0 Timer A1 Timer A2 Timer A3 Timer A4 Timer B0 Timer B1 Timer B2
15. "Timers"
NOTES: 1. Address relative to address in INTB. 2. Use bits IFSR6 and IFSR7 in the IFSR register to select. 3. During I2C mode, interrupts NACK and ACK comprise the interrupt source. 4. Use bits IFSR26 and IFSR27 in the IFSR2A register to select. 5. These interrupts cannot be disabled using the I flag. 6. Bus collision detection: During IE mode, this bus collision detection constitutes the interrupt source. During I2C mode, however, a start condition or a stop condition detection constitutes the interrupt source.
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12. Interrupt
Table 12.3
Relocatable Vector Table (2)
Interrupt Source
INT0 INT1 INT2
Vector Address (1) Address (L) to Address (H) +116 to +119 (0074h to 0077h) +120 to +123 (0078h to 007Bh) +124 to +127 (007Ch to 007Fh) +128 to +131 (0080h to 0083h) to +160 to +163 (00A0h to 00A3h) +164 to +167 (00A4h to 00A7h) +168 to +171(00A8h to 00ABh) +172 to +175(00ACh to 0AFh) +176 to +179(00B0h to 00B3h) +180 to +183(00B4h to 00B7h) +184 to +187(00B8h to 00BBh) +188 to +191(00BCh to 00BFh) +192 to +195(00C0h to 00C3h) +196 to +199(00C4h to 00C7h) +200 to +203(00C8h to 00CBh) +204 to +207(00CCh to 00CFh)
Software Interrupt Number 29 30 31 32 to 40 41 42 43 44 45 46 47 48 49 50 51 52 to 63
Reference
12.6 "INT Interrupt"
INT Instruction Interrupt (3)
M16C/60, M16C/20 series software manual
14. "DMAC" 17. "Serial Interface"
DMA2 DMA3 UART5 Bus Collision Detection(4) UART5 Transmit, NACK5(2) UART5 Receive, ACK5 (2) UART6 Bus Collision Detection (4) UART6 Transmit, NACK6 (2) UART6 Receive, ACK6 (2) UART7 Bus Collision Detection (4) UART7 Transmit, NACK7 (2) UART7 Receive, ACK7 (2) - (Reserved)
NOTES: 1. Address relative to address in INTB. 2. During I2C mode, interrupts NACK and ACK comprise the interrupt source. 3. These interrupts cannot be disabled using the I flag. 4. Bus collision detection: During IE mode, this bus collision detection constitutes the factor of an interrupt. 5. Bus collision detection: During IE mode, this bus collision detection constitutes the interrupt source. During I2C mode, however, a start condition or a stop condition detection constitutes the interrupt source.
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12. Interrupt
12.5
Interrupt Control
The following describes how to enable / disable the maskable interrupts, and how to set the priority in which order they are accepted. What is explained here does not apply to nonmaskable interrupts. Use the I flag in the FLG register, IPL, and bits ILVL2 to ILVL0 in each interrupt control register to enable / disable the maskable interrupts. Whether an interrupt is requested or not is indicated by the IR bit in each interrupt control register. Figures 12.3 and 12.4 show the Interrupt Control Registers.
Interrupt Control Register 1 (2)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TB5IC TB4IC / U1BCNIC (3) TB3IC / U0BCNIC (3) BCNIC DM0IC to DM3IC KUPIC (4) ADIC S0TIC to S2TIC S0RIC to S2RIC TA0IC to TA4IC TB0IC to TB2IC U5BCNIC to U7BCNIC S5TIC to S7TIC S5RIC to S7RIC
Bit Symbol
Address 0045h 0046h 0047h 004Ah 004Bh, 004Ch, 0069h, 006Ah 004Dh 004Eh 0051h, 0053h, 004Fh 0052h, 0054h, 0050h 0055h to 0059h 005Ah to 005Ch 006Bh, 006Eh, 0071h 006Ch, 006Fh, 0072h 006Dh, 0070h, 0073h Function
b2 b1 b0
After Reset XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b XXXXX000b RW RW
Bit Name 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1
ILVL0 Interrupt priority level select bit
ILVL1
ILVL2
0 : Level 0 (interrupt disabled) 1 : Level 1 0 : Level 2 1 : Level 3 0 : Level 4 1 : Level 5 0 : Level 6 1 : Level 7
RW
RW
IR -- (b7-b4)
Interrupt request bit
0: Interrupt not requested 1: Interrupt requested
RW (1) --
No register bits. If necessary, set to 0. Read as undefined value
NOTES : 1. The IR bit can only be reset by writing a 0. (Do not write a 1). 2. To rewrite the interrupt control register, do so at a point that does not generate the interrupt request for that register. 3. Use the IFSR2A register to select. 4. To use the key input interrupts, set the PCR7 bit in the PCR register to 0 (key input enabled).
Figure 12.3
Interrupt Control Register (1)
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12. Interrupt
Interrupt Control Register 2 (2)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol INT7IC (6,7) INT6IC (6,7) INT3IC (4) S4IC/INT5IC (4) S3IC/INT4IC (4) INT0IC to INT2IC
Bit Symbol
Address 0042h 0043h 0044h 0048h 0049h 005Dh to 005Fh Function
b2 b1 b0
After Reset XX00X000b XX00X000b XX00X000b XX00X000b XX00X000b XX00X000b RW RW
Bit Name 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1
ILVL0 Interrupt priority level select bit
ILVL1
ILVL2
0 : Level 0 (interrupt disabled) 1 : Level 1 0 : Level 2 1 : Level 3 0 : Level 4 1 : Level 5 0 : Level 6 1 : Level 7
RW
RW
IR POL -- (b5) -- (b7-b6)
Interrupt request bit Polarity select bit (3, 5) Reserved bit
0: Interrupt not requested 1: Interrupt requested 0 : Select falling edge 1 : Select rising edge Set to 0
RW (1) RW RW --
No register bits. If necessary, set to 0. Read as undefined value
NOTES : 1. The IR bit can only be reset by writing a 0. (Do not write a 1). 2. To rewrite the interrupt control register, do so at a point that does not generate the interrupt request for that register. 3. If the IFSRi bit in the IFSR register are 1 (both edges), set the POL bit in the INTiIC register to 0 (falling edge) (i = 0 to 5). Similarly, if bits IFSR30 and IFSR31 in the IFSR3A register are 1 (both edges), set the POL bits in registers INT6IC and INT7IC to 0 (falling edge). 4. When the BYTE pin is low and the processor mode is memory expansion or microprocessor mode, set bits ILVL2 to ILVL0 in registers INT5IC to INT3IC to 000b (interrupts disabled). 5. Set the POL bit in the S3IC or S4IC register to 0 (falling edge) when the IFSR6 bit in the IFSR register = 0 (SI/ O3 selected) or IFSR7 bit = 0 (SI/O4 selected), respectively. 6. When the processor mode is memory expansion or microprocessor mode, set bits ILVL2 to ILVL0 in registers INT6IC and INT7IC to 000b (interrupts disabled). 7. To use the INT6 interrupts, set the PCR5 bit in the PCR register to 0 (INT6 input enabled). To use the INT7 interrupts, set the PCR6 bit in the PCR register to 0 (INT7 input enabled).
Figure 12.4
Interrupt Control Register (2)
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12. Interrupt
12.5.1
I Flag
The I flag enables or disables the maskable interrupt. Setting the I flag to 1 (enabled) enables the maskable interrupt. Setting the I flag to 0 (disabled) disables all maskable interrupts.
12.5.2
IR Bit
The IR bit is set to 1 (interrupt requested) when an interrupt request is generated. Then, when the interrupt request is accepted, the IR bit is cleared to 0 (interrupt not requested). The IR bit can be cleared to 0 in a program. Do not write a 1 to this bit.
12.5.3
Bits ILVL2 to ILVL0 and IPL
Interrupt priority levels can be set using bits ILVL2 to ILVL0. Table 12.4 shows the Settings of Interrupt Priority Levels and Table 12.5 shows the Interrupt Priority Levels Enabled by IPL. The followings are conditions under which an interrupt is accepted: * I flag = 1 * IR bit = 1 * Interrupt priority level > IPL The I flag, IR bit, bits ILVL2 to ILVL0 and IPL are independent each other. In no case do they affect one another.
Table 12.4
Bits ILVL2 to ILVL0 000b 001b 010b 011b 100b 101b 110b 111b
Settings of Interrupt Priority Levels
Interrupt Priority Level
Level 0 (interrupt disabled)
Table 12.5
IPL 000b 001b 010b 011b 100b 101b 110b 111b
Interrupt Priority Levels Enabled by IPL
Enabled Interrupt Priority Levels Interrupt levels 1 and above are enabled Interrupt levels 2 and above are enabled Interrupt levels 3 and above are enabled Interrupt levels 4 and above are enabled Interrupt levels 5 and above are enabled Interrupt levels 6 and above are enabled Interrupt levels 7 and above are enabled All maskable interrupts are disabled
Level 1 Level 2 Level 3 Level 4 Level 5 Level 6 Level 7
Priority Order Low
High
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12. Interrupt
12.5.4
Interrupt Sequence
An interrupt sequence - what are performed over a period from the instant an interrupt request is accepted to the instant the interrupt routine is executed - is described here. If an interrupt request occurs during execution of an instruction, the processor determines its priority when the execution of the instruction is completed, and transfers control to the interrupt sequence from the next cycle. If an interrupt occurs during execution of either the SMOVB, SMOVF, SSTR or RMPA instruction, the processor temporarily suspends the instruction being executed, and transfers control to the interrupt sequence. The CPU behavior during the interrupt sequence is described below. Figure 12.5 shows Time Required for Executing Interrupt Sequence. (1) The CPU obtains interrupt information (interrupt number and interrupt request level) by reading address 00000h. Then, the IR bit applicable to the interrupt information is set to 0 (interrupt not requested). (2) The FLG register, prior to an interrupt sequence, is saved to a temporary register (1) within the CPU. (3) Flags I, D, and U in the FLG register become as follows: * The I flag is set to 0 (interrupt disabled) * The D flag is set to 0 (single-step interrupt disabled) * The U flag is set to 0 (ISP selected) Note that the U flag does not change states if an INT instruction for software interrupt Nos. 32 to 63 is executed. (4) The temporary register (1) within the CPU is saved to the stack. (5) The PC is saved to the stack. (6) The interrupt priority level of the acknowledged interrupt in IPL is set. (7) The start address of the relevant interrupt routine set in the interrupt vector is stored in the PC. After the interrupt sequence is completed, an instruction is executed from the starting address of the interrupt routine. NOTE: 1. Temporary register cannot be modified by users.
1 CPU clock Address bus Data bus RD WR (2)
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
Address 00000h Interrupt information
Indeterminate (1) Indeterminate (1) Indeterminate (1)
SP-2 SP-2 contents
SP-4 SP-4 contents
vec vec contents
vec+2 vec+2 contents
PC
NOTES : 1. The indeterminate state depends on the instruction queue buffer. A read cycle occurs when the instruction queue buffer is ready to accept instructions. 2. The WR signal timing shown here is for the case where the stack is located in the internal RAM.
Figure 12.5
Time Required for Executing Interrupt Sequence
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12. Interrupt
12.5.5
Interrupt Response Time
Figure 12.6 shows the Interrupt Response Time. The interrupt response or interrupt acknowledge time denotes a time from when an interrupt request is generated till when the first instruction in the interrupt routine is executed. Specifically, it consists of a time from when an interrupt request is generated till when the executing instruction is completed ((a) on Figure 12.6) and a time during which the interrupt sequence is executed ((b) on Figure 12.6).
Interrupt request generated
Interrupt request acknowledged Time
Instruction (a)
Interrupt sequence (b)
Instruction in interrupt routine
Interrupt response time
(a) A time from when an interrupt request is generated till when the instruction at the time executing is completed. The length of this time varies with the instruction being executed. The DIVX instruction requires the longest time, which is equal to 30 cycles (without wait state, the divisor being a register). (b) A time during which the interrupt sequence is executed. For details, see the table below. Note, however, that the values in this table must be increased 2 cycles for the DBC interrupt and 1 cycle for the address match and single-step interrupts. Interrupt Vector Address SP Value Even Even Odd Odd Even Odd Even Odd 16-Bit Bus, Without Wait 18 cycles 19 cycles 19 cycles 20 cycles 8-Bit Bus, Without Wait 20 cycles 20 cycles 20 cycles 20 cycles
Figure 12.6
Interrupt Response Time
12.5.6
Variation of IPL when Interrupt Request IS Accepted
When a maskable interrupt request is accepted, the interrupt priority level of the accepted interrupt is set in the IPL. When a software interrupt or special interrupt request is accepted, one of the interrupt priority levels listed in Table 12.6 is set in the IPL. Table 12.6 lists the IPL Level That is Set to IPL When a Software or Special Interrupt is Accepted.
Table 12.6 IPL Level That is Set to IPL When a Software or Special Interrupt is Accepted
Interrupt Sources Watchdog Timer, NMI, Oscillation Stop and Re-Oscillation Detection, Low Voltage Detection Software, Address Match, DBC, Single-Step
Level Set to IPL 7 Not changed
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12. Interrupt
12.5.7
Saving Registers
In the interrupt sequence, the FLG register and PC are saved to the stack. At this time, the 4 high-order bits of the PC and the 4 high-order (IPL) and 8 low-order bits in the FLG register, 16 bits in total, are saved to the stack first. Next, the 16 low-order bits of the PC are saved. Figure 12.7 shows the Stack Status Before and After Acceptance of Interrupt Request. The other necessary registers must be saved in a program at the beginning of the interrupt routine. Use the PUSHM instruction, and all registers except SP can be saved with a single instruction.
Address MSB
Stack LSB
Address MSB
Stack LSB [SP] New SP value
m-4 m-3 m-2 m-1 m m+1 Content of previous stack Content of previous stack [SP] SP value before interrupt request is accepted.
m-4 m-3 m-2 m-1 m m+1 FLGH
PCL PCM FLGL PCH
Content of previous stack Content of previous stack
PCL PCM PCH FLGL FLGH
: 8 low-order bits of PC : 8 middle-order bits of PC : 4 high-order bits of PC : 8 low-order bits of FLG : 4 high-order bits of FLG
Stack status before interrupt request is acknowledged
Stack status after interrupt request is acknowledged
Figure 12.7
Stack Status Before and After Acceptance of Interrupt Request
The operation of saving registers carried out in the interrupt sequence is dependent on whether the SP (1), at the time of acceptance of an interrupt request, is even or odd. If the SP (1) is even, the FLG register and the PC are saved, 16 bits at a time. If odd, they are saved in two steps, 8 bits at a time. Figure 12.8 shows the Operation of Saving Register. NOTE: 1. When any INT instruction in software numbers 32 to 63 has been executed, this is the SP indicated by the U flag. Otherwise, it is the ISP.
(1) SP contains even number
Address Stack Sequence in which order registers are saved
(2) SP contains odd number
Address Stack Sequence in which order registers are saved
[SP] - 5 (Odd) [SP] - 4 (Even) [SP] - 3 (Odd) [SP] - 2 (Even) [SP] - 1 (Odd) [SP] (Even) FLGH PCL PCM FLGL PCH
[SP] - 5 (Even) [SP] - 4 (Odd) (2) Saved simultaneously, all 16 bits [SP] - 3 (Even) [SP] - 2 (Odd) (1) Saved simultaneously, all 16 bits [SP] - 1 (Even) [SP] (Odd) Completed saving registers in four operations. PCL PCM PCH FLGL FLGH : 8 low-order bits of PC : 8 middle-order bits of PC : 4 high-order bits of PC : 8 low-order bits of FLG : 4 high-order bits of FLG FLGH PCL PCM FLGL PCH
(3) (4) (1) (2)
Saved, 8 bits at a time
Completed saving registers in two operations.
NOTE : 1. [SP] denotes the initial value of the SP when interrupt request is acknowledged. After registers are saved, the SP content is [SP] minus 4.
Figure 12.8
Operation of Saving Register
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12. Interrupt
12.5.8
Returning from an Interrupt Routine
The FLG register and PC in the state in which they were immediately before entering the interrupt sequence are restored from the stack by executing the REIT instruction at the end of the interrupt routine. Thereafter the CPU returns to the program which was being executed before accepting the interrupt request. Return the other registers saved by a program within the interrupt routine using the POPM or similar instruction before executing the REIT instruction. Register bank is switched back to the bank used prior to the interrupt sequence by the REIT instruction.
12.5.9
Interrupt Priority
If two or more interrupt requests are sampled at the same sampling points (a timing to detect whether an interrupt request is generated or not), the interrupt with the highest priority is acknowledged. For maskable interrupts (peripheral functions interrupt), any desired priority level can be selected using bits ILVL2 to ILVL0. However, if two or more maskable interrupts have the same priority level, their interrupt priority is resolved by hardware, with the highest priority interrupt accepted. The watchdog timer and other special interrupts have their priority levels set in hardware. Figure 12.9 shows the Hardware Interrupt Priority. Software interrupts are not affected by the interrupt priority. If an instruction is executed, control branches invariably to the interrupt routine.
Reset NMI DBC Watchdog Timer Oscillation Stop and Re-Oscillation Detection, Low Voltage Detection Peripheral Function Single Step Address Match
Figure 12.9 Hardware Interrupt Priority
High
Low
12.5.10 Interrupt Priority Level Select Circuit
The interrupt priority level select circuit selects the highest priority interrupt in a sampled interrupt request(s) at the same sampling point. Figure 12.10 shows the Interrupts Priority Select Circuit.
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12. Interrupt
Higher
Priority level of each interrupt
UART7 transmit, NACK7 UART6 receive, ACK6 UART6 bus collision detection UART5 transmit, NACK5 DMA3 UART7 receive, ACK7 UART7 bus collision detection UART6 transmit, NACK6 UART5 receive, ACK5 UART5 bus collision detection DMA2 INT1 Timer B2 Timer B0
Level 0 (initial value)
Priority level of each interrupt
UART0 receive, ACK0 UART2 receive, ACK2 A/D conversion DMA1 UART2 bus collision SI/O4, INT5 Timer A0 UART1 transmit, NACK1 UART0 transmit, NACK0 UART2 transmit, NACK2 Key input interrupt DMA0 SI/O3, INT4 INT6 INT7
Priority of peripheral function interrupts (if priority levels are same)
Timer A3 Timer A1 Timer B4, UART1 bus collision INT3 INT2 INT0 Timer B1 Timer A4 Timer A2 Timer B3, UART0 bus collision Timer B5 UART1 receive, ACK1
Lower
IPL Interrupt request level determinate output to clock generating circuit (Figure 10.1 Clock Generation Circuit) I flag Address match Watchdog timer Oscillation stop and re-oscillation detection Low voltage detection DBC NMI Interrupt request accepted
Figure 12.10 Interrupts Priority Select Circuit
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12. Interrupt
12.6
INT Interrupt
INTi interrupt (i = 0 to 7) is triggered by the edges of external inputs. The edge polarity is selected using the IFSRi bit in the IFSR register, or the IFSR30 or IFSR31 bit in the IFSR3A register. INT4 and INT5 share the interrupt vector and interrupt control register with SI/O3 and SI/O4, respectively. To use the INT4 interrupt, set the IFSR6 bit in the IFSR register to 1 (INT4). To use the INT5 interrupt, set the IFSR7 bit in the IFSR register to 1 (INT5). After modifying the IFSR6 or IFSR7 bit, clear the corresponding IR bit to 0 (interrupt not requested) before enabling the interrupt. To use the INT6 interrupt, set the PCR5 bit in the PCR register to 0 (INT6 input enabled). To use the INT7 interrupt, set the PCR6 bit in the PCR register to 0 (INT7 input enabled). Figure 12.11 shows the IFSR Register, and Figure 12.12 shows Registers IFSR2A, IFSR3A, and PCR.
Interrupt Source Select Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol IFSR
Bit Symbol
Address 0207h Bit Name INT0 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) INT1 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) INT2 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) INT3 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) INT4 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) INT5 interrupt polarity switch 0 : One edge bit 1 : Both edges (1) Interrupt request source select bit (2) Interrupt request source select bit (2) 0 : SI/O3 (3) 1 : INT4 0 : SI/O4 (3) 1 : INT5 Function
After Reset 00h RW RW RW RW RW RW RW RW RW
IFSR0 IFSR1 IFSR2 IFSR3 IFSR4 IFSR5 IFSR6 IFSR7
NOTES : 1. When setting this bit to 1 (both edges), make sure the POL bit in registers INT0IC to INT5IC are set to 0 (falling edge). 2. During memory expansion and microprocessor modes, when the data bus is 16 bits wide (BYTE pin is "L"), set this bit to 0 (SI/O3, SI/O4). 3. When setting this bit to 0 (SI/O3, SI/O4), make sure the POL bit in registers S3IC and S4IC are set to 0 (falling edge).
Figure 12.11 IFSR Register
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12. Interrupt
Interrupt Source Select Register 2
b7 b6 b5 b4 b3 b2 b1 b0
000000
Symbol IFSR2A
Bit Symbol
Address 0206h Bit Name Reserved bits Set to 0 Function
After Reset 00h RW RW RW RW
-- (b5-b0) IFSR26 IFSR27
Interrupt request source select 0 : Timer B3 bit (1) 1 : UART0 bus collision detection Interrupt request source select 0 : Timer B4 bit (2) 1 : UART1 bus collision detection
NOTES : 1. Timer B3 and UART0 bus collision detection share the vector and interrupt control register. When using Timer B3 interrupt, clear the IFSR26 bit to 0 (Timer B3). When using UART0 bus collision detection, set the IFSR26 bit to 1. 2. Timer B4 and UART1 bus collision detection share the vector and interrupt control register. When using Timer B4 interrupt, clear the IFSR27 bit to 0 (Timer B4). When using UART1 bus collision detection, set the IFSR27 bit to 1.
Interrupt Source Select Register 3
b7 b6 b5 b4 b3 b2 b1 b0
000000
Symbol IFSR3A
Bit Symbol
Address 0205h Bit Name INT6 interrupt polarity switch bit INT7 interrupt polarity switch bit Reserved bits Function 0 : One edge 1 : Both edges (1) 0 : One edge 1 : Both edges (1) Set to 0
After Reset 00h RW RW RW RW
IFSR30 IFSR31 -- (b7-b2)
NOTE : 1. When setting this bit to 1 (both edges), make sure the POL bit in registers INT6IC and INT7IC are set to 0 (falling edge).
Port Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PCR
Bit Symbol
Address 0366h Bit Name Function
After Reset 00000XX0b RW
PCR0
Port P1 control bit
Operation performed when the P1 register is read 0 : When the port is set for input, the input levels of pins P1_0 to P1_7 are read. When set for output, the port latch is read. 1 : The port latch is read regardless of whether the port is set for input or output.
RW
-- (b4-b1) PCR5 PCR6 PCR7
No register bits. If necessary, set to 0. Read as 0 INT6 input enable bit (1) INT7 input enable bit
(2)
-- RW RW RW
0 : Enabled 1 : Disabled 0 : Enabled 1 : Disabled 0 : Enabled 1 : Disabled
Key input enable bit (3)
NOTES : 1. To use the AN2_4 pin as an analog input pin, set the PCR5 bit to 1 (INT6 input disabled). 2. To use the AN2_5 pin as an analog input pin, set the PCR6 bit to 1 (INT7 input disabled). 3. To use pins AN4 to AN7 as analog input pins, set the PCR7 bit to 1 (key input disabled).
Figure 12.12 Registers IFSR2A, IFSR3A, and PCR
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M16C/64 Group
12. Interrupt
12.7
NMI Interrupt
An NMI interrupt is generated when input on the NMI pin changes state from high to low. The NMI interrupt is a non-maskable interrupt. To use the NMI interrupt, set the PM24 bit in the PM2 register to 1 (NMI function).
12.8
Key Input Interrupt
Of P10_4 to P10_7, a key input interrupt is generated when input on any of pins P10_4 to P10_7 which has had bits PD10_4 to PD10_7 in the PD10 register set to 0 (input) goes low. Key input interrupts can be used as a key-on wake up function, the function which gets the microcomputer out of wait or stop mode. However, if using the key input interrupt, do not use P10_4 to P10_7 as analog input pins. Figure 12.13 shows the block diagram of the Key Input Interrupt. Note, however, that while input on any pin which has had bits PD10_4 to PD10_7 set to 0 (input mode) is pulled low, inputs on all other pins of the port are not detected as interrupts. Set the PCR7 bit in the PCR register to 0 (key input enabled) to use key input interrupts.
Pull-up transistor
PU25 bit in PUR2 register PD10_7 bit in PD10 register PD10_7 bit in PD10 register
KUPIC register
KI3 Pull-up transistor KI2 Pull-up transistor KI1 Pull-up transistor KI0 PD10_4 bit in PD10 register PD10_5 bit in PD10 register PD10_6 bit in PD10 register
Interrupt control circuit
Key input interrupt request
Figure 12.13 Key Input Interrupt
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M16C/64 Group
12. Interrupt
12.9
Address Match Interrupt
An address match interrupt is generated immediately before executing the instruction at the address indicated by the RMADi register (i = 0 to 3). Set the start address of any instruction in the RMADi register. Use bits AIER0 and AIER1 in the AIER register and bits AIER20 and AIER21 in the AIER2 register to enable or disable the interrupt. Note that the address match interrupt is unaffected by the I flag and IPL. When address match interrupt requests are acknowledged, the value of the PC that is saved to the stack area (refer to 12.5.7 "Saving Registers") varies depending on the instruction at the address indicated by the RMADi register (The value of the PC that is saved to the stack area is not the correct return address.) Therefore, follow one of the methods described below to return from the address match interrupt. * Rewrite the content of the stack and then use the REIT instruction to return. * Restore the stack to its previous state before the interrupt request was accepted by using the POP or similar other instruction and then use a jump instruction to return. Table 12.7 shows the Value of the PC That Is Saved to the Stack Area When an Address Match Interrupt Request is Accepted. Note that when using the external bus in 8 bits width, no address match interrupts can be used for external areas. Figure 12.14 shows Registers AIER, AIER2, and RMAD0 to RMAD3.
Table 12.7 Value of the PC That Is Saved to the Stack Area When an Address Match Interrupt Request is Accepted
Instruction at the Address Indicated by the RMADi Register 16-bit op-code instruction Instruction shown below among 8-bit operation code instructions ADD.B:S #IMM8, dest SUB.B:S #IMM8, dest AND.B:S #IMM8, dest OR.B:S #IMM8, dest MOV.B:S #IMM8, dest STZ.B:S #IMM8, dest STNZ.B:S #IMM8, dest STZX.B:S #IMM81, #IMM82,dest CMP.B:S #IMM8, dest PUSHM src POPM dest JMPS #IMM8 JSRS #IMM8 MOV.B:S #IMM, dest (However, dest = A0 or A1) Instructions other than the above
Value of the PC that is saved to the stack area The address indicated by the RMADi register +2
The address indicated by the RMADi register +1
NOTE: Value of the PC that is saved to the stack area: Refer to 12.5.7 "Saving Registers".
Table 12.8 Relationship between Address Match Interrupt Sources and Associated Registers
Address Match Interrupt Sources Address Match Interrupt 0 Address Match Interrupt 1 Address Match Interrupt 2 Address Match Interrupt 3
Address Match Interrupt Enable Bit AIER0 AIER1 AIER20 AIER21
Address Match Interrupt Register RMAD0 RMAD1 RMAD2 RMAD3
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M16C/64 Group
12. Interrupt
Address Match Interrupt Enable Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol AIER
Bit Symbol
Address 020Eh Bit Name Address match interrupt 0 enable bit Address match interrupt 1 enable bit Function 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled
After Reset XXXXXX00b RW RW RW --
AIER0 AIER1 -- (b7-b2)
No register bits. If necessary, set to 0. Read as undefined value
Address Match Interrupt Enable Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol AIER2
Bit Symbol
Address 020Fh Bit Name Address match interrupt 2 enable bit Address match interrupt 3 enable bit Function 0 : Interrupt disabled 1 : Interrupt enabled 0 : Interrupt disabled 1 : Interrupt enabled
After Reset XXXXXX00b RW RW RW --
AIER20 AIER21 -- (b7-b2)
No register bits. If necessary, set to 0. Read as undefined value
Address Match Interrupt Register i (i = 0 to 3)
(b23) b7 (b19) b3 (b16) (b15) b0 b7 (b8) b0 b7 b0
Symbol RMAD0 RMAD1 RMAD2 RMAD3 Function
Address 0212h to 0210h 0216h to 0214h 021Ah to 0218h 021Eh to 021Ch
After Reset X00000h X00000h X00000h X00000h Setting Range 00000h to FFFFFh RW RW --
Address setting register for address match interrupt (b19 to b0) No register bits. If necessary, set to 0. Read as undefined value
Figure 12.14 Registers AIER, AIER2, and RMAD0 to RMAD3
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M16C/64 Group
13. Watchdog Timer
13. Watchdog Timer
The watchdog timer detects whether the program is out of control. Therefore, we recommend using the watchdog timer to improve reliability of a system. The watchdog timer contains a 15-bit counter, and count source protection mode (enabled / disabled) is set here. Table 13.1 shows the Watchdog Timer Specification. Refer to 5.4 "Watchdog Timer Reset" for details of watchdog timer reset. Figure 13.1 shows the Watchdog Timer Block Diagram. Figure 13.2 shows the Registers WDTR, WDTS, and WDC. Figure 13.3 shows the CSPR Register and OFS1 Address.
Table 13.1 Watchdog Timer Specification
Item Count Source Count Operation Count Start Condition
Count Stop Condition Watchdog Timer Reset Condition Operation When the Timer Underflows Select Function
When count source protection mode When count source protection mode is is disabled enabled CPU clock 125kHz on-chip oscillator clock Decrement Either of the followings can be selected. Count automatically starts after reset. Count starts by writing to the WDTS register. Stop mode, wait mode, hold state None Reset Write 00h, and then FFh to the WDTR register. Underflow Watchdog timer interrupt or watchdog Watchdog timer reset timer reset Prescaler divide ratio Set the WDC7 bit in the WDC register to select this mode. Count source protection mode Set the CSPROINI bit (flash memory) in the OFS1 address to select whether this mode is enabled or disabled after reset. If this mode is set to disabled after reset, set the CSPRO bit (program) in the CSPR register. Start up or stop watchdog timer after reset Set the WDTON bit in the OFS1 address to select startup or stop.
Prescaler 1/16 CPU clock HOLD 1/128 1/2
CM07 = 0, WDC7 = 0 CSPRO = 0 CM07 = 0, WDC7 = 0 CM07 = 1 PM12 = 0 Watchdog timer interrupt request
Watchdog timer
foco-s
CSPRO = 1 PM12 = 1 Watchdog timer reset
Set to 7FFFh (1)
Write to WDTR register Internal reset signal ("L" active)
CSPRO WDC7 PM12 CM07
: bit in CSPR register : bit in WDC register : bit in PM1 register : bit in CM0 register
NOTE : 1. 0FFFh is set when the CSPRO bit is set to 1 (count source protection mode enabled).
Figure 13.1
Watchdog Timer Block Diagram
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M16C/64 Group
13. Watchdog Timer
Watchdog Timer Reset Register
b7 b0
Symbol WDTR
Address 037Dh Function
After Reset Indeterminate RW
Setting 00h and then FFh initializes the watchdog timer. (1, 3) The watchdog timer is initialized to 7FFFh when count source protection mode is disabled, and to 0FFFh when count source protection mode is enabled. (2)
WO
NOTES : 1. Make sure no interrupts or DMA transfers will occur before writing FFh after writing 00h. 2. The watchdog timer is set to 0FFFh when the CSPRO bit in the CSPR register is set to 1 (count source protection mode enabled). 3. After the watchdog timer interrupt occurs, reset the watchdog timer by setting the WDTR register.
Watchdog Timer Start Register
b7 b0
Symbol WDTS
Address 037Eh Function
After Reset Indeterminate RW WO
The watchdog timer starts counting after a write instruction to this register
Watchdog Timer Control Register
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol WDC
Bit Symbol
Address 037Fh Bit Name Higher-order bits of watchdog timer No register bit. If necessary, set to 0. Read as 0 Reserved bit Prescaler select bit Set to 0 0 : Divided by 16 1 : Divided by 128 Function
After Reset 00XXXXXXb RW RO -- RW RW
-- (b4-b0) -- (b5) -- (b6) WDC7
Figure 13.2
Registers WDTR, WDTS, and WDC
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M16C/64 Group
13. Watchdog Timer
Count Source Protection Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
0000000
Symbol CSPR
Bit Symbol
Address 037Ch Bit Name Reserved bits Count source protection mode select bit (2) Set to 0 Function
After Reset (1) 00h RW RW RW
-- (b6-b0) CSPRO
0 : Count source protection mode disabled 1 : Count source protection mode enabled
NOTES : 1. When a 0 is written to the CSPROINI bit in the OFS1 address, 10000000b is set after reset. 2. Write a 0 and then a 1 to set the CSPRO bit to 1. 0 cannot be set in a program.
Optional Feature Select Address (1)
b7 b6 b5 b4 b3 b2 b1 b0
111
11
Symbol OFS1
Bit Symbol
Address FFFFFh Bit Name Watchdog timer start select bit
(3)
After Reset FFh (2) Function RW
WDTON
0 : Watchdog timer starts automatically after reset 1 : Watchdog timer is in a stopped state after reset Set to 1 0 : ROM code protection enabled 1 : ROM code protection disabled Set to 1 0 : Count source protection mode enabled after reset 1 : Count source protection mode disabled after reset
RW
-- (b2-b1)
Reserved bits
RW RW RW
ROMCP1 ROM code protection bit -- (b6-b4) Reserved bits
After-reset count source CSPROINI protection mode select bit (3)
RW
NOTES : 1. The OFS1 address exists in flash memory. Set the values when writing a program. 2. The OFS1 address is set to FFh when a block including the OFS1 address is erased. 3. Set the WDTON bit to 0 (watchdog timer starts automatically after reset) when setting the CSPROINI bit to 0 (count source protection mode enabled after reset).
Figure 13.3
CSPR Register and OFS1 Address
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M16C/64 Group
13. Watchdog Timer
13.1
Count Source Protection Mode Disabled
The CPU clock is used for the watchdog timer count source when count source protection mode is disabled. Table 13.2 lists the Watchdog Timer Specifications (When Count Source Protection Mode is Disabled).
Table 13.2 Watchdog Timer Specifications (When Count Source Protection Mode is Disabled)
Item Count Source Count Operation Period
Specification CPU Clock Decrement Prescaler divide ratio (n) x watchdog timer count value (32768) (1) CPU clock n: 16 or 128 (selected by the WDC7 bit in the WDC register) example: When CPU clock frequency = 16 MHz and prescaler divided by 16, period = approximately 32.8ms * Reset * Write 00h, and then FFh to the WDTR register. * Underflow Set the WDTON bit (2) in the OFS1 address (FFFFFh) to select the watchdog timer operation after reset. * When the WDTON bit is set to 1 (watchdog timer is in stop state after reset) The watchdog timer and prescaler stop after reset and count starts by writing to the WDTS register. * When the WDTON bit is set to 0 (watchdog timer starts automatically after reset) The watchdog timer and prescaler start counting automatically after reset. Stop mode, wait mode, hold state (count resumes from the hold value after exiting.) * When the PM 12 bit in the PM1 register is set to 0 Watchdog timer interrupt * When the PM 12 bit in the PM1 register is set to 1 Watchdog timer reset (see 5.4 "Watchdog Timer Reset")
Watchdog Timer Reset Condition Count Start Condition
Count Stop Condition Operation when the Timer Underflows
NOTES: 1. Write 00h, and then FFh to the WDTR register to initialize the watchdog timer. The prescaler is initialized after reset. Some errors in the period of the watchdog timer may be caused by the prescaler. 2. The WDTON bit cannot be changed by a program. Write a 0 to bit 0 of address FFFFFh with a flash programmer to set the WDTON bit.
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M16C/64 Group
13. Watchdog Timer
13.2
Count Source Protection Mode Enabled
The 125 kHz on-chip oscillator clock is used for the watchdog timer count source when count source protection mode is enabled. If the CPU clock stops when a program is out of control, the clock can still be supplied to the watchdog timer. Table 13.3 lists the Watchdog Timer Specifications (When Count Source Protection Mode is Enabled).
Table 13.3 Watchdog Timer Specifications (When Count Source Protection Mode is Enabled)
Item Count Source Count Operation Period
Specification
125 kHz on-chip oscillator clock Decrement
Watchdog timer count value (4096) 125 kHz on-chip oscillator clock example: When 125 kHz on-chip oscillator clock = 125 kHz, period = approximately 32.8ms * Reset * Write 00h, and then FFh to the WDTR register. * Underflow Set the WDTON bit (1) in the OFS1 address (FFFFFh) to select the watchdog timer operation after reset. * When the WDTON bit is set to 1 (watchdog timer is in stop state after reset) The watchdog timer and prescaler stop after reset and count starts by writing to the WDTS register. * When the WDTON bit is set to 0 (watchdog timer starts automatically after reset) The watchdog timer and prescaler start counting automatically after reset. None (Count does not stop in wait mode or in hold state once count starts. The MCU does not enter stop mode.) Watchdog timer reset (see 5.4 "Watchdog Timer Reset" ) * When the CSPRO bit in the CSPR register is set to 1 (count source protection mode enabled) (2), the followings are set automatically. -Set 0FFFh to the watchdog timer. -Set the CM14 bit in the CM1 register to 0 (125 kHz on-chip oscillator on). -Set the PM12 bit in the PM1 register to 1 (The watchdog timer reset is generated when watchdog timer underflows.). * The following conditions apply in count source protection mode. -Writing to the CM10 bit in the CM1 register is disabled (It remains unchanged even if it is set to 1. The MCU does not enter stop mode.). -Writing to the CM14 bit in the CM1 register is disabled (It remains unchanged even if it is set to 1. The 125 kHz on-chip oscillator does not stop.).
Watchdog Timer Reset Condition Count Start Condition
Count Stop Condition Operation when the Timer Underflows Registers, Bits
NOTES: 1. The WDTON bit cannot be changed by a program. Write 0 to bit 0 of address FFFFFh with a flash programmer to set the WDTON bit. 2. Even if 0 is written to the CSPROINI bit in the OFS1 address, the CSPRO is set to 1. The CSPROINI bit cannot be changed by a program. Write 0 to bit 7 of address FFFFFh with a flash programmer to set the CSPROINI bit.
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M16C/64 Group
14. DMAC
14. DMAC
The DMAC (Direct Memory Access Controller) allows data to be transferred without the CPU intervention. Four DMAC channels are included. Each time a DMA request occurs, the DMAC transfers one (8 or 16-bit) data from the source address to the destination address. The DMAC uses the same data bus as used by the CPU. Because the DMAC has higher priority of bus control than the CPU and because it makes use of a cycle steal method, it can transfer one word (16 bits) or one byte (8 bits) of data within a very short time after a DMA request is generated. Figure 14.1 shows the DMAC Block Diagram. Table 14.1 lists the DMAC Specifications. Figures 14.2 to 14.5 show the DMAC-related registers.
Address bus DMA0 source pointer SAR0 (20) (addresses 0182h to 0180h) DMA0 destination pointer DAR0 (20) (addresses 0186h to 0184h) DMA0 forward address pointer (20) (1) DMA1 source pointer SAR1 (20) (addresses 0192h to 0190h) DMA1 destination pointer DAR1 (20) (addresses 0196h to 094h) DMA0 transfer counter reload register TCR0 (16) (addresses 0189h, 0188h) DMA0 transfer counter TCR0 (16) DMA1 transfer counter reload register TCR1 (16) (addresses 0199h, 0198h) DMA1 transfer counter TCR1 (16) DMA2 transfer counter reload register TCR2 (16) (addresses 01A9h, 01A8h) DMA2 transfer counter TCR2 (16) DMA3 transfer counter reload register TCR3 (16) (addresses 01B9h, 01B8h) DMA3 transfer counter TCR3 (16) DMA latch high-order bits DMA latch low-order bits DMA2 source pointer SAR2 (20) (addresses 01A2h to 01A0h) DMA2 destination pointer DAR2 (20) (addresses 01A6h to 01A4h) DMA2 forward address pointer (20) (1) DMA3 source pointer SAR3 (20) (addresses 01B2h to 01B0h) DMA3 destination pointer DAR3 (20) (addresses 01B6h to 01B4h) DMA3 forward address pointer (20) (1) DMA1 forward address pointer (20) (1)
Data bus low-order bits
Data bus high-order bits NOTE : 1. Pointer is incremented by a DMA request.
Figure 14.1
DMAC Block Diagram
A DMA request is generated by a write to the DSR bit in the DMiSL register (i = 0 to 3), as well as by an interrupt request which is generated by any function specified by bits DMS and DSEL4 to DSEL0 in the DMiSL register. However, unlike in the case of interrupt requests, DMA requests are not affected by the I flag and the interrupt control register, so that even when interrupt requests are disabled and no interrupt request can be accepted, DMA requests are always accepted. Furthermore, because the DMAC does not affect interrupts, the IR bit in the interrupt control register does not change state due to a DMA transfer. A data transfer is initiated each time a DMA request is generated when the DMAE bit in the DMiCON register = 1 (DMA enabled). However, if the cycle in which a DMA request is generated is faster than the DMA transfer cycle, the number of transfer requests generated and the number of times data is transferred may REJ09B0392-0064 Rev.0.64 Page 123 of 373 Oct 12, 2007
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M16C/64 Group not match. Refer to 14.4 "DMA Request" for details.
Table 14.1 DMAC Specifications (3)
14. DMAC
Item No. of Channels Transfer Memory Space
Specification 4 (cycle steal method) * From given address in the 1-Mbyte space to a fixed address * From a fixed address to given address in the 1-Mbyte space * From a fixed address to a fixed address 128 Kbytes (with 16-bit transfers) or 64 Kbytes (with 8-bit transfers)
Maximum No. of Bytes Transferred
DMA Request Factors (1, 2) Falling edge of INT0 to INT7 Both edges of INT0 to INT7 Timer A0 to timer A4 interrupt requests Timer B0 to timer B5 interrupt requests UART0 to 2, UART5 to 7 transmission interrupt requests UART0 to 2, UART5 to 7 reception / ACK interrupt requests SI/O3, SI/O4 interrupt requests A/D conversion interrupt requests Software triggers Channel Priority DMA0 > DMA1 > DMA2 > DMA3 (DMA0 takes precedence) Transfer Unit 8 bits or 16 bits Transfer Address Direction Forward or fixed (The source and destination addresses cannot both be in the forward direction.) Transfer Single Transfer is completed when the DMAi transfer counter underflows. Mode Transfer Repeat When the DMAi transfer counter underflows, it is reloaded with the value of Transfer the DMAi transfer counter reload register and a DMA transfer is continued with it. DMA Interrupt Request When the DMAi transfer counter underflowed Generation Timing DMA Transfer Start Data transfer is initiated each time a DMA request is generated when the DMAE bit in the DMAiCON register = 1 (enabled). DMA Trans- Single * When the DMAE bit is set to 0 (disabled) fer Stop Transfer * After the DMAi transfer counter underflows Repeat When the DMAE bit is set to 0 (disabled) Transfer Reload Timing for Forward When a data transfer is started after setting the DMAE bit to 1 (enabled), the Address Pointer and DMAi forward address pointer is reloaded with the value of the SARi or DARi Transfer Counter pointer whichever is specified to be in the forward direction and the DMAi transfer counter is reloaded with the value of the DMAi transfer counter reload register. DMA Transfer Cycles Minimum 3 cycles between SFR and internal RAM NOTES: 1. DMA transfer is not effective to any interrupt. DMA transfer is affected neither by the I flag nor by the interrupt control register. 2. The selectable factors of DMA requests differ with each channel. 3. Make sure that no DMAC-related registers (addresses 0180h to 01BFh) are accessed by the DMAC. i = 0 to 3
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M16C/64 Group
14. DMAC
DMAi Source Select Register (i = 0 to 3)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol DM0SL DM1SL DM2SL DM3SL Bit Symbol DSEL0 DSEL1 DSEL2 DSEL3 DSEL4 -- (b5) DMS Bit Name
Address 0398h 039Ah 0390h 0392h Function
After Reset 00h 00h 00h 00h RW RW RW
DMA request source select bit
(NOTE 1) RW RW
No register bit. If necessary, set to 0. Read as 0 DMA request source expansion select bit 0: Basic request source 1: Extended request source A DMA request is generated by setting this bit to 1 when the DMS bit is 0 (basic source) and bits DSEL4 to DSEL0 are 00001b (software trigger). Read as 0
-- RW
DSR
Software DMA request bit
RW
NOTE : 1. The sources of DMAi requests can be selected by a combination of the DMS bit and bits DSEL4 to DSEL0 in the manner described in Figure 14.3.
Figure 14.2
Registers DM0SL, DM1SL, DM2SL, and DM3SL (1)
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M16C/64 Group
14. DMAC
DMA0 DSEL4 to DSEL0 DMS = 0 (Basic Factor of Request) 00000b Falling edge of INT0 pin Software trigger 00001b Timer A0 00010b Timer A1 00011b Timer A2 00100b Timer A3 00101b Timer A4 00110b Timer B0 00111b Timer B1 01000b Timer B2 01001b UART0 transmission 01010b UART0 reception 01011b UART2 transmission 01100b UART2 reception 01101b A/D conversion 01110b UART1 transmission 01111b UART1 reception 10000b UART5 transmission 10001b UART5 reception 10010b UART6 transmission 10011b UART6 reception 10100b UART7 transmission 10101b UART7 reception 10110b 10111b 11XXXb X indicates 0 or 1. - indicates no setting. DMA1 DSEL4 to DSEL0 00000b Software trigger 00001b Timer A0 00010b Timer A1 00011b Timer A2 00100b Timer A3 00101b Timer A4 00110b Timer B0 00111b Timer B1 01000b Timer B2 01001b UART0 transmission 01010b UART0 reception / ACK0 01011b UART2 transmission 01100b UART2 reception / ACK2 01101b A/D conversion 01110b UART1 reception / ACK1 01111b UART1 transmission 10000b UART5 transmission 10001b UART5 reception / ACK5 10010b UART6 transmission 10011b UART6 reception / ACK6 10100b UART7 transmission 10101b UART7 reception / ACK7 10110b 10111b 11XXXb X indicates 0 or 1. - indicates no setting. DMS = 0 (Basic Factor of Request) DMS = 1 (Extended Factor of Request) Falling edge of INT1 pin SI / O3 SI / O4 Both edges of INT1 pin Falling edge of INT5 pin Both edges of INT5 pin DMS = 1 (Extended Factor of Request) Both edges of INT0 pin Timer B3 Timer B4 Timer B5 Falling edge of INT4 pin Both edges of INT4 pin -
DMA2 DSEL4 to DSEL0 DMS = 0 (Basic Factor of Request) 00000b Falling edge of INT2 pin Software trigger 00001b 00010b Timer A0 00011b Timer A1 00100b Timer A2 00101b Timer A3 00110b Timer A4 Timer B0 00111b 01000b Timer B1 01001b Timer B2 01010b UART0 transmission 01011b UART0 reception 01100b UART2 transmission 01101b UART2 reception 01110b A/D conversion 01111b UART1 transmission 10000b UART1 reception UART5 transmission 10001b UART5 reception 10010b UART6 transmission 10011b UART6 reception 10100b UART7 transmission 10101b UART7 reception 10110b 10111b 11XXXb X indicates 0 or 1. - indicates no setting. DMS = 1 (Extended Factor of Request) Both edges of INT2 pin Timer B3 Timer B4 Timer B5 Falling edge of INT6 pin Both edges of INT6 pin -
DMA3 DSEL4 to DSEL0 DMS = 0 (Basic Factor of Request) DMS = 1 (Extended Factor of Request) 00000b 00001b 00010b 00011b 00100b 00101b 00110b 00111b 01000b 01001b 01010b 01011b 01100b 01101b 01110b 01111b 10000b Falling edge of INT3 pin Software trigger Timer A0 Timer A1 Timer A2 Timer A3 Timer A4 Timer B0 Timer B1 Timer B2 UART0 transmission UART0 reception / ACK0 UART2 transmission UART2 reception / ACK2 A/D conversion UART1 reception / ACK1 UART1 transmission UART5 transmission UART5 reception / ACK5 UART6 transmission UART6 reception / ACK6 UART7 transmission UART7 reception / ACK7 SI / O3 SI / O4 Both edges of INT3 pin Falling edge of INT7 pin Both edges of INT7 pin -
10001b 10010b 10011b 10100b 10101b 10110b 10111b 11XXXb X indicates 0 or 1. - indicates no setting.
Figure 14.3
Registers DM0SL, DM1SL, DM2SL, and DM3SL (2)
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M16C/64 Group
14. DMAC
DMAi Control Register (i = 0 to 3)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol DM0CON DM1CON DM2CON DM3CON Bit Symbol DMBIT DMASL DMAS DMAE DSD DAD -- (b7-b6) Bit Name
Address 018Ch 019Ch 01ACh 01BCh Function 0 : 16 bits 1 : 8 bits
After Reset 00000X00b 00000X00b 00000X00b 00000X00b RW RW RW RW (1) RW RW RW --
Transfer unit bit select bit
Repeat transfer mode select 0 : Single transfer bit 1 : Repeat transfer DMA request bit DMA enable bit 0 : DMA not requested 1 : DMA requested 0 : Disabled 1 : Enabled
Source address direction select 0 : Fixed bit (2) 1 : Forward Destination address direction select bit (2) 0 : Fixed 1 : Forward
No register bits. If necessary, set to 0. Read as 0
NOTES : 1. The DMAS bit can be set to 0 by writing a 0 in a program (This bit remains unchanged even if 1 is written). 2. Set at least either the DAD bit or DSD bit to 0 (address direction fixed).
Figure 14.4
Registers DM0CON, DM1CON, DM2CON, and DM3CON
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M16C/64 Group
14. DMAC
DMAi Source Pointer (i = 0 to 3) (1)
(b23) b7 (b19) b3 (b16) (b15) b0 b7 (b8) b0 b7 b0
Symbol SAR0 SAR1 SAR2 SAR3 Function Set the source address of transfer
Address 0182h to 0180h 0192h to 0190h 01A2h to 01A0h 01B2h to 01B0h
After Reset 0XXXXXh 0XXXXXh 0XXXXXh 0XXXXXh Setting Range 00000h to FFFFFh RW RW --
No register bits. If necessary, set to 0. Read as 0 NOTE : 1. If the DSD bit in the DMiCON register is 0 (fixed), write to this register when the DMAE bit in the DMiCON register is 0 (DMA disabled). If the DSD bit is 1 (forward direction), this register can be written to at any time. If the DSD bit is 1 and the DMAE bit is 1 (DMA enabled), the DMAi forward address pointer can be read from this register. Otherwise, the value written to it can be read.
DMAi Destination Pointer (i = 0 to 3) (1)
(b23) b7 (b19) b3 (b16) (b15) b0 b7 (b8) b0 b7 b0
Symbol DAR0 DAR1 DAR2 DAR3 Function Set the destination address of transfer
Address 0186h to 0184h 0196h to 0194h 01A6h to 01A4h 01B6h to 01B4h
After Reset 0XXXXXh 0XXXXXh 0XXXXXh 0XXXXXh Setting Range 00000h to FFFFFh RW RW --
No register bits. If necessary, set to 0. Read as 0 NOTE : 1. If the DAD bit in the DMiCON register is 0 (fixed), write to this register when the DMAE bit in the DMiCON register is 0 (DMA disabled). If the DAD bit is 1 (forward direction), this register can be written to at any time. If the DAD bit is 1 and the DMAE bit is 1 (DMA enabled), the DMAi forward address pointer can be read from this register. Otherwise, the value written to it can be read.
DMAi Transfer Counter (i = 0 to 3)
(b15) b7 (b8) b0 b7 b0
Symbol TCR0 TCR1 TCR2 TCR3 Function
Address 0189h to 0188h 0199h to 0198h 01A9h to 01A8h 01B9h to 01B8h
After Reset Indeterminate Indeterminate Indeterminate Indeterminate Setting Range RW
Set the transfer count minus 1. The written value is stored in the DMAi transfer counter reload register, and when the DMAE bit in the DMiCON register is set to 1 (DMA enabled) or the DMAi transfer counter underflows when the DMASL bit in the DMiCON register is 1 (repeat transfer), the value of the DMAi transfer counter reload register is transferred to the DMAi transfer counter. When read, the DMAi transfer counter is read.
0000h to FFFFh
RW
Figure 14.5
Registers SAR0, SAR1, SAR2, SAR3, DAR0, DAR1, DAR2, DAR3, TCR0, TCR1, TCR2, and TCR3
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M16C/64 Group
14. DMAC
14.1
Transfer Cycles
Transfer cycle is composed of a bus cycle to read data from source address (source read) and a bus cycle to write data to destination address (destination write). The number of read and write bus cycles depends on source and destination addresses. During memory extension and microprocessor modes, it is also affected by the BYTE pin level. Furthermore, the bus cycle itself is extended by a software wait or RDY signal.
14.1.1
Effect of Source and Destination Addresses
When a 16-bit data is transferred with a 16-bit data bus and a source address starts with an odd address, source-read cycle is incremented by one bus cycle, compared to a source address starting with an even address. When a 16-bit data is transferred with a 16-bit data bus and a destination address starts with an odd address, destination-write cycle is incremented by one bus cycle, compared to a destination address starting with an even address.
14.1.2
Effect of BYTE Pin Level
During memory extension and microprocessor modes, if 16 bits of data are to be transferred on an 8-bit data bus (input on the BYTE pin = high), the operation is accomplished by transferring 8 bits of data twice. Therefore, this operation requires two bus cycles to read data and two bus cycles to write data. Furthermore, if the DMAC is to access the internal area (internal ROM, internal RAM, or SFR), unlike in the case of the CPU, the DMAC does it through the data bus width selected by the BYTE pin.
14.1.3
Effect of Software Wait
For memory or SFR accesses in which one or more software wait states are inserted, the number of bus cycles required for that access increases by an amount equal to software wait states.
14.1.4
Effect of RDY Signal
During memory extension and microprocessor modes, DMA transfers to and from an external area are affected by the RDY signal. Refer to 8.2.6 "RDY Signal". Figure 14.6 shows the example of the Transfer Cycles for Source Read. For convenience, the destination write cycle is shown as one cycle and the source read cycles for the different conditions are shown. In reality, the destination write cycle is subject to the same conditions as the source read cycle, with the transfer cycle changing accordingly. When calculating transfer cycles, take into consideration each condition for the source read and the destination write cycle, respectively. For example, when data is transferred in 16 bit units using an 8-bit bus ((2) on Figure 14.6), two source read bus cycles and two destination write bus cycles are required.
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M16C/64 Group
14. DMAC
(1) When the transfer unit is 8 or 16 bits and the source of transfer is an even address
BCLK Address bus RD signal WR signal Data bus
CPU use Source Destination Dummy cycle CPU use CPU use Source Destination Dummy cycle CPU use
(2) When the transfer unit is 16 bits and the source address of transfer is an odd address, or when the transfer unit is 16 bits and an 8-bit bus is used
BCLK Address bus RD signal WR signal Data bus
CPU use Source Source + 1 Destination Dummy cycle CPU use CPU use Source Source + 1 Destination Dummy cycle CPU use
(3) When the source read cycle under condition (1) has one wait state inserted
BCLK Address bus RD signal WR signal Data bus
CPU use Source Destination Dummy cycle CPU use CPU use Source Destination Dummy cycle CPU use
(4) When the source read cycle under condition (2) has one wait state inserted
BCLK Address bus RD signal WR signal Data bus
CPU use Source Source + 1 Destination Dummy cycle CPU use CPU use Source Source + 1 Destination Dummy cycle CPU use
NOTE : 1. The same timing changes occur with the respective conditions at the destination as at the source.
Figure 14.6
Transfer Cycles for Source Read
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M16C/64 Group
14. DMAC
14.2
DMA Transfer Cycles
The number of DMA transfer cycles can be calculated as follows. Table 14.2 lists the DMAC Transfer Cycles. Table 14.3 lists the Coefficients j and k. Number of transfer cycles per transfer unit = Number of read cycles x j + Number of write cycles x k
Table 14.2 DMAC Transfer Cycles
Transfer Unit 8-bit Transfers (DMBIT= 1)
Bus Width 16-bit (BYTE = "L") 8-bit (BYTE = "H")
Access Address Even Odd Even Odd Even Odd Even Odd
Single-Chip Mode No. of Read Cycles 1 1 1 2 No. of Write Cycles 1 1 1 2 -
16-bit Transfers 16-bit (DMBIT= 0) (BYTE = "L") 8-bit (BYTE = "H") - indicates that no condition exists. Table 14.3 Coefficients j and k
Memory Expansion Mode Microprocessor Mode No. of Read No. of Write Cycles Cycles 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2
Internal Area Internal ROM, SFR RAM 1-Wait 2-Wait No With (2) (2) Wait Wait j k 1 1 2 2 2 2 3 3
External Area Separate Bus No Wait 1 2 With Wait (1) 1-Wait 2-Wait 3-Wait 2 3 4 2 3 4 Multiplex Bus With Wait (1) 1-Wait 2-Wait 3-Wait 3 3 4 3 3 4
NOTES: 1. It depends on the set value of the CSE register. 2. It depends on the set value of the PM20 bit in the PM2 register.
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M16C/64 Group
14. DMAC
14.3
DMA Enabled
When a data transfer starts after setting the DMAE bit in the DMiCON register (i = 0 to 3) to 1 (enabled), the DMAC operates as follows: (1) Reload the forward address pointer with the SARi register value when the DSD bit in the DMiCON register is 1 (forward) or the DARi register value when the DAD bit in the DMiCON register is 1 (forward). (2) Reload the DMAi transfer counter with the DMAi transfer counter reload register value. If the DMAE bit is set to 1 again while it remains set, the DMAC performs the above operation. However, if a DMA request may occur simultaneously when the DMAE bit is being written, follow the steps below. Step 1: Write 1 to the DMAE bit and DMAS bit in the DMiCON register simultaneously. Step 2: Make sure that the DMAi is in an initial state as described above (1) and (2) in a program. If the DMAi is not in an initial state, the above steps should be repeated.
14.4
DMA Request
The DMAC can generate a DMA request as triggered by the factor of request that is selected with the DMS bit and bits DSEL4 to DSEL0 in the DMiSL register (i = 0 to 3) on either channel. Table 14.1 lists the Timing at Which the DMAS Bit Changes State. Whenever a DMA request is generated, the DMAS bit is set to 1 (DMA requested) regardless of whether or not the DMAE bit is set. If the DMAE bit is set to 1 (enabled) when this occurs, the DMAS bit is set to 0 (DMA not requested) immediately before a data transfer starts. This bit cannot be set to 1 in a program (it can only be set to 0). The DMAS bit may be set to 1 when the DMS bit or bits DSEL4 to DSEL0 change state. Therefore, always be sure to set the DMAS bit to 0 after changing the DMS bit or bits DSEL4 to DSEL0. Because if the DMAE bit is 1, a data transfer starts immediately after a DMA request is generated, the DMAS bit in almost all cases is 0 when read in a program. Read the DMAE bit to determine whether the DMAC is enabled.
Table 14.4
Timing at Which the DMAS Bit Changes State
DMA Factor Software Trigger Peripheral Function
DMAS Bit in the DMiCON Register Timing at which the bit is set to 1 Timing at which the bit is set to 0 When the DSR bit in the DMiSL register * Immediately before a data transfer is set to 1 starts * When set by writing a 0 in a program When the interrupt control register for the peripheral function that is selected by bits DSEL4 to DSEL0 and DMS in the DMiSL register has its IR bit set to 1
i = 0 to 3
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M16C/64 Group
14. DMAC
14.5
Channel Priority and DMA Transfer Timing
If several channels of DMA0 to DMA3 are enabled and DMA transfer request signals are detected active in the same sampling period (one period from a falling edge to the next falling edge of BCLK), the DMAS bit on each channel is set to 1 (DMA requested) at the same time. In this case, the DMA requests are arbitrated according to the channel priority: DMA0 > DMA1 > DMA2 > DMA3. The following describes DMAC operation when DMA0 and DMA1 requests are detected active in the same sampling period. Figure 14.7 shows an example of DMA Transfer by External Factors. In Figure 14.7, DMA0 request having priority is received first to start a transfer when DMA0 and DMA1 requests are generated simultaneously. After one DMA0 transfer is completed, a bus access privilege is returned to the CPU. When the CPU has completed one bus access, a DMA1 transfer starts. After one DMA1 transfer is completed, the bus access privilege is again returned to the CPU. In addition, DMA requests cannot be incremented since each channel has one DMAS bit. Therefore, when DMA requests, as DMA1 in Figure 14.7, occurs more than one time, the DMAS bit is set to 0 after getting the bus access privilege. The bus access privilege is returned to the CPU when one transfer is completed. Refer to 8.2.7 "HOLD Signal" for details about bus access privilege.
An example when DMA requests for external factors are detected active at the same time and DMA transfer is executed in the shortest cycle
BCLK DMA0 DMA1 CPU INT0 DMAS bit in DMA0 INT1 DMAS bit in DMA1
Figure 14.7 DMA Transfer by External Factors
Bus access privilege
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M16C/64 Group
15. Timers
15. Timers
Eleven 16-bit timers, each capable of operating independently of the others, can be classified by function as either Timer A (five) and Timer B (six). The count source for each timer acts as a clock, to control such timer operations as counting, reloading, etc. Figure 15.1 shows Timers A and B count source, and Figures 15.2 and 15.3 show block diagrams of Timer A and Timer B configuration, respectively.
Clock Generation Circuit
Main clock generation circuit or PLL frequency synthesizer
CM21 = 0
f1
CM21 = 1
f1TIMAB PCLK0 = 1 1/2 1/8 f2TIMAB
PCLK0 = 0
f1TIMAB or f2TIMAB f8TIMAB
125 KHz on-chip oscillator
Subclock generation circuit
fOCO-S fC
fOCO-S fC32
1/4 1/2
f32TIMAB f64TIMAB fOCO-S fC32
1/32
Reset Set the CPSR bit in the CPSRF register to 1 (prescaler reset).
CM21 : bit in the CM2 register PCLK0 : bit in the PCLKR register
Figure 15.1
Timers A and B Count Source
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M16C/64 Group
15. Timers
fC32 fOCO-S f64TIMAB f32TIMAB f8TIMAB f1TIMAB or f2TIMAB
00 01 10 11
TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0 10
00: Timer mode 10: One-shot timer mode 11: PWM mode
000 001 010 011 101 110
TCS2 to TCS0
1
01 00 11
Timer A0
01: Event counter mode
TA0TGH to TA0TGL
Timer A0 interrupt
TA0IN (1)
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS7
TMOD1 to TMOD0 10
00: Timer mode 10: One-shot timer mode 11: PWM mode
000 001 010 011 101 110
TCS6 to TCS4
1
01 00 11
Timer A1
01: Event counter mode
TA1TGH to TA1TGL
Timer A1 interrupt
TA1IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0 10
00: Timer mode 10: One-shot timer mode 11: PWM mode
000 001 010 011 101 110
TCS2 to TCS0
1
01 00 11
Timer A2
01: Event counter mode
TA2TGH to TA2TGL
Timer A2 interrupt
TA2IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS7
TMOD1 to TMOD0 10
00: Timer mode 10: One-shot timer mode 11: PWM mode
000 001 010 011 101 110
TCS6 to TCS4
1
01 00 11
Timer A3
01: Event counter mode
TA3TGH to TA3TGL
Timer A3 interrupt
TA3IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0 10
00: Timer mode 10: One-shot timer mode 11: PWM mode
000 001 010 011 101 110
TCS2 to TCS0
1
01 00 11
Timer A4
01: Event counter mode
TA4TGH to TA4TGL
Timer A4 interrupt
TA4IN
Noise filter
Timer B2 overflow or underflow TCK1 to TCK0, TMOD1 to TMOD0 : bits in the TAiMR register TAiGH to TAiGL : bits in the ONSF register or TRGSR register TCS0 to TCS7 : bits in registers TACS0 to TACS2 i = 0 to 4 NOTE: 1. Be aware that TA0IN shares pins with TB5IN.
Figure 15.2
Timer A Configuration
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M16C/64 Group
15. Timers
fC32 fOCO-S f64TIMAB f32TIMAB f8TIMAB f1TIMAB or f2TIMAB
00 01 10 11
Timer B2 overflow or underflow (to a count source of Timer A)
TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0
00: Timer mode 10: Pulse width / pulse period measurement mode
1 0
000 001 010 011 101 110
TCS2 to TCS0
1
Timer B0
TCK1
Timer B0 interrupt
01: Event counter mode
TB0IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS7
TMOD1 to TMOD0
00: Timer mode 10: Pulse width / pulse period measurement mode
000 001 010 011 101 110
TCS6 to TCS4
1
1 0
Timer B1
TCK1
Timer B1 interrupt
01: Event counter mode
TB1IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS3
00: Timer mode 10: Pulse width / pulse period measurement mode
1 0
TMOD1 to TMOD0
000 001 010 011 101 110
TCS2 to TCS0
1
Timer B2
TCK1
Timer B2 interrupt
01: Event counter mode
TB2IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0
00: Timer mode 10: Pulse width / pulse period measurement mode
000 001 010 011 101 110
TCS2 to TCS0
1
1 0
Timer B3
TCK1
Timer B3 interrupt
01: Event counter mode
TB3IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS7
TMOD1 to TMOD0
00: Timer mode 10: Pulse width / pulse period measurement mode
1 0
000 001 010 011 101 110
TCS6 to TCS4
1
Timer B4
TCK1
Timer B4 interrupt
01: Event counter mode
TB4IN
00 01 10 11
Noise filter TCK1 to TCK0 0 TCS3
TMOD1 to TMOD0
00: Timer mode 10: Pulse width / pulse period measurement mode
1 0
000 001 010 011 101 110
TCS2 to TCS0
1
Timer B5
TCK1
Timer B5 interrupt
01: Event counter mode
TCK1 to TCK0, TMOD1 to TMOD0 : bits in the TBiMR register (i = 0 to 5) TCS0 to TCS7 : bits in registers TBCS0 to TBCS3
Noise filter
TB5IN (1)
NOTE: 1. Be aware that TB5IN shares pins with TA0IN.
Figure 15.3
Timer B Configuration
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M16C/64 Group
15. Timers
15.1
Timer A
Figure 15.4 shows a Timer A Block Diagram. Figures 15.5 to 15.9 show registers related to Timer A. Timer A supports the following four modes. Except in event counter mode, Timers A0 to A4 all have the same function. Use bits TMOD1 to TMOD0 in the TAiMR register (i = 0 to 4) to select the desired mode. * Timer Mode The timer counts an internal count source. * Event Counter Mode The timer counts pulses from an external device or overflows and underflows of other timers. * One-shot Timer Mode The timer outputs a pulse only once before it reaches the minimum count 0000h. * Pulse Width Modulation (PWM) Mode The timer outputs pulses in a given width successively.
fC32 fOCO-S f64TIMAB f32TIMAB f8TIMAB f1TIMAB or f2TIMAB
Count source select
00 01 10 11
TCK1 to TCK0 0
TCS3 or TCS7
Data Bus
*Timer: TMOD1 to TMOD0 = 00, MR2 = 0 *One-shot timer: TMOD1 to TMOD0 = 10 TMOD1 to TMOD0, *Pulse width modulation: TMOD1 to TMOD0 = 11 MR2 *Timer (gate function): TMOD1 to TMOD0 = 00, MR2 = 1 *Event counter: TMOD1 to TMOD0 = 01
TAiS
Reload Register
000 001 010 011 101 110
TCS2 to TCS0 or TCS6 to TCS4
1
Counter Increment / decrement Always decrement except in event counter mode
Polarity Select TAiIN TB2 overflow (1) TAj overflow (1) TAk overflow (1)
00 01 10 11
Decrement
00 10 11 01
TMOD1 to TMOD0 To external trigger circuit
TAiTGH to TAiTGL
TAiUD 0 1 MRO 0 1
MR2
POFSi
TAiOUT
Toggle Flip Flop i = 0 to 4 j = i - 1, however, j = 4 if i = 0 k = i + 1, however, k = 0 if i = 4 Tai TAj TAk Timer A0 Timer A4 Timer A1 Timer A1 Timer A0 Timer A2 Timer A2 Timer A1 Timer A3 Timer A3 Timer A2 Timer A4 Timer A4 Timer A3 Timer A0
NOTES: 1. Overflow or underflow TCK1 to TCK0, TMOD1 to TMOD0, MR2 to MR1 : bits in the TAiMR register TAiTGH to TAiTGL : bits in the ONSF register when i=0, bits in the TRGSR register when i = 1 to 4 TAiS : bits in the TABSR register TAiUD : bits in the UDF register TCS0 to TCS7 : bits in the registers TACS0 to TACS2 POFSi : bits in the TAPOFS register
Figure 15.4
Timer A Block Diagram
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M16C/64 Group
15. Timers
Timer Ai Mode Register (i= 0 to 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TA0MR to TA4MR
Bit Symbol
Address 0336h to 033Ah Bit Name Function
b1 b0
After Reset 00h RW RW
TMOD0
Operation mode select bit
TMOD1 MR0 MR1 MR2 MR3 TCK0 TCK1
0 0 1 1
0 : Timer mode 1 : Event counter mode 0 : One-shot timer mode 1 : Pulse width modulation (PWM) mode
RW RW
Function varies with each operation mode
RW RW RW
Count source select bit (1) (Function varies with each operation mode)
RW RW
NOTE : 1. Valid when the bit3 or the bit 7 in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Timer Ai Register (i= 0 to 4) (1)
(b15) b7 (b8) b0 b7 b0
Symbol TA0 TA1 TA2 TA3 TA4 Mode Timer mode
Address 0327h to 0326h 0329h to 0328h 032Bh to 032Ah 032Dh to 032Ch 032Fh to 032Eh Function Divide the count source by n + 1 where n = set value
After Reset Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate Setting Range 0000h to FFFFh RW RW
Divide the count source by FFFFh - n + Event counter mode 1 where n = set value when counting up or by n + 1 when counting down (5) One-shot timer mode Pulse width modulation mode (16-bit PWM) Divide the count source by n where n = set value, and the counter stops Modify the pulse width as follows: PWM period: (216 - 1) / fj PWM pulse width: n / fj where n = set value, fj = count source frequency Modify the pulse width as follows: PWM period: (28 - 1) x (m + 1) / fj PWM pulse width: (m + 1)n / fj where n = high-order address set value, m = low-order address set value, fj = count source frequency
0000h to FFFFh
RW
0000h to FFFFh (2, 4) 0000h to FFFEh (3, 4)
WO WO
Pulse width modulation mode (8-bit PWM)
00h to FEh (High-order address) 00h to FFh (Low-order address)
(3, 4)
WO
NOTES : 1. Access to the register in 16-bit units. 2. If the TAi register is set to 0000h, the counter does not work and timer Ai interrupt requests are not generated either. Furthermore, if pulse output is selected, no pulses are output from the TAiOUT pin. 3. If the TAi register is set to 0000h, the pulse width modulator does not work, the output level on the TAiOUT pin remains low, and timer Ai interrupt requests are not generated either. The same applies when the 8 high-order bits of the timer TAi register are set to 00h while operating as an 8-bit pulse width modulator. 4. Use the MOV instruction to write to the TAi register. 5. The timer counts pulses from an external device or overflows or underflows in other timers.
Figure 15.5
Registers TA0MR to TA4MR and TA0 to TA4
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M16C/64 Group
15. Timers
Count Start Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TABSR
Bit Symbol
Address 0320h Bit Name Timer A0 count start flag Timer A1 count start flag Timer A2 count start flag Timer A3 count start flag Timer A4 count start flag Timer B0 count start flag Timer B1 count start flag Timer B2 count start flag 0 : Stop counting 1 : Start counting Function
After Reset 00h RW RW RW RW RW RW RW RW RW
TA0S TA1S TA2S TA3S TA4S TB0S TB1S TB2S
Up / Down Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol UDF
Bit Symbol
Address 0324h Bit Name Function 0 : Decrement 1 : Increment
After Reset 00h RW RW RW
TA0UD TA1UD TA2UD TA3UD TA4UD TA2P
Timer A0 up / down flag Timer A1 up / down flag Timer A2 up / down flag Timer A3 up / down flag Timer A4 up / down flag Timer A2 two-phase pulse signal processing select bit Timer A3 two-phase pulse signal processing select bit Timer A4 two-phase pulse signal processing select bit
Enabled during event counter mode (when not using two-phase pulse signal)
RW RW RW
0 : Two-phase pulse signal processing disabled 1 : Two-phase pulse signal processing enabled (1, 2)
RW
TA3P
RW
TA4P
RW
NOTES : 1. Set the port direction bits for pins TA2IN to TA4IN and pins TA2OUT to TA4OUT to 0 (input mode). 2. When not using the two-phase pulse signal processing function, set the bit corresponding to Timer A2 to Timer A4 to 0.
Figure 15.6
Registers TABSR and UDF
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M16C/64 Group
15. Timers
One-Shot Start Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol ONSF
Bit Symbol
Address 0322h Bit Name Timer A0 one-shot start flag Timer A1 one-shot start flag Timer A2 one-shot start flag Timer A3 one-shot start flag Timer A4 one-shot start flag Z-phase input enable bit 0 : Z-phase input disabled 1 : Z-phase input enabled
b7 b6
After Reset 00h Function The timer starts counting by setting this bit to 1 while bits TMOD1 and TMOD0 in the TAiMR register (i = 0 to 4) = 10b (one-shot timer mode) and the MR2 bit in the TAiMR register = 0 (TAiOS bit enabled). Read as 0 RW RW RW RW RW RW RW RW RW
TA0OS TA1OS TA2OS TA3OS TA4OS
TAZIE
TA0TGL
Timer A0 event / trigger select bit
TA0TGH
0 0 1 1
0: 1: 0: 1:
Input on TA0IN pin is selected (1) TB2 is selected (2) TA4 is selected (2) TA1 is selected (2)
NOTES : 1. Make sure the PD7_1 bit in the PD7 register is set to 0 ( input mode). 2. Overflow or underflow.
Trigger Select Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TRGSR
Bit Symbol
Address 0323h Bit Name Function b1 0 0 1 1 b3 0 0 1 1 b5 0 0 1 1 b7 0 0 1 1 b0 0 : Input on TA1IN is selected 1 : TB2 is selected (2) 0 : TA0 is selected (2) 1 : TA2 is selected (2) b2 0 : Input on TA2IN is selected 1 : TB2 is selected (2) 0 : TA1 is selected (2) 1 : TA3 is selected (2) b4 0 : Input on TA3IN is selected 1 : TB2 is selected (2) 0 : TA2 is selected (2) 1 : TA4 is selected (2) b6 0 : Input on TA4IN is selected 1 : TB2 is selected (2) 0 : TA3 is selected (2) 1 : TA0 is selected (2)
(1)
After Reset 00h RW RW RW
(1)
TA1TGL TA1TGH TA2TGL TA2TGH TA3TGL TA3TGH TA4TGL TA4TGH
Timer A1 event / trigger select bit
Timer A2 event / trigger select bit
RW RW RW RW RW RW
Timer A3 event / trigger select bit
(1)
Timer A4 event / trigger select bit
(1)
NOTES : 1. Set the port direction bits for the pins TA1IN to TA4IN to 0 (input mode). 2. Overflow or underflow
Figure 15.7
Registers ONSF and TRGSR
REJ09B0392-0064 Rev.0.64 Page 140 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Clock Prescaler Reset Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol CPSRF
Bit Symbol
Address 0015h Bit Name Function
After Reset 0XXXXXXXb RW --
-- (b6-b0) CPSR
No register bits. If necessary, set to 0. Read as undefined value Initializing the clock prescaler. (Read as 0)
Clock prescaler reset flag
RW
Timer A Count Source Select Register 0, Timer A Count Source Select Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TACS0 to TACS1
Bit Symbol
Address 01D0h to 01D1h Bit Name TAi count source select bit
b2 b1 b0
After Reset 00h Function RW
(1)
TCS0 TCS1 TCS2
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : f64TIMAB 0 : Do not set 1 : fOCO-S 0 : f C32 1 : Do not set
RW RW RW
TCS3
TAi count source option specified bit
1 : TCK0, TCK1 enabled, TCS0 to TCS2 disabled 0 : TCK0, TCK1 disabled, TCS0 to TCS2 enabled
b6 b5 b4
RW
TCS4
TCS5
TAj count source select bit
TCS6
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : f64TIMAB 0 : Do not set 1 : fOCO-S 0 : fC32 1 : Do not set
(1)
RW
RW
RW
TCS7
TAj count source option specified bit
1 : TCK0, TCK1 enabled, TCS4 to TCS6 disabled 0 : TCK0, TCK1 disabled, TCS4 to TCS6 enabled
RW
TACS0 register: i = 0, j = 1
TACS1 register: i = 2, j = 3
NOTE : 1. Set this value at the PCLK0 bit in the PCLKR register.
Figure 15.8
Registers CPSRF, TACS0, and TACS1
REJ09B0392-0064 Rev.0.64 Page 141 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer A Count Source Select Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TACS2
Bit Symbol
Address 01D2h Bit Name Function
b2 b1 b0
After Reset X0h RW
(1)
TCS0 TCS1 TCS2
TA4 count source select bit
0 0 0 0 1 1 1 1
0 0 1 1 0 0 1 1
0 1 0 1 0 1 0 1
: : : : : : : :
f1TIMAB or f2TIMAB f8TIMAB f32TIMAB f64TIMAB Do not set fOCO-S fC32 Do not set
RW RW RW
TCS3
TA4 count source option specified bit
1 : TCK0, TCK1 enabled, TCS0 to TCS2 disabled 0 : TCK0, TCK1 disabled, TCS0 to TCS2 enabled
RW
-- (b7-b4)
No register bits. If necessary, set to 0. Read as undefined value.
--
NOTE : 1. Set this value at the PCLK0 bit in the PCLKR register.
Timer A Waveform Output Function Select Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TAPOFS
Bit Symbol
Address 01D5h Bit Name TA0OUT output polar control bit TA1OUT output polar control bit TA2OUT output polar control bit TA3OUT output polar control bit TA4OUT output polar control bit No register bits. If necessary, set to 0. Read as undefined value Function 0 : Output waveform "H" active 1 : Output waveform "H" active (output reversed)
After Reset XXX00000b RW RW RW RW RW RW --
POFS0 POFS1 POFS2 POFS3 POFS4 -- (b7-b5)
Figure 15.9
Registers TACS2 and TAPOFS
REJ09B0392-0064 Rev.0.64 Page 142 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.1.1
Timer Mode
In timer mode, the timer counts a count source generated internally (see Table 15.1). Figure 15.10 shows TAiMR Register in Timer Mode.
Table 15.1 Specifications in Timer Mode
Specification f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 * Decrement * When the timer underflows, it reloads the reload register contents and continues counting 1 / (n+1) n: set value of TAi register 0000h to FFFFh Set the TAiS bit in the TABSR register to 1 (start counting) Set the TAiS bit to 0 (stop counting) Timer underflow I/O port or gate input I/O port or pulse output Count value can be read by reading the TAi register * When not counting Value written to the TAi register is written to both reload register and counter * When counting Value written to the TAi register is written to only reload register (Transferred to counter when reloaded next) * Gate function Counting can be started and stopped by an input signal to the TAiIN pin * Pulse output function Whenever the timer underflows, the output polarity of TAiOUT pin is inverted. When the TAiS bit is set to 0 (stop counting), the pin outputs "L." * Output polarity control While the output polarity of the TAiOUT pin is inverted (the TAiS bit is set to 0 (stop counting)), the pin outputs "H."
Item Count Source Count Operation Divide Ratio Count Start Condition Count Stop Condition Interrupt Request Generation Timing TAiIN Pin Function TAiOUT Pin Function Read from Timer Write to Timer
Select Function
i = 0 to 4
Timer Ai Mode Register (i = 0 to 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TA0MR to TA4MR
Bit Symbol
Address 0336h to 033Ah Function
After Reset 00h RW RW RW
0
00
Bit Name
TMOD0 Operation mode select bit TMOD1
b1 b0
0
0 : Timer mode
MR0
Pulse output function select bit
0 : No pulse output (TAiOUT pin functions as I/O port) 1 : Pulse output (1) (TAiOUT pin functions as a pulse output pin)
b4 b3
RW
MR1 Gate function select bit MR2 MR3 TCK0 Count source select bit (4) TCK1 Set to 0 in timer mode
0 0 1 1
0: Gate function not available 1: (TAiIN pin functions as I/O port) 0 : Counts while input on the TAiIN pin is low (2) 1 : Counts while input on the TAiIN pin is high (2)
RW RW RW
b1 b0
0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
(3)
RW
NOTES : 1. The TA0OUT pin is N-channel open drain output. 2. Set the port direction bit for the TAiIN pin to 0 (input mode). 3. Selected by the PCLK0 bit in the PCLKR register. 4. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Figure 15.10 TAiMR Register in Timer Mode
REJ09B0392-0064 Rev.0.64 Page 143 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.1.2
Event Counter Mode
In event counter mode, the timer counts pulses from an external device or overflows and underflows of other timers. Timers A2, A3, and A4 can count two-phase external signals. Table 15.2 lists Specifications in Event Counter Mode (When Not Processing Two-Phase Pulse Signal). Figure 15.11 shows the TAiMR Register in Event Counter Mode (when not using two-phase pulse signal processing).
Table 15.2 Specifications in Event Counter Mode (When Not Processing Two-Phase Pulse Signal)
Item Count Source
Specification * External signals input to the TAiIN pin (effective edge can be selected in a program) * Timer B2 overflows or underflows, Timer Aj (j = i - 1, except j = 4 if i = 0) overflows or underflows, Timer Ak (k = i + 1, except k=0 if i = 4) overflows or underflows Count Operation * Increment or decrement can be selected by program. * When the timer overflows or underflows, it reloads the reload register contents and continues counting. When operating in free-running mode, the timer continues counting without reloading. Divide Ratio * 1/ (FFFFh - n + 1) for increment * 1/ (n + 1) for decrement n: set value of the TAi register 0000h to FFFFh Count Start Condition Set the TAiS bit in the TABSR register to 1 (start counting) Count Stop Condition Set the TAiS bit to 0 (stop counting) Interrupt Request Genera- Timer overflow or underflow tion Timing TAiIN Pin Function I/O port or count source input TAiOUT Pin Function I/O port, pulse output Read from Timer Count value can be read by reading the TAi register Write to Timer * When not counting Value written to the TAi register is written to both reload register and counter * When counting Value written to the TAi register is written to only reload register (Transferred to counter when reloaded next) Select Function * Free-run count function Even when the timer overflows or underflows, the reload register content is not reloaded to it * Pulse output function Whenever the timer underflows or underflows, the output polarity of the TAiOUT pin is inverted. When the TAiS bit is set to 0 (stop counting), the pin outputs low. * Output polarity control While the output polarity of the TAiOUT pin is inverted (the TAiS bit is set to 0 (stop counting)), the pin outputs high. i = 0 to 4
REJ09B0392-0064 Rev.0.64 Page 144 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Ai Mode Register (i = 0 to 4) (When Not Using Two-Phase Pulse Signal Processing)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TA0MR to TA4MR
Bit Symbol
Address 0336h to 033Ah Function
b1 b0
After Reset 00h RW RW RW
00
01
Bit Name
TMOD0 TMOD1 Pulse output function select bit
Operation mode select bit 0
1 : Event counter mode (1)
MR0
0 : Pulse is not output (TAiOUT pin functions as I/O port) 1 : Pulse is output (3) (TAiOUT pin functions as pulse output pin) 0 : Counts falling edge of external signal 1 : Counts rising edge of external signal
RW
MR1 MR2 MR3 TCK0 TCK1
Count polarity select bit (2)
RW RW RW RW RW
Write 0 in event counter mode Write 0 in event counter mode Count operation type select bit 0 : Reload type 1 : Free-run type
Can be 0 or 1 when not using two-phase pulse signal processing
NOTES : 1. During event counter mode, the count source can be selected using registers ONSF and TRGSR. 2. Valid when bits TAiTGH and TAiTGL in the ONSF or TRGSR register are 00b (TAiIN pin input). 3. The TA0OUT pin is N-channel open drain output.
Figure 15.11 TAiMR Register in Event Counter Mode (when not using two-phase pulse signal processing)
REJ09B0392-0064 Rev.0.64 Page 145 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Table 15.3 lists Specifications in Event Counter Mode (when processing two-phase pulse signal with Timers A2, A3, and A4). Figure 15.12 shows Registers TA2MR to TA4MR in Event Counter Mode (when using two-phase pulse signal processing with Timers A2, A3, and A4).
Table 15.3
Item Count Source Count Operation
Specifications in Event Counter Mode (when processing two-phase pulse signal with Timers A2, A3, and A4)
Specification
Two-phase pulse signals input to TAiIN or TAiOUT pin * Increment or decrement can be selected by two-phase pulse signal * When the timer overflows or underflows, it reloads the reload register contents and continues counting. When operating in free-running mode, the timer continues counting without reloading. Divide Ratio * 1/ (FFFFh - n + 1) for increment * 1/ (n + 1) for decrement n: set value of the TAi register 0000h to FFFFh Count Start Condition Set the TAiS bit in the TABSR register to 1 (start counting) Count Stop Condition Set the TAiS bit to 0 (stop counting) Interrupt Request Generation Timing Timer overflow or underflow TAiIN Pin Function Two-phase pulse input TAiOUT Pin Function Two-phase pulse input Read from Timer Count value can be read by reading Timer A2, A3, or A4 register Write to Timer When not counting Value written to the TAi register is written to both reload register and counter When counting Value written to the TAi register is written to only reload register (Transferred to counter when reloaded next) Select Function (1) Normal processing operation (Timer A2 and Timer A3) The timer increments rising edges or decrements falling edges on the TAjIN pin when input signals on the TAjOUT pin is "H".
TAjOUT TAjIN
Increment Increment Increment Decrement Decrement Decrement
Multiply-by-4 processing operation (Timer A3 and Timer A4) If the phase relationship is such that TAkIN pin goes "H" when the input signal on the TAkOUT pin is "H," the timer increments rising and falling edges on pins TAkOUT and TAkIN. If the phase relationship is such that the TAkIN pin goes "L" when the input signal on the TAkOUT pin is "H," the timer counts down rising and falling edges on pins TAkOUT and TAkIN.
TAkOUT Increment all edges TAkIN Increment all edges Decrement all edges Decrement all edges
Counter initialization by Z-phase input (Timer A3) The timer count value is initialized to 0 by Z-phase input.
i = 2 to 4, j = 2, 3, k = 3, 4 NOTE: 1. Only Timer A3 is selectable. Timer A2 is fixed to normal processing operation, and Timer A4 is fixed to multiply-by-4 processing operation. REJ09B0392-0064 Rev.0.64 Page 146 of 373 Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Ai Mode Register (i = 2 to 4) (When Using Two-Phase Pulse Signal Processing)
b7 b6 b5 b4 b3 b2 b1 b0
010001
Symbol TA2MR to TA4MR
Bit Symbol
Address 0338h to 033Ah Bit Name
b1 b0
After Reset 00h Function RW RW RW RW RW RW RW RW RW
TMOD0 Operation mode select bit TMOD1 MR0 MR1 MR2 MR3 TCK0 TCK1
0
1 : Event counter mode
Set to 0 to use two-phase pulse signal processing Set to 0 to use two-phase pulse signal processing Set to 1 to use two-phase pulse signal processing Set to 0 to use two-phase pulse signal processing Count operation type select bit Two-phase pulse signal processing operation type select bit (1, 2) 0 : Reload type 1 : Free-run type 0 : Normal processing operation 1 : Multiply-by-4 processing operation
NOTES : 1. The TCK1 bit can be set only for Timer A3 mode register. No matter how this bit is set, Timers A2 and A4 always operate in normal processing mode and x4 processing mode, respectively. 2. To use two-phase pulse signal processing, following the register setting below: * Set the TAiP bit in the UDF register to 1 (two-phase pulse signal processing function enabled). * Set bits TAiTGH and TAiTGL in the TRGSR register to 00b (TAiIN pin input). * Set the port direction bits for TAiIN and TAiOUT to 0 (input mode).
Figure 15.12 Registers TA2MR to TA4MR in Event Counter Mode (when using two-phase pulse signal processing with Timers A2, A3, and A4)
REJ09B0392-0064 Rev.0.64 Page 147 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.1.2.1
Counter Initialization by Two-Phase Pulse Signal Processing
This function initializes the timer count value to 0 by Z-phase (counter initialization) input during twophase pulse signal processing. This function can only be used in Timer A3 event counter mode during two-phase pulse signal processing, free-running type, multiply-by-4 processing, with Z phase entered from the ZP pin. Counter initialization by Z-phase input is enabled by writing 0000h to the TA3 register and setting the TAZIE bit in the ONSF register to 1 (Z-phase input enabled). Counter initialization is accomplished by detecting Z-phase input edge. The active edge can be chosen to be the rising or falling edge by using the POL bit in the INT2IC register. The Z-phase pulse width applied to the ZP pin must be equal to or greater than one clock cycle of Timer A3 count source. The counter is initialized at the next count timing after recognizing Z-phase input. Figure 15.13 shows the Relationship between the Two-Phase Pulse (A Phase and B Phase) and the Z Phase. If Timer A3 overflow or underflow coincides with the counter initialization by Z phase input, a Timer A3 interrupt request is generated twice in succession. Do not use Timer A3 interrupt when using this function.
TA3OUT (A phase) TA3IN (B phase) Count source ZP (1) Input equal to or greater than one clock cycle of count source Timer A3 m m+1 1 2 3 4 5
NOTE : 1. This timing diagram is for the case where the POL bit in the INT2IC register = 1 (rising edge).
Figure 15.13 Relationship between the Two-Phase Pulse (A Phase and B Phase) and the Z Phase
REJ09B0392-0064 Rev.0.64 Page 148 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.1.3
One-Shot Timer Mode
In one-shot timer mode, the timer is activated only once by one trigger (see Table 15.4). When the trigger occurs, the timer starts up and continues operating for a given period. Figure 15.14 shows the TAiMR Register in One-Shot Timer Mode.
Table 15.4 Specifications in One-shot Timer Mode
Item Count Source Count Operation
Divide Ratio Count Start Condition
Count Stop Condition Interrupt Request Generation Timing TAiIN Pin Function TAiOUT Pin Function Read from Timer Write to Timer
Specification f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 * Decrement * When the counter reaches 0000h, it stops counting after reloading a new value. * If a trigger occurs when counting, the timer reloads a new count and restarts counting. 1/n n: set value of the TAi register 0000h to FFFFh However, the counter does not work if the divide-by-n value is set to 0000h. The TAiS bit in the TABSR register = 1 (start counting) and one of the following triggers occurs. * External trigger input from the TAiIN pin * Timer B2 overflow or underflow, Timer Aj (j = i - 1, except j = 4 if i = 0) overflow or underflow, Timer Ak (k = i + 1, except k = 0 if i = 4) overflow or underflow * The TAiOS bit in the ONSF register is set to 1 (timer starts) * When the counter is reloaded after reaching 0000h * The TAiS bit is set to 0 (stop counting) When the counter reaches 0000h I/O port or trigger input I/O port or pulse output An indeterminate value is read by reading the TAi register * When not counting and until the 1st count source is input after counting starts Value written to the TAi register is written to both reload register and counter * When counting (after 1st count source input) Value written to the TAi register is written to only reload register (Transferred to counter when reloaded next) * Pulse output function The timer outputs low when not counting and high when counting. * Output polarity control While the output polarity of TAiOUT pin is inverted (the TAiS bit is set to 0 (stop counting)), the pin outputs high.
Select Function
i = 0 to 4
REJ09B0392-0064 Rev.0.64 Page 149 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Ai Mode Register (i = 0 to 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TA0MR to TA4MR
Bit Symbol
Address 0336h to 033Ah Function
After Reset 00h RW RW RW
0
10
Bit Name
TMOD0 TMOD1
Operation mode select bit b1 b0 1 0 : One-shot timer mode
MR0
Pulse output function select bit
0 : No pulse output (TAiOUT pin functions as I/O port) 1 : Pulse output (1) (TAiOUT pin functions as a pulse output pin) 0 : Falling edge of input signal to TAiIN pin (3) 1 : Rising edge of input signal to TAiIN pin (3) 0 : TAiOS bit enabled 1 : Selected by bits TAiTGH and TAiTGL
RW
MR1 MR2 MR3 TCK0
External trigger select bit (2) Trigger select bit
RW RW RW
Set to 0 in one-shot timer mode
b7 b6
Count source select bit (5) TCK1
0 0 1 1
0 : f1TIMAB or f2TIMAB (4) 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
RW
NOTES : 1. The TA0OUT pin is N-channel open drain output. 2. Valid when bits TAiTGH and TAiTGL in the ONSF register or TRGSR register are set to 00b (TAiIN pin input). 3. Set the port direction bit for the TAiIN pin to 0 (input mode). 4. Selected by the PCLK0 bit in the PCLKR register. 5. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Figure 15.14 TAiMR Register in One-Shot Timer Mode
REJ09B0392-0064 Rev.0.64 Page 150 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.1.4
Pulse Width Modulation (PWM) Mode
In PWM mode, the timer outputs pulses of a given width in succession (see Table 15.5). The counter functions as either 16-bit pulse width modulator or 8-bit pulse width modulator. Figure 15.15 shows TAiMR Register in PWM Mode. Figures 15.16 and 15.17 show an Example of 16-Bit Pulse Width Modulator Operation and 8-bit Pulse Width Modulator Operation, respectively.
Table 15.5 Specifications in PWM Mode
Item Count Source Count Operation
16-bit PWM
Specification f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 * Decrement (operating as an 8-bit or a 16-bit pulse width modulator) * The timer reloads a new value at a rising edge of PWM pulse and continues counting. * The timer is not affected by a trigger that occurs during counting. * Pulse width n / fj n: set value of the TAi register 16 - 1) / fj fixed fj: count source frequency (1TIMAB, f2TIMAB, * Cycle time (2
f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32)
8-bit PWM
Count Start Condition
Count Stop Condition Interrupt Request Generation Timing TAiIN Pin Function TAiOUT Pin Function Read from Timer Write to Timer
* Pulse width n x (m+1) / fj n: set value of the TAi register high-order address m: set value of the TAi register low-order * Cycle time (28-1) x (m+1) / fj address * The TAiS bit of the TABSR register is set to 1 (start counting) * The TAiS bit = 1 and external trigger input from the TAiIN pin * The TAiS bit = 1 and one of the following external triggers occurs Timer B2 overflow or underflow, Timer Aj (j = i - 1, except j = 4 if i = 0) overflow or underflow, Timer Ak (k = i + 1, except k = 0 if i = 4) overflow or underflow The TAiS bit is set to 0 (stop counting) On the falling edge of PWM pulse I/O port or trigger input Pulse output An indeterminate value is read by reading the TAi register * When not counting Value written to the TAi register is written to both reload register and counter * When counting Value written to the TAi register is written to only reload register (Transferred to counter when reloaded next) * Output polarity control While the output polarity of TAiOUT pin is inverted (the TAiS bit is set to 0 (stop counting)), the pin outputs high.
Select Function
i = 0 to 4
REJ09B0392-0064 Rev.0.64 Page 151 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Ai Mode Register (i = 0 to 4)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TA0MR to TA4MR
Bit Symbol
Address 0336h to 033Ah Function
After Reset 00h RW RW RW
11
Bit Name
TMOD0 TMOD1
Operation mode select bit b1 b0 1 1 : PWM mode
MR0
Pulse output function select bit (4)
0 : No pulse output (TAiOUT pin functions as I/O port) 1 : Pulse output (1) (TAiOUT pin functions as a pulse output pin) 0 : Falling edge of input signal to TAiIN pin (3) 1 : Rising edge of input signal to TAiIN pin (3) 0 : Write 1 to the TAiS bit in the TABSR register 1 : Selected by bits TAiTGH and TAiTGL
RW
MR1 MR2 MR3 TCK0
External trigger select bit (2) Trigger select bit
RW RW RW
16 / 8-bit PWM mode select 0 : Functions as a 16-bit pulse width modulator bit 1 : Functions as an 8-bit pulse width modulator
b7 b6
Count source select bit (6) TCK1
0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
(5)
RW
NOTES : 1. The TA0OUT pin is N-channel open drain output. 2. Valid when bits TAiTGH and TAiTGL bit in the ONSF register or TRGSR register are set to 00b (TAiIN pin input). 3. Set the port direction bit for the TAiIN pin to 0 (input mode). 4. Set this bit to 1 (pulse output) to output PWM pulse. 5. Selected by the PCLK0 bit in the PCLKR register. 6. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Figure 15.15 TAiMR Register in PWM Mode
REJ09B0392-0064 Rev.0.64 Page 152 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
1 / fj x (216 - 1)
Count source
Input signal to TAiIN pin "H" "L" PWM pulse output from TAiOUT pin When TOFSi = 0 "H" (waveform output = "H" active, not inverted) "L" When TOFSi = 1 (waveform output = "L" active, inverted) "H" "L" "1" "0" Trigger is not generated by this signal.
1 / fj x n
IR bit in TAiIC register
fj: count source frequency (f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32)
i = 0 to 4 TOFSi: bit in the TAPOFS register
Set to 0 upon accepting an interrupt request or by writing in program.
NOTES : 1. n = 0000h to FFFEh 2. This timing diagram is for the case where the TAi register is 0003h, bits TAiTGH and TAiTGL in the ONSF register or TRGSR register are 00b (input to the TAiIN pin), the MR1 bit in the TAiMR register is 1 (rising edge), and the MR2 bit in the TAiMR register is 1 (trigger selected by bits TAiTGH and TAiTGL).
Figure 15.16 Example of 16-Bit Pulse Width Modulator Operation
1 / fj x (m + 1) x (28 - 1) Count source (1)
Input signal to TAiIN pin
"H" "L"
1 / fj x (m+1)
8-bit prescaler underflow signal (2) "H" "L"
PWM pulse output from TAiOUT pin When TOFSi = 0 "H" (waveform output = "H" H"ctive, not inverted) "L"
1 / fj x (m + 1) x n
"H" When TOFSi = 1 (waveform output = "L" "L" active, inverted) IR bit in TAiIC register "1" "0"
i = 0 to 4 TOFSi: bit in TAPOFS register
fj: count source frequency (f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32)
Set to 0 upon accepting an interrupt request or by writing in program.
NOTES : 1. The 8-bit prescaler counts the count source. 2. The 8-bit pulse width modulator counts underflow signals of the 8-bit prescaler. 3. m = 00h to FFh, n=00h to FEh 4. This timing diagram is for the case where the TAi register is 0202h, bits TAiTGH and TAiTGL in the ONSF register or TRGSR register are 00b (input to the TAiIN pin), the MR1 bit in the TAiMR register is 0 (falling edge), and the MR2 bit in the TAiMR register is 1 (trigger selected by bits TAiTGH and TAiTGL).
Figure 15.17 Example of 8-Bit Pulse Width Modulator Operation
REJ09B0392-0064 Rev.0.64 Page 153 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.2
Timer B
Figure 15.18 shows Timer B Block Diagram. Figures 15.19 to 15.21 show registers related to Timer B. Timer B supports the following three modes. Use bits TMOD1 and TMOD0 in the TBiMR register (i = 0 to 5) to select the desired mode. * Timer Mode : The timer counts an internal count source. * Event Counter Mode : The timer counts pulses from an external device or overflows or underflows of other timers. * Pulse Period, Pulse Width Measurement Mode: The timer measures pulse period or pulse width of an external signal.
Data Bus
f1TIMAB or f2TIMAB f8TIMAB f32TIMAB fC32 f1TIMAB or f2TIMAB f8TIMAB f32TIMAB f64TIMAB fOCO-S fC32
Select Clock Source
00 01 10 11 TCS2 to TCS0 or TCS6 to TCS4 1 1
TCK1 to TCK0
0
TCS3 or TCS7
00: Timer 10: Pulse Period and Pulse Width Measurement
TMOD1 to TMOD0
Reload Register
TCK1
000 001 010 011 101 110
TBj Overflow (1)
01: Event Counter
Counter
0
TBiIN
Polarity Switching and Edge Pulse
TBiS
Counter Reset Circuit
NOTE : 1. Overflows or underflows. TCK1 to TCK0, TMOD1 to TMOD0 : bits in the TBiMR register TBiS : bits in the TABSR register or TBSR register TCS0 to TCS7 : bits in registers TBCS0 to TBCS3
i = 0 to 5 j = i - 1; however, j = 2 when i = 0, j = 5 when i = 3 TBi Timer B0 Timer B1 Timer B2 Timer B3 Timer B4 Timer B5 TBj Timer B2 Timer B0 Timer B1 Timer B5 Timer B3 Timer B4
Figure 15.18 Timer B Block Diagram
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Bi Mode Register (i = 0 to 5)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TB0MR to TB2MR TB3MR to TB5MR
Bit Symbol
Address 033Bh to 033Dh 031Bh to 031Dh Bit Name Function
b1 b0
After Reset 00XX0000b 00XX0000b RW RW
TMOD0
Operation mode select bit
0 0 1 1
TMOD1 MR0 MR1 -- (b4) MR3 TCK0 TCK1
0 : Timer mode 1 : Event counter mode 0 : Pulse period measurement mode Pulse width measurement mode 1 : Do not set
RW RW RW -- RO RW RW
Function varies with each operation mode
No register bit. If necessary, set to 0. Read as undefined value Function varies with each operation mode Count source select bit (1) (Function varies with each operation mode)
NOTE : 1. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Timer Bi Register (i = 0 to 5) (1)
(b15) b7 (b8) b0 b7 b0
Symbol TB0 TB1 TB2 TB3 TB4 TB5 Mode Timer mode Event counter mode Pulse period measurement mode Pulse width measurement mode
Address 0331h to 0330h 0333h to 0332h 0335h to 0334h 0311h to 0310h 0313h to 0312h 0315h to 0314h Function Divide the count source by n + 1 where n = set value Divide the count source by n + 1 where n = set value (2)
After Reset Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate Setting Range 0000h to FFFFh 0000h to FFFFh RW RW RW
Measures a pulse period or width
0000h to FFFFh (3)
RW (4)
NOTES : 1. Access to the register in 16-bit units. 2. The timer counts pulses from an external device or overflows or underflows of other timers. 3. Set it when the TBiS bit in the TABSR or TBSR register is set to 0 (count stops). 4. Read only (RO) when the TBiS bit in the TABSR or TBSR register is set to 1 (count starts).
Figure 15.19 Register TB0MR to TB5MR and TB0 to TB5
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Count Start Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TABSR
Bit Symbol
Address 0320h Bit Name Timer A0 count start flag Timer A1 count start flag Timer A2 count start flag Timer A3 count start flag Timer A4 count start flag Timer B0 count start flag Timer B1 count start flag Timer B2 count start flag 0 : Stop counting 1 : Start counting Function
After Reset 00h RW RW RW RW RW RW RW RW RW
TA0S TA1S TA2S TA3S TA4S TB0S TB1S TB2S
Timer B3, B4, B5 Count Start Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TBSR
Bit Symbol
Address 0300h Bit Name Function
After Reset 000XXXXXb RW -- RW RW RW
-- POFS0 (b4-b0) TB3S TB4S TB5S
No register bits. If necessary, set to 0. Read as undefined value 0 : Stop counting 1 : Start counting
Timer B3 count start flag Timer B4 count start flag Timer B5 count start flag
Clock Prescaler Reset Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol CPSRF
Bit Symbol
Address 0015h Bit Name Function
After Reset 0XXXXXXXb RW --
-- (b6-b0) CPSR
No register bits. If necessary, set to 0. Read as undefined value Initializing the clock prescaler. (Read as 0)
Clock prescaler reset flag
RW
Figure 15.20 Register TABSR, TBSR, and CPSRF
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer B Count Source Select Register 0, Timer B Count Source Select Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TBCS0 TBCS2
Bit Symbol
Address 01C8h 01E8h Bit Name Function
b2 b1 b0
After Reset 00h 00h RW RW RW
TCS0 TCS1
TBi count source select bit
TCS2
TCS3
TBi count source option specified bit TBj count source select bit
0 0 0 : f1TIMAB or f2TIMAB (1) 0 0 1 : f8TIMAB 0 1 0 : f32TIMAB 0 1 1 : f64TIMAB 1 0 0 : Do not set 1 0 1 : fOCO-S 1 1 0 : f C32 1 1 1 : Do not set 1 : TCK0, TCK1 enabled, TCS0 to TCS2 disabled 0 : TCK0, TCK1 disabled, TCS0 to TCS2 enabled
b6 b5 b4
RW
RW
TCS4
TCS5 TCS6 TBj count source option specified bit
TCS7
0 0 0 : f1TIMAB or f2TIMAB (1) 0 0 1 : f8TIMAB 0 1 0 : f32TIMAB 0 1 1 : f64TIMAB 1 0 0 : Do not set 1 0 1 : fOCO-S 1 1 0 : f C32 1 1 1 : Do not set 1 : TCK0, TCK1 enabled, TCS4 to TCS6 disabled 0 : TCK0, TCK1 disabled, TCS4 to TCS6 enabled
RW
RW RW
RW
TBCS0 register: i = 0, j = 1
TBCS2 register: i = 3, j = 4
NOTE : 1. Set this value at the PCLK0 bit in the PCLKR register.
Timer B Count Source Select Register 1, Timer B Count Source Select Register 3
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TBCS1 TBCS3
Bit Symbol
Address 01C9h 01E9h Bit Name Function
b2 b1 b0
After Reset X0h X0h RW RW RW RW
TCS0 TCS1 TCS2
TBi count source select bit
TCS3
TBi count source option specified bit
0 0 0 : f1TIMAB or f2TIMAB (1) 0 0 1 : f8TIMAB 0 1 0 : f32TIMAB 0 1 1 : f64TIMAB 1 0 0 : Do not set 1 0 1 : fOCO-S 1 1 0 : fC32 1 1 1 : Do not set 1 : TCK0, TCK1 enabled, TCS0 to TCS2 disabled 0 : TCK0, TCK1 disabled, TCS0 to TCS2 enabled
RW
-- (b7-b4) TBCS1 register: i = 2
No register bits. If necessary, set to 0. Read as undefined value
--
TBCS3 register: i = 5
NOTE : 1. Set this value at the PCLK0 bit in the PCLKR register.
Figure 15.21 Registers TBCS0, TBCS1, TBCS2, and TBCS3
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Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.2.1
Timer Mode
In timer mode, the timer counts a count source generated internally (see Table 15.6). Figure 15.22 shows the TBiMR Register in Timer Mode.
Table 15.6 Specifications in Timer Mode
Item Count Source Count Operation
Divide Ratio Count Start Condition Count Stop Condition Interrupt Request Generation Timing TBiIN Pin Function Read from Timer Write to Timer
Specification f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 * Decrement * When the timer underflows, it reloads the reload register contents and continues counting 1 / (n + 1) n: set value of the TBi register 0000h to FFFFh Set the TBiS bit (1) to 1 (start counting) Set the TBiS bit to 0 (stop counting) Timer underflow I/O port Count value can be read by reading the TBi register * When not counting Value written to the TBi register is written to both reload register and counter * When counting Value written to the TBi register is written to only reload register (Transferred to counter when reloaded next)
i = 0 to 5 NOTE: 1. Bits TB0S to TB2S are assigned to bits 5 to 7 in the TABSR register, and bits TB3S to TB5S are assigned to bits 5 to 7 in the TBSR register.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Bi Mode Register (i = 0 to 5)
b7 b6 b5 b4 b3 b2 b1 b0
0000
Symbol TB0MR to TB2MR TB3MR to TB5MR
Bit Symbol
Address 033Bh to 033Dh 031Bh to 031Dh Function
After Reset 00XX0000b 00XX0000b RW RW RW RW
Bit Name
TMOD0 Operation mode select bit TMOD1 MR0 Set to 0 in timer mode MR1 -- MR3 TCK0 Count source select bit TCK1
(2)
b1 b0
0
0 : Timer mode
RW No register bit. If necessary, set to 0. Read as undefined value Write 0 in timer mode. Read as undefined value in timer mode
b7 b6
-- RO RW RW
0 0 1 1
0 : f1TIMAB or f2TIMAB (1) 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
NOTES : 1. Selected by the PCLK0 bit in the PCLKR register. 2. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS2 is set to 0 (TCK0, TCK1 enabled).
Figure 15.22 TBiMR Register in Timer Mode
REJ09B0392-0064 Rev.0.64 Page 159 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.2.2
Event Counter Mode
In event counter mode, the timer counts pulses from an external device or overflows and underflows of other timers (see Table 15.7). Figure 15.23 shows the TBiMR Register in Event Counter Mode.
Table 15.7 Specifications in Event Counter Mode
Item Count Source
Count Operation
Divide Ratio Count Start Condition Count Stop Condition Interrupt Request Generation Timing TBiIN Pin Function Read from Timer Write to Timer
Specification * External signals input to TBiIN pin (effective edge rising edge, falling edge, or both rising and falling edges) can be selected in a program) * Timer Bj overflow or underflow (j = i - 1, except j = 2 if i = 0, j = 5 if i = 3) * Decrement * When the timer underflows, it reloads the reload register contents and continues counting. 1 / (n + 1) n: set value of the TBi register 0000h to FFFFh Set the TBiS bit (1) to 1 (start counting) Set the TBiS bit to 0 (stop counting) Timer underflow Count source input Count value can be read by reading the TBi register. * When not counting Value written to the TBi register is written to both reload register and counter * When counting Value written to the TBi register is written to only reload register (Transferred to counter when reloaded next)
i = 0 to 5 NOTE: 1. Bits TB0S to TB2S are assigned to bits 5 to 7 in the TABSR register, and bits TB3S to TB5S are assigned to bits 5 to 7 in the TBSR register.
REJ09B0392-0064 Rev.0.64 Page 160 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Bi Mode Register (i = 0 to 5)
b7 b6 b5 b4 b3 b2 b1 b0
01
Symbol TB0MR to TB2MR TB3MR to TB5MR
Bit Symbol
Address 033Bh to 033Dh 031Bh to 031Dh Function
b1 b0
After Reset 00XX0000b 00XX0000b RW RW RW
Bit Name
TMOD0 TMOD1
Operation mode select bit 0
1 : Event counter mode
b3 b2
MR0 Count polarity select bit MR1
(1)
0 0 1 1
0 : Counts falling edges of external signal 1 : Counts rising edges of external signal 0 : Counts falling and rising edges external signal 1 : Do not set to this value
RW
RW
-- MR3 TCK0
No register bit. If necessary, set to 0. Read as undefined value Write 0 in event counter mode. Read as undefined value in event counter mode Invalid in event counter mode. Set 0 or 1 Event clock select 0 : Input from TBiIN pin (2) 1 : TBj overflow or underflow (j = i - 1; however, j = 2 if i = 0, j = 5 if i = 3)
-- RO RW
TCK1
RW
NOTES : 1. Valid when the TCK1 bit = 0 (input from TBiIN pin). If the TCK1 bit = 1 (TBj overflow or underflow), these bits can be set to 0 or 1. 2. Set the port direction bit for the TBiIN pin to 0 (input mode).
Figure 15.23 TBiMR Register in Event Counter Mode
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
15.2.3
Pulse Period and Pulse Width Measurement Modes
In pulse period and pulse width measurement mode, the timer measures pulse period or pulse width of an external signal (see Table 15.8). Figure 15.24 shows the TBiMR Register in Pulse Period and Pulse Width Measurement Mode. Figure 15.25 shows the Operation Timing when Measuring a Pulse Period. Figure 15.26 shows the Operation Timing when Measuring a Pulse Width.
Table 15.8 Specifications in Pulse Period and Pulse Width Measurement Mode
Item Count Source Count Operation Count Start Condition Count Stop Condition Interrupt Request Generation Timing TBiIN Pin Function Read from Timer Write to Timer
Specification f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 * Increment * Counter value is transferred to reload register at an effective edge of measurement pulse. The counter value is set to 0000h to continue counting. Set the TBiS bit (3) to 1 (start counting) Set the TBiS bit to 0 (stop counting) * When an effective edge of measurement pulse is input (1) Timer overflow. When an overflow occurs, the MR3 bit in the TBiMR register is set to 1 (overflowed) simultaneously. Measurement pulse input Contents of the reload register (measurement result) can be read by reading the TBi register (2) Value written to the TBi register is written to neither reload register nor counter
i = 0 to 5 NOTES: 1. Interrupt request is not generated when the first effective edge is input after the timer started counting. 2. Value read from the TBi register is indeterminate until the second valid edge is input after the timer starts counting. 3. Bits TB0S to TB2S are assigned to bits 5 to 7 in the TABSR register, and bits TB3S to TB5S are assigned to bits 5 to 7 in the TBSR register.
REJ09B0392-0064 Rev.0.64 Page 162 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Timer Bi Mode Register (i = 0 to 5)
b7 b6 b5 b4 b3 b2 b1 b0
10
Symbol TB0MR to TB2MR TB3MR to TB5MR
Bit Symbol
Address 033Bh to 033Dh 031Bh to 031Dh Function
b1 b0
After Reset 00XX0000b 00XX0000b RW RW RW
Bit Name
TMOD0 TMOD1
Operation mode select bit 1
0 : Pulse period, pulse width measurement mode 0 : Pulse period measurement (Measurement between a falling edge and the next falling edge of measured pulse) 1 : Pulse period measurement (Measurement between a rising edge and the next rising edge of measured pulse) 0 : Pulse width measurement (Measurement between a falling edge and the next rising edge of measured pulse and between a rising edge and the next falling edge) 1 : Do not set to this value
b3 b2
0 MR0 0 Measurement mode select bit MR1 1 -- MR3 TCK0 Count source select bit TCK1
(3)
RW
1
RW
No register bit. If necessary, set to 0. Read as undefined value Timer Bi overflow flag (1) 0 : No overflow 1 : Overflow
b7 b6
-- RO RW RW
0 0 1 1
0 : f1TIMAB or f2TIMAB (2) 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
NOTES : 1. This flag is indeterminate after reset. When the TBiS bit in the TABSR register or TBSR register is set to 1 (start counting), the MR3 bit is cleared to 0 (no overflow) by writing to the TBiMR register. The MR3 bit cannot be set to 1 in a program. 2. Selected by the PCLK0 bit in the PCLKR register. 3. Valid when the TCS3 bit or TCS7 bit in registers TACS0 to TACS3 is set to 0 (TCK0, TCK1 enabled).
Figure 15.24 TBiMR Register in Pulse Period and Pulse Width Measurement Mode
REJ09B0392-0064 Rev.0.64 Page 163 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
15. Timers
Count source
Measurement pulse
"H" "L" Transfer (indeterminate value) Transfer (measured value)
Reload register transfer timing
counter
(NOTE 1) (NOTE 1) (NOTE 2)
Timing at which counter reaches 0000h TBiS bit
"1" "0" "1" "0"
IR bit in TBiIC register
Set to 0 upon accepting an interrupt request or by writing in program MR3 bit in TBiMR register
"1" "0"
Bits TB0S to TB2S are assigned to bits 5 to 7 in the TABSR register, and bits TB3S to TB5S are assigned to bits 5 to 7 in the TABSR register. i = 0 to 5 NOTES : 1. Counter is initialized at completion of measurement. 2. Timer has overflowed. 3. This timing diagram is for the case where bits MR1 and MR0 in the TBiMR register are 00b (measure the interval from falling edge to falling edge of the measurement pulse).
Figure 15.25 Operation Timing when Measuring a Pulse Period
Count source
Measurement pulse
"H" "L"
Transfer (indeterminate value) Transfer (measured value) Transfer (measured value) Transfer (measured value)
Reload register transfer timing
counter
(NOTE 1)
(NOTE 1)
(NOTE 1)
(NOTE 1)
(NOTE 2)
Timing at which counter reaches 0000h
"1" "0"
TBiS bit
IR bit in TBiIC register
"1" "0" "1" "0"
MR3 bit in TBiMR register
Set to 0 upon accepting an interrupt request or by writing in program
Bits TB0S to TB2S are assigned to bits 5 to 7 in the TABSR register, and bits TB3S to TB5S are assigned to bits 5 to 7 in the TABSR register. i = 0 to 5 NOTES : 1. Counter is initialized at completion of measurement. 2. Timer has overflowed. 3. This timing diagram is for the case where bits MR1 and MR0 in the TBiMR register are 10b (measure the interval from a falling edge to the next rising edge and the interval from a rising edge to the next falling edge of the measurement pulse).
Figure 15.26 Operation Timing when Measuring a Pulse Width
REJ09B0392-0064 Rev.0.64 Page 164 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
16. Three-Phase Motor Control Timer Function
Timers A1, A2, A4, and B2 can be used to output three-phase motor drive waveforms. Table 16.1 lists the Three-phase Motor Control Timer Functions Specifications. Figure 16.1 shows the Three-phase Motor Control Timer Functions Block Diagram. Also, the related registers are shown on Figures 16.2 to 16.7.
Table 16.1 Three-phase Motor Control Timer Functions Specifications
Input "L" to the SD pin Timer A4, A1, A2 (used in one-shot timer mode) Timer A4: U- and U-phase waveform control Timer A1: V- and V-phase waveform control Timer A2: W- and W-phase waveform control Timer B2 (used in timer mode) Carrier wave cycle control Dead time timer (3 eight-bit timers and shared reload register) Dead time control Output Waveform Triangular wave modulation, sawtooth wave modulation * Enable to output "H" or "L" for one cycle * Enable to set positive-phase level and negative-phase level independently Triangular wave modulation : count source x (m + 1) x 2 Carrier Wave Cycle Sawtooth wave modulation : count source x (m + 1) m: setting value of the TB2 register, 0000h to FFFFh Count source: f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 Three-Phase PWM Output Triangular wave modulation: count source x n x 2 Width Sawtooth wave modulation: count source x n n: setting value of registers TA4, TA1, and TA2 (of registers TA4, TA41, TA1, TA11, TA2, and TA21 when setting the INV11 bit to 1), 0001h to FFFFh Count source: f1TIMAB, f2TIMAB, f8TIMAB, f32TIMAB, f64TIMAB, fOCO-S, fC32 Dead Time Count source x p, or no dead time p: setting value of the DTT register, 01h to FFh Count source: f1TIMAB, f2TIMAB, f1TIMAB divided by 2, f2TIMAB divided by 2 Active Level Enable to select "H" or "L" Positive and NegativePositive-and negative-phases concurrent active disable function Phase Concurrent Active Positive-and negative-phases concurrent active detect function Disable Function Interrupt Frequency Timer B2 interrupt is generated every q times q: carrier wave cycle-to-cycle basis, 1 to 15 NOTES: 1. Forced cutoff with SD input is effective when the IVPCR1 bit in the TB2SC register is set to 1 (threephase output forcible cutoff by SD input enabled). If an "L" signal is applied to the SD pin when the IVPCR1 bit is 1, the related pins go to a high-impedance state regardless of which functions of those pins are being used. 2. Related pins: P7_2/CLK2/TA1OUT/V, P7_3/CTS2/RTS2/TA1IN/V, P7_4/TA2OUT/W, P7_5/TA2IN/W, P8_0/TA4OUT/RXD5/SCL5/U, P8_1/TA4IN/CTS5/RTS5/U
Item Three-Phase Waveform Output Pin Forced Cutoff Input (1) Used Timers
Specification Six pins (U, U, V, V, W, W)
REJ09B0392-0064 Rev.0.64 Page 165 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
INV00 to INV07 : bits in the INVC0 register INV10 to INV15 : bits in the INVC1 register DUi, DUBi : bits in the IDBi register (i = 0,1) TA1S to TA4S : bits in the TABSR register PWCOM : bits in the TB2SC register
INV01 INV11 1 0 PWCON Timer B2 underflow f1 or f2 Timer B2 1/2 0 1 INV12 INV06 Transfer trigger (1) Trigger U-phase output control circuit DU1 bit DU0 bit
ICTB2 register n = 1 to 15 Circuit to set interrupt generation frequency ICTB2 counter n = 1 to 15
Value to be written to INV03 bit Write signal to INV03 bit
INV03 DQ T R
INV00 Reload control signal for Timer A1
RESET Timer B2 NMI Interrupt INV05 request bit INV04
INV02
(Timer mode)
Write signal to Timer B2 INV10
INV07
Reload register n = 1 to 255 Trigger Dead time timer n = 1 to 255 DQ T
INV14
Inverse control
U
Start trigger signal for Timers A1, A2, and A4 TA4 register Reload Selector Trigger Timer A4 counter INV11 TA41 register Reload Timer A4 control signal
DQ T DUB1 bit DQ T
DQ T DUB0 bit DQ T
U-phase output signal
(One-shot timer mode) TQ
Timer A4 one-shot pulse INV13
Three-phase output shift register (U phase) DQ T Inverse control U
When setting the TA4S bit to 0, signal is set to 0. TA1 register TA11 register Reload Selector Trigger Timer A1 counter Reload
U-phase output signal
INV06 Trigger
Trigger
Dead Time Timer n = 1 to 255
Timer A4 control signal
(One-shot timer mode) TQ INV11
Timer A1 one-shot pulse
V-phase output control circuit
V-phase output signall V-phase output signal
DQ T DQ T
Inverse control Inverse control
V
V
When setting the TA1S bit to 0, signal is set to 0. TA2 register TA21 register Reload Selector Trigger Timer A2 counter Reload Timer A2 oneshot pulse Timer A2 one-shot pulse INV06 Trigger Trigger
Dead Time Timer n = 1 to 255
(One-shot timer mode) TQ INV11
W-phase output control circuit
W-phase output signal W-phase output signal
DQ T DQ T
Inverse control Inverse control
W
W
When setting the TA2S bit to 0, signal is set to 0.
Switching to P8_0, P8_1 and P7_2 to P7_5 is not shown in this diagram. NOTE: 1. Transfer trigger is generated only when registers IDB0 and IDB1 are set and the first timer B2 underflows, if the INV06 bit is set to 0 (triangular wave modulation).
Figure 16.1
Three-phase Motor Control Timer Functions Block Diagram
REJ09B0392-0064 Rev.0.64 Page 166 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Three-Phase PWM Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol INVC0
Bit Symbol
Address 0308h Bit Name Interrupt enable output polarity select bit Interrupt enable output specification bit (2) Mode select bit
(4)
After Reset 00h Function RW
INV00
INV01
0 : The ICTB2 counter is decremented by one on the rising edge of Timer A1 reload control signal 1 : The ICTB2 counter is decremented by one on the falling edge of Timer A1 reload control signal (3) 0 : ICTB2 counter is decremented by one when Timer B2 underflows 1 : Selected by the INV00 bit (3) 0 : No three-phase control timer functions 1 : Three-phase control timer function (5) 0 : Disables three-phase control timer output (5) 1 : Enables three-phase control timer output 0 : Enables concurrent active output 1 : Disables concurrent active output 0 : Not detected 1 : Detected (7) 0 : Triangular wave modulation mode 1 : Sawtooth wave modulation mode (9) Transfer trigger is generated when the INV07 bit is set to 1. Trigger to the dead time timer is also generated when setting the INV06 bit to 1. Read as 0.
RW
RW
INV02 INV03 INV04 INV05 INV06
RW RW RW RW RW
Output control bit (6) Positive-and negativephases concurrent active disable function bit Positive-and negativephases concurrent active output detect flag Modulation mode select bit (8)
INV07
Software trigger select bit
RW
NOTES : 1. Set the INVC0 register after the PRC1 bit in the PRCR register is set to 1 (write enabled). Rewrite bits INV00 to INV02 and INV06 when Timers A1, A2, A4 and B2 stop. 2. Set the INV01 bit to 1 after setting the ICTB2 register 3. Bits INV00 and INV01 are enabled only when the INV11 bit is set to 1 (three-phase mode 1). The ICTB2 counter is decremented by one every time Timer B2 underflows, regardless of INV00 and INV01 bit settings, when the INV11 bit is set to 0 (three-phase mode). When setting the INV01 bit to 1, set Timer A1 count start flag to 1 before the first Timer B2 underflow. When the INV00 bit is set to 1, the first interrupt is generated when Timer B2 underflows n-1 times, if n is the value set in the ICTB2 counter. Subsequent interrupts are generated every n times Timer B2 underflows. 4. Set the INV02 bit to 1 to operate the dead time timer, U-, V-and W-phase output control circuits and ICTB2 counter. 5. When the INVC03 bit is set to 1, the pins applied to U/V/W output three-phase PWM. Pins U, U, V, V, W and W, including pins shared with other output functions, are all placed in high-impedance states when the following conditions are all met. * The INV02 bit is set to 1 (three-phase motor control timer function) * The INV03 bit is set to 0 (three-phase motor control timer output disabled) * Direction registers of each port are set to 0 (input mode) 6. The INV03 bit is set to 0 when the followings conditions are all met. * Reset * A concurrent active state occurs while the INV04 bit is set to 1 * The INV03 bit is set to 0 by program * A signal applied to the SD pin changes "H" to "L" When both bits INVC04 and INVC05 are set to 1, the INVC03 bit is set to 0. 7. The INV05 bit can not be set to 1 by program. Set the INV04 bit to 0 as well when setting the INV05 bit to 0. 8. The following table describes how the INV06 bit works. Item Mode INV06 = 0 Triangular wave modulation mode INV06 = 1 Sawtooth wave modulation mode
Timing to transfer from registers Transferred once by generating a Transferred every time a transfer IDB0 and IDB1 to three-phase transfer trigger after setting registers trigger is generated output shift register IDB0 and IDB1 Timing to trigger the dead time timer when the INV16 bit = 0 INV13 bit On the falling edge of a one-shot pulse of the timer A1, A2, or A4 On the falling edge of a one-shot pulse of the timer A1, A2, or A4, and transfer a trigger
Enabled when the INV11 bit = 1 and Disabled the INV06 bit = 0
Transfer trigger : Timer B2 underflows and write to the INV07 bit, or write to the TB2 register when INV10 = 1 9. When the INV06 bit is set to 1, set the INV11 bit to 0 (three-phase mode 0) and the PWCON bit in the TB2SC register to 0 (reload Timer B2 with Timer B2 underflow).
Figure 16.2
INVC0 Register
REJ09B0392-0064 Rev.0.64 Page 167 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Three-Phase PWM Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol INVC1
Bit Symbol
Address 0309h Bit Name Timer A1, A2, and A4 start trigger select bit Timer A1-1, A2-1 and A4-1 control bit (2) Dead time timer count source select bit Carrier wave detect bit (4) Output polarity control bit Dead time disable bit Function
After Reset 00h RW RW
INV10
0 : Timer B2 underflow 1 : Timer B2 underflow and write to Timer B2 0 : Three-phase mode 0 (3) 1 : Three-phase mode 1 0 : f1TIMAB or f2TIMAB 1 : f1TIMAB divided by 2 or f2TIMAB divided by 2 0 : Timer A1 reload control signal is 0 1 : Timer A1 reload control signal is 1 0 : Active "L" of an output waveform 1 : Active "H" of an output waveform 0 : Dead time enabled 1 : Dead time disabled 0 : Falling edge of a one-shot pulse of Timer A1, A2, and A4 1 : Rising edge of the three-phase output shift register (U-, V-, W-phase) Set to 0
INV11 INV12 INV13 INV14 INV15
RW RW RO RW RW
INV16
Dead time timer trigger select bit (5)
RW
-- (b7)
Reserved bit
RW
NOTES : 1. Rewrite the INVC1 register after the PRC1 bit in the PRCR register is set to 1 (write enabled). Rewrite while the timers A1, A2, A4, and B2 stop. 2. The following table lists how the INV11 bit works. Item Mode Registers TA11, TA21, and TA41 Not used INV11 = 0 Three-phase mode 0 Used Enabled INV11 = 1 Three-phase mode 1
Bits INV00 and INV01 in the INVC0 Disabled. register The ICTB2 counter is decremented whenever Timer B2 underflows INV13 bit Disabled
Enabled when INV11 = 1 and INV06 = 0
3. When the INV06 bit is set to 1 (sawtooth wave modulation mode), set the INV11 bit to 0 (three-phase mode 0). Also, when the INV11 bit is set to 0, set the PWCON bit in the TB2SC register to 0 (timer B2 is reloaded when Timer B2 underflows). 4. The INV13 bit is enabled only when the INV06 bit is set to 0 (triangular wave modulation mode) and the INV11 bit to 1 (three-phase mode 1). 5. If the following conditions are all met, set the INV16 bit to 1 (rising edge of the three-phase output shift register). * The INV15 bit is set to 0 (dead time timer enabled) * The Dij bit and DiBj bit always have different values when the INV03 bit is set to 1 (the positive-phase and negative-phase always output opposite level signals) (i = U, V or W, j = 0, 1). If above conditions are not met, set the INV16 bit to 0 (dead time timer is triggered on the falling edge of a oneshot pulse of timers).
Figure 16.3
INVC1 Register
REJ09B0392-0064 Rev.0.64 Page 168 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Three-Phase Output Buffer Register i (1) (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol IDB0 IDB1
Bit Symbol
Address 030Ah 030Bh Bit Name U-phase output buffer i U-phase output buffer i V-phase output buffer i V-phase output buffer i W-phase output buffer i W-phase output buffer i No register bits. If necessary, set to 0. Read as undefined value Function Write output level 0 : Active level 1 : Inactive level
After Reset XX111111b XX111111b RW RW RW RW RW RW RW --
DUi DUBi DVi DVBi DWi DWBi -- (b7-b6)
When read, the value of the three-phase shift register is read.
NOTE : 1. Values of registers IDB0 and IDB1 are transferred to the three-phase output shift register by a transfer trigger. After the transfer trigger occurs, the values written in the IDB0 register determine each phase output signal first. Then the value written in the IDB1 register on the falling edge of Timers A1, A2, and A4 one-shot pulse determines each phase output signal.
Dead Time Timer (1, 2)
b7 b0
Symbol DTT Function
Address 030Ch
After Reset Indeterminate Setting Range RW
If setting value is n, the timer stops when counting n times a count source selected by the INV12 after start trigger occurs. Positive or negative phase, which changes from inactive level to active level, shifts when the dead time timer stops.
1 to 255
WO
NOTES : 1. Use the MOV instruction to set the DTT register. 2. The DTT register is enabled when the INV15 bit in the INVC1 register is set to 0 (dead time enabled). No dead time can be set when the INV15 bit is set to 1 (dead time disabled). The INV06 bit in the INVC0 register determines start trigger of the DTT register.
Timer B2 Interrupt Generation Frequency Set Counter
b7 b0
(1, 2, 3) After Reset Indeterminate Setting Range RW
Symbol ICTB2 Function
Address 030Dh
When the INV01 bit is set to 0 (the ICTB2 counter increments whenever Timer B2 underflows) and the setting value is n, Timer B2 interrupt is generated every nth time Timer B2 underflow occurs. When the INV01 bit is set to 1 (the INV00 bit selects count timing of the ICTB2 counter) and setting value is n, Timer B2 interrupt is generated every nth time Timer B2 underflow meeting the condition selected in the INV00 bit occurs. No register bits. If necessary, set to 0
1 to 15
WO
--
NOTES : 1. Use the MOV instruction to set the ICTB2 register. 2. If the INV01 bit in the INVCO register is set to 1, set the ICTB2 register when the TB2S bit in the TABSR register is set to 0 (Timer B2 counter stopped). If the INV01 bit is set to 0 and the TB2S bit to 1 (Timer B2 counter start), do not set the ICTB2 register when Timer B2 underflows. 3. If the INV00 bit is set to 1, the first interrupt is generated when Timer B2 underflows n-1 times, n being the value set in the ICTB2 counter. Subsequent interrupts are generated every n times Timer B2 underflows.
Figure 16.4
Registers IDB0, IDB1, DTT, and ICTB2
REJ09B0392-0064 Rev.0.64 Page 169 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Timer Ai Mode Register (i = 1, 2, 4)
b7 b6 b5 b4 b3 b2 b1 b0
010010
Symbol TA1MR TA2MR TA4MR
Bit symbol
Address 0337h 0338h 033Ah Bit Name Function
After Reset 00h 00h 00h RW RW
TMOD0 Operation mode select bit TMOD1 MR0 MR1 Pulse output function select bit External trigger select bit Set to 0 with the three-phase motor control timer function Set to 0 with the three-phase motor control timer function Set to 1 (selected by the TRGSR register) with the three-phase motor control timer function Set to 10b (one-shot timer mode) with the three-phase motor control timer function
RW RW RW
MR2
Trigger select bit
RW
MR3 TCK0
Set to 0 with the three-phase motor control timer function
b7 b6
RW RW RW
Count source select bit (2) TCK1
0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
(1)
NOTES : 1. Selected by the PCLK0 bit in the PCLKR register. 2. Valid when bits TCS3 and TCS7 in registers TACS0 to TACS2 are set to 0. Selected by bits TCS2 to TCS0 or TCS6 to TCS4 in registers TACS0 to TACS2 when bits TCS3 and TCS7 are set to 1. (Refer to Figure 15.8 Registers TACS0 and TACS and Figure 15.9 TACS2 Register ).
Timer B2 Special Mode Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TB2SC
Bit Symbol
Address 033Eh Bit Name Timer B2 reload timing switch bit Three-phase output port SD control bit 1 (4) Function
After Reset XXXXXX00b RW RW
PWCON
0 : Timer B2 underflow 1 : Timer A output at odd-numbered occurrences (2) 0 : Three-phase output forcible cutoff by SD input (high-impedance) disabled 1 : Three-phase output forcible cutoff by SD input (high-impedance) enabled (3)
IVPCR1
RW
-- (b7-b2)
No register bits. If necessary, set to 0. Read as 0
--
NOTES : 1. Write to this register after setting the PRC1 bit in the PRCR register to 1 (write enabled). 2. If the INV11 bit is 0 (three-phase mode 0) or the INV06 bit is 1 (sawtooth wave modulation mode), set the PWCON bit to 0 (Timer B2 underflow). 3. Make sure to set the PD8_5 bit to 0 (input) when setting the IVPCR1 bit to 1 (three-phase output forcible cutoff by SD input enabled ). 4. Related pins are U(P8_0), U(P8_1), V(P7_2), V(P7_3), W(P7_4), and W(P7_5). If a low-level signal is applied to the P8_5/NMI/SD pin, three-phase motor control timer output is disabled (INV03 = 0). Then, the target pins go to a high-impedance state regardless of which functions of those pins are being used. After forced interrupt (cutoff), input "H" to the P8_5/NMI/SD pin and set the IVPCR1 bit to 0 to cancel the forced cutoff.
Figure 16.5
Registers TA1, TA2, TA4, TA11, TA21, TA41, and TB2SC
REJ09B0392-0064 Rev.0.64 Page 170 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Timer B2 Register (1)
(b15) b7 (b8) b0 b7 b0
Symbol TB2
Address 0335h to 0334h
After Reset Indeterminate
Function If setting value is n, count source is divided by n+1. Timers A1, A2 and A4 start every time an underflow occurs. NOTE : 1. Read and write in 16-bit units.
Setting Range 0000h to FFFFh
RW RW
Trigger Select Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TRGSR
Bit Symbol
Address 0323h Bit Name Function
After Reset 00h RW RW RW RW RW RW RW RW RW
TA1TGL A1TGH TA2TGL TA2TGH TA3TGL
Timer A1 event / trigger select bit
Set to 01b (TB2 underflow) before using a V-phase output control circuit
Timer A2 event / trigger select bit
Set to 01b (TB2 underflow) before using a W-phase output control circuit
b5
b4
Timer A3 event / trigger select bit TA3TGH TA4TGL TA4TGH
0 0 1 1
0 : Input on TA3IN is selected 1 : TB2 is selected (2) 0 : TA2 is selected (2) 1 : TA4 is selected (2)
(1)
Timer A4 event / trigger select bit
Set to 01b (TB2 underflow) before using a U-phase output control circuit
NOTES : 1. Set the corresponding port direction bit to 0 (input mode). 2. Overflow or underflow
Count Start Flag
b7 b6 b5 b4 b3 b2 b1 b0
Symbol TABSR
Bit Symbol
Address 0320h Bit Name Timer A0 count start flag Timer A1 count start flag Timer A2 count start flag Timer A3 count start flag Timer A4 count start flag Timer B0 count start flag Timer B1 count start flag Timer B2 count start flag 0 : Stop counting 1 : Start counting Function
After Reset 00h RW RW RW RW RW RW RW RW RW
TA0S TA1S TA2S TA3S TA4S TB0S TB1S TB2S
Figure 16.6
Registers TB2, TRGSR, and TABSR
REJ09B0392-0064 Rev.0.64 Page 171 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
Timer Ai Mode Register (i = 1, 2, 4)
b7 b6 b5 b4 b3 b2 b1 b0
010010
Symbol TA1MR TA2MR TA4MR
Bit symbol
Address 0337h 0338h 033Ah Bit Name Function
After Reset 00h 00h 00h RW RW
TMOD0 Operation mode select bit TMOD1 MR0 MR1 Pulse output function select bit External trigger select bit Set to 0 with the three-phase motor control timer function Set to 0 with the three-phase motor control timer function Set to 1 (selected by the TRGSR register) with the three-phase motor control timer function Set to 10b (one-shot timer mode) with the three-phase motor control timer function
RW RW RW
MR2
Trigger select bit
RW
MR3 TCK0
Set to 0 with the three-phase motor control timer function
b7 b6
RW RW RW
Count source select bit TCK1
(2)
0 0 1 1
0 : f1TIMAB or f2TIMAB 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
(1)
NOTES : 1. Selected by the PCLK0 bit in the PCLKR register. 2. Valid when bits TCS3 and TCS7 in registers TACS0 to TACS2 are set to 0. Selected by bits TCS2 to TCS0 or TCS6 to TCS4 in registers TACS0 to TACS2 when bits TCS3 and TCS7 are set to 1. (Refer to Figure 15.8 Registers TACS0 and TACS and Figure 15.9 TACS2 Register ).
Timer B2 Mode Register
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol TB2MR
Bit Symbol
Address 033Dh Bit Name Function
After Reset 00XX0000b RW RW RW RW RW -- RO RW RW
TMOD0 Operation mode select bit TMOD1 MR0 MR1 -- (b4) MR3 TCK0 Count source select bit TCK1
(2)
Set to 00b (timer mode) when using the three-phase motor control timer function
Disabled when using the three-phase motor control timer function. If necessary, set to 0. Read as undefined value No register bit. If necessary, set to 0. Read as undefined value When write in three-phase motor control timer function, set to 0. Read as undefined value in three-phase motor control timer function
b7 b6
0 0 1 1
0 : f1TIMAB or f2TIMAB (1) 1 : f8TIMAB 0 : f32TIMAB 1 : fC32
NOTES : 1. Selected by the PCLK0 bit in the PCLKR register. 2. Valid when the TCS3 bit in the TBCS1 register is set to 0. Selected by bits TCS2 to TCS0 in the TBCS1 register when the TCS3 bit in the TBCS1 register is set to 1 (Refer to Figure 15.21 TBCS1 Register).
Figure 16.7
Registers TA1MR, TA2MR, TA4MR, and TB2MR
REJ09B0392-0064 Rev.0.64 Page 172 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
16. Three-Phase Motor Control Timer Function
The three-phase motor control timer function is enabled by setting the INV02 bit in the INVC0 register to 1. When this function is on, timer B2 is used to control the carrier wave, and timers A4, A1, and A2 are used to control three-phase PWM outputs (U, U, V, V, W, and W). The dead time is controlled by a dedicated dead time timer. Figure 16.8 shows an Example of Triangular Wave Modulation Operation and Figure 16.9 shows an Example of Sawtooth Wave Modulation Operation.
Triangular Waveform as a Carrier Wave
Carrier wave Signal wave
TB2S bit in TABSR register Timer B2
Timer A1 reload control signal (1) Timer A4 start trigger signal (1) TA4 register (2) TA4-1 register (2) Reload register (2) Timer A4 one-shot pulse (1) U-phase output signal (1) U-phase output signal
(1)
m m m m m m n
n n n n n n p
p p p p
q q q p q
r r q q
Rewrite registers IDB0 and IDB1 Rewritten value is reflected here
INV14 = 0 ("L" active)
U-phase U-phase Dead time
INV14 = 1 ("H" active)
U-phase Dead time U-phase
INV00,INV01 : bits in the INVC0 register INV11, INV14: bits in the INVC1 register NOTES: 1. Internal signals. See Figure 16.1 Three-phase Motor Control Timer Functions Block Diagram. 2. Applies only when the INV11 bit is set to 1 (three-phase mode).
The above applies when INVC0 = 00XX11XXb (X varies depending on each system) and INVC1 = 010XXXXb. The followings are examples of PWM output change. (a) When INV11 = 1 (three-phase mode 1) - INV01 = 0 and ICTB2 = 2h (Timer B2 interrupt is generated with every second Timer B2 underflow) or INV01 = 1, INV00 = 1, and ICTB2 = 1h (Timer B2 interrupt is generated on the falling edge of Timer A reload control signal) - Default value of the timer: TA41 = m, TA4 = m Registers TA4 and TA41 are changed whenever Timer B2 interrupt is generated. First time: TA41 = n, TA4 = n. Second time: TA41 = p, TA4 = p. - Default value of registers IDB0 and IDB1 DU0 = 1, DUB0 = 0, DU1 = 0, DUB1 = 1 They are changed to DU0 = 1, DUB0 = 0, DU1 = 1, DUB1 = 0 by the third Timer B2 interrupt. (b) When INV11 = 0 (three-phase mode 0) - INV01 = 0, ICTB2 = 1h (Timer B2 interrupt is generated whenever Timer B2 underflows) - Default value of the timer: TA4 = m The TA4 register is changed whenever Timer B2 interrupt is generated. First time: TA4 = m Second time: TA4 = n. Third time: TA4 = n Fourth time: TA = p. Fifth time: TA4=p. - Default value of registers IDB0 and IDB1: DU0 = 1, DUB0 = 0, DU1 = 0, DUB1 = 1 They are changed to DU0 = 1, DUB0 = 0, DU1 = 1, DUB1 = 0 by the sixth Timer B2 interrupt.
Figure 16.8
Example of Triangular Wave Modulation Operation
REJ09B0392-0064 Rev.0.64 Page 173 of 373
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M16C/64 Group
16. Three-Phase Motor Control Timer Function
Sawtooth Waveform as a Carrier Wave
Carrier Wave Signal Wave
Timer B2 Timer A4 start trigger signal
(1)
Timer A4 one-shot pulse
(1)
Rewrite registers IDB0 and IDB1 U-phase output signal
(1)
Rewritten value is reflected here
U-phase output signal
(1)
INV14 = 0 ("L" active)
U-phase Dead time U-phase
INV14 = 1 ("H" active)
U-phase Dead time U-phase
INV14: bit in the INVC1 register NOTE: 1. See Figure 16.1 Three-Phase Motor Control Timer Functions Block Diagram. The above applies when INVC0 = 01XX110Xb (X varies depending on each system) and INVC1 = 010XXX00b The following is an example of PWM output change. - Default value of registers IDB0 and IDB1: DU0 = 0, DUB0 = 1, DU1 = 1, DUB1 = 1 They are changed to DU0 = 1, DUB0 = 0, DU1 = 1, DUB1 = 1 by the timer B2 interrupt.
Figure 16.9
Example of Sawtooth Wave Modulation Operation
REJ09B0392-0064 Rev.0.64 Page 174 of 373
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M16C/64 Group
17. Serial Interface
17. Serial Interface
Serial interfaces consist of eight channels: UART0 to UART2, UART5 to UART7, SI/O3, and SI/O4.
17.1
UARTi (i = 0 to 2, 5 to 7)
Each UARTi has an exclusive timer to generate a transfer clock, so it operates independently of each other. Figures 17.1 to 17.3 show the block diagrams of UARTi. Figure 17.4 shows the UARTi Transmit / Receive Unit. UARTi has the following modes: * Clock synchronous serial I/O mode * Clock asynchronous serial I/O mode (UART mode) * Special mode 1 (I2C mode) * Special mode 2 * Special mode 3 (Bus collision detection function, IE mode) * Special mode 4 (SIM mode) : UART2 Figures 17.5 to 17.11 show the UARTi-related registers. Refer to tables for each mode for register setting. UART6 and UART7 cannot be used in memory expansion mode or microprocessor mode.
REJ09B0392-0064 Rev.0.64 Page 175 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
17. Serial Interface
1/2
f2SIO f1SIO
0 1
PCLK1 f1SIO or f2SIO f8SIO 1/4 f32SIO
f1
1/8
RXD0
RXD polarity switching circuit
1/16
UART reception SMD2 to SMD0 010, 100, 101, 110 Clock sync type 001
Clock source selection
CLK1 to CLK0 CKDIR f1SIO or 00 Internal f2SIO 01 0 f8SIO 10 f32SIO 1 External
Reception control circuit
Receive clock
TXD polarity switching circuit
TXD0
Transmit/ receive unit
U0BRG register
1 / (n + 1)
1/16
UART transmission 010, 100, 101, 110 Clock sync type 001 Clock synchronous type (when internal clock is selected) 0
Transmission control circuit
Transmit clock
1/2
CKPOL
CLK0
CLK polarity reversing circuit
CTS / RTS selected
1 Clock synchronous type (when external clock is selected) CKDIR Clock synchronous type (when internal clock is selected)
CTS / RTS disabled
CTS0 / RTS0
RTS0
0 1 RCSP 0 CTS / RTS disabled
1 CRS 0 CTS0 from UART1
CTS0
n: values set to the U0BRG register
1 CRD VSS
PCLK1 : bit in the PCLKR register SMD2 to SMD0, CKDIR : bits in the U0MR register CLK1 to CLK0, CKPOL, CRD, CRS : bits in the U0C0 register RCSP : bit in the UCON register
Figure 17.1
UART0 Block Diagram
f2SIO f1SIO 1/8 1/4 0 1 PCLK1 f1SIO or f2SIO f8SIO f32SIO TXD polarity switching circuit
1/2
f1
RXD1
RXD polarity switching circuit 1/16
TXD1
UART reception SMD2 to SMD0 010, 100, 101, 110 Clock sync type 001
Clock source selection
CLK1 to CLK0 CKDIR f1SIO or 00 Internal f2SIO 01 0 f8SIO 10 f32SIO 1 External
Reception control circuit
Receive clock
U1BRG register
Transmit/ receive unit
1 / (n + 1)
1/16
UART transmission 010, 100, 101, 110 Clock sync type 001 Clock synchronous type (when internal clock is selected) 0 1 CKDIR
Transmission control circuit
Transmit clock
1/2
Clock synchronous type (when external clock is selected) CKPOL CLK polarity reversing circuit Clock output pin select Clock synchronous type (when internal clock is selected)
CLK1
0
CLKMD0
1 1 CTS / RTS selected CRS 1 CLKMD1 0 0 0 CTS / RTS disabled 0 1 VSS 1 CRD RCSP CTS / RTS disabled
CTS1 / RTS1/ CTS0 / CLKS1
RTS1 CTS1
to CTS0 in UART0
n: Values set to the U1BRG register
PCLK1 : bit in the PCLKR register SMD2 to SMD0, CKDIR : bits in the U1MR register CLK1 to CLK0, CKPOL, CRD, CRS : bits in the U1C0 register CLKMD0, CLKMD1, RCSP : bits in the UCON register
Figure 17.2
UART1 Block Diagram
REJ09B0392-0064 Rev.0.64 Page 176 of 373
Oct 12, 2007
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
17. Serial Interface
1/2
f2SIO f1SIO
0 1
PCLK1 f1SIO or f2SIO f8SIO 1/4 f32SIO
f1
1/8
RXDi
RXD polarity switching circuit 1/16
UART reception SMD2 to SMD0 010, 100, 101, 110 Clock sync type 001
Clock source selection
CLK1 to CLK0 CKDIR f1SIO or 00 Internal f2SIO 01 0 f8SIO 10 f32SIO 1 External
Reception control circuit
Receive clock
UiBRG register
Transmit/ receive unit
TXD polarity switching circuit (1)
TXDi
1 / (n + 1)
1/16
UART transmission 010, 100, 101, 110 Clock sync type 001 Clock synchronous type (when internal clock is selected) 0
Transmission control circuit
Transmit clock
1/2
CKPOL
CLKi
CLK polarity reversing circuit
1 Clock synchronous type CKDIR Clock synchronous type (when external clock is selected) (when internal clock is selected)
CTS / RTS selected
CTS / RTS disabled
CTSi / RTSi
RTSi
0 1 VSS CRD CTS / RTS disabled
1 CRS 0
CTSi
n: values set to the UiBRG register i = 2, 5 to 7
PCLK1 : bit in the PCLKR register SMD2 to SMD0, CKDIR : bits in the U2MR register CLK1 to CLK0, CKPOL, CRD, CRS : bits in the U2C0 register
NOTE : 1. UART2 is an N-channel open-drain output. CMOS output cannot be set.
Figure 17.3
UART2, and UART5 to UART7 Block Diagram
REJ09B0392-0064 Rev.0.64 Page 177 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
17. Serial Interface
IOPOL
RXDi
RXD data reverse circuit
0 1
No reverse
Reverse
STPS 1SP 0 SP 1 2SP SP
PAR
PRYE 0
PAR disabled
I2C Clock sync type 0 1 SMD2 to SMD0
Clock sync type UART (7 bits) UART (8 bits)
0
UART (7 bits) 0
UARTi receive register
PAR enabled UART
1
UART (9 bits)
1 I2C
I2C
1
clock sync type UART (8 bits) UART (9 bits)
0
0
0
0
0
0
0
D8
D7
D6
D5
D4
D3
D2
D1
D0
UiRB register
Logic reverse circuit + MSB / LSB conversion circuit
Data bus high-order bits Data bus low-order bits
Logic reverse circuit + MSB / LSB conversion circuit
D8
D7
UART (8 bits) UART (9 bits)
D6
D5
D4
D3
D2
D1
D0
UiTB register
STPS 2SP 1 SP SP 0 1SP
PAR
PRYE
PAR enabled
SMD2 to SMD0
UART
UART (9 bits)
I2C
I2C
clock sync type
1 0
1 0 I2C clock sync type
1
1
PAR disabled
0
UART (7 bits) UART (8 bits) Clock sync type
0 UART (7 bits)
UARTi transmit register
Error signal output disabled
SP : stop bit PAR: parity bit i = 0 to 2, 5 to 7
0
IOPOL 0 1
No reverse
TXDi
UiERE 1
Error signal output circuit
Error signal output enabled
Reverse
TXD data reverse circuit
SMD2 to SMD0, STPS, PRYE, IOPOL, CKDIR : bits in the UiMR register CLK1 to CLK0, CKPOL, CRD, CRS : bits in the UiC0 register UiERE : bit in the UiC1 register
Figure 17.4
UARTi Transmit / Receive Unit
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17. Serial Interface
UARTi Transmit Buffer Register (i = 0 to 2, 5 to 7)
(b15) b7 (b8) b0 b7 b0
(1)
Symbol U0TB U1TB U2TB U5TB U6TB U7TB
Address 024Bh to 024Ah 025Bh to 025Ah 026Bh to 026Ah 028Bh to 028Ah 029Bh to 029Ah 02ABh to 02AAh Function
After Reset Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate RW WO --
Transmit data No register bits. If necessary, set to 0. Read as undefined value NOTE : 1. Use MOV instruction to write to this register.
UARTi Receive Buffer Register (i = 0 to 2, 5 to 7)
(b15) b7 (b8) b0 b7 b0
Symbol U0RB U1RB U2RB U5RB U6RB U7RB
Bit Symbol
Address 024Fh to 024Eh 025Fh to 025Eh 026Fh to 026Eh 028Fh to 028Eh 029Fh to 029Eh 02AFh to 02AEh Bit Name Function Receive data (D7 to D0) Receive data (D8)
After Reset Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate Indeterminate RW RO RO -- RW RO RO RO RO
-- (b7-b0) -- (b8) -- (b10-b9) ABT OER FER PER SUM
No register bits. If necessary, set to 0. Read as undefined value Arbitration lost detect flag (2) Overrun error flag (1) Framing error flag (1, 3) Parity error flag (1,3) Error sum flag (1, 3) 0 : Not detected 1 : Detected 0 : No overrun error 1 : Overrun error found 0 : No framing error 1 : Framing error found 0 : No parity error 1 : Parity error found 0 : No error 1 : Error found
NOTES : 1. When bits SMD2 to SMD0 in the UiMR register = 000b (serial interface disabled) or the RE bit in the UiC1 register = 0 (reception disabled), all of bits SUM, PER, FER, and OER are set to 0 (no error). The SUM bit is set to 0 (no error) when all of bits PER, FER, and OER = 0 (no error). Bits PER and FER are set to 0 by reading the lower byte of the UiRB register. 2. The ABT bit is set to 0 by writing 0 in a program. (Writing a 1 has no effect.) 3. These error flags are disabled when bits SMD2 to SMD0 are set to 001b (clock synchronous serial I/O mode) or to 010b (I2C mode). Read as undefined values.
Figure 17.5
Registers U0TB to U2TB, U5TB to U7TB, U0RB to U2RB, and U5RB to U7RB
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M16C/64 Group
17. Serial Interface
UARTi Bit Rate Register (i = 0 to 2, 5 to 7)
b7 b0
(1, 2, 3)
Symbol U0BRG, U1BRG, U2BRG U5BRG, U6BRG, U7BRG Function
Address 0249h, 0259h, 0269h 0289h, 0299h, 02A9h
After Reset Indeterminate Indeterminate Setting Range 00h to FFh RW WO
If set value = n, UiBRG divides the count source by n + 1 NOTES : 1. Write to this register while serial interface is neither transmitting nor receiving. 2. Use MOV instruction to write to this register. 3. Write to this register after setting bits CLK1 to CLK0 in the UiC0 register.
UARTi Transmit / Receive Mode Register (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0MR, U1MR, U2MR U5MR, U6MR, U7MR
Bit Symbol
Address 0248h, 0258h, 0268h 0288h, 0298h, 02A8h Function
b2 b1 b0
After Reset 00h 00h RW RW RW RW RW RW
Bit Name
SMD0 SMD1 SMD2 CKDIR STPS
0 0 0 : Serial interface disabled 0 0 1 : Clock synchronous serial I/O mode 0 1 0 : I2C mode (3) Serial I/O mode select bit 1 0 0 : UART mode transfer data 7 bits long 1 0 1 : UART mode transfer data 8 bits long 1 1 0 : UART mode transfer data 9 bits long Do not set except above Internal / external clock select bit Stop bit length select bit Odd / even parity select bit Parity enable bit TXD, RXD I/O polarity reverse bit 0 : Internal clock 1 : External clock 0 : 1 stop bit 1 : 2 stop bits Valid when PRYE = 1 0 : Odd parity 1 : Even parity 0 : Parity disabled 1 : Parity enabled 0 : No reverse 1 : Reverse
(1)
PRY
RW
PRYE IOPOL
RW RW
NOTE : 1. Set the corresponding port direction bit for each CLKi pin to 0 (input mode). 2. To receive data, set the corresponding port direction bit for each RXDi pin to 0 (input mode). 3. Set the corresponding port direction bit for pins SCL and SDA to 0 (input mode).
Figure 17.6
Registers U0BRG to U2BRG, U5BRG to U7BRG, U0MR to U2MR, and U5MR to U7MR
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17. Serial Interface
UARTi Transmit / Receive Control Register 0 (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0C0, U1C0, U2C0 U5C0, U6C0, U7C0
Bit Symbol
Address 024Ch, 025Ch, 026Ch 028Ch, 029Ch, 02ACh Bit Name
b1 b0
After Reset 00001000b 00001000b Function RW RW RW
CLK0 UiBRG count source select bit (6) CLK1 CTS / RTS function select bit
(4)
0 0 1 1
0 : f1SIO or f2SIO is selected 1 : f8SIO is selected 0 : f32SIO is selected 1 : Do not set to this value
(5)
CRS
Valid when CRD = 0 0 : CTS function selected (1) 1 : RTS function selected 0 : Data present in transmit register (during transmission) 1 : No data present in transmit register (transmission completed) 0 : CTS / RTS function enabled 1 : CTS / RTS function disabled (P6_0, P6_4, P7_3, P8_1, P1_0, and P4_4 can be used as I/O ports)
RW
TXEPT
Transmit register empty flag
RO
CRD
CTS / RTS disable bit
RW
NCH
Data output select bit
(2)
0 : Pins TXDi / SDAi and SCLi are CMOS output 1 : Pins TXDi / SDAi and SCLi are Nchannel open-drain output 0 : Transmit data is output at the falling edge of transfer clock and receive data is input at the rising edge 1 : Transmit data is output at the rising edge of transfer clock and receive data is input at the falling edge 0 : LSB first 1 : MSB first
RW
CKPOL
CLK polarity select bit
RW
UFORM
Transfer format select bit (3)
RW
NOTES : 1. Set the corresponding port direction bit for each CTSi pin to 0 (input mode). 2. TXD2 / SDA2 and SCL2 are N-channel open-drain output. Cannot be set to the CMOS output. No NCH bit in the U2C0 register is assigned. If necessary, set to 0. 3. The UFORM bit is enabled when bits SMD2 to SMD0 in the UiMR register are set to 001b (clock synchronous serial I/O mode), or 101b (UART mode, 8-bit transfer data). Set this bit to 1 when bits SMD2 to SMD0 are set to 010b (I 2C mode), and to 0 when bits SMD2 to SMD0 are set to 100b (UART mode, 7-bit transfer data) or 110b (UART mode, 9-bit transfer data). 4. CTS1 / RTS1 can be used when the CLKMD1 bit in the UCON register = 0 (only CLK1 output) and the RCSP bit in the UCON register = 0 (CTS0 / RTS0 not separated). 5. Selected by the PCLK1 bit in the PCLKR register. 6. When changing bits CLK1 and CLK0, set the UiBRG register.
Figure 17.7
Registers U0C0 to U2C0 and U5C0 to U7C0
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17. Serial Interface
UARTi Transmit / Receive Control Register 1 (i = 0, 1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0C1, U1C1
Bit Symbol
Address 024Dh, 025Dh Bit Name Transmit enable bit Transmit buffer empty flag Receive enable bit Receive complete flag Function 0 : Transmission disabled 1 : Transmission enabled 0 : Data present in UiTB register 1 : No data present in UiTB register 0 : Reception disabled 1 : Reception enabled 0 : Data present in UiRB register 1 : No data present in UiRB register
After Reset 00XX0010b RW RW RO RW RO
TE TI RE RI -- (b5-b4) UiLCH UiERE
No register bits. If necessary, set to 0. Read as undefined value 0 : No reverse 1 : Reverse 0 : Output disabled 1 : Output enabled
--
Data logic select bit (1) Error signal output enable bit
RW RW
NOTE : 1. The UiLCH bit enabled when bits SMD2 to SMD0 in the UiMR register are set to 001b (clock sychronous serial I/ O mode), 100b (UART mode, 7-bit transfer data), or 101b (UART mode, 8-bit transfer data). Set this bit to 0 when bits SMD2 to SMD0 are set to 010b (I2C mode) or 110b (UART mode, 9-bit transfer data).
UARTi Transmit / Receive Control Register 1 (i = 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U2C1 U5C1, U6C1, U7C1
Bit symbol
Address 026Dh 028Dh, 029Dh, 02ADh Function 0 : Transmission disabled 1 : Transmission enabled 0 : Data present in UiTB register 1 : No data present in UiTB register 0 : Reception disabled 1 : Reception enabled 0 : No data present in UiRB register 1 : Data present in UiRB register 0 : UiTB register empty (TI = 1) 1 : Transmit completed (TXEPT = 1)
After Reset 00000010b 00000010b RW RW RO RW RO RW RW RW RW
Bit Name Transmit enable bit Transmit buffer empty flag Receive enable bit Receive complete flag UARTi transmit interrupt source select bit UARTi continuous receive mode enable bit Data logic select bit (1) Error signal output enable bit
TE TI RE RI UilRS UiRRM UiLCH UiERE
0 : Continuous receive mode disabled 1 : Continuous receive mode enabled 0 : No reverse 1 : Reverse 0 : Output disabled 1 : Output enabled
NOTE : 1. The UiLCH bit is enabled when bits SMD2 to SMD0 in the UiMR register are set to 001b (clock synchronous serial I/O mode), 100b (UART mode, 7-bit transfer data), or 101b (UART mode, 8-bit transfer data). Set this bit to 0 when bits SMD2 to SMD0 are set to 010b (I 2C mode) or 110b (UART mode, 9-bit transfer data).
Figure 17.8
Registers U0C1 to U2C1 and U5C1 to U7C1
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17. Serial Interface
UART Transmit / Receive Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol UCON
Bit symbol
Address 0250h Bit Name UART0 transmit interrupt source select bit UART1 transmit interrupt source select bit UART0 continuous receive mode enable bit UART1 continuous receive mode enable bit UART1CLK, CLKS select bit 0 UART1CLK, CLKS select bit 1
(1)
After Reset X0000000b Function RW RW RW RW RW
U0IRS U1IRS U0RRM U1RRM
0 : Transmit buffer empty (Tl = 1) 1 : Transmission completed (TXEPT = 1) 0 : Transmit buffer empty (Tl = 1) 1 : Transmission completed (TXEPT = 1) 0 : Continuous receive mode disabled 1 : Continuous receive mode enabled 0 : Continuous receive mode disabled 1 : Continuous receive mode enabled Valid when CLKMD1 = 1 0 : Clock output from CLK1 1 : Clock output from CLKS1 0 : CLK output is only from CLK1 1 : Transfer clock output from multiple-pin output function selected 0 : CTS / RTS shared pin 1 : CTS / RTS separated (CTS0 supplied from the P6_4 pin)
CLKMD0
RW
CLKMD1 RCSP -- (b7)
RW RW --
Separate UART0 CTS / RTS bit
No register bit. If necessary, set to 0. Read as undefined value
NOTE : 1. When using multiple transfer clock output pins, make sure the following conditions are met: the CKDIR bit in the U1MR register = 0 (internal clock)
UARTi Special Mode Register (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol U0SMR, U1SMR, U2SMR U5SMR, U6SMR, U7SMR
Bit Symbol
Address 0247h, 0257h, 0267h 0287h, 0297h, 02A7h Function 0 : Other than I2C mode 1 : I2C mode 0 : Update per bit 1 : Update per byte 0 : Stop-condition detected 1 : Start-condition detected (busy) Set to 0
After Reset X0000000b X0000000b RW RW RW RW RW
Bit Name I2C mode select bit Arbitration lost detect flag control bit Bus busy flag (1) Reserved bit
IICM ABC BBS -- (b3) ABSCS
Bus collision detect sampling 0 : Rising edge of transfer clock clock select bit 1 : Underflow signal of Timer Aj (2) Auto clear function select bit 0 : No auto clear function of transmit enable bit 1 : Auto clear at occurrence of bus collision Transmit start condition select bit 0 : Not synchronized to RXDi 1 : Synchronized to RXDi (3)
RW
ACSE SSS -- (b7)
RW RW --
No register bit. If necessary, set to 0. Read as undefined value
NOTES : 1. The BBS bit is set to 0 by writing a 0 in a program (Writing a 1 has no effect). 2. Underflow signal of Timer A3 in UART0 and UART6, underflow signal of Timer A4 in UART1 and UART7, and underflow signal of Timer A0 in UART2 and UART5 3. When a transfer begins, the SSS bit is set to 0 (not synchronized to RXDi).
Figure 17.9
Registers UCON, U0SMR to U2SMR, and U5SMR to U7SMR
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M16C/64 Group
17. Serial Interface
UARTi Special Mode Register 2 (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0SMR2, U1SMR2, U2SMR2 U5SMR2, U6SMR2, U7SMR2
Bit Symbol
Address 0246h, 0256h, 0266h 0286h,0296h,02A6h Function
After Reset X0000000b X0000000b RW RW RW RW RW
Bit Name I2C mode select bit 2 Clock synchronization bit SCL wait output bit SDA output stop bit
IICM2 CSC SWC ALS
See Table 17.13 I2C Mode Functions 0 : Disabled 1 : Enabled 0 : Disabled 1 : Enabled 0 : Disabled 1 : Enabled 0 : Disabled 1 : Enabled 0: Transfer clock 1: "L" output 0: Enabled 1: Disabled (high-impedance)
STAC
UARTi initialization bit
RW
SWC2 SDHI -- (b7)
SCL wait output bit 2 SDA output disable bit
RW RW --
No register bit. If necessary, set to 0. Read as undefined value
UARTi Special Mode Register 3 (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0SMR3, U1SMR3, U2SMR3 U5SMR3, U6SMR3, U7SMR3
Bit Symbol
Address 0245h, 0255h, 0265h 0285h, 0295h, 02A5h Function
After Reset 000X0X0Xb 000X0X0Xb RW -- RW -- RW -- RW RW RW
Bit Name
-- (b0) CKPH -- (b2) NODC -- (b4) DL0 DL1 DL2
No register bit. If necessary, set to 0. Read as undefined value Clock phase set bit 0 : Without clock delay 1 : With clock delay
No register bit. If necessary, set to 0. Read as undefined value Clock output select bit 0 : CLKi is CMOS output 1 : CLKi is N-channel open drain output
No register bit. If necessary, set to 0. Read as undefined value b7 b6 b5 0 0 0 : Without delay 0 0 1 : 1 to 2 cycle(s) of UiBRG count source 0 1 0 : 2 to 3 cycles of UiBRG count source 0 1 1 : 3 to 4 cycles of UiBRG count source 1 0 0 : 4 to 5 cycles of UiBRG count source 1 0 1 : 5 to 6 cycles of UiBRG count source 1 1 0 : 6 to 7 cycles of UiBRG count source 1 1 1 : 7 to 8 cycles of UiBRG count source
SDAi digital delay setup bit (1, 2)
NOTES : 1. Bits DL2 to DL0 are used to generate a delay in SDAi output by digital means during I2C mode. In other than I2C mode, set these bits to 000b (no delay). 2. The amount of delay varies with the load on pins SCLi and SDAi. Also, when using an external clock, the amount of delay increases by about 100 ns.
Figure 17.10 Registers U0SMR2 to U2SMR2, U5SMR2 to U7SMR2, U0SMR3 to U2SMR3, and U5SMR3 to U7SMR3
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M16C/64 Group
17. Serial Interface
UARTi Special Mode Register 4 (i = 0 to 2, 5 to 7)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol U0SMR4, U1SMR4, U2SMR4 U5SMR4, U6SMR4, U7SMR4
Bit Symbol
Address 0244h, 0254h, 0264h 0284h, 0294h, 02A4h Function 0 : Clear 1 : Start 0 : Clear 1 : Start 0 : Clear 1 : Start
After Reset 00h 00h RW RW RW RW
Bit Name Start condition generate bit
(1)
STAREQ RSTAREQ STPREQ
Restart condition generate bit (1) Stop condition generate bit
(1)
STSPSEL SCL, SDA output select bit
0 : Start and stop conditions not output 1 : Start and stop conditions output 0 : ACK 1 : NACK 0 : Serial interface data output 1 : ACK data output 0 : Disabled 1 : Enabled 0 : SCL "L" hold disabled 1 : SCL "L" hold enabled
RW
ACKD
ACK data bit
RW
ACKC SCLHI SWC9
ACK data output enable bit SCL output stop enable bit SCL wait bit 3
RW RW RW
NOTE : 1. Set to 0 when each condition is generated.
Figure 17.11 Registers U0SMR4 to U2SMR4 and U5SMR4 to U7SMR4
REJ09B0392-0064 Rev.0.64 Page 185 of 373
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17. Serial Interface
17.1.1
Clock Synchronous Serial I/O Mode
The clock synchronous serial I/O mode uses a transfer clock to transmit and receive data. Table 17.1 lists the Clock Synchronous Serial I/O Mode Specifications. Table 17.2 lists Registers to Be Used and Settings in Clock Synchronous Serial I/O Mode.
Table 17.1 Clock Synchronous Serial I/O Mode Specifications
Item Transfer Data Format Transfer Clock Transfer data length: 8 bits * CKDIR bit in the UiMR register = 0 (internal clock): fj / (2(n+1)) fj = f1SIO, f2SIO, f8SIO, f32SIO n = setting value of UiBRG register * CKDIR bit = 1 (external clock) : input from CLKi pin Selectable from CTS function, RTS function or CTS / RTS function disable Before transmission starts, satisfy the following requirements (1) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in UiTB register) * If CTS function is selected, input on the CTSi pin = "L" Before reception starts, satisfy the following requirements (1) * The RE bit in the UiC1 register = 1 (reception enabled) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present and dummy written in the UiTB register) For transmission, one of the following conditions can be selected * The UiIRS bit (3) = 0 (transmit buffer empty): when transferring data from the UiTB register to the UARTi transmit register (at start of transmission) * The UiIRS bit =1 (transfer completed): when the serial interface finished sending data from the UARTi transmit register For reception * When transferring data from the UARTi receive register to the UiRB register (at completion of reception) Overrun error (2) This error occurs if the serial interface started receiving the next data before reading the UiRB register and received the 7th bit of the next data * CLK polarity selection Transfer data input / output can be chosen to occur synchronously with the rising or the falling edge of the transfer clock * LSB first, MSB first selection Whether to start sending / receiving data beginning with bit 0 or beginning with bit 7 can be selected * Continuous receive mode selection Reception is enabled immediately by reading the UiRB register * Switching serial data logic This function reverses the logic value of the transmit / receive data * Transfer clock output from multiple pins selection (UART1) The output pin can be selected in a program from two UART1 transfer clock pins that have been set * Separate CTS / RTS pins (UART0) CTS0 and RTS0 are input / output from separate pins
00h to FFh
Specification
Transmission, Reception Control Transmission Start Condition
Reception Start Condition
Interrupt Request Generation Timing
Error Detection
Select Function
i = 0 to 2, 5 to 7 NOTES: 1. When an external clock is selected, the conditions must be met while if the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock), the external clock is in the high state; if the CKPOL bit in the UiC0 register = 1 (transmit data output at the rising edge and the receive data taken in at the falling edge of the transfer clock), the external clock is in the low state. 2. If an overrun error occurs, the receive data of the UiRB register will be indeterminate. The IR bit in the SiRIC register does not change to 1 (interrupt requested). 3. Bits U0IRS and U1IRS correspond to bits 0 and 1 in the UCON register respectively. Bits U2IRS, REJ09B0392-0064 Rev.0.64 Page 186 of 373 Oct 12, 2007
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M16C/64 Group
17. Serial Interface
U5IRS, U6IRS, and U7IRS are in registers U2C1, U5C1, U6C1, and U7C1 respectively.
Table 17.2 Registers to Be Used and Settings in Clock Synchronous Serial I/O Mode
Register UiTB
(3)
Bit 0 to 7 0 to 7 OER 0 to 7 SMD2 to SMD0 CKDIR IOPOL CLK1 to CLK0 CRS TXEPT CRD NCH CKPOL UFORM TE TI RE RI UiIRS (1) UiRRM (1) UiLCH UiERE 0 to 7 0 to 7 0 to 2 NODC 4 to 7 0 to 7 U0IRS, U1IRS U0RRM, U1RRM CLKMD0 CLKMD1 RCSP 7 Set transmission data
Function Reception data can be read Overrun error flag Set a bit rate Set to 001b Select the internal clock or external clock Set to 0 Select the count source for the UiBRG register Select either CTS or RTS to use functions Transmit register empty flag Enable or disable the CTS or RTS function Select TXDi pin output mode (2) Select the transfer clock polarity Select the LSB first or MSB first Set this bit to 1 to enable transmission / reception Transmit buffer empty flag Set this bit to 1 to enable reception Reception complete flag Select the source of UARTi transmit interrupt Set this bit to 1 to use continuous reception mode Set this bit to 1 to use inverted data logic Set to 0 Set to 0 Set to 0 Set to 0 Select clock output mode Set to 0 Set to 0 Select the source of UART0 / UART1 transmit interrupt Set this bit to 1 to use continuous reception mode Select the transfer clock output pin when CLKMD1 = 1 Set this bit to 1 to output UART1 transfer clock from two pins Set this bit to 1 to accept as input the CTS0 signal of UART0 from the P6_4 pin Set to 0
UiRB (3) UiBRG UiMR (3)
UiC0
UiC1
UiSMR UiSMR2 UiSMR3
UiSMR4 UCON
i = 0 to 2, 5 to 7 NOTES: 1. Set bits 4 and 5 in registers U0C1 and U1C1 to 0. Bits U0IRS, U1IRS, U0RRM, and U1RRM are in the UCON register. 2. The TXD2 pin is N channel open-drain output. Set the NCH bit in the U2C0 register to 0. 3. Set bits not listed above to 0 when writing to the registers in clock synchronous serial I/O mode.
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17. Serial Interface
Table 17.3 lists the functions of the input / output pins during clock synchronous serial I/O mode. Table 17.3 shows pin functions for the case where the multiple transfer clock output pin select function is not selected. Table 17.4 lists the P6_4 Pin Functions during clock synchronous serial I/O mode. Note that for a period from when UARTi operating mode is selected to when transfer starts, the TXDi pin outputs "H" (If the N-channel open-drain output is selected, this pin is in high-impedance state).
Table 17.3
Pin Functions during Clock Synchronous Serial I/O Mode (Multiple Transfer Clock Output Pin Function Not Selected)
Pin Name TXDi RXDi
Function Serial data output Serial data input
Method of Selection (Outputs dummy data when performing reception only) Set the port direction bit corresponding to the RXDi pin = 0 (can be used as an input port when performing transmission only) The CKDIR bit in the UiMR register = 0 The CKDIR bit in the UiMR register = 1 Set the port direction bit corresponding to the CLKi pin = 0 The CRD bit in the UiC0 register = 0 The CRS bit in the UiC0 register = 0 Set the port direction bit corresponding to the CTSi pin = 0 The CRD bit in the UiC0 register = 0 The CRS bit in the UiC0 register = 1 The CRD bit in the UiC0 register = 1
CLKi
Transfer clock output Transfer clock input
CTSi / RTSi
CTS input
RTS output
I/O port i = 0 to 2, 5 to 7
Table 17.4
P6_4 Pin Functions during Clock Synchronous Serial I/O Mode
Bit Set Value Pin Function P6_4
CTS1 RTS1 CTS0 (1)
U1C0 Register CRD 1 0 0 0 0 1 0 CRS 0 0 0 1 RCSP
UCON Register CLKMD1 0 0 0 0 1 (2) 1 CLKMD0 0 0 -
PD6 Register PD6_4 Input: 0, Output: 1
CLKS1
- indicates either 0 or 1 NOTES: 1. In addition to this, set the CRD bit in the U0C0 register to 0 (CTS0 / RTS0 enabled) and the CRS bit in the U0C0 register to 1 (RTS0 selected). 2. When the CLKMD1 bit = 1 and the CLKMD0 bit = 0, the following logic levels are output: * High if the CLKPOL bit in the U1C0 register = 0 * Low if the CLKPOL bit in the U1C0 register = 1
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17. Serial Interface
(1) Example of Transmit Timing (when internal clock is selected) Tc
Transfer clock "1" "0" "1" "0" "H" "L"
Data is transferred from the UiTB register to the UARTi transmit register
TE bit in UiC1 register TI bit in UiC1 register
Data is set in the UiTB register
CTSi CLKi
TCLK
Pulse stops because an "H" signal is applied to CTSi
Pulse stops because the TE bit is set to 0
TXDi
TXEPT flag in UiC0 register IR bit in SiTIC register
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
D0 D1 D2 D3 D4 D5 D6 D7
"1" "0" "1" "0" Set to 0 by an interrupt request acknowledgement or by program
TC = TCLK = 2(n + 1) / fj fj: frequency of UiBRG count source (f1SIO, f2SIO, f8SIO, f32SIO) n: value set to the UiBRG register
i = 0 to 2, 5 to 7
The above timing diagram applies to the case where the register bits are set as follows: * The CKDIR bit in the UiMR register = 0 (internal clock) * The CRD bit in the UiC0 register = 0 (CTS / RTS enabled), the CRS bit = 0 (CTS selected) * The CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and receive data taken in at the rising edge of the transfer clock) * The UiIRS bit in the UiC1 register = 0 (an interrupt request occurs when the UiTB register becomes empty)
(2) Example of Receive Timing (when external clock is selected)
RE bit in UiC1 register TE bit in UiC1 register TI bit in UiC1 register
"1" "0" "1" "0" "1" "0" "H" "L"
Data is transferred from the UiTB register to the UARTi transmit register
Dummy data is set in the UiTB register
RTSi
1 / fEXT
An "L" signal is applied when the UiRB register is read
CLKi Received data is taken in RXDi RI bit in UiC1 register IR bit in SiRIC register D0 D1 D2 D3 D4 D5 D6 D7 D0 D1 D2 D3 D4 D5 D6 Read by the UiRB register D7 D0 D1 D2 D3 D4 D5 D6
"1" "0" "1" "0"
Data is transferred from the UARTi receive register to the UiRB register
Set to 0 by an interrupt request acknowledgement or by program
OER flag in UiRB register
"1" "0" i = 0 to 2, 5 to 7
Make sure the following conditions are met when input to the CLKi pin before receiving data is high: * The TE bit in the UiC0 register = 1 (transmit enabled) * The RE bit in the UiC1 register = 1 (receive enabled) * Write dummy data to the UiTB register
The above timing diagram applies to the case where the register bits are set as follows: * The CKDIR bit in the UiMR register = 1 (external clock) * The CRD bit in the UiC0 register = 0 (CTS / RTS enabled), the CRS bit = 1 (RTS selected) * The CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and receive data taken in at the rising edge of the transfer clock)
fEXT: frequency of the external clock
Figure 17.12 Transmit and Receive Operation during Clock Synchronous Serial I/O Mode
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17. Serial Interface
17.1.1.1
Counter Measure for Communication Error
If a communication error occurs while transmitting or receiving in clock synchronous serial I/O mode, follow the procedures below. * Resetting the UiRB register (i = 0 to 2, 5 to 7) (1) Set the RE bit in the UiC1 register to 0 (reception disabled) (2) Set bits SMD2 to SMD0 in the UiMR register to 000b (serial interface disabled) (3) Set bits SMD2 to SMD0 in the UiMR register to 001b (clock synchronous serial I/O mode) (4) Set the RE bit in the UiC1 register to 1 (reception enabled) * Resetting the UiTB register (i = 0 to 2, 5 to 7) (1) Set bits SMD2 to SMD0 in the UiMR register to 000b (serial interface disabled) (2) Set bits SMD2 to SMD0 in the UiMR register to 001b (clock synchronous serial I/O mode) (3) A 1 is written to the RE bit in the UiC1 register (transmission enabled), regardless of the value of the TE bit in the UiCi register
17.1.1.2
CLK Polarity Select Function
Use the CKPOL bit in the UiC0 register (i = 0 to 2, 5 to 7) to select the transfer clock polarity. Figure 17.13 shows the Transfer Clock Polarity.
(1) When the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock)
CLKi TXDi RXDi D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6
"H" is output from the CLKi pin during no transmission.
D7 D7
(2) When the CKPOL bit = 1 (transmit data output at the rising edge and the receive data taken in at the falling edge of the transfer clock) "L" is output from the CLKi pin
during no transmission.
CLKi TXDi RXDi D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7
The above applies to the case where the UFORM bit in the UiC0 register = 0 (LSB first) and the UiLCH bit in the UiC1 register = 0 (no reverse). i = 0 to 2, 5 to 7
Figure 17.13 Transfer Clock Polarity
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17. Serial Interface
17.1.1.3
LSB First / MSB First Select Function
Use the UFORM bit in the UiC0 register (i = 0 to 2, 5 to 7) to select the transfer format. Figure 17.14 shows the Transfer Format.
(1) When the UFORM Bit in the UiC0 Register = 0 (LSB First)
CLKi TXDi RXDi D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7
(2) When the UFORM Bit in the UiC0 Register = 1 (MSB First)
CLKi TXDi RXDi D7 D7 D6 D6 D5 D5 D4 D4 D3 D3 D2 D2 D1 D1 D0 D0
The above applies to the case where the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock), and the UiLCH bit in the UiC1 register = 0 (no reverse). i = 0 to 2, 5 to 7
Figure 17.14 Transfer Format
17.1.1.4
Continuous Reception Mode
In continuous reception mode, receive operation becomes enabled when the receive buffer register is read. It is not necessary to write dummy data into the transmit buffer register to enable receive operation in this mode. However, a dummy read of the receive buffer register is required when starting the operating mode. When the UiRRM bit (i = 0 to 2, 5 to 7) = 1 (continuous reception mode), the TI bit in the UiC1 register is set to 0 (data present in the UiTB register) by reading the UiRB register. In this case, i.e., UiRRM bit = 1, do not write dummy data to the UiTB register in a program. Bits U0RRM and U1RRM correspond to bits 2 and 3 in the UCON register, respectively. Bits U2RRM, U5RRM, U6RRM, and U7RRM are in registers U2C1, U5C1, U6C1, and U7C1.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
17. Serial Interface
17.1.1.5
Serial Data Logic Switching Function
When the UiLCH bit in the UiC1 register (i = 0 to 2, 5 to 7) = 1 (reverse), the data written to the UiTB register has its logic reversed before being transmitted. Similarly, the received data has its logic reversed when read from the UiRB register. Figure 17.15 shows Serial Data Logic Switching.
(1) When the UiLCH Bit in the UiC1 Register = 0 (No Reverse)
Transfer Clock TXDi (No Reverse)
"H" "L" "H" "L"
D0
D1
D2
D3
D4
D5
D6
D7
(2) When the UiLCH Bit in the UiC1 Register = 1 (Reverse)
Transfer Clock TXDi (Reverse)
"H" "L" "H" "L"
D0
D1
D2
D3
D4
D5
D6
D7
This applies to the case where the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge of the transfer clock), and the UFORM bit in the UiC0 register = 0 (LSB first) i = 0 to 2, 5 to 7
Figure 17.15 Serial Data Logic Switching
17.1.1.6
Transfer Clock Output from Multiple Pins (UART1)
Use bits CLKMD1 to CLKMD0 in the UCON register to select one of the two transfer clock output pins (see Figure 17.16). This function can be used when the selected transfer clock for UART1 is an internal clock.
Microcomputer
TXD1 (P6_7) CLKS1 (P6_4) CLK1 (P6_5) IN CLK IN CLK
Transfer enabled when the CLKMD0 bit in the UCON register = 0
Transfer enabled when the CLKMD0 bit in the UCON register = 1
The above applies to the case where the CKDIR bit in the U1MR register = 0 (internal clock) and the CLKMD1 bit in the UCON register = 1 (transfer clock output from multiple pins).
Figure 17.16 Transfer Clock Output from Multiple Pins
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17. Serial Interface
17.1.1.7
CTS / RTS Function
The CTS function is used to start transmit and receive operation when "L" is applied to the CTSi / RTSi (i = 0 to 2, 5 to 7) pin. Transmit and receive operation begins when the CTSi / RTSi pin is held "L". If the "L" signal is switched to "H" during a transmit or receive operation, the operation stops before the next data. For the RTS function, the CTSi / RTSi pin outputs "L" when the microcomputer is ready to receive. The output level becomes "H" on the first falling edge of the CLKi pin. * The CRD bit in the UiC0 register = 1 (disable CTS / RTS function) CTSi / RTSi pin is programmable I/O function * The CRD bit = 0, CRS bit = 0 (CTS function selected) CTSi / RTSi pin is CTS function * The CRD bit = 0, CRS bit = 1 (RTS function selected) CTSi / RTSi pin is RTS function
17.1.1.8
CTS / RTS Separate Function (UART0)
This function separates CTS0 / RTS0, outputs RTS0 from the P6_0 pin, and inputs CTS0 from the P6_4 pin. To use this function, set the register bits as shown below. * The CRD bit in the U0C0 register = 0 (enable CTS / RTS of UART0) * The CRS bit in the U0C0 register = 1 (output RTS of UART0) * The CRD bit in the U1C0 register = 0 (enable CTS / RTS of UART1) * The CRS bit in the U1C0 register = 0 (input CTS of UART1) * The RCSP bit in the UCON register = 1 (inputs CTS0 from the P6_4 pin) * The CLKMD1 bit in the UCON register = 0 (CLKS1 not used) Note that when using the CTS / RTS separate function, CTS / RTS of UART1 function cannot be used.
Microcomputer
TXD0 (P6_3) RXD0 (P6_2) CLK0 (P6_1) RTS0 (P6_0) CTS0 (P6_4) IN OUT CLK CTS RTS
IC
Figure 17.17 CTS / RTS Separate Function
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M16C/64 Group
17. Serial Interface
17.1.2
Clock Asynchronous Serial I/O (UART) Mode
The UART mode allows transmitting and receiving data after setting the desired bit rate and transfer data format. Table 17.5 lists the UART Mode Specifications.
Table 17.5 UART Mode Specifications
Specification * Character bit (transfer data): selectable from 7, 8, or 9 bits * Start bit : 1 bit * Parity bit : selectable from odd, even, or none * Stop bit : selectable from 1 bit or 2 bits * The CKDIR bit in the UiMR register = 0 (internal clock): fj / (16(n + 1)) fj = f1SIO, f2SIO, f8SIO, f32SIO n: setting value of UiBRG register 00h to FFh * CKDIR bit = 1 (external clock): fEXT / (16(n + 1)) fEXT: input from CLKi pin n: setting value of UiBRG register 00h to FFh Selectable from CTS function, RTS function or CTS / RTS function disabled Before transmission starts, satisfy the following requirements * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in the UiTB register) * If CTS function is selected, input on the CTSi pin = "L" Before reception starts, satisfy the following requirements * The RE bit in the UiC1 register = 1 (reception enabled) * Start bit detection For transmission, one of the following conditions can be selected * The UiIRS bit (2) = 0 (transmit buffer empty): when transferring data from the UiTB register to the UARTi transmit register (at start of transmission) * The UiIRS bit =1 (transfer completed): when the serial interface completes sending data from the UARTi transmit register For reception * When transferring data from the UARTi receive register to the UiRB register (at completion of reception) * Overrun error (1) This error occurs if the serial interface started receiving the next data before reading the UiRB register and received the bit one before the last stop bit of the next data * Framing error (3) This error occurs when the number of stop bits set is not detected * Parity error (3) This error occurs when if parity is enabled, the number of 1 in parity and character bits does not match the number of 1 set * Error sum flag This flag is set to 1 when any of the overrun, framing, or parity errors occur * LSB first, MSB first selection Whether to start sending / receiving data beginning with bit 0 or beginning with bit 7 can be selected * Serial data logic switch This function reverses the logic of the transmit / receive data. The start and stop bits are not reversed. * TXD, RXD I/O polarity switch This function reverses the polarities of the TXD pin output and RXD pin input. The logic levels of all I/O data are reversed. * Separate CTS / RTS pins (UART0) CTS0 and RTS0 are input / output from separate pins.
Item Transfer Data Format
Transfer Clock
Transmission, Reception Control Transmission Start Condition
Reception Start Condition
Interrupt Request Generation Timing
Error Detection
Select Function
i = 0 to 2, 5 to 7 NOTES: 1. If an overrun error occurs, the receive data of the UiRB register will be indeterminate. The IR bit in the SiRIC register does not change. 2. Bits U0IRS and U1IRS are bits 0 and 1 in the UCON register. Bits U2IRS, U5IRS, U6IRS, and U7IRS are in registers U2C1, U5C1, U6C1, and U7C1. 3. The timing at which the framing error flag and the parity error flag are set is detected when data is transferred from the UARTi receive register to the UiRB register.
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17. Serial Interface
Table 17.6
Registers to Be Used and Settings in UART Mode
Register UiTB 0 to 8 UiRB 0 to 8
Bit Set transmission data
(1)
Function Reception data can be read (1) Error flag Set a bit rate Set these bits to 100b when transfer data is 7 bits long Set these bits to 101b when transfer data is 8 bits long Set these bits to 110b when transfer data is 9 bits long Select the internal clock or external clock Select the stop bit Select whether parity is included and whether odd or even Select the TXD / RXD input / output polarity Select the count source for the UiBRG register Select CTS or RTS to use functions Transmit register empty flag Enable or disable the CTS or RTS function Select TXDi pin output mode (3) Set to 0 LSB first or MSB first can be selected when transfer data is 8 bits long. Set this bit to 0 when transfer data is 7 or 9 bits long. Set this bit to 1 to enable transmission Transmit buffer empty flag Set this bit to 1 to enable reception Reception complete flag Select the source of UARTi transmit interrupt Set to 0 Set this bit to 1 to use reversed data logic Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Select the source of UART0 / UART1 transmit interrupt Set to 0 Invalid because CLKMD1 = 0 Set to 0 Set this bit to 1 to accept as input CTS0 signal of UART0 from the P6_4 pin Set to 0
UiBRG UiMR
OER, FER, PER, SUM 0 to 7 SMD2 to SMD0
UiC0
CKDIR STPS PRY, PRYE IOPOL CLK0, CLK1 CRS TXEPT CRD NCH CKPOL UFORM
UiC1
TE TI RE RI UiIRS (2)
UiRRM (2) UiLCH UiERE UiSMR 0 to 7 UiSMR2 0 to 7 UiSMR3 0 to 7 UiSMR4 0 to 7 UCON U0IRS, U1IRS U0RRM, U1RRM CLKMD0 CLKMD1 RCSP 7
i = 0 to 2, 5 to 7 NOTES: 1. The bits used for transmit / receive data are as follows: bit 0 to bit 6 when transfer data is 7 bits long; bit 0 to bit 7 when transfer data is 8 bits long; bit 0 to bit 8 when transfer data is 9 bits long. 2. Set the bit 4 and bit 5 in registers U0C1 and U1C1 to 0. Bits U0IRS, U1IRS, U0RRM, and U1RRM are included in the UCON register. 3. TXD2 pin is N channel open-drain output. Set the NCH bit in the U2C0 register to 0.
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17. Serial Interface
Table 17.7 lists the functions of the input / output pins during UART mode. Table 17.8 lists the P6_4 Pin Functions in UART Mode. Note that for a period from when the UARTi operating mode is selected to when transfer starts, the TXDi pin outputs "H" (If the N-channel open-drain output is selected, this pin is in high-impedance state).
Table 17.7 I/O Pin Functions in UART Mode
Pin Name TXDi RXDi
Function Serial data output Serial data input
Method of Selection ("H" output when performing reception only) Set the port direction bit corresponding to the RXDi pin to 0 (can be used as an input port when performing transmission only) The CKDIR bit in the UiMR register = 0 The CKDIR bit in the UiMR register = 1 Set the port direction bit corresponding to the CLKi pin to 0 The CRD bit in the UiC0 register = 0 The CRS bit in the UiC0 register = 0 Set the port direction bit corresponding to the CTSi pin to 0 The CRD bit in the UiC0 register = 0 The CRS bit in the UiC0 register = 1 The CRD bit in the UiC0 register = 1
CLKi
Input / output port Transfer clock input
CTSi / RTSi
CTS input
RTS input
Input / output port i = 0 to 2 , 5 to 7
Table 17.8
P6_4 Pin Functions in UART Mode
Bit Set Value Pin Function P6_4
CTS1 RTS1 CTS0
(1)
U1C0 Register CRD 1 0 0 0 0 1 0 CRS 0 0 0 1
UCON Register RCSP 0 0 0 0 CLKMD1 0 0
PD6 Register PD6_4 Input: 0, Output: 1
- indicates either 0 or1. NOTE: 1. In addition to this, set the CRD bit in the U0C0 register to 0 (CTS0 / RTS0 enabled) and the CRS bit in the U0C0 register to 1 (RTS0 selected).
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17. Serial Interface
(1) 8-bit Data Transmit Timing (with a Parity and 1 Stop Bit)
The transfer clock stops once because an "H" signal is applied to the CTS pin when the stop bit is verified. The transfer clock resumes running as soon as an "L" signal is applied to the CTS pin.
Tc
Transfer clock TE bit in UiC1 register TI bit in UiC1 register
"1" "0" "1" "0" "H"
Data is set in the UiTB register
Data is transferred from the UiTB register to the UARTi transmit register
CTSi
"L" Start bit Parity bit
D1 D2 D3 D4 D5 D6 D7 P SP
Stop bit
ST D0 D1 D2 D3 D4 D5
Pulse stops because the TE bit is set to 0
D6 D7 P SP ST D0 D1
TXDi
TXEPT bit in UiC0 register IR bit in SiTIC register
"1" "0" "1" "0"
ST
D0
Set to 0 by an interrupt request acknowledgement or by program
i = 0 to 2, 5 to 7 The above timing diagram applies to the case where the register bits are set as follows: * The PRYE bit in the UiMR register = 1 (parity enabled) * The STPS bit in the UiMR register = 0 (1 stop bit) * The CRD bit in the UiC0 register = 0 (CTS / RTS enabled) and the CRS bit = 0 (CTS selected) * The UiIRS bit in the UiC1 register = 1 (an interrupt request occurs when transmit completed) Tc = 16 (n + 1) / fj or 16 (n + 1) / fEXT fj : frequency of UiBRG count source (f1SIO, f2SIO, f8SIO, f32SIO) fEXT : frequency of UiBRG count source (external clock) n : value set to UiBRG
(2) 9-bit Data Transmit Timing (with No Parity and 2 Stop Bits) Tc
Transfer clock TE bit in UiC1 register TI bit in UiC1 register
"1" "0" "1" "0" Stop bit
D1 D2 D3 D4 D5 D6 D7 D8 SP SP
Data is set in the UiTB register
Data is transferred from the UiTB register to the UARTi transmit register
Start bit Stop bit
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP SP ST D0 D1
TXDi
TXEPT bit in UiC0 register IR bit in SiTIC register
"1" "0" "1" "0"
ST
D0
Set to 0 by an interrupt request acknowledgement or by program
i = 0 to 2, 5 to 7 The above timing diagram applies to the case where the register bits are set as follows: * The PRYE bit in the UiMR register = 0 (parity disabled) * The STPS bit in the UiMR register = 1 (2 stop bits) * The CRD bit in the UiC0 register = 1 (CTS / RTS disabled) * The UiIRS bit in the UiC1 register = 0 (an interrupt request occurs when transmit buffer becomes empty)
TC = 16 (n + 1) / fj or 16 (n + 1) / fEXT fj : frequency of UiBRG count source (f1SIO, f2SIO, f8SIO, f32SIO) fEXT: frequency of UiBRG count source (external clock) n : value set to UiBRG
Figure 17.18 Transmit Timing in UART Mode
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17. Serial Interface
Example of Receive Timing When Transfer Data is 8 Bits Long (Parity Disabled, One Stop Bit)
UiBRG count source RE bit in UiC1 register RXDi
"1" "0"
Stop bit Start bit Sampled "L"
D0 D1 D7
Receive data taken in
Transferred from UARTi receive register to UiRB register
Transfer clock RI bit in UiC1 register RTSi IR bit in SiRIC register
"1" "0" "H" "L" "1" "0"
Reception triggered when transfer clock is generated by falling edge of start bit
Set to 0 by an interrupt request acknowledgement or by program
The above timing diagram applies to the case where the register bits are set as follows: * The PRYE bit in the UiMR register = 0 (parity disabled) * The STPS bit in the UiMR register = 0 (1 stop bit) * The CRD bit in the UiC0 register = 0 (CTSi / RTSi enabled) and the CRS bit = 1 (RTSi selected) i = 0 to 2, 5 to 7
Figure 17.19 Receive Timing in UART Mod
17.1.2.1
Bit Rate
In UART mode, the frequency set by the UiBRG register (i = 0 to 2, 5 to 7) divided by 16 become bit rates. Table 17.9 lists an Example of Bit Rates and Settings.
Table 17.9 Example of Bit Rates and Settings
Bit Rate (bps) 1200 2400 4800 9600 14400 19200 28800 31250 38400 51200
Count Source of UiBRG f8SIO f8SIO f8SIO f1SIO f1SIO f1SIO f1SIO f1SIO f1SIO f1SIO
Peripheral Function Clock: 16 Peripheral Function Clock: 24 MHz MHz Set Value of Bit Rate (bps) Set value of Bit Rate (bps) UiBRG: n UiBRG: n 103 (67h) 1202 155 (9Bh) 1202 51 (33h) 2404 77 (4Dh) 2404 25 (19h) 4808 38 (26h) 4808 103 (67h) 9615 155 (9Bh) 9615 68 (44h) 14493 103 (67h) 14423 51 (33h) 19231 77 (4Dh) 19231 34 (22h) 28571 51 (33h) 28846 31 (1Fh) 31250 47 (2Fh) 31250 25 (19h) 38462 38 (26h) 38462 19 (13h) 50000 28 (1Ch) 51724
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17. Serial Interface
17.1.2.2
Counter Measure for Communication Error
If a communication error occurs while transmitting or receiving in UART mode, follow the procedures below. * Resetting the UiRB register (i = 0 to 2, 5 to 7) (1) Set the RE bit in the UiC1 register to 0 (reception disabled) (2) Set the RE bit in the UiC1 register to 1 (reception enabled) * Resetting the UiTB register (1) Set bits SMD2 to SMD0 in the UiMR register to 000b (serial interface disabled) (2) Reset bits SMD2 to SMD0 in the UiMR register to 001b, 101b, and 110b. (3) 1 is written to the RE bit in the UiC1 register (transmission enabled), regardless of the TE bit in the UiC1 register
17.1.2.3
LSB First / MSB First Select Function
As shown in Figure 17.20, use the UFORM bit in the UiC0 register to select the transfer format. This function is valid when transfer data is 8 bits long.
(1) When the UFORM Bit in the UiC0 Register = 0 (LSB First)
CLKi TXDi RXDi ST ST D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 P P SP SP
(2) When the UFORM Bit in the UiC0 Register = 1 (MSB First)
CLKi TXDi RXDi ST ST D7 D7 D6 D6 D5 D5 D4 D4 D3 D3 D2 D2 D1 D1 D0 D0 P P SP SP
ST : start bit P : parity bit SP : stop bit i = 0 to 2, 5 to 7 The above applies to the case where the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock), the UiLCH bit in the UiC1 register = 0 (no reverse), the STPS bit in the UiMR register = 0 (1 stop bit), and the PRYE bit in the UiMR register = 1 (parity enabled).
Figure 17.20 Transfer Format
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17. Serial Interface
17.1.2.4
Serial Data Logic Switching Function
The data written to the UiTB register has its logic reversed before being transmitted. Similarly, the received data has its logic reversed when read from the UiRB register. Figure 17.21 shows Serial Data Logic Switching.
(1) When the UiLCH bit in the UiC1 Register = 0 (No Reverse)
Transfer "L" Clock "H" TXDi (No Reverse) "L"
"H"
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
(2) When the UiLCH Bit in the UiC1 Register = 1 (Reverse)
Transfer Clock TXDi (Reverse)
"H" "L" "H" "L"
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
ST : start bit P : parity bit SP : stop bit i = 0 to 2, 5 to 7 The above applies to the case where the CKPOL bit in the UiC0 register the UFORM bit in the UiC0 register the STPS bit in the UiMR register the PRYE bit in the UiMR register = 0 (transmit data output at the falling edge of the transfer clock), = 0 (LSB first), = 0 (1 stop bit), and = 1 (parity enabled).
Figure 17.21 Serial Data Logic Switching
17.1.2.5
TXD and RXD I/O Polarity Reverse Function
This function reverses the polarities of the TXDi pin output and RXDi pin input. The logic levels of all input / output data (including bits for start, stop, and parity) are reversed. Figure 17.22 shows the TXD and RXD I/O Polarity Reverse.
(1) When the IOPOL Bit in the UiMR Register = 0 (No Reverse)
Transfer "L" Clock "H" TXDi (No Reverse) "L" "H" RXDi (No Reverse) "L"
"H"
ST ST
D0 D0
D1 D1
D2 D2
D3 D3
D4 D4
D5 D5
D6 D6
D7 D7
P P
SP SP
(2) When the IOPOL Bit in the UiMR Register = 1 (Reverse)
Transfer Clock TXDi (Reverse) RXDi (Reverse)
"H" "L" "H" "L" "H" "L"
ST ST
D0 D0
D1 D1
D2 D2
D3 D3
D4 D4
D5 D5
D6 D6
D7 D7
P P
SP SP
ST: start bit P : parity bit SP: stop bit i = 0 to 2, 5 to 7
The above applies to the case where the UFORM bit in the UiC0 register = 0 (LSB first), the STPS bit in the UiMR register = 0 (1 stop bit), and the PRYE bit in the UiMR register = 1 (parity enabled).
Figure 17.22 TXD and RXD I/O Polarity Reverse
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17. Serial Interface
17.1.2.6
CTS / RTS Function
The CTS function is used to start transmit operation when "L" is applied to the CTSi / RTSi (i = 0 to 2, 5 to 7) pin. Transmit operation begins when the CTSi / RTSi pin is held "L". If the "L" signal is switched to "H" during a transmit operation, the operation stops after the ongoing transmit / receive operation is completed. When the RTS function is used, the CTSi / RTSi pin outputs "L" when the microcomputer is ready to receive. The output level becomes "H" on the first falling edge of the CLKi pin. * CRD bit in the UiC0 register = 1 (disable CTS / RTS function) CTSi / RTSi pin is programmable I/O function * The CRD bit = 0, the CRS bit = 0 (CTS function is selected) CTSi / RTSi pin is CTS function * The CRD bit = 0, the CRS bit = 1 (RTS function is selected) CTSi / RTSi pin is RTS function
17.1.2.7
CTS / RTS Separate Function (UART0)
This function separates CTS0 / RTS0, outputs RTS0 from the P6_0 pin, and inputs CTS0 from the P6_4 pin. To use this function, set the register bits as shown below. * The CRD bit in the U0C0 register = 0 (enable CTS / RTS of UART0) * The CRS bit in the U0C0 register = 1 (output RTS of UART0) * The CRD bit in the U1C0 register = 0 (enable CTS / RTS of UART1) * The CRS bit in the U1C0 register = 0 (input CTS of UART1) * The RCSP bit in the UCON register = 1 (inputs CTS0 from the P6_4 pin) * The CLKMD1 bit in the UCON register = 0 (CLKS1 not used) Note that when using the CTS / RTS separate function, CTS / RTS of UART1 function cannot be used.
microcomputer
TXD0 (P6_3) RXD0 (P6_2) IN OUT
IC
RTS0 (P6_0) CTS0 (P6_4)
CTS RTS
Figure 17.23 CTS / RTS Separate Function
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17. Serial Interface
17.1.3
Special Mode 1 (I2C mode)
I2C mode is provided for use as a simplified I2C interface compatible mode. Table 17.10 lists the specifications of I2C mode. Tables 17.11 and 17.12 list the registers used in I2C mode and the register values set. Table 17.13 lists the I2C Mode Functions. Figure 17.24 shows the block diagram for I2C mode. Figure 17.25 shows Transfer to UiRB Register and Interrupt Timing. As shown in Table 17.13, the microcomputer is placed in I2C mode by setting bits SMD2 to SMD0 to 010b and the IICM bit to 1. Because SDAi transmit output has a delay circuit attached, SDAi output does not change state until SCLi goes low and remains stably low.
Table 17.10 I2C Mode Specifications
Item Transfer Data Format Transfer Clock
Specification Transfer data length: 8 bits * During master CKDIR bit in the UiMR register = 0 (internal clock): fj / (2(n+1)) fj = f1SIO, f2SIO, f8SIO, f32SIO n = setting value of the UiBRG register 00h to FFh * During slave CKDIR bit = 1 (external clock): input from the SCLi pin Before transmission starts, satisfy the following requirements (1) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in UiTB register) Before reception starts, satisfy the following requirements (1) * The RE bit in the UiC1 register = 1 (reception enabled) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in the UiTB register) When start or stop condition is detected, acknowledge undetected, or acknowledge detected Overrun error (2) This error occurs if the serial interface started receiving the next data before reading the UiRB register and received the 8th bit of the next data * Arbitration lost Timing at which the ABT bit in the UiRB register is updated can be selected * SDAi digital delay No digital delay or a delay of 2 to 8 UiBRG count source clock cycles selectable * Clock phase setting With or without clock delay selectable
Transmission Start Condition Reception Start Condition
Interrupt Request Generation Timing Error Detection
Select Function
i = 0 to 2, 5 to 7 NOTES: 1. When an external clock is selected, the conditions must be met while the external clock is in high state. 2. If an overrun error occurs, the received data of the UiRB register will be indeterminate. The IR bit in the SiRIC register does not change.
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17. Serial Interface
SDAi Delay circuit STSPSEL = 1 STSPSEL = 0 ACKC = 0 SDHI
DQ T
Start and stop condition generation block SDA (STSP) SCL (STSP)
IICM2 = 1
DMA0 to DMA3 request
ACKC = 1
Transmission register UARTi
IICM = 1 and IICM2 = 0
UARTi transmit, NACK interrupt request
ACKD bit
ALS DMA0, DMA2 request
IICM2 = 1
Arbitration
Reception register UARTi
Noise filter
Start condition detection
S R Q
IICM = 1 and IICM2 = 0
UARTi receive, ACK interrupt request, DMA1, DMA3 request
Bus busy
NACK
Stop condition detection
DQ T DQ T
SCLi
Falling edge detection IICM = 0
R
Port register (1) Internal clock SWC2 External clock
R S
ACK
I/O port
Q
9th bit
STSPSEL=0 UARTi STSPSEL IICM = 1 =1
Noise filter
CLK control UARTi 9th bit falling edge SWC
Start / stop condition detection interrupt request
This diagram applies to the case where bits SMD2 to SMD0 in the UiMR register = 010b and the IICM bit in the UiSMR register = 1. IICM : bit in the UiSMR register IICM2, SWC, ALS, SWC2, SDHI : bits in the UiSMR2 register STSPSEL, ACKD, ACKC : bits in the UiSMR4 register i = 0 to 2, 5 to 7 If the IICM bit = 1, the pin can be read even when the port direction bit corresponding to the SCLi pin = 1 (output mode).
Figure 17.24 I2C Mode Block Diagram
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17. Serial Interface
Table 17.11
Register UiTB UiRB (3)
Registers to Be Used and Settings in I2C Mode (1)
Bit Function Master Set transmission data Reception data can be read ACK or NACK is set in this bit Arbitration lost detection flag Overrun error flag Set a bit rate Set to 010b Set to 0 Set to 0 Select the count source for the UiBRG register Invalid because CRD = 1 Transmit register empty flag Set to 1 Set to 1 (2) Set to 0 Set to 1 Set this bit to 1 to enable transmission Transmit buffer empty flag Set this bit to 1 to enable reception Reception complete flag Invalid Set to 0 Slave Set transmission data Reception data can be read ACK or NACK is set in this bit Invalid Overrun error flag Invalid Set to 010b Set to 1 Set to 0 Invalid Invalid because CRD = 1 Transmit register empty flag Set to 1 Set to 1 (2) Set to 0 Set to 1 Set this bit to 1 to enable transmission Transmit buffer empty flag Set this bit to 1 to enable reception Reception complete flag Invalid Set to 0
UiBRG UiMR (3)
UiC0
0 to 7 0 to 7 8 ABT OER 0 to 7 SMD2 to SMD0 CKDIR IOPOL CLK1, CLK0 CRS TXEPT CRD (4) NCH CKPOL UFORM TE TI RE RI UiIRS (1) UiRRM (1), UiLCH, UiERE IICM ABC BBS 3 to 7 IICM2 CSC SWC ALS STAC SWC2 SDHI 7
UiC1
UiSMR
Set to 1 Select the timing at which arbitration lost is detected Bus busy flag Set to 0 See Table 17.13 I2C Mode Functions Set this bit to 1 to enable clock synchronization Set this bit to 1 to have SCLi output fixed to "L" at the falling edge of the 9th bit of clock Set this bit to 1 to have SDAi output stopped when arbitration lost is detected Set to 0 Set this bit to 1 to have SCLi output forcibly pulled low Set this bit to 1 to disable SDAi output Set to 0
Set to 1 Invalid Bus busy flag Set to 0 See Table 17.13 I2C Mode Functions Set to 0 Set this bit to 1 to have SCLi output fixed to "L" at the falling edge of the 9th bit of clock Set to 0 Set this bit to 1 to initialize UARTi at start condition detection Set this bit to 1 to have SCLi output forcibly pulled low Set this bit to 1 to disable SDAi output Set to 0
UiSMR2
i = 0 to 2, 5 to 7 NOTES: 1. Set the bit 4 and bit 5 in registers U0C1 and U1C1 to 0. Bits U0IRS, U1IRS, U0RRM, and U1RRM are in the UCON register. 2. The TXD2 pin is N channel open-drain output. No NCH bit in the U2C0 register is assigned. When write, set to 0. 3. Set the bits not listed above to 0 when writing to the registers in I2C mode. 4. When using UART1 in I2C mode and enabling the CTS / RTS separate function of UART0, set the CRD bit in the U1C0 register to 0 (CTS / RTS enabled) and the CRS bit to 0 (CTS input).
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17. Serial Interface
Table 17.12
Registers to Be Used and Settings in I2C Mode (2)
Register
Bit Set to 0
Function Master Set to 0 See Table 17.13 "I2C Mode Functions" Set the amount of SDAi digital delay Set to 0 Set to 0 Set to 0 Set to 0 Select ACK or NACK Set this bit to 1 to output ACK data Set to 0 Slave
UiSMR3 0, 2, 4, and NODC CKPH DL2 to DL0 UiSMR4 STAREQ RSTAREQ STPREQ STSPSEL ACKD ACKC SCLHI
SWC9
See Table 17.13 "I2C Mode Functions" Set the amount of SDAi digital delay Set this bit to 1 to generate start condition Set this bit to 1 to generate restart condition Set this bit to 1 to generate stop condition Set this bit to 1 to output each condition Select ACK or NACK Set this bit to 1 to output ACK data Set this bit to 1 to have SCLi output stopped when stop condition is detected Set to 0
IFSR2A IFSR26, ISFR27 UCON U0IRS, U1IRS 2 to 7 i = 0 to 2, 5 to 7
Set to 1 Invalid Set to 0
Set this bit to 1 to set the SCLi to "L" hold at the falling edge of the 9th bit of clock Set to 1 Invalid Set to 0
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17. Serial Interface
Table 17.13
Function
I2C Mode Functions
Clock Synchronous Serial I/O Mode (SMD2 to SMD0 = 001b, IICM = 0)
I2C Mode (SMD2 to SMD0 = 010b, IICM = 1) IICM2 = 0 (NACK/ACK interrupt) CKPH = 0 (No clock delay) CKPH = 1 (Clock delay) IICM2 = 1 (UART transmit / receive interrupt) CKPH = 0 (No clock delay) CKPH = 1 (Clock delay)
Factor of Interrupt Number 5, 6, 7, 10, 27, and 28 (1, 5, 7)) Factor of Interrupt Number 15, 17, 19, 21, 23, and 24 (1,
6)
-
Start condition detection or stop condition detection (See Table 17.14 "STSPSEL Bit Functions") No acknowledgment detection (NACK) Rising edge of SCLi 9th bit UARTi transmission Rising edge of SCLi 9th bit UARTi transmission Falling edge of SCLi next to the 9th bit
UARTi transmission Transmission started or completed (selected by UiIRS)
Factor of Interrupt Number 16, 18, 20, 22, 25, and 26 (1,
6)
UARTi reception Acknowledgment detection (ACK) When 8th bit received Rising edge of SCLi 9th bit CKPOL = 0 (rising edge) CKPOL = 1 (falling edge) CKPOL = 0 (rising edge) Rising edge of SCLi 9th bit CKPOL = 1 (falling edge)
UARTi reception Falling edge of SCLi 9th bit
Timing for Transferring Data from the UART Reception Shift Register to the UiRB Register UARTi Transmission Output Delay Functions of TXDi / SDAi Functions of RXDi / SCLi Functions of CLKi Noise Filter Width Read RXDi and SCLi Pin Levels Initial Value of TXDi and SDAi Outputs Initial and End Values of SCLi DMA1 Factor (6) Store Received Data
Falling edge of SCLi 9th bit
Falling and rising edges of SCLi 9th bit
Not delayed TXDi output RXDi input CLKi input or output port selected 15ns Possible when the corresponding port direction bit = 0 CKPOL = 0 ("H") CKPOL = 1 ("L") UARTi reception 1st to 8th bits of the received data are stored into bits 0 to 7 in the UiRB register
Delayed SDAi input / output SCLi input / output
- (Cannot be used in I2C mode)
200ns Always possible no matter how the corresponding port direction bit is set
The value set in the port register before setting I2C mode (2) "H" "L" "H" "L"
Acknowledgment detection (ACK) 1st to 8th bits of the received data are stored into bits 7 to 0 in the UiRB register
UARTi reception Falling edge of SCLi 9th bit 1st to 7th bits of the received data are stored into bits 6 to 0 in the UiRB register. 8th bit is stored into bit 8 in the UiRB register 1st to 8th bits are stored into bits 7 to 0 in the UiRB register (3) Bits 6 to 0 in the UiRB register are read as bits 7 to 1. Bit 8 in the UiRB register is read as bit 0 (4)
Read Received Data
The UiRB register status is read
i = 0 to 2, 5 to 7 NOTES: 1. If the source or factor of any interrupt is changed, the IR bit in the interrupt control register for the changed interrupt may inadvertently be set to 1 (interrupt requested). (Refer to 24.7 "Interrupt") If one of the bits shown below is changed, the interrupt source, the interrupt timing, etc. change. Therefore, always be sure to clear the IR bit to 0 (interrupt not requested) after changing those bits. Bits SMD2 to SMD0 in the UiMR register, the IICM bit in the UiSMR register, the IICM2 bit in the UiSMR register, and the CKPH bit in the UiSMR3 register 2. Set the initial value of SDAi output while bits SMD2 to SMD0 in the UiMR register = 000b (serial interface disabled). 3. Second data transfer to the UiRB register (rising edge of SCLi 9th bit) 4. First data transfer to the UiRB register (falling edge of SCLi 9th bit) 5. See Figure 17.27 "STSPSEL Bit Functions". 6. See Figure 17.25 "Transfer to UiRB Register and Interrupt Timing". 7. When using UART0, be sure to set the IFSR26 bit in the IFSR2A register to 1 (factor of interrupt: UART0 bus collision). When using UART1, be sure to set the IFSR27 bit in the IFSR2A register to 1 (factor of interrupt: UART1 bus collision).
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17. Serial Interface
(1) IICM2 = 0 (ACK and NACK interrupts), CKPH = 0 (no clock delay)
1st bit 2nd bit 3rd bit 4th bit 5th bit 6th bit 7th bit 8th bit 9th bit
SCLi SDAi D7 D6 D5 D4 D3 D2 D1 D0 D8 (ACK, NACK)
ACK interrupt (DMA1, DMA3 request), NACK interrupt Transfer to UiRB register
b15 b9 b8 D8 b7 D7 D6 D5 D4 D3 D2 D1 b0 D0
...
UiRB register
(2) IICM2 = 0, CKPH = 1 (clock delay)
1st bit 2nd bit 3rd bit 4th bit 5th bit 6th bit 7th bit 8th bit 9th bit
SCLi SDAi D7 D6 D5 D4 D3 D2 D1 D0 D8 (ACK, NACK)
ACK interrupt (DMA1, DMA3 request), NACK interrupt Transfer to UiRB register
b15 b9 b8 D8 b7 D7 D6 D5 D4 D3 D2 D1 b0 D0
...
UiRB register
(3) IICM2 = 1 (UART transmit / receive interrupt), CKPH = 0
1st bit 2nd bit 3rd bit 4th bit 5th bit 6th bit 7th bit 8th bit 9th bit
SCLi SDAi D7 D6 D5 D4 D3 D2 D1 D0 D8 (ACK, NACK)
Receive interrupt Transmit (DMA1, DMA3 interrupt request) Transfer to UiRB register
b15 b9 b8 D0 b7 D7 D6 D5 D4 D3 D2 b0 D1
...
UiRB register
(4) IICM2 = 1, CKPH = 1
1st bit 2nd bit 3rd bit 4th bit 5th bit 6th bit 7th bit 8th bit 9th bit
SCLi SDAi D7 D6 D5 D4 D3 D2 D1 D0 D8 (ACK, NACK)
Transmit interrupt
Receive interrupt (DMA1, DMA3 request) Transfer to UiRB register
b15 b9 b8 D0 b7 D7 D6 D5 D4 D3 D2 b0 D1
Transfer to UiRB register
b15 b9 b8 D8 b7 D7 D6 D5 D4 D3 D2 D1 b0 D0
...
...
i = 0 to 2, 5 to 7
UiRB register
UiRB register
This diagram applies to the case where the following condition is met. * The CKDIR bit in the UiMR register = 0 (slave selected)
Figure 17.25 Transfer to UiRB Register and Interrupt Timing
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17. Serial Interface
17.1.3.1
Detection of Start and Stop Condition
Whether a start or a stop condition has been detected is determined. A start condition detect interrupt request is generated when the SDAi pin changes state from high to low while the SCLi pin is in the high state. A stop condition detect interrupt request is generated when the SDAi pin changes state from low to high while the SCLi pin is in the high state. Because the start and stop condition detect interrupts share the interrupt control register and vector, check the BBS bit in the UiSMR register to determine which interrupt source is requesting the interrupt.
3 to 6 cycles < duration for setting-up 3 to 6 cycles < duration for holding (1)
(1)
Duration for setting up
SCLi
Duration for holding
(Start condition)
SDA i
SDAi
(Stop condition) i = 0 to 2, 5 to 7 When the PCLK1 bit in the PCLKR register = 1, this is the cycle number of f1SIO, and the PCLK1 bit = 0, the cycle number of f2SIO.
Figure 17.26 Detection of Start and Stop Condition
17.1.3.2
Output of Start and Stop Condition
A start condition is generated by setting the STAREQ bit in the UiSMR4 register (i = 0 to 2, 5 to 7) to 1 (start). A restart condition is generated by setting the RSTAREQ bit in the UiSMR4 register to 1 (start). A stop condition is generated by setting the STPREQ bit in the UiSMR4 register to 1 (start). The output procedure is described below. (1) Set the STAREQ bit, RSTAREQ bit or STPREQ bit to 1 (start). (2) Set the STSPSEL bit in the UiSMR4 register to 1 (output). The function of the STSPSEL bit is shown in Tables 17.14 and 17.27.
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17. Serial Interface
Table 17.14
STSPSEL Bit Functions
Function Output of Pins SCLi and SDAi
Start / Stop Condition Interrupt Request Generation Timing
STSPSEL = 0 Output of transfer clock and data Output of start / stop condition is accomplished by a program using ports (not automatically generated in hardware) Detect start / stop condition
STSPSEL = 1 Output of a start / stop condition according to bits STAREQ, RSTAREQ, and STPREQ
Complete generating start / stop condition
(1) When Slave CKDIR = 1 (external clock)
STSPSEL bit SCLi SDAi 0
1st 2nd 3rd 4th 5th 6th 7th 8th 9th bit
Start condition detection interrupt
Stop condition detection interrupt
(2) When Master CKDIR = 0 (internal clock), CKPH = 1 (clock delayed)
STSPSEL bit
Set to 1 in a program
SCLi SDAi
Set to 0 in a program
Set to 1 in a program
Set to 0 in a program
1st 2nd 3rd 4th 5th 6th 7th 8th 9th bit
Set STAREQ = 1 (start) i = 0 to 2, 5 to 7
Start condition detection interrupt
Set STPREQ=1 Stop condition detection (start) interrupt
Figure 17.27 STSPSEL Bit Functions
17.1.3.3
Arbitration
Unmatching of the transmit data and SDAi pin input data is checked synchronously with the rising edge of SCLi. Use the ABC bit in the UiSMR register to select the timing at which the ABT bit in the UiRB register is updated. If the ABC bit = 0 (update per bit), the ABT bit is set to 1 at the same time unmatching is detected during check, and is cleared to 0 when not detected. In cases when the ABC bit is set to 1, if unmatching is ever detected, the ABT bit is set to 1 (unmatching detected) at the falling edge of the clock pulse of 9th bit. If the ABT bit needs to be updated per byte, clear the ABT bit to 0 (undetected) after detecting acknowledge in the first byte, before transferring the next byte. Setting the ALS bit in the UiSMR2 register to 1 (SDA output stop enabled) factors arbitration-lost to occur, in which case the SDAi pin is placed in the high-impedance state at the same time the ABT bit is set to 1 (unmatching detected).
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17. Serial Interface
17.1.3.4
Transfer Clock
The transfer clock is used to transmit and receive data as is shown in Figure 17.25 Transfer to UiRB Register and Interrupt Timing. The CSC bit in the UiSMR2 register is used to synchronize the internally generated clock (internal SCLi) and an external clock supplied to the SCLi pin. In cases when the CSC bit is set to 1 (clock synchronization enabled), if a falling edge on the SCLi pin is detected while the internal SCLi is high, the internal SCLi goes low, at which time the value of the UiBRG register is reloaded with and starts counting in the low-level interval. If the internal SCLi changes state from low to high while the SCLi pin is low, counting stops, and when the SCLi pin goes high, counting restarts. In this way, the UARTi transfer clock is equivalent to AND of the internal SCLi and the clock signal applied to the SCLi pin. The transfer clock works between a half cycle before the falling edge of the internal SCLi 1st bit and the rising edge of the 9th bit. To use this function, select an internal clock for the transfer clock. The SWC bit in the UiSMR2 register determines whether the SCLi pin is fixed to be or freed from lowlevel output at the falling edge of the 9th clock pulse. If the SCLHI bit in the UiSMR4 register is set to 1 (enabled), SCLi output is turned off (placed in the high-impedance state) when a stop condition is detected. Setting the SWC2 bit in the UiSMR2 register = 1 (0 output) makes it possible to forcibly output a lowlevel signal from the SCLi pin even while sending or receiving data. Clearing the SWC2 bit to 0 (transfer clock) allows the transfer clock to be output from or supplied to the SCLi pin, instead of outputting a low-level signal. If the SWC9 bit in the UiSMR4 register is set to 1 (SCL hold low enabled) when the CKPH bit in the UiSMR3 register = 1, the SCLi pin is fixed to low-level output at the falling edge of the clock pulse next to the 9th. Setting the SWC9 bit = 0 (SCL hold low disabled) frees the SCLi pin from low-level output.
17.1.3.5
SDA Output
The data written to bits 7 to 0 (D7 to D0) in the UiTB register is output in descending order from D7. The 9th bit (D8) is ACK or NACK. Set the initial value of SDAi transmit output when IICM = 1 (I2C mode) and bits SMD2 to SMD0 in the UiMR register = 000b (serial interface disabled). Bits DL2 to DL0 in the UiSMR3 register allow to add no delays or a delay of 2 to 8 UiBRG count source clock cycles to SDAi output. Setting the SDHI bit in the UiSMR2 register = 1 (SDA output disabled) forcibly places the SDAi pin in the high-impedance state. Do not write to the SDHI bit at the rising edge of the UARTi transfer clock. This is because the ABT bit may inadvertently be set to 1 (detected).
17.1.3.6
SDA Input
When the IICM2 bit = 0, the 1st to 8th bits (D7 to D0) of received data are stored in bits 7 to 0 in the UiRB register. The 9th bit (D8) is ACK or NACK. When the IICM2 bit = 1, the 1st to 7th bits (D7 to D1) of received data are stored in bits 6 to 0 in the UiRB register and the 8th bit (D0) is stored in bit 8 in the UiRB register. Even when the IICM2 bit = 1, providing the CKPH bit = 1, the same data as when the IICM2 bit = 0 can be read. To read the data, read the UiRB register after the rising edge of 9th bit of the corresponding clock pulse.
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17. Serial Interface
17.1.3.7
ACK and NACK
If the STSPSEL bit in the UiSMR4 register is set to 0 (start and stop conditions not generated) and the ACKC bit in the UiSMR4 register is set to 1 (ACK data output), the value of the ACKD bit in the UiSMR4 register is output from the SDAi pin. If the IICM2 bit = 0, the NACK interrupt request is generated if the SDAi pin remains high at the rising edge of the 9th bit of transmit clock pulse. The ACK interrupt request is generated if the SDAi pin is low at the rising edge of the 9th bit of transmit clock pulse. If ACKi is selected to generate a DMA1 or DMA3 request source, a DMA transfer can be activated by detection of an acknowledge.
17.1.3.8
Initialization of Transmission / Reception
If a start condition is detected while the STAC bit = 1 (UARTi initialization enabled), the serial interface operates as described below. * The transmit shift register is initialized, and the content of the UiTB register is transferred to the transmit shift register. In this way, the serial interface starts sending data synchronously with the next clock pulse applied. However, the UARTi output value does not change state and remains the same as when a start condition was detected until the first bit of data is output synchronously with the input clock. * The receive shift register is initialized, and the serial interface starts receiving data synchronously with the next clock pulse applied. * The SWC bit is set to 1 (SCL wait output enabled). Consequently, the SCLi pin is pulled low at the falling edge of the 9th clock pulse. Note that when UARTi transmission / reception is started using this function, the TI bit does not change state. Select the external clock as the transfer clock to start UARTi transmission / reception with this setting.
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17. Serial Interface
17.1.4
Special Mode 2
In special mode 2, serial communication between one or multiple masters and multiple slaves is available. Transfer clock polarity and phase are selectable. Table 17.15 lists the Special Mode 2 Specifications. Table 17.16 lists the Registers to Be Used and Settings in Special Mode 2. Figure 17.28 shows Special Mode 2 Communication Control Example (UART2).
Table 17.15 Special Mode 2 Specifications
Item Transfer Data Format Transfer Clock Specification Transfer data length: 8 bits * Master mode The CKDIR bit in the UiMR register = 0 (internal clock): fj / (2(n + 1)) fj = f1SIO, f2SIO, f8SIO, f32SIO n: setting value of UiBRG register 00h to FFh * Slave mode * The CKDIR bit = 1 (external clock selected): input from the CLKi pin Controlled by input / output ports Before transmission starts, satisfy the following requirements (1) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in UiTB register) Before reception starts, satisfy the following requirements (1)
Transmit / Receive Control Transmission Start Condition
Reception Start Condition
* The RE bit in the UiC1 register * The TE bit * The TI bit
Interrupt Request Generation Timing
= 1 (reception enabled) = 1 (transmission enabled) = 0 (data present in the UiTB register)
While transmitting, one of the following conditions can be selected * The UiIRS bit in the UiC1 register= 0 (transmit buffer empty): when transferring data from the UiTB register to the UARTi transmit register (at start of transmission) * The UiIRS bit =1 (transfer completed): when the serial interface completed sending data from the UARTi transmit register While receiving * When transferring data from the UARTi receive register to the UiRB register (at completion of reception)
Error Detection
Overrun error (2)
This error occurs if the serial interface starts receiving the next data before reading the UiRB register and receives the 7th bit of the next data Clock phase setting Selectable from four combinations of transfer clock polarities and phases
Select Function
i = 0 to 2, 5 to 7 NOTES: 1. When an external clock is selected, the conditions must be met while if the CKPOL bit in the UiC0 register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock), the external clock is in high state; if the CKPOL bit = 1 (transmit data output at the rising edge and the receive data taken in at the falling edge of the transfer clock), the external clock is in low state. 2. If an overrun error occurs, the received data of the UiRB register will be indeterminate. The IR bit in the SiRIC register does not change.
P1_3 P1_2 P7_2(CLK2) P7_1(RXD2) P7_0(TXD2) Microcomputer (master) P9_3 P7_2(CLK2) P7_1(RXD2) P7_0(TXD2) Microcomputer (slave)
P9_3 P7_2(CLK2) P7_1(RXD2) P7_0(TXD2) Microcomputer (slave)
Figure 17.28 Special Mode 2 Communication Control Example (UART2)
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17. Serial Interface
Table 17.16
Registers to Be Used and Settings in Special Mode 2
Register UiTB UiRB
(3) (3)
Bit 0 to 7 0 to 7 OER 0 to 7 SMD2 to SMD0 CKDIR IOPOL CLK0, CLK1 CRS TXEPT CRD NCH CKPOL UFORM TE TI RE RI UiIRS (1) UiRRM (1),UiLCH, UiERE 0 to 7 0 to 7 CKPH NODC 0, 2, 4 to 7 0 to 7 U0IRS, U1IRS U0RRM, U1RRM CLKMD0 CLKMD1, RCSP, 7 Set transmission data
Function Reception data can be read Overrun error flag Set a bit rate Set to 001b Set to 0 in master mode or 1 in slave mode Set to 0 Select the count source for the UiBRG register Invalid because CRD = 1 Transmit register empty flag Set to 1 Select TXDi pin output format (2) Clock phases can be set in combination with the CKPH bit in the UiSMR3 register Set to 0 Set to 1 to enable transmission / reception Transmit buffer empty flag Set to 1 to enable reception Reception complete flag Select UART2 transmit interrupt source Set to 0 Set to 0 Set to 0 Clock phases can be set in combination with the CKPOL bit in the UiC0 register Set to 0 Set to 0 Set to 0 Select UART0 and UART1 transmit interrupt source Set to 0 Invalid because CLKMD1 = 0 Set to 0
UiBRG UiMR (3)
UiC0
UiC1
UiSMR UiSMR2 UiSMR3
UiSMR4 UCON
i = 0 to 2, 5 to 7 NOTES: 1. Set bits 4 and 5 in registers U0C0 and U1C1 to 0. Bits U0IRS, U1IRS, U0RRM, and U1RRM are in the UCON register. 2. The TXD2 pin is N channel open-drain output. No NCH bit in the U2C0 register is assigned. When write, set to 0. 3. Set the bits not listed above to 0 when writing to the registers in special mode 2.
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17. Serial Interface
17.1.4.1
Clock Phase Setting Function
One of four combinations of transfer clock phases and polarities can be selected using the CKPH bit in the UiSMR3 register and the CKPOL bit in the UiC0 register. Make sure the transfer clock polarity and phase are the same for the master and salves to be communicated. Figure 17.29 shows the Transmission and Reception Timing in Master Mode (Internal Clock). Figure 17.30 shows the Transmission and Reception Timing (CKPH = 0) in Slave Mode (External Clock) while Figure 17.31 shows the Transmission and Reception Timing (CKPH = 1) in Slave Mode (External Clock).
"H" Clock output (CKPOL = 0, CKPH = 0) "L"
Clock output "H" (CKPOL = 1, CKPH = 0) "L"
"H" Clock output (CKPOL = 0, CKPH = 1) "L" "H" Clock output (CKPOL = 1, CKPH = 1) "L" "H" "L"
Data output timing
D0
D1
D2
D3
D4
D5
D6
D7
Data input timing
Figure 17.29 Transmission and Reception Timing in Master Mode (Internal Clock)
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17. Serial Interface
Slave control input
"H" "L"
"H" Clock input (CKPOL = 0, CKPH = 0) "L"
"H" Clock input (CKPOL = 1, CKPH = 0) "L"
Data output timing
(1)
"H" "L"
undefined
D0
D1
D2
D3
D4
D5
D6
D7
Data input timing
Note: 1. UART2 output is an N-channel open drain and must be pulled-up externally.
Figure 17.30 Transmission and Reception Timing (CKPH = 0) in Slave Mode (External Clock)
Slave control input
"H" "L"
Clock input (CKPOL=0, CKPH=1)
"H" "L" "H" "L"
Clock input (CKPOL=1, CKPH=1)
Data output timing
(1)
"H" "L"
D0
D1
D2
D3
D4
D5
D6
D7
Data input timing
Note: 1. UART2 output is an N-channel open drain and must be pulled-up externally.
Figure 17.31 Transmission and Reception Timing (CKPH = 1) in Slave Mode (External Clock)
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17. Serial Interface
17.1.5
Special Mode 3 (IE mode)
In this mode, one bit of IEBus is approximated with one byte of UART mode waveform. Table 17.17 lists the Registers to Be Used and Settings in IE Mode. Figure 17.32 shows the Bus Collision Detect Function-Related Bits. If the TXDi pin (i = 0 to 2, 5 to 7) output level and RXDi pin input level do not match, a UARTi bus collision detect interrupt request is generated. Use bits IFSR26 and IFSR27 in the IFSR2A register to enable the UART0 / UART1 bus collision detect function.
Table 17.17
Register UiTB UiRB (3) UiBRG UiMR
Registers to Be Used and Settings in IE Mode
Bit 0 to 8 0 to 8 OER, FER, PER, SUM 0 to 7 SMD2 to SMD0 CKDIR STPS PRY PRYE IOPOL CLK1, CLK0 CRS TXEPT CRD NCH CKPOL UFORM TE TI RE RI UiIRS (1) UiRRM (1), UiLCH, UiERE 0 to 3, 7 ABSCS ACSE SSS 0 to 7 0 to 7 0 to 7 IFSR26, IFSR27 U0IRS, U1IRS U0RRM, U1RRM CLKMD0 CLKMD1, RCSP, 7 Function Set transmission data Reception data can be read Error flag Set a bit rate Set to 110b Select the internal clock or external clock Set to 0 Invalid because PRYE = 0 Set to 0 Select the TXD and RXD input / output polarity Select the count source for the UiBRG register Invalid because CRD = 1 Transmit register empty flag Set to 1 Select TXDi pin output format (2) Set to 0 Set to 0 Set to 1 to enable transmission Transmit buffer empty flag Set to 1 to enable reception Reception complete flag Select the source of UARTi transmit interrupt Set to 0 Set to 0 Select the sampling timing at which to detect a bus collision Set this bit to 1 to use the auto clear function of transmit enable bit Select the transmit start condition Set to 0 Set to 0 Set to 0 Set to 1 Select the source of UART0 / UART1 transmit interrupt Set to 0 Invalid because CLKMD1 = 0 Set to 0
UiC0
UiC1
UiSMR
UiSMR2 UiSMR3 UiSMR4 IFSR2A UCON
i = 0 to 2, 5 to 7 NOTES: 1. Set bits 4 and 5 in registers U0C0 and U1C1 to 0. Bits U0IRS, U1IRS, U0RRM, and U1RRM are in the UCON register. 2. The TXD2 pin is N channel open-drain output. No NCH bit in the U2C0 register is assigned. When write, set to 0. 3. Set the bits not listed above to 0 when writing to the registers in IE mode.
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17. Serial Interface
(1) The ABSCS Bit in the UiSMR Register (Bus collision detect sampling clock select)
If ABSCS = 0, bus collision is determined at the rising edge of the transfer clock
(i = 0 to 2, 5 to 7)
Transfer clock
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP
TXDi RXDi
Trigger signal is applied to the TAjIN pin
Timer Aj
If ABSCS = 1, bus collision is determined when timer Aj (one-shot timer mode) underflows. Timer Aj: Timer A3 in UART0; Timer A4 in UART1; Timer A0 in UART2 Timer A0 in UART5; Timer A3 in UART6; Timer A4 in UART7
(2) The ACSE Bit in the UiSMR Register (Auto clear of transmit enable bit) Transfer clock
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP
TXDi RXDi IR bit in UiBCNIC and BCNIC register TE bit in UiC1 register
If ACSE bit = 1 (automatically clear when bus collision occurs), the TE bit is cleared to 0 (transmission disabled) when the IR bit in the UiBCNIC register = 1 (unmatching detected).
(3) The SSS Bit in the UiSMR Register (Transmit start condition select)
If SSS bit = 0, the serial interface starts sending data one transfer clock cycle after the transmission enable condition is met.
Transfer clock
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP
TXDi
Transmit enable conditions are met If SSS bit = 1, the serial interface starts sending data at the rising edge of RXDi
(1)
CLKi
ST D0 D1 D2 D3 D4 D5 D6 D7 D8 SP
TXDi RXDi
(2)
NOTES : 1. The falling edge of RXDi when IOPOL = 0; the rising edge of RXDi when IOPOL = 1. 2. The transmit condition must be met before the falling edge of RXD (1). The above diagram applies to the case where IOPOL = 1 (reversed). i = 0 to 2, 5 to 7
Figure 17.32 Bus Collision Detect Function-Related Bits
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17. Serial Interface
17.1.6
Special Mode 4 (SIM Mode) (UART2)
SIM interface devices can communicate in UART mode. Both direct and inverse formats are available. The TXD2 pin outputs a low-level signal when a parity error is detected. Table 17.18 lists the SIM Mode Specifications. Table 17.19 lists the Registers to Be Used and Settings in SIM Mode.
Table 17.18 SIM Mode Specifications
Item Transfer Data Format Transfer Clock
Specification * Direct format * Inverse format * The CKDIR bit in the U2MR register = 0 (internal clock): fi / (16(n + 1)) fi = f1SIO, f2SIO, f8SIO, f32SIO n = setting value of the U2BRG register 00h to FFh * The CKDIR bit = 1 (external clock): fEXT / (16(n + 1)) fEXT = input from the CLK2 pin n = setting value of the U2BRG register 00h to FFh Before transmission starts, satisfy the following requirements * The TE bit in the U2C1 register = 1 (transmission enabled) * The TI bit in the U2C1 register = 0 (data present in the U2TB register) Before reception starts, satisfy the following requirements * The RE bit in the U2C1 register = 1 (reception enabled) * Start bit detection * While transmitting When the serial interface completed sending data from the UART2 transmit register (the U2IRS bit =1) * While receiving When transferring data from the UART2 receive register to the U2RB register (at completion of reception) * Overrun error (1) This error occurs if the serial interface started receiving the next data before reading the U2RB register and received the bit one before the last stop bit of the next data * Framing error (3) This error occurs when the number of stop bits set is not detected * Parity error (3) During reception, if a parity error is detected, parity error signal is output from the TXD2 pin. During transmission, a parity error is detected by the level of input to the RXD2 pin when a transmission interrupt occurs * Error sum flag This flag is set to 1 when one of the overrun, framing, and parity errors occurs
Transmission Start Condition Reception Start Condition Interrupt Request Generation Timing (2)
Error Detection
NOTES: 1. If an overrun error occurs, the received data of the U2RB register will be indeterminate. The IR bit in the S2RIC register does not change. 2. A transmit interrupt request is generated by setting the U2IRS bit to 1 (transmission completed) and the U2ERE bit to 1 (error signal output) in the U2C1 register after reset is canceled. Therefore, when using SIM mode, set the IR bit to 0 (interrupt not requested) after setting the bits. 3. The timing at which the framing error flag and the parity error flag are set is detected when data is transferred from the UART2 receive register to the U2RB register.
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17. Serial Interface
Table 17.19
Registers to Be Used and Settings in SIM Mode
Register U2TB
(1)
Bit 0 to 7 0 to 7 OER,FER,PER,SUM 0 to 7 SMD2 to SMD0 CKDIR STPS PRY PRYE IOPOL CLK0,CLK1 CRS TXEPT CRD NCH CKPOL UFORM TE TI RE RI U2IRS U2RRM U2LCH U2ERE 0 to 3 0 to 7 0 to 7 0 to 7 Set transmission data
Function Reception data can be read Error flag Set a bit rate Set to 101b Select the internal clock or external clock Set to 0 Set to 1 in direct format or 0 in inverse format Set to 1 Set to 0 Select the count source for the U2BRG register Invalid because CRD = 1 Transmit register empty flag Set to 1 Set to 0 Set to 0 Set to 0 in direct format or 1 in inverse format Set to 1 to enable transmission Transmit buffer empty flag Set to 1 to enable reception Reception complete flag Set to 1 Set to 0 Set to 0 in direct format or 1 in inverse format Set to 1 Set to 0 Set to 0 Set to 0 Set to 0
U2RB (1) U2BRG U2MR
U2C0
U2C1
U2SMR (1) U2SMR2 U2SMR3 U2SMR4
NOTE: 1. Set the bits not listed above to 0 when writing to the registers in SIM mode.
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17. Serial Interface
(1) Transmit Timing
Transfer clock TE bit in U2C1 register TI bit in U2C1 register
"1" "0" "1" "0"
Tc
Data is written to the U2TB register
(Note 1)
TXD2
Parity error signal returned from receiving end
Start bit
ST D0 D1 D2 D3 D4 D5 D6
Parity bit
D7 P SP
Stop bit
Data is transferred from the U2TB register to the UART2 transmit register
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
RXD2 pin level
(2)
An "L" signal is applied from the SIM card due to a parity error
ST D0 D1 D2 D3 D4 D5 D6 D7 P SP ST D0 D1 D2 D3 D4 D5 D6 D7 P SP
TXEPT bit in U2C0 register IR bit in S2TIC register
"1" "0" "1" "0"
An interrupt routine detects "H" or "L"
An interrupt routine detects "H" or "L"
The above timing diagram applies to the case where data is transmitted in the direct format. * The STPS bit in the U2MR register = 0 (1 stop bit) * The PRY bit in the U2MR register = 1 (even parity) * The UFORM bit in the U2C0 register = 0 (LSB first) * The U2LCH bit in the U2C1 register = 0 (no reverse) * The U2IRS bit in the U2C1 register = 1 (transmit completed)
Set to 0 by an interrupt request acknowledgement or by program
TC = 16 (n + 1) / fi or 16 (n + 1) / fEXT fi : frequency of U2BRG count source (f1SIO, f2SIO, f8SIO, f32SIO) fEXT : frequency of U2BRG count source (external clock) n : value set to U2BRG
(2) Receive Timing
Transfer clock RE bit in U2C1 register Transmit waveform from transmitting end
"1" "0" Start bit
ST D0 D1
Tc
Parity bit
D2 D3 D4 D5 D6 D7 P SP
Stop bit
ST D0 D1 D2 D3 D4 D5 D6 D7 P SP
TXD2
RXD2 pin level (3)
ST D0 D1 D2 D3 D4 D5 D6 D7 P SP ST D0 D1
TXD2 provides "L" output due to a parity error
D2 D3 D4 D5 D6 D7 P SP
RI bit in U2C1 register
"1" "0"
IR bit in S2RIC register
"1" "0"
Read the U2RB register
Set to 0 by an interrupt request acknowledgement or by program
The above timing diagram applies to the case where data is received in the direct format. * The STPS bit in the U2MR register = 0 (1 stop bit) * The PRY bit in the U2MR register = 1 (even parity) * The UFORM bit in the U2C0 register = 0 (LSB first) * The U2LCH bit in the U2C1 register = 0 (no reverse) * The U2IRS bit in the U2C1 register = 1 (transmit completed) TC = 16 (n + 1) / fi or 16 (n + 1) / fEXT fi : frequency of U2BRG count source (f1SIO, f2SIO, f8SIO, f32SIO) fEXT : frequency of U2BRG count source (external clock) n : value set to U2BRG
NOTES: 1. Data transmission starts when BRG overflows after a value is set to the U2TB register on the rising edge of the TI bit. 2. Because pins TXD2 and RXD2 are connected, a composite waveform, consisting of transmit waveform from the TXD2 pin and parity error signal from the receiving end, is generated. 3. Because pins TXD2 and RXD2 are connected, a composite waveform, consisting of transmit waveform from the transmitting end and parity error signal from the TXD2 pin, is generated.
Figure 17.33 Transmit and Receive Timing in SIM Mode
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17. Serial Interface
Figure 17.34 shows an Example of SIM Interface Connection. Connect TXD2 and RXD2, and then place a pull-up resistance.
Microcomputer
SIM card
TXD2 RXD2
Figure 17.34 Example of SIM Interface Connection
17.1.6.1
Parity Error Signal Output
The parity error signal is enabled by setting the U2ERE bit in the U2C1 register to 1 (error signal output). The parity error signal is output when a parity error is detected while receiving data. A low-level signal is output from the TXD2 pin in the timing shown in Figure 17.35. If the U2RB register is read while outputting a parity error signal, the PER bit is cleared to 0 (no parity error) and at the same time the TXD2 output is returned high. When transmitting, a transmission complete interrupt request is generated at the falling edge of the transfer clock pulse that immediately follows the stop bit. Therefore, whether a parity error signal has been returned can be determined by reading the port that shares the RXD2 pin in a transmission complete interrupt routine.
Transfer clock RXD2 TXD2 RI bit in U2C1 register
"H" "L" "H" "L" "H" "L" "1" "0"
ST
D0
D1
D2
D3
D4
D5
D6
D7
P
SP
(NOTE 1)
This timing diagram applies to the case where the direct format is implemented. Note: 1. The output of microcomputer is in the high-impedance state (pulled up externally).
ST : Start bit P : Even Parity SP : Stop bit
Figure 17.35 Parity Error Signal Output Timing
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17. Serial Interface
17.1.6.2
Format
Two formats are available: direct format and inverse format. In direct format, set the PRYE bit in the U2MR register to 1 (parity enabled), the PRY bit to 1(even parity), the UFORM bit in the U2C0 register to 0 (LSB first) and the U2LCH bit in the U2C1 register to 0 (not inverted). When data are transmitted, data set in the U2TB register are transmitted with the even-numbered parity, starting from D0. When data are received, received data are stored in the U2RB register, starting from D0. The even-numbered parity determines whether a parity error occurs. In inverse format, set the PRYE bit to 1, the PRY bit to 0 (odd parity), the UFORM bit to 1 (MSB first), and the U2LCH bit to 1 (inverted). When data are transmitted, values set in the U2TB register are logically inversed and are transmitted with the odd-numbered parity, starting from D7. When data are received, received data are logically inversed to be stored in the U2RB register, starting from D7. The odd-numbered parity determines whether a parity error occurs.
(1) Direct format Transfer clock TXD2
"H" "L" "H" "L"
D0
D1
D2
D3
D4
D5
D6
D7
P
P : Even parity
(2) Inverse format Transfer clock TXD2
"H" "L" "H" "L"
D7
D6
D5
D4
D3
D2
D1
D0
P
P : Odd parity
Figure 17.36 SIM Interface Format
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17. Serial Interface
17.2
SI/O3 and SI/O4
SI/O3 and SI/O4 are exclusive clock-synchronous serial I/Os. Figure 17.37 shows the SI/O3 and SI/O4 Block Diagram, and Figure 17.38 shows the Registers S3C, S4C, S3BRG, S4BRG, S3TRR, and S4TRR. Table 17.20 shows the SI/O3 and SI/O4 Specifications.
Main clock, PLL clock, or on-chip oscillator clock
1/2 f1SIO
f2SIO PCLK1 = 0
Clock source select SMi1 to SMi0 = 00b = 01b = 10b 1/2
Data bus
1/8
PCLK1 = 1 f8SIO 1/4
SMi6 = 0
f32SIO
SMi6 = 1 Synchronous
circuit
1 / (n + 1)
SiBRG register
SMi4 CLKi
CLK polarity reversing circuit
SMi3 SMi6
SMi6 S I/O counter i S I / Oi interrupt request
SMi2 SMi3 SOUTi SINi SMi5 LSB MSB
SiTRR register 8 NOTE : i = 3, 4 n: velue set in the SiBRG register
Figure 17.37 SI/O3 and SI/O4 Block Diagram
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17. Serial Interface
SI/Oi Control Register (i = 3, 4)
b7 b6 b5 b4 b3 b2 b1 b0
(1)
Symbol S3C S4C
Bit symbol
Address 0272h 0276h Bit Name Function b1 b0 0 0 : Selecting f1SIO or f2SIO 0 1 : Selecting f8SIO 1 0 : Selecting f32SIO 1 1 : Do not set
(5)
After Reset 01000000b 01000000b RW
SMi0 SMi1 SMi2
Internal synchronous clock select bit (6)
RW
SOUTi output disable bit
(4)
0 : SOUTi output enabled 1 : SOUTi output disabled (high-Impedance) 0 : Input / output port serial interface disabled 1 : SOUTi output, CLKi function serial interface enabled
0 : Transmit data is output at falling edge of transfer clock and receive data is input at rising edge 1 : Transmit data is output at rising edge of transfer clock and receive data is input at falling edge
RW
SMi3
SI/Oi port select bit
RW
SMi4
CLK polarity select bit
RW
SMi5 SMi6 SMi7
Transfer direction select bit Synchronous clock select bit
0 : LSB first 1 : MSB first 0 : External clock (2) 1 : Internal clock (3)
RW RW RW
Valid when SMi6 = 0 (7) SOUTi initial value set bit 0 : "L" output 1 : "H" output
NOTES : 1. Make sure this register is written to by the next instruction after setting the PRC2 bit in the PRCR register to 1 (write enabled). 2. Set the SMi3 bit to 1 and the corresponding port direction bit to 0 (input mode). 3. Set the SMi3 bit to 1 (SOUTi output, CLKi function). 4. When the SMi2 bit is set to 1, the target pin goes to high-impedance state regardless of which function of the pin is being used. 5. Selected by the PCLK1 bit in the PCLKR register. 6. When the values of bits SMi1 and SMi0 are changed, set the SiBRG register. 7. Set the value when SMi3 bit is set to 0 (I/O port). When the SMi3 bit is set to 1 (SOUTi output) subsequently, the selected level signal by the SMi7 bit is output from the SOUTi pin.
SI/Oi Bit Rate Register (i = 3, 4) (1, 2, 3)
b7 b0
Symbol S3BRG S4BRG Function
Address 0273h 0277h
After Reset Indeterminate Indeterminate Setting Range 00h to FFh RW WO
BRGi divides the count source by n + 1 where n = set value NOTES : 1. Write to this register while serial interface is neither transmitting nor receiving. 2. Use MOV instruction to write to this register. 3. Write to this register after setting bits SMi1 and SMi0 in the SiC register.
SI/Oi Transmit / Receive Register (i = 3, 4) (1, 2)
b7 b0
Symbol S3TRR S4TRR Function
Address 0270h 0274h
After Reset Indeterminate Indeterminate Setting Range RW RW
Transmission / reception starts by writing transmit data to this register. After transmission / reception completes, reception data can be read by reading this register. NOTES : 1. Write to this register while serial interface is neither transmitting nor receiving. 2. To receive data, set the corresponding port direction bit for SINi to 0 (input mode).
Figure 17.38 Registers S3C, S4C, S3BRG, S4BRG, S3TRR, and S4TRR
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17. Serial Interface
SI/O 34 Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
0
0
Symbol S34C2
Bit Symbol
Address 0278h Bit Name Reserved bit Set to 0 Function
After Reset 00XXX0X0b RW RW -- RW --
-- (b0) -- (b1) -- (b2) -- (b5-b3) SM26
No register bit. If necessary, set to 0. Read as undefined value Reserved bit Set to 0
No register bits. If necessary, set to 0. Read as undefined value SOUT3 status after transmission 0 : High-impedance 1 : Last bit level retained SOUT4 status after transmission 0 : High-impedance 1 : Last bit level retained
SOUT3 output control bit (1)
RW
SM27
SOUT4 output control bit (1)
RW
NOTE : 1. Bits SM26 and SM27 are valid when the SMi3 bit in registers S3C and S4C are set to 1 (SOUT, CLK)
Figure 17.39 S34C2 Register
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Under development
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M16C/64 Group
17. Serial Interface
Table 17.20
SI/O3 and SI/O4 Specifications
Item Transfer Data Format Transfer Clock
Transmission / Reception Start Condition Interrupt Request Generation Timing
CLKi Pin Function SOUTi Pin Function SINi Pin Function Select Function
Specification Transfer data length: 8 bits * The SMi6 bit in the SiC (i = 3, 4) register = 1 (internal clock): fj / (2(n + 1)) fj = f1SIO, f8SIO, f32SIO n = setting value of the SiBRG register 00h to FFh * The SMi6 bit = 0 (external clock): input from the CLKi pin (1) Before transmission / reception starts, satisfy the following requirements Write transmit data to the SiTRR register (2, 3) * When the SMi4 bit in the SiC register = 0 The rising edge of the last transfer clock pulse (4) * When the SMi4 bit = 1 The falling edge of the last transfer clock pulse (4) I/O port, transfer clock input, transfer clock output I/O port, transmit data output, high-impedance I/O port, receive data input * LSB first or MSB first selection Whether to start sending / receiving data beginning with bit 0 or beginning with bit 7 can be selected * CLK polarity selection Whether transmit data is output / input at the rising edge or falling edge of transfer clock can be selected. * Function for setting an SOUTi initial value set function When the SMi6 bit in the SiC register = 0 (external clock), the SOUTi pin output level while not transmitting can be selected. * SOUTi state selection after transmission Whether to set to high-impedance or retain the last bit level can be selected.
NOTES: 1. To set the SMi6 bit in the SiC register to 0 (external clock), follow the procedure described below. * If the SMi4 bit in the SiC register = 0, write transmit data to the SiTRR register while input on the CLKi pin is high. The same applies when rewriting the SMi7 bit in the SiC register. * If the SMi4 bit = 1, write transmit data to the SiTRR register while input on the CLKi pin is low. The same applies when rewriting the SMi7 bit. * Because shift operation continues as long as the transfer clock is supplied to the SI/Oi circuit, stop the transfer clock after supplying eight pulses. If the SMi6 bit = 1 (internal clock), the transfer clock automatically stops. 2. Unlike UART0 to UART2, SI/Oi (i = 3 to 4) is not separated between the transfer register and buffer. Therefore, do not write the next transmit data to the SiTRR register during transmission. 3. When the SMi6 bit = 1 (internal clock) and bits SM26 (SOUT3) and SM27 (SOUT4) in the S34C2 register = 0 (high-impedance after transmission), SOUTi retains the last data for a 1/2 transfer clock period after completion of transfer and, thereafter, goes to high-impedance state. However, if transmit data is written to the SiTRR register during this period, SOUTi immediately goes to high-impedance state, with the data hold time thereby reduced. 4. When the SMi6 bit = 1 (internal clock), the transfer clock stops in the high state if the SMi4 bit = 0, or stops in the low state if the SMi4 bit = 1.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
17. Serial Interface
17.2.1
SI/Oi Operation Timing
Figure 17.40 shows the SI/Oi Operation Timing .
0.5 to 1.0 cycle (max.) (2) SI/Oi internal clock "H"
"L"
CLKi output Signal written to SiTRR register
"H" "L"
SOUTi output SINi input IR bit in SiIC register i = 3, 4
"H" "L" "H" "L"
D0
D1
D2
D3
D4
D5
D6
D7
"1" "0"
NOTES : 1. This diagram applies to the case where the SiC register bits are set as follows: SMi2 = 0 (SOUTi output), SMi3 = 1 (SOUTi output, CLKi function), SMi4 = 0 (transmit data output at the falling edge and receive data input at the rising edge of the transfer clock), SMi5 = 0 (LSB first) and SMi6 = 1 (internal clock) Bits SM26 (SOUT3) and SM27 (SOUT4) in the S34C2 register are 0 (high-impedance after transmission). 2. If the SMi6 bit = 1 (internal clock), the serial I/O starts sending or receiving data a maximum of 0.5 to 1.0 transfer clock cycles after writing to the SiTRR register.
Figure 17.40 SI/Oi Operation Timing
17.2.2
CLK Polarity Selection
The SMi4 bit in the SiC register allows selection of the polarity of the transfer clock. Figure 17.41 shows the Polarity of Transfer Clock
(1) When the SMi4 bit in the SiC register = 0 CLKi SOUTi SINi D0 D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7
(2) When the SMi4 bit = 1 CLKi SOUTi SINi
i = 3, 4 NOTES: This diagram applies to the case where the SiC register bits are set as follows: 1. When the SMi5 = 0 (LSB first) and the SMi6 = 1 (internal clock) 2. When the SMi6 bit =1 (internal clock), high level is output from the CLKi pin if not transferring data. 3. When the SMi6 bit =1
D0 D0
D1 D1
D2 D2
D3 D3
D4 D4
D5 D5
D6 D6
D7 D7
Figure 17.41 Polarity of Transfer Clock
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M16C/64 Group
17. Serial Interface
17.2.3
Functions for Setting an SOUTi Initial Value
If the SMi6 bit in the SiC register = 0 (external clock), the SOUTi pin output can be fixed high or low when not transferring. However, the last bit value of the former data is retained between data and data when transmitting data consecutively. Figure 17.42 shows the timing chart for setting an SOUTi initial value and how to set it.
(Example) When "H" Selected for SOUTi Initial Value (1)
Signal written to SiTRR register
Initial value setting of SOUTi output and starting of transmission / reception
SMi7 bit
SMi3 bit
Set the SMi3 bit to 0 (SOUTi pin functions as an I/O port)
SOUTi (internal)
D0
Set the SMi7 bit to 1 (SOUTi initial value = "H")
SOUTi pin output (i = 3, 4)
Port output Initial value = "H" (3) Port selection switching (I/O port SOUTi)
D0
Set the SMi3 bit to 1 (SOUTi pin functions as SOUTi output) "H" level is output from the SOUTi pin Write to the SiTRR register
Setting the SOUTi initial value to "H" (2)
NOTES: This diagram applies to the case where the bits in the SiC register are set as follows: 1. SMi2 = 0 (SOUTi output), SMi5 = 0 (LSB first) and SMi6 = 0 (external clock) 2. SOUTi can only be initialized when input on the CLKi pin is in the high state if the SMi4 bit in the SiC register = 0 (transmit data output at the falling edge of the transfer clock) or in the low state if the SMi4 bit = 1 (transmit data output at the rising edge of the transfer clock). 3. If the SMi6 bit = 1 (internal clock) or if the SMi2 bit = 1 (SOUT output disabled), this output goes to the high-impedance state.
Serial transmit / reception starts
Figure 17.42 SOUTi Initial Value Setting
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M16C/64 Group
17. Serial Interface
17.2.4
Functions for Selecting SOUTi State after Transmission
If bits SM26 and SM27 in the S34C2 register = 1 (last bit level retained), output from the SOUTi pin retains the last bit level after transmission. Figure 17.43 shows the Level of SOUT3 Pin after Transmission.
SI/O internal clock
"H" "L" "H"
CLK3 output
"L"
When SM26 = 0 (high-impedance) SOUT3 output When SM26 = 1 (last bit level retained)
D6
D7
D6
D7
The above SOUT3 example applies to the case where The SM32 bit in the S3C register = 0 (SOUT3 output), The SM33 bit in the S3C register = 1 (SOUT3 output, CLK3 selected), The SM34 bit in the S3C register = 0 (transmit data output at the falling edge and the receive data taken in at the rising edge of the transfer clock), The SM35 bit in the S3C register = 0 (LSB first), and The SM36 bit in the S3C register = 1 (internal clock)
Figure 17.43 Level of SOUT3 Pin after Transmission
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
18. A/D Converter
The microcomputer contains one A/D converter circuit based on 10-bit successive approximation method. The analog inputs share the pins with P10_0 to P10_7, P9_5, P9_6, P0_0 to P0_7, and P2_0 to P2_7. Similarly, ADTRG input shares the pin with P9_7. Therefore, when using these inputs, make sure the corresponding port direction bits are set to 0 (input mode). When not using the A/D converter, set the ADSTBY bit to 0 (A/D operation stop: standby), so that no current will flow for the A/D converter, helping to reduce the power consumption of the chip. The A/D conversion result is stored in the ADi register for pins ANi, AN0_i, and AN2_i (i = 0 to 7). Table 18.1 shows the A/D Converter Specifications. Figure 18.1 shows the A/D Converter Block Diagram, and Figures 18.2 and 18.3 show the A/D converter-related registers.
Table 18.1 A/D Converter Specifications
Item A/D Conversion Method Analog Input Voltage
(1)
Performance Successive approximation 0V to AVCC (VCC1)
Operating clock AD
(1)
fAD, divide-by-2 of fAD, divide-by-3 of fAD, divide-by-4 of fAD, divide-by-6 of fAD, divide-by-12 of fAD Resolution 10-bit Integral Nonlinearity When AVCC = VREF = 5V Error AN0 to AN7 input, AN0_0 to AN0_7 input or AN2_0 to AN2_7 input: 3LSB ANEX0 or ANEX1 input: 3LSB When AVCC = VREF = 3.0V AN0 to AN7 input, AN0_0 to AN0_7 input or AN2_0 to AN2_7 input: 3LSB ANEX0 or ANEX1 input: 3LSB Operating Modes One-shot mode, repeat mode, single sweep mode, repeat sweep mode 0, repeat sweep mode 1 8 pins (AN0 to AN7) + 2 pins (ANEX0 and ANEX1) + 8 pins (AN0_0 to AN0_7) Analog Input Pins + 8 pins (AN2_0 to AN2_7) A/D Conversion Start * Software trigger Condition The ADST bit in the ADCON0 register is set to 1 (A/D conversion start) * External trigger (retriggerable) Input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) Conversion Speed per 43 AD cycles minimum Pin NOTES: 1. Set AD frequency as follows: When VCC1 = 4.0 to 5.5 V, 2 MHz AD 25 MHz When VCC1 = 3.2 to 4.0 V, 2 MHz AD 16 MHz When VCC1 = 3.0 to 3.2 V, 2 MHz AD 10 MHz
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
0
CKS2
A/D conversion rate selection
1
1 0 CKS0 0
CKS1
AD
f1
fAD fAD
1/2 1/3
0 1 TRG 1
1/2
Software trigger ADTRG VREF AVSS
0 1 ADSTBY
Trigger
Analog circuit
Successive conversion register
ADCON1 register
ADCON0 register AD0 register (16 bits) AD1 register (16 bits) AD2 register (16 bits) AD3 register (16 bits) AD4 register (16 bits) AD5 register (16 bits) AD6 register (16 bits) AD7 register (16 bits) Data bus (high-order) ADCON2 register Data bus (low-order)
PM00 PM01
(1)
Decoder for register
Vref
Decoder for channel selection
Port P10 group AN0 AN1 AN2 AN3 AN4 AN5 AN6 AN7 VIN
ADGSEL1.0 ANEX1.0 = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b CH2 to CH0 = 000b = 001b = 010b = 011b = 100b = 101b = 110b = 111b
Comparator
Port P0 group
PM01 and PM00 = 00b (1) ADGSEL1.0 ANEX1.0 = 00b = 10b = 10b = 00b = 00b = 10b = 10b = 00b = 10b = 00b = 10b = 00b = 10b = 00b = 10b = 00b CH2 to CH0 = 000b = 001b = 010b = 011b = 100b = 101b = 110b = 111b
AN0_0 AN0_1 AN0_2 AN0_3 AN0_4 AN0_5 AN0_6 AN0_7 Port P2 group
PM01 and PM00 = 00b ADGSEL1.0 = 11b AN2_0 = 11b AN2_1 = 11b AN2_2 = 11b AN2_3 = 11b AN2_4 = 11b AN2_5 = 11b AN2_6 = 11b AN2_7
ANEX1.0 = 00b = 00b = 00b = 00b = 00b = 00b = 00b = 00b
CH2 to CH0 = 000b = 001b = 010b = 011b = 100b = 101b = 110b = 111b ADEX1 to ADEX0 = 01b ADEX1 to ADEX0 = 10b
ANEX0 ANEX1 NOTE : 1. Port P0 group (AN0_0 to AN0_7) can be used as analog input pins even when bits PM01 and PM00 are set to 01b (memory expansion mode) and bits PM05 and PM04 are set to 11b (multiplex bus allocated to the entire CS space).
Figure 18.1
A/D Converter Block Diagram
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M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name Function
After Reset 00000XXXb RW RW RW RW
CH0 CH1 CH2 MD0
Analog input pin select bit Function varies with each operation mode
A/D operation mode select bit 0
MD1
b4 b3 0 0 : One-shot mode 0 1 : Repeat mode 1 0 : Single sweep mode 1 1 : Repeat sweep mode 0 or repeat sweep mode 1 0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start Refer to NOTE 3 of the ADCON2 Register
RW
RW
TRG ADST CKS0
Trigger select bit A/D conversion start flag Frequency select bit 0
RW RW RW
NOTE : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name Function
After Reset 0000X000b RW RW RW
SCAN0 SCAN1 MD2 -- (b3) CKS1
A/D sweep pin select bit
Function varies with each operation mode
0 : Any mode other than repeat sweep mode A/D operation mode select 1 bit 1 1 : Repeat sweep mode 1 No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register 0 : A/D operation stopped (standby) 1 : A/D operation enabled Function varies with each operation mode
RW -- RW RW RW RW
ADSTBY A/D standby bit (2) ADEX0 ADEX1
Extended pin select bit
NOTES: 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. If the ADSTBY bit is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.2
Registers ADCON0 and ADCON1
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M16C/64 Group
18. A/D Converter
A/D Control Register 2 (1)
b7 b6 b5 b4 b3 b2 b1 b0
000
Symbol ADCON2
Bit Symbol
Address 03D4h Bit Name Function
After Reset 0000X00Xb RW -- RW RW --
-- (b0) ADGSEL0
No register bit. If necessary, set to 0. Read as undefined value b2 b1 0 0 : Select port P10 group 0 1 : Do not set 1 0 : Select port P0 group 1 1 : Select port P2 group
A/D input group select bit ADGSEL1 -- (b3)
No register bit. If necessary, set to 0. Read as undefined value 0: Selects fAD, fAD divided by 2, or fAD divided by 4. 1: Selects fAD divided by 3, fAD divided by 6, or fAD divided by 12. Set to 0
CKS2 -- (b7-b5)
Frequency select bit 2 (2)
RW
Reserved bits
RW
NOTES : 1. If the ADCON2 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AD frequency is selected by a combination of the CKS0 bit in the ADCON0 register, the CKS1 bit in the ADCON1 register, and the CKS2 bit in the ADCON2 register. CKS2 0 0 0 0 1 1 1 1 CKS1 0 0 1 1 0 0 1 1 CKS0 0 1 0 1 0 1 0 1 AD fAD divided by 4 fAD divided by 2 fAD fAD divided by 12 fAD divided by 6 fAD divided by 3
A/D Register (i = 0 to 7)
(b15) b7 (b8) b0 b7 b0
0
Symbol AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7
Address 03C1h to 03C0h 03C3h to 03C2h 03C5h to 03C4h 03C7h to 03C6h 03C9h to 03C8h 03CBh to 03CAh 03CDh to 03CCh 03CFh to 03CEh Function
After Reset 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb 000000XXb, XXXXXXXXb RW RO RO -- RO
Eight low-order bits of A/D conversion result Two high-order bits of A/D conversion result No register bits. If necessary, set to 0. Read as undefined value Reserved bit NOTE : 1. Use the MOV instruction to write to this register. Set to 0
Figure 18.3
Registers ADCON2 and AD0 to AD7
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M16C/64 Group
18. A/D Converter
18.1 18.1.1
Mode Description One-Shot Mode
In one-shot mode, analog voltage applied to a selected pin is converted to a digital code once. Table 18.2 shows the One-Shot Mode Specifications. Figure 18.4 shows the Registers ADCON0 and ADCON1 (One-shot Mode).
Table 18.2 One-Shot Mode Specifications
Item Function
A/D Conversion Start Condition
A/D Conversion Stop Condition Interrupt Request Generation Timing Analog Input Pin Reading of Result of A/D Converter
Specification Bits CH2 to CH0 in the ADCON0 register and bits ADGSEL1 and ADGSEL0 in the ADCON2 register, or bits ADEX1 and ADEX0 in the ADCON1 register select a pin. Analog voltage applied to the pin is converted to a digital code once. * When the TRG bit in the ADCON0 register is 0 (software trigger) the ADST bit in the ADCON0 register is set to 1 (A/D conversion starts) * When the TRG bit is 1 (ADTRG trigger) input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) * Completion of A/D conversion (The ADST bit is cleared to 0 (A/D conversion stop)) * Set the ADST bit to 0 Completion of A/D conversion Select one pin from AN0 to AN7, AN0_0 to AN0_7, AN2_0 to AN2_7, ANEX0, and ANEX1 Read one of the registers AD0 to AD7 that corresponds to the selected pin
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M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name
b2
After Reset 00000XXXb Function RW RW RW RW RW RW
CH0 CH1 CH2 MD0 MD1 TRG ADST CKS0 Analog input pin select bit (2)
0 0 0 0 1 1 1 1 0
b1
0 0 1 1 0 0 1 1
b0
0 : Select AN0 1 : Select AN1 0 : Select AN2 1 : Select AN3 0 : Select AN4 1 : Select AN5 0 : Select AN6 1 : Select AN7
b4
b3
A/D operation mode select bit 0
0 : One-shot mode
Trigger select bit A/D conversion start flag Frequency select bit 0
0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start Refer to NOTE 3 of the ADCON2 Register
RW RW RW
NOTES : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
1
0
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name Function Invalid in one-shot mode
After Reset 0000X000b RW RW RW
SCAN0 SCAN1 MD2 -- (b3) CKS1
A/D sweep pin select bit
A/D operation mode select Set to 0 when one-shot mode is selected bit 1 No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register Set to 1 (A/D operation enabled) b7 b6 0 0 : ANEX0 and ANEX1 are not used 0 1 : ANEX0 input is A/D converted 1 0 : ANEX1 input is A/D converted 1 1 : Do not set
RW -- RW RW RW RW
ADSTBY A/D standby bit (2) ADEX0 Extended pin select bit ADEX1
NOTES : 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. If the ADSTBY bit is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.4
Registers ADCON0 and ADCON1 (One-shot Mode)
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M16C/64 Group
18. A/D Converter
18.1.2
Repeat Mode
In repeat mode, analog voltage applied to a selected pin is repeatedly converted to a digital code. Table 18.3 shows the Repeat Mode Specifications. Figure 18.5 shows the Registers ADCON0 and ADCON1 (Repeat Mode).
Table 18.3 Repeat Mode Specifications
Item Function
A/D Conversion Start Condition
A/D Conversion Stop Condition Interrupt Request Generation timing Analog Input Pin Reading of Result of A/D Converter
Specification Bits CH2 to CH0 in the ADCON0 register and bits ADGSEL1 and ADGSEL0 in the ADCON2 register, or bits ADEX1 and ADEX0 in the ADCON1 register select a pin. Analog voltage applied to this pin is repeatedly converted to a digital code. * When the TRG bit in the ADCON0 register is 0 (software trigger) the ADST bit in the ADCON0 register is set to 1 (A/D conversion start) * When the TRG bit is 1 (ADTRG trigger) input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) Set the ADST bit to 0 (A/D conversion stop) No interrupt requests generated Select one pin from AN0 to AN7, AN0_0 to AN0_7, AN2_0 to AN2_7, ANEX0, and ANEX1 Read one of the registers AD0 to AD7 that corresponds to the selected pin
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
01
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name Function b2 b1 b0 0 0 0 : Select AN0 0 0 1 : Select AN1 0 1 0 : Select AN2 0 1 1 : Select AN3 1 0 0 : Select AN4 1 0 1 : Select AN5 1 1 0 : Select AN6 1 1 1 : Select AN7 b4 b3 0 1 : Repeat mode
After Reset 00000XXXb RW RW
CH0
CH1
Analog input pin select bit (2)
RW
CH2 MD0 MD1 TRG ADST CKS0
RW RW RW
A/D operation mode select bit 0
Trigger select bit A/D conversion start flag Frequency select bit 0
0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start
RW RW
Refer to NOTE 3 of the ADCON2 Register RW
NOTES : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7, and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
1
0
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name Function Invalid in repeat mode
After Reset 0000X000b RW RW RW
SCAN0 SCAN1 MD2 -- (b3) CKS1
A/D sweep pin select bit
A/D operation mode select Set to 0 when repeat mode is selected bit 1 No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register Set to 1 (A/D operation enabled) b7 b6 0 0 : ANEX0 and ANEX1 are not used 0 1 : ANEX0 input is A/D converted 1 0 : ANEX1 input is A/D converted 1 1 : Do not set
RW -- RW RW RW RW
ADSTBY A/D standby bit (2) ADEX0 Extended pin select bit ADEX1
NOTES : 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. When the ADSTBY bit is reset from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.5
Registers ADCON0 and ADCON1 (Repeat Mode)
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M16C/64 Group
18. A/D Converter
18.1.3
Single Sweep Mode
In single sweep mode, analog voltage that is applied to selected pins is converted one-by-one to a digital code. Table 18.4 shows the Single Sweep Mode Specifications. Figure 18.6 shows Registers ADCON0 and ADCON1 (Single Sweep Mode).
Table 18.4 Single Sweep Mode Specifications
Item Function
A/D Conversion Start Condition
A/D Conversion Stop Condition Interrupt Request Generation timing Analog Input Pin Reading of Result of A/D Converter
Specification Bits SCAN1 and SCAN0 in the ADCON1 register and bits ADGSEL1 and ADGSEL0 in the ADCON2 register select pins. Analog voltage applied to the pins is converted one-by-one to a digital code. * When the TRG bit in the ADCON0 register is 0 (software trigger) the ADST bit in the ADCON0 register is set to 1 (A/D conversion start) * When the TRG bit is 1 (ADTRG trigger) input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) * Completion of A/D conversion (The ADST bit is cleared to 0 (A/D conversion stop)) * Set the ADST bit to 0 Completion of A/D conversion Select from AN0 and AN1 (2 pins), AN0 to AN3 (4 pins), AN0 to AN5 (6 pins), and AN0 to AN7 (8 pin) (1) Read one of the registers AD0 to AD7 that corresponds to the selected pin
NOTE: 1. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
01
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name Function b2 b1 b0 0 0 0 : Select AN0 0 0 1 : Select AN1 0 1 0 : Select AN2 0 1 1 : Select AN3 1 0 0 : Select AN4 1 0 1 : Select AN5 1 1 0 : Select AN6 1 1 1 : Select AN7 b4 b3 0 1 : Repeat mode
After Reset 00000XXXb RW RW
CH0
CH1
Analog input pin select bit (2)
RW
CH2 MD0 MD1 TRG ADST CKS0
RW RW RW
A/D operation mode select bit 0
Trigger select bit A/D conversion start flag Frequency select bit 0
0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start
RW RW
Refer to NOTE 3 of the ADCON2 Register RW
NOTES : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7, and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name
b1 b0
After Reset 0000X000b Function RW RW RW RW -- RW RW RW RW
SCAN0 A/D sweep pin select bit (2) SCAN1 MD2 -- (b3) CKS1
When repeat sweep mode 1 is selected 0 0 1 1 0 : AN0 (1 pin) 1 : AN1 (2 pins) 0 : AN2 (3 pins) 1 : AN3 (4 pins)
A/D operation mode select 1 : Repeat sweep mode 1 bit 1 No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register Set to 1 (A/D operation enabled)
b7
ADSTBY A/D standby bit (3) ADEX0 Extended pin select bit ADEX1
0 0 1 1
b6
0 : ANEX0 and ANEX1 are not used 1 : Do not set 0 : Do not set 1 : Do not set
NOTES : 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin. 3. If the ADSTBY bit is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.6
Registers ADCON0 and ADCON1 (Single Sweep Mode)
REJ09B0392-0064 Rev.0.64 Page 239 of 373
Oct 12, 2007
Under development
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M16C/64 Group
18. A/D Converter
18.1.4
Repeat Sweep Mode 0
In repeat sweep mode 0, analog voltage applied to selected pins is repeatedly converted to a digital code. Table 18.5 shows the Repeat Sweep Mode 0 Specifications. Figure 18.7 shows Registers ADCON0 and ADCON1 (Repeat Sweep Mode 0).
Table 18.5 Repeat Sweep Mode 0 Specifications
Item Function
A/D Conversion Start Condition
A/D Conversion Stop Condition Interrupt Request Generation timing Analog Input Pin Reading of Result of A/D Converter
Specification Bits SCAN1 and SCAN0 in the ADCON1 register and bits ADGSEL1 and ADGSEL0 in the ADCON2 register select pins. Analog voltage applied to the pins is repeatedly converted to a digital code. * When the TRG bit in the ADCON0 register is 0 (software trigger) the ADST bit in the ADCON0 register is set to 1 (A/D conversion start) * When the TRG bit is 1 (ADTRG trigger) input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) Set the ADST bit to 0 (A/D conversion stop) No interrupt requests generated Select from AN0 and AN1 (2 pins), AN0 to AN3 (4 pins), AN0 to AN5 (6 pins), and AN0 to AN7 (8 pin) (1) Read one of the registers AD0 to AD7 that corresponds to the selected pin
NOTE: 1. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7.
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Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
11
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name Function
After Reset 00000XXXb RW RW
CH0 CH1 CH2 MD0 MD1 TRG ADST CKS0 A/D operation mode select bit 0
b4
Analog input pin select bit Invalid in repeat sweep mode 0
RW RW
1
b3
RW RW RW RW RW
1 : Repeat sweep mode 0 or repeat sweep mode 1
Trigger select bit A/D conversion start flag Frequency select bit 0
0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start Refer to NOTE 3 of the ADCON2 Register
NOTE : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
1
0
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name
b1 b0
After Reset 0000X000b Function RW RW RW RW -- RW RW RW RW
SCAN0 SCAN1 MD2 -- (b3) CKS1
When repeat sweep mode 0 is selected 0 A/D sweep pin select bit (2) 0 1 1 A/D operation mode select bit 1 0 : AN0 to AN1 (2 pins) 1 : AN0 to AN3 (4 pins) 0 : AN0 to AN5 (6 pins) 1 : AN0 to AN7 (8 pins)
Set to 0 when repeat sweep mode 0 is selected
No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register Set to 1 (A/D operation enabled)
b7
ADSTBY A/D standby bit (3) ADEX0 Extension pin select bit ADEX1
0 0 1 1
b6
0 : ANEX0 and ANEX1 are not used 1 : Do not set 0 : Do not set 1 : Do not set
NOTES : 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin. 3. If the ADSTBY bit is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.7
Registers ADCON0 and ADCON1 (Repeat Sweep Mode 0)
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
18.1.5
Repeat Sweep Mode 1
In repeat sweep mode 1, analog voltage selectively applied to all pins is repeatedly converted to a digital code. Table 18.6 shows the Repeat Sweep Mode 1 Specifications. Figure 18.8 shows Registers ADCON0 and ADCON1 (Repeat Sweep Mode 1).
Table 18.6 Repeat Sweep Mode 1 Specifications
Item Function
A/D Conversion Start Condition
A/D Conversion Stop Condition Interrupt Request Generation timing Analog Input Pins to be Given Priority When A/D Converted Reading of Result of A/D Converter
Specification The input voltages on all pins selected by bits ADGSEL1 and ADGSEL0 in the ADCON2 register are A/D converted repeatedly, with priority given to pins selected by bits SCAN1 and SCAN0 in the ADCON1 register and bits ADGSEL1 and ADGSEL0. Example: If AN0 selected, input voltages are A/D converted in order of AN0AN1AN0AN2AN0AN3, and so on. * When the TRG bit in the ADCON0 register is 0 (software trigger), the ADST bit in the ADCON0 register is set to 1 (A/D conversion start) * When the TRG bit is 1 (ADTRG trigger), input on the ADTRG pin changes state from high to low after the ADST bit is set to 1 (A/D conversion start) Set the ADST bit to 0 (A/D conversion stop) No interrupt requests generated Select from AN0 (1 pin), AN0 and AN1 (2 pins), AN0 to AN2 (3 pins), and AN0 to AN3 (4 pins) (1) Read one of the registers AD0 to AD7 that corresponds to the selected pin
NOTES: 1. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7.
REJ09B0392-0064 Rev.0.64 Page 242 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
18. A/D Converter
A/D Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
11
Symbol ADCON0
Bit Symbol
Address 03D6h Bit Name Function
After Reset 00000XXXb RW RW
CH0 CH1 CH2 MD0 MD1 TRG ADST CKS0 A/D operation mode select bit 0 b4 b3 1 1 : Repeat sweep mode 0 or repeat sweep mode 1 0 : Software trigger 1 : ADTRG trigger 0 : A/D conversion stop 1 : A/D conversion start Refer to NOTE 3 of the ADCON2 Register Analog input pin select bit Invalid in repeat sweep mode 1
RW RW RW RW RW RW RW
Trigger select bit A/D conversion start flag Frequency select bit 0
NOTE : 1. If the ADCON0 register is rewritten during A/D conversion, the conversion result will be indeterminate.
A/D Control Register 1 (1)
b7 b6 b5 b4 b3 b2 b1 b0
1
1
Symbol ADCON1
Bit Symbol
Address 03D7h Bit Name
b1 b0
After Reset 0000X000b Function RW RW RW RW -- RW RW RW RW
SCAN0 SCAN1 MD2 -- (b3) CKS1
When repeat sweep mode 1 is selected 0 A/D sweep pin select bit (2) 0 1 1 0 : AN0 (1 pin) 1 : AN1 (2 pins) 0 : AN2 (3 pins) 1 : AN3 (4 pins)
A/D operation mode select 1 : Repeat sweep mode 1 bit 1 No register bit. If necessary, set to 0. Read as undefined value Frequency select bit 1 Refer to NOTE 3 of the ADCON2 Register Set to 1 (A/D operation enabled)
b7
ADSTBY A/D standby bit (3) ADEX0 Extended pin select bit ADEX1
0 0 1 1
b6
0 : ANEX0 and ANEX1 are not used 1 : Do not set 0 : Do not set 1 : Do not set
NOTES : 1. If the ADCON1 register is rewritten during A/D conversion, the conversion result will be indeterminate. 2. AN0_0 to AN0_7 and AN2_0 to AN2_7 can be used in the same way as AN0 to AN7. Use bits ADGSEL1 and ADGSEL0 in the ADCON2 register to select the desired pin. 3. If the ADSTBY bit is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or more before starting A/D conversion.
Figure 18.8
Registers ADCON0 and ADCON1 (Repeat Sweep Mode 1)
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M16C/64 Group
18. A/D Converter
18.2
Conversion Rate
The conversion rate is defined as follows. Start dummy time depends on which AD is selected. Table 18.7 shows Start Dummy Time. When the ADST bit in the ADCON0 register is set to 1 (A/D conversion start), A/D conversion starts after start dummy time elapses. 0 (A/D conversion stop) is read if the ADST bit is read before A/D conversion starts. For multiple pins or A/D conversion repeat mode, for each pin, between-execution dummy time is inserted between A/D conversion execution time and the next A/D conversion execution time. The ADST bit is set to 0 during the end dummy time, and the last A/D conversion result is set to the ADi register in one-shot mode and single sweep mode. While in one-shot mode: Start dummy time + A/D conversion execution time + end dummy time When two pins are selected while in single sweep mode: Start dummy time + (A/D conversion execution time + between-execution dummy time + A/D conversion execution time) + end dummy time Start dummy time: See Table 18.7 "Start Dummy Time" A/D conversion execution time: 40 AD cycles per pin Between-execution dummy time: 1 AD cycle End dummy time: 2 to 3 cycles of fAD
Table 18.7 Start Dummy Time
AD Selection fAD fAD divided by 2 fAD divided by 3 fAD divided by 4 fAD divided by 6 fAD divided by 12
Start Dummy Time 1 to 2 cycles of fAD 2 to 3 cycles of fAD 3 to 4 cycles of fAD 3 to 4 cycles of fAD 4 to 5 cycles of fAD 7 to 8 cycles of fAD
18.3
Extended Analog Input Pins
In one-shot and repeat modes, pins ANEX0 and ANEX1 can be used as analog input pins. Use bits ADEX1 and ADEX0 in the ADCON1 register to select whether or not to use ANEX0 and ANEX1. The A/D conversion results of ANEX0 and ANEX1 inputs are stored in registers AD0 and AD1, respectively.
18.4
Current Consumption Reducing Function
When not using the A/D converter, power consumption can be reduced by setting the ADSTBY bit in the ADCON1 register to 0 (A/D operation stopped: standby) to shut off any analog circuit current flow. To use the A/D converter, set the ADSTBY bit to 1 (A/D operation enabled) after operating longer than one cycle of a timer count source, and then set the ADST bit in the ADCON0 register to 1 (A/D conversion start). Do not set bits ADST and ADSTBY to 1 at the same time. Also, do not set the ADSTBY bit to 0 (A/D operation stopped: standby) during A/D conversion.
REJ09B0392-0064 Rev.0.64 Page 244 of 373
Oct 12, 2007
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M16C/64 Group
18. A/D Converter
18.5
Output Impedance of Sensor under A/D Conversion
Microcomputer Sensor equivalent circuit R0 VIN C (10.0 pF) VC R (10.0 kW) Sampling time 15
AD
Figure 18.9
Analog Input Pin and External Sensor Equivalent Circuit
REJ09B0392-0064 Rev.0.64 Page 245 of 373
Oct 12, 2007
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M16C/64 Group
19. D/A Converter
19. D/A Converter
19.1 Summary
The D/A converter consists of two independent 8-bit R-2R type D/A converters. D/A conversion is performed by writing to the DAi register (i = 0 to 1). To output the result of conversion, set the DAiE bit in the DACON register to 1 (output enabled). Before using D/A conversion, clear the corresponding port direction bit to 0 (input mode). When the DAiE bit is set to 1 (input enabled), pull-up of a corresponding port is disabled. Output analog voltage (V) is determined by a set value (n: decimal) in the DAi register. n V = VREF x --------- (n = 0 to 255) 256 VREF: reference voltage Table 19.1 lists the D/A Converter Performance. Figure 19.1 shows the D/A Converter Block Diagram. Figure 19.2 shows Registers DACON, DA0, and DA1. Figure 19.3 shows the D/A Converter Equivalent Circuit.
Table 19.1 D/A Converter Performance
Item D/A Conversion Method Resolution Analog Output Pin
Performance R-2R 8 bits 2 channels (DA0 and DA1)
Low-Order Bits of Data Bus
DA0 register
0
R-2R resistor ladder
1
DA0 DA0E bit
DA1 register
0
R-2R resistor ladder
1
DA1 DA1E bit
Figure 19.1
D/A Converter Block Diagram
REJ09B0392-0064 Rev.0.64 Page 246 of 373
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M16C/64 Group
19. D/A Converter
D/A Control Register (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol DACON
Bit Symbol
Address 03DCh Bit Name D/A 0 output enable bit D/A 1 output enable bit Function 0 : Output disabled 1 : Output enabled 0 : Output disabled 1 : Output enabled
After Reset 00h RW RW RW --
DA0E DA1E -- (b7-b2)
No register bits. If necessary, set to 0. Read as 0
NOTE : 1. When not using the D/A converter, clear the DAiE bit (i = 0 to 1) to 0 (output disabled) to reduce the unnecessary current consumption in the chip and set the DAi register to 00h to prevent current from flowing into the R-2R resistor ladder.
D/Ai Register (i = 0 to 1) (1)
b7 b0
Symbol DA0 DA1 Function Output value of D/A conversion
Address 03D8h 03DAh
After Reset 00h 00h Setting Range 00h to FFh RW RW
NOTE : 1. When not using the D/A converter, clear the DAiE bit (i = 0 to 1) to 0 (output disabled) to reduce the unnecessary current consumption in the chip and set the DAi register to 00h to prevent current from flowing into the R-2R resistor ladder.
Figure 19.2
Registers DACON, DA0, and DA1
DAiE bit r DAi 0 R R R R R R R 2R
1 2R MSB DAi register 2R 2R 2R 2R 2R 2R 2R LSB
0
1
AVSS VREF (2) i = 0 to 1 NOTES: 1. The above diagram applies when the DAi register is set to 2Ah. 2. VREF is not related to ADSTBY bit in the AD0CON1 register.
Figure 19.3
D/A Converter Equivalent Circuit
REJ09B0392-0064 Rev.0.64 Page 247 of 373
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M16C/64 Group
20. CRC Operation
20. CRC Operation
The Cyclic Redundancy Check (CRC) operation detects an error in data blocks. The microcomputer uses a generator polynomial of CRC_CCITT (X16 + X12 + X5 + 1) to generate CRC code. The CRC code consists of 16 bits which are generated for each data block in given length, separated in 8 bit units. After the initial value is set in the CRCD register, the CRC code is set in that register each time one byte of data is written to the CRCIN register. CRC code generation for one-byte data is finished in two cycles. Figure 20.1 shows the CRC Circuit Block Diagram. Figure 20.2 shows Registers CRCD and CRCIN. Figure 20.3 shows an example using the CRC Operation.
Data bus (high-order) Data bus (low-order)
Eight low-order bits
Eight high-order bits
CRCD register
CRC code generating circuit X16 + X12 + X5 + 1
CRCIN register
Figure 20.1
CRC Circuit Block Diagram
CRC Data Register
(b15) b7 (b8) b0 b7 b0
Symbol CRCD
Address 03BDh to 03BCh
After Reset Indeterminate
Function When data is written to the CRCIN register after setting the initial value in the CRCD register, the CRC code can be read out from the CRCD register.
Setting Range 0000h to FFFFh
RW RW
CRC Input Register
b7 b0
Symbol CRCIN
Address 03BEh
After Reset Indeterminate
Function Data input
Setting Range 00h to FFh
RW RW
Figure 20.2
Registers CRCD and CRCIN
REJ09B0392-0064 Rev.0.64 Page 248 of 373
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M16C/64 Group
20. CRC Operation
Setup procedure and CRC operation when generating CRC code "80C4h"
* CRC operation performed by the M16C CRC code : remainder of a division in which the value written to the CRCIN register with its bit positions reversed is divided by the generator polynomial Generator polynomial : X16 + X12 + X5 + 1 (1 0001 0000 0010 0001b)
* Setting procedure (1) Reverse the bit positions of the value "80C4h" by program in 1-byte units. 80h 01h, C4h 23h
b15
b0
(2) Write 0000h (initial value)
CRCD register
b7
b0
(3) Write 01h
b15
b0
CRCIN register Two cycles later, the CRC code for 80h, i.e., 9188h, has its bit positions reversed to become 1189h which is stored in the CRCD register. CRCD register
1189h
b7
b0
(4) Write 23h
b15
b0
CRCIN register Two cycles later, the CRC code for 80C4h, i.e., 8250h, has its bit positions reversed to become 0A41h which is stored in the CRCD register. CRCD register
0A41h
* Details of CRC operation As shown in (3) above, bit position of 01h (00000001b) written to the CRCIN register is reversed and becomes 10000000b. Add 1000 0000 0000 0000 0000 0000b, as 10000000b plus 16 digits, to 0000 0000 0000 0000 0000 0000b, as 0000 0000 0000 0000b plus 8 digits as the default value of the CRCD register to perform the modulo-2 division. 1000 0000 1 1000 0000 1000 1000 0000 0 1 1000 Modulo-2 operation is operation that complies with the law given below. 0+0=0 0+1=1 1+0=1 1+1=0 -1 = 1
1 0001 0000 0010 0001 1000 0000 0000 0000 1000 1000 0001 0000 1000 0001 0000 Generator polynomial 1000 1000 0001 1001 0001 CRC code
Data
0001 0001 1000 1001b (1189h), the remainder 1001 0001 1000 1000b (9188h) with inversed bit position, can be read from the CRCD register. When going on to (4) above, 23h (00100011b) written in the CRCIN register is reversed and becomes 11000100b. Add 1100 0100 0000 0000 0000 0000b, as 11000100b plus 16 digits, to 1001 0001 1000 1000 0000 0000b, as 1001 0001 1000 1000b plus 8 digits as a remainder of (3) left in the CRCD register to perform the modulo-2 division. 0000 1010 0100 0001b (0A41h), the remainder with reversed bit position, can be read from the CRCD register.
Figure 20.3
CRC Operation
REJ09B0392-0064 Rev.0.64 Page 249 of 373
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M16C/64 Group
21. Programmable I/O Ports
21. Programmable I/O Ports
88 programmable input / output ports (I/O ports) are available. The direction registers determine individual port status, input or output. The pull-up control registers determine whether the pots, divided into groups of four ports, are pulled up or not. P8_5 is an input port and no pull-up is allowed. Port P8_5 shares the pin with NMI, so that the NMI input level can be read from the P8_5 bit in the P8 register. Figures 21.1 to 21.5 show the I/O ports. Figure 21.6 shows the I/O Pins. Each pin functions as an I/O port, a peripheral function input / output, or a bus control pin. To set peripheral functions, refer to the description for individual functions. If any pin is used as a peripheral function input or D/A converter output pin, set the direction bit of the corresponding pin to 0 (input mode). Any pin used as an output pin for peripheral functions other than the D/A converter is directed for output no matter how the corresponding direction bit is set. To use as bus control pins, refer to 8.2 "Bus Control". P0 to P5 are capable of VCC2-level input / output; P6 to P10 are capable of VCC1- level input / output.
21.1
Port Pi Direction Register (PDi Register, i = 0 to 10)
Figure 21.7 shows the Pi Direction Registers. This register selects whether the I/O port is to be used for input or output. Each bit in the PDi register corresponds to one port. During memory extension or microprocessor mode, the PDi registers for the pins functioning as bus control pins (A0 to A19, D0 to D15, CS0 to CS3, RD, WRL / WR, WRH / BHE, ALE, RDY, HOLD, HLDA, and BCLK) cannot be modified.
21.2
Port Pi Register (Pi Register, i = 0 to 10)
Figure 21.8 shows the Pi Registers. Data input / output to and from external devices are accomplished by reading and writing to the Pi register. Each bit of the Pi register consists of a port latch to hold the output data and a circuit to read the pin status. For ports set for input mode, the input level of the pin can be read by reading the corresponding Pi register, and data can be written to the port latch by writing to the Pi register. For ports set for output mode, the port latch can be read by reading the corresponding Pi register, and data can be written to the port latch by writing to the Pi register. The data written to the port latch is output from the pin. Each bit in the Pi register correspond to each port. During memory extension or microprocessor mode, the Pi registers for the pins functioning as bus control pins (A0 to A19, D0 to D15, CS0 to CS3, RD, WRL / WR, WRH / BHE, ALE, RDY, HOLD, HLDA, and BCLK) cannot be modified.
21.3
Pull-up Control Register 0 to Pull-up Control Register 2 (Registers PUR0 to PUR2)
Figures 21.9 and 21.10 show the Registers PUR0 to PUR2. Bits in registers PUR0 to PUR2 can be used to select whether or not to pull the corresponding port high in 4 pin units. The port chosen to be pulled high has a pull-up resistor connected to it when the direction bit is set for input mode. However, the pull-up control register has no effect on P0 to P3, P4_0 to P4_3, and P5 during memory extension or microprocessor mode. Although the register contents can be modified, no pull-up resistors are connected.
21.4
Port Control Register (PCR Register)
Figure 21.11 shows the PCR Register. When the P1 register is read after setting the PCR0 bit in the PCR register to 1, the corresponding port latch can be read no matter how the PD1 register is set. REJ09B0392-0064 Rev.0.64 Page 250 of 373 Oct 12, 2007
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M16C/64 Group
21. Programmable I/O Ports
Pull-up selection Direction register
P0_0 to P0_7, P2_0 to P2_3, P2_6 to P2_7, P10_0 to P10_3
(dotted section included) Data bus
Port latch (NOTE 1)
P3_0 to P3_7, P4_0 to P4_3, P5_0 to P5_4, P5_6
(dotted section not included)
Analog input
Pull-up selection Direction register
1
P1_0
Port P1 control register
output
Data bus
Port latch
(NOTE 1)
Pull-up selection Direction register
1
P1_1 to P1_3
Port P1 control register
output
Data bus
Port latch (NOTE 1)
CMOS / Nch Selection
NOTE: 1.
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC. VCC: VCC1 for ports P6 to P10, and VCC2 for ports P0 to P5.
Figure 21.1
I/O Ports (1)
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M16C/64 Group
21. Programmable I/O Ports
Pull-up selection Direction register
P1_4
(dotted section not included)
P1_5 to P1_7
(dotted section included)
Port P1 control register Data bus Port latch (NOTE 1)
Input to respective peripheral functions
Pull-up selection
P2_4, P2_5 P10_4 to P10_7
Direction register
Data bus
Port latch (NOTE 1)
Analog input Input to respective peripheral functions Port control register
Pull-up selection Direction register
1
P4_4, P5_7, P6_0, P6_4, P7_3 to P7_5, P8_1, P9_0, P9_2
Data bus
output
Port latch (NOTE 1)
Input to respective peripheral functions
NOTE: 1.
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC. VCC: VCC1 for ports P6 to P10, and VCC2 for ports P0 to P5.
Figure 21.2
I/O Ports (2)
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M16C/64 Group
21. Programmable I/O Ports
Pull-up selection Direction register
1
P4_5 to P4_7, P6_1 to P6_3, P6_5 to P6_7, P7_2, P7_6 to P7_7, P8_0
Data bus
output
Port latch (NOTE 1) CMOS / Nch selection
Input to respective peripheral functions
Pull-up selection
P5_5, P8_2 to P8_4, P9_1, P9_7
Direction register
Data bus
Port latch (NOTE 1)
Input to respective peripheral functions
P7_0, P7_1
Direction register
1
output
Data bus
Port latch (NOTE 1)
Input to respective peripheral functions
NOTE: 1.
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC. VCC: VCC1 for ports P6 to P10, and VCC2 for ports P0 to P5.
Figure 21.3
I/O Ports (3)
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21. Programmable I/O Ports
NMI enabled Direction register
P8_5
Data bus
Port latch (NOTE 1)
NMI interrupt input NMI enabled SD input
Pull-up selection D/A output enabled Direction register
P9_3, P9_4
Data bus
Port latch (NOTE 1)
Input to respective peripheral functions
Analog output D/A output enabled Pull-up selection
P9_5
(Inside dotted-line included)
Direction register
1
P9_6
(Inside dotted-line not included)
output
Data bus
Port latch (NOTE 1)
Input to respective peripheral functions Analog input
NOTE: 1.
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC. VCC: VCC1 for ports P6 to P10, and VCC2 for ports P0 to P5.
Figure 21.4
I/O Ports (4)
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21. Programmable I/O Ports
Pull-up selection Direction register
P8_7
Data bus
Port latch (NOTE 1) fC
Rf Pull-up selection Direction register
1
P8_6
Rd
output
Data bus
Port latch (NOTE 1)
NOTE: 1.
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC. VCC: VCC1 for ports P6 to P10, and VCC2 for ports P0 to P5.
Figure 21.5
I/O Ports (5)
BYTE BYTE signal input
(NOTE 1)
CNVSS CNVSS signal input
(NOTE 1)
RESET RESET signal input NOTE: 1.
(NOTE 1)
symbolizes a parasitic diode. Make sure the input voltage on each port will never exceed VCC1.
Figure 21.6
I/O Pins
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21. Programmable I/O Ports
Port Pi Direction Register (i = 0 to 10) (1, 2)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PD0 to PD3 PD4 to PD7 PD8 PD9, PD10
Bit Symbol
Address 03E2h, 03E3h, 03E6h, 03E7h 03EAh, 03EBh, 03EEh, 03EFh 03F2h 03F3h, 03F6h Bit Name Port Pi_0 direction bit Port Pi_1 direction bit Port Pi_2 direction bit Port Pi_3 direction bit Port Pi_4 direction bit Port Pi_5 direction bit Port Pi_6 direction bit Port Pi_7 direction bit Function 0 : Input mode (Functions as an input port) 1 : Output mode (Functions as an output port)
After Reset 00h 00h 00h 00h RW RW RW RW RW RW RW RW RW
PDi_0 PDi_1 PDi_2 PDi_3 PDi_4 PDi_5 PDi_6 PDi_7
NOTES : 1. Make sure the PD9 register is written following the instruction to set the PRC2 bit in the PRCR register to 1 (write enabled). 2. During memory extension and microprocessor modes, the PDi register for the pins functioning as bus control pins (A0 to A19, D0 to D15, CS0 to CS3, RD, WRL / WR, WRH / BHE, ALE, RDY, HOLD, HLDA and BCLK) cannot be modified.
Figure 21.7
Registers PD0 to PD10
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21. Programmable I/O Ports
Port Pi Register (i = 0 to 10) (2)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol P0 to P3 P4 to P7 P8 P9, P10
Bit Symbol
Address 03E0h, 03E1h, 03E4h, 03E5h 03E8h, 03E9h, 03ECh, 03EDh 03F0h 03F1h, 03F4h Bit Name Port Pi_0 bit Port Pi_1 bit Port Pi_2 bit Port Pi_3 bit Port Pi_4 bit Port Pi_5 bit Port Pi_6 bit Port Pi_7 bit Function
After Reset Indeterminate Indeterminate Indeterminate Indeterminate RW RW RW RW RW RW RW RW RW
Pi_0 Pi_1 Pi_2 Pi_3 Pi_4 Pi_5 Pi_6 Pi_7
The pin level on any I/O port which is set for input mode can be read by reading the corresponding bit in this register. The pin level on any I/O port which is set for output mode can be controlled by writing to the corresponding bit in this register 0 : "L" level 1 : "H" level (1)
NOTES : 1. Since P7_0, P7_1, and P8_5 are N-channel open drain ports, the pin status becomes high-impedance. 2. During memory extension and microprocessor modes, the Pi register for the pins functioning as bus control pins (A0 to A19, D0 to D15, CS0 to CS3, RD, WRL / WR, WRH / BHE, ALE, RDY, HOLD, HLDA and BCLK) cannot be modified.
Figure 21.8
Registers P0 to P10
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21. Programmable I/O Ports
Pull-up Control Register 0 (1)
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PUR0
Bit Symbol
Address 0360h Bit Name P0_0 to P0_3 pull-up P0_4 to P0_7 pull-up P1_0 to P1_3 pull-up P1_4 to P1_7 pull-up P2_0 to P2_3 pull-up P2_4 to P2_7 pull-up P3_0 to P3_3 pull-up P3_4 to P3_7 pull-up Function 0 : Not pulled high 1 : Pulled high (2)
After Reset 00h RW RW RW RW RW RW RW RW RW
PU00 PU01 PU02 PU03 PU04 PU05 PU06 PU07
NOTES : 1. During memory extension or microprocessor mode, the corresponding register contents can be modified, but the pins are not pulled high. 2. The pin for which this bit is 1 (pulled high) and the direction bit is 0 (input mode) is pulled high.
Pull-up Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PUR1
Bit Symbol
Address 0361h Bit Name P4_0 to P4_3 pull-up
(2)
After Reset (5) 00000000b 00000010b Function 0 : Not pulled high 1 : Pulled high (3) RW RW RW RW RW RW RW RW RW
PU10 PU11 PU12 PU13 PU14 PU15 PU16 PU17
P4_4 to P4_7 pull-up (4) P5_0 to P5_3 pull-up (2) P5_4 to P5_7 pull-up (2) P6_0 to P6_3 pull-up P6_4 to P6_7 pull-up P7_2 to P7_3 pull-up (1) P7_4 to P7_7 pull-up
NOTES : 1. Pins P7_0 and P7_1 do not have pull-ups. 2. During memory extension and microprocessor modes, the pins are not pulled high although the contents of these bits can be modified. 3. To enable the pull-up registers, the corresponding bit in the register should be set to 1 (pulled high) and the respective bits in the direction register should be set to 0 (input mode). 4. If bits PM01 to PM00 in the PM0 register are set to 01b (memory expansion mode) or 11b (microprocessor mode) in a program during single-chip mode, the PU11 bit becomes 1. 5. The values after hardware reset 1 or brown-out reset is as follows: * 00000000b when input on CNVSS pin is "L" * 00000010b when input on CNVSS pin is "H" The values after software reset, watchdog timer reset, and oscillation stop detection reset are as follows: * 00000000b when bits PM01 to PM00 are 00b (single-chip mode) * 00000010b when bits PM01 to PM00 are 01b (memory expansion mode) or 11b (microprocessor mode)
Figure 21.9
Registers PUR0 and PUR1
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21. Programmable I/O Ports
Pull-up Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PUR2
Bit Symbol
Address 0362h Bit Name P8_0 to P8_3 pull-up P8_4 to P8_7 pull-up (2) P9_0 to P9_3 pull-up P9_4 to P9_7 pull-up P10_0 to P10_3 pull-up P10_4 to P10_7 pull-up No register bits. If necessary, set to 0. Read as 0 Function 0 : Not pulled high 1 : Pulled high (1)
After Reset 00h RW RW RW RW RW RW RW --
PU20 PU21 PU22 PU23 PU24 PU25 -- (b7-b6)
NOTES : 1. To enable the pull-up registers, the corresponding bit in the register should be set to 1 (pulled high) and the respective bits in the direction register should be set to 0 (input mode). 2. The P8_5 pin does not have pull-up.
Figure 21.10 PUR2 Register
Port Control Register
b7 b6 b5 b4 b3 b2 b1 b0
Symbol PCR
Bit Symbol
Address 0366h Bit Name Function
After Reset 00000XX0b RW
PCR0
Port P1 control bit
Operation performed when the P1 register is read 0 : When the port is set for input, the input levels of pins P1_0 to P1_7 are read. When set for output, the port latch is read. 1 : The port latch is read regardless of whether the port is set for input or output.
RW
-- (b4-b1) PCR5 PCR6 PCR7
No register bits. If necessary, set to 0. Read as 0 INT6 input enable bit (1) INT7 input enable bit (2) Key input enable bit (3) 0 : Enabled 1 : Disabled 0 : Enabled 1 : Disabled 0 : Enabled 1 : Disabled
-- RW RW RW
NOTES : 1. To use the AN2_4 pin as an analog input pin, set the PCR5 bit to 1 (INT6 input disabled). 2. To use the AN2_5 pin as an analog input pin, set the PCR6 bit to 1 (INT7 input disabled). 3. To use pins AN4 to AN7 as analog input pins, set the PCR7 bit to 1 (key input disabled).
Figure 21.11 PCR Register
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21. Programmable I/O Ports
Table 21.1
Unassigned Pin Handling in Single-chip Mode
Pin Name Ports P0 to P5
Connection (2) One of the followings: Set for input mode and connect a pin to VSS via resistor (pull-down) Set for input mode and connect a pin to VCC2 via resistor (pull-up) Set for output mode and leave the pins open (1) One of the followings: Set for input mode and connect a pin to VSS via resistor (pull-down) Set for input mode and connect a pin to VCC1 via resistor (pull-up) Set for output mode and leave the pins open (1, 3) Open Connect to VCC1 (pull-up) via resistor Connect to VCC1 Connect to VSS
Ports P6 to P10
XOUT (4) XIN AVCC, VREF AVSS, BYTE
NOTES: 1. When setting the port for output mode and leave it open, be aware that the port remains in input mode until it is switched to output mode in a program after reset. For this reason, the voltage level on the pin becomes indeterminate, causing the power supply current to increase while the port remains in input mode. 2. Furthermore, by considering a possibility that the contents of the direction registers could be changed by noise or noise-induced loss of control, it is recommended that the contents of the direction registers be regularly reset in software to improve reliability of the program. 3. Make sure the unused pins are processed with the shortest possible wiring from the microcomputer pins (within 2 cm). 4. When the ports P7_0, P7_1, and P8_5 are set for output mode, make sure a low-level signal is output from the pins. 5. The ports P7_0, P7_1, and P8_5 are N-channel open-drain outputs. 6. This applies when external clock is input to the XIN pin or when VCC1 is connected to via a resistor.
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21. Programmable I/O Ports
Table 21.2
Unassigned Pin Handling in Memory Expansion Mode and Microprocessor Mode
Pin Name Ports P0 to P5
Connection (2) One of the followings: Set for input mode and connect a pin to VSS via resistor (pull-down) Set for input mode and connect a pin to VCC2 via resistor (pull-up) Set for output mode and leave the pins open (1, 3) One of the followings: Set for input mode and connect a pin to VSS via resistor (pull-down) Set for input mode and connect a pin to VCC1 via resistor (pull-up) Set for output mode and leave the pins open (1, 4) Open Connect to VCC2 (pull-up) via resistor Connect to VCC1 (pull-up) via resistor Connect to VCC1 Connect to VSS
Ports P6 to P10
BHE, ALE, HLDA,
XOUT (5), BCLK (6)
HOLD , RDY
XIN AVCC, VREF AVSS
NOTES: 1. When setting the port for output mode and leave it open, be aware that the port remains in input mode until it is switched to output mode in a program after reset. For this reason, the voltage level on the pin becomes indeterminate, causing the power supply current to increase while the port remains in input mode. 2. Furthermore, by considering a possibility that the contents of the direction registers could be changed by noise or noise-induced loss of control, it is recommended that the contents of the direction registers be regularly reset in software to improve reliability of the program. 3. Make sure the unused pins are processed with the shortest possible wiring from the microcomputer pins (within 2 cm). 4. If the CNVSS pin has the VSS level applied to it, these pins are set for input ports until the processor mode is switched over in a program after reset. For this reason, the voltage levels on these pins become indeterminate, causing the power supply current to increase while they remain set for input ports. 5. When the ports P7_0, P7_1, and P8_5 are set for output mode, make sure a low-level signal is output from the pins. 6. The ports P7_0, P7_1, and P8_5 are N-channel open-drain outputs. 7. This applies when external clock is input to the XIN pin or when VCC1 is connected to via a resistor. 8. If the PM07 bit in the PM0 register is set to 1 (BCLK not output), connect this pin to VCC2 via a resistor (pulled high).
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21. Programmable I/O Ports
Microcomputer
Port P0 to P10 (Input mode)
. . . . . .
Microcomputer
Port P6 to P10 (Input mode)
. . . . . .
(Input mode) (Output mode)
XIN XOUT
(Input mode)
Open
VCC1
VCC2
Port P4_5 / CS1 to P4_7 / CS3
(Output mode)
XIN BHE HLDA ALE XOUT BCLK (1) HOLD
Open
VCC1
Open
VCC1
Open VCC2 VCC1
AVCC
VREF BYTE
RDY AVCC
AVSS
VREF
VSS In single-chip mode
AVSS
VSS In memory expansion mode or in microprocessor mode
NOTE: 1. If the PM07 bit in the PM0 register is set to 1 (BCLK not output), connect this pin to VCC2 via a resistor (pulled high).
Figure 21.12 Unassigned Pin Handling
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22. Flash Memory Version
22. Flash Memory Version
The flash memory can perform in three rewrite modes: CPU rewrite mode, standard serial I/O mode, and parallel I/O mode. Table 22.1 lists specifications of the flash memory version. See Tables 1.1 and 1.2 Specifications Overview for the items not listed in Table 22.1.
Table 22.1 Flash Memory Version Specifications
Specification 3 modes (CPU rewrite, standard serial I/O, parallel I/O) See Figure 22.1 "Flash Memory Block Diagram" 1 block (16 Kbytes) 2 blocks (4 Kbytes each) In units of 2 words Block erase Program and erase controlled by software command The lock bit protects each block 8 commands 100 times (2, 3) 10 years Parallel I/O and standard serial I/O modes are supported
Item Flash Memory Rewrite Mode Erase Block Program ROM 1 Program ROM 2 Data Flash Program Method Erase Method Program and Erase Control Method Protect Method Number of Commands Program and Erase Endurance Data Retention ROM Code Protection
NOTE: 1. Definition of program and erase endurance The program and erase endurance refers to the number of per-block erasures. For example, assume a case where a 4 Kbyte block is programmed in 1,024 operations, writing two words at a time, and erased thereafter. In this case, the block is reckoned as having been programmed and erased once. If the program and erase endurance is 100 times, each block can be erased up to 100 times.
Table 22.2
Flash Memory Rewrite Modes Overview
CPU rewrite Mode (1) Standard Serial I/O Mode Program ROM 1, program ROM 2, and data flash are rewritten using a dedicated serial programmer. Standard serial I/O mode 1: clock synchronous serial I/O Standard serial I/O mode 2: clock asynchronous serial I/O Parallel I/O Mode Program ROM 1, program ROM 2 and data flash are rewritten using a dedicated parallel programmer.
Program ROM 1, program ROM 2, and data flash are rewritten when the CPU executes software commands. EW0 mode: Rewritable in areas other than flash memory (2) EW1 mode: Rewritable in the flash memory Areas Which Can Program ROM 1, program ROM 2, and Be Rewritten data flash Operating Mode Single-chip mode Memory expansion mode (EW0 mode) ROM Programmer None
Flash Memory Rewrite Mode Function
Program ROM 1, program ROM Program ROM 1 and 2, and data flash program ROM 2 Boot mode Parallel I/O mode Serial programmer Parallel programmer
NOTES: 1. The PM13 bit remains set to 1 while the FMR01 bit in the FMR0 register = 1 (CPU rewrite mode enabled). The PM13 bit is reverted to its original value by clearing the FMR01 bit to 0 (CPU rewrite mode disabled). However, if the PM13 bit is changed during CPU rewrite mode, its changed value is not reflected until after the FMR01 bit is cleared to 0. 2. In CPU rewrite mode, bits PM10 and PM13 in the PM1 register are set to 1. The rewrite control program can only be executed in the internal RAM or in an external area that is enabled for use when the PM13 bit = 1. When the PM13 bit = 0 and the flash memory is used in 4-Mbyte mode, the extended accessible area (40000h to BFFFFh) cannot be used.
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22. Flash Memory Version
22.1
Memory Map
The flash memory contains program ROM 1, program ROM 2, and data flash. Figure 22.1 shows a Flash Memory Block Diagram. Program ROM 1 is divided into several blocks, each of which can be protected (locked) from program or erase. Program ROM 1 and program ROM 2 can be rewritten in CPU rewrite, standard serial I/O, and parallel I/O modes. Program ROM 2 can be used when the PRG2C0 bit in the PRG2C register is set to 0 (program ROM 2 enabled). The user boot code area is in program ROM 2. Data flash can be used when the PM10 bit in the PM1 register is set to 1 (0E000h to 0FFFFh: data flash). Data flash is divided into block A and block B.
00E000h 00EFFFh 00F000h 00FFFFh 010000h
Block A Block B Program ROM 2
Data flash
013FFFh 080000h
Block 7 : 64 Kbytes 08FFFFh 090000h
Block 6 : 64 Kbytes 09FFFFh 0A0000h Block 5 : 64 Kbytes
0AFFFFh 0B0000h
Block 4 : 64 Kbytes 0BFFFFh 0C0000h
Program ROM 1
Block 3 : 64 Kbytes
0CFFFFh 0D0000h Block 2 : 64 Kbytes
0DFFFFh 0E0000h
Block 1 : 64 Kbytes 0EFFFFh 0F0000h Block 0 : 64 Kbytes
0FFFFFh
NOTES: 1. To specify a block, use an even address in that block. 2. Shown here is a block diagram during single-chip mode.
Figure 22.1
Flash Memory Block Diagram
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22. Flash Memory Version
22.1.1
Boot Mode
The microcomputer enters boot mode when a hardware reset occurs while an "L" signal is applied to the P5_5 pin and an "H" signal is applied to pins CNVSS and P5_0. In boot mode, user boot mode or standard serial I/O mode is selected in accordance with the data in the user boot code area. Refer to 22.4 "Standard Serial I/O Mode" for details.
22.1.2
User Boot Function
User boot mode can be selected by the status of a port when the MCU starts in boot mode. Table 22.3 shows the user boot function specifications.
Table 22.3 User Boot Function Specifications
Item Entry Pin User Boot Start Level User Boot Start Address
Specification None or select a port from P0_0 to P10_7 Select "H" or "L" Address 10000h (the start address of program ROM 2)
Set "UserBoot" in ASCII code to the addresses 13FF0h to 13FF7h in the user boot code area and select a port for entry from addresses13FF8h to 13FF9h and the start level with the address 13FFBh. After starting boot mode, user boot mode or standard serial I/O mode is selected in accordance with the level of the selected port. In addition, if addresses 13FF0h to 13FF7h are set to "UserBoot" in ASCII code and address 13FF8h to 13FFBh are set to "00h", user boot mode is selected. In user boot mode, the program of address 10000h (the start address of program ROM2) is executed. Figure 22.2 shows user boot code area, Table 22.4 shows the start mode, Tables 22.5 and 22.6 the values to be set to the user boot code area.
Program ROM 2 10000h User Boot Start Address 13FF0h
User Boot Code Area Boot Code
13FF8h 13FFAh 13FFBh 13FFCh 13FF0h 13FFFh User Boot Code Area 13FFFh
Address Bit Start Level Select Reserved Space
Port information for entry
Figure 22.2
User Boot Code Area
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22. Flash Memory Version
Table 22.4
Start Mode (When the Port Pj_j is Selected for Entry)
Boot Code (13FF0h to 13FF7h) "UserBoot" in ASCII code
Port information for entry Address (13FF8h to 13FF9h) 0000h Pi register address Pi register address Bit (13FFAh) 00h Start level Select (13FFBh) 00h
Port Pi_j input level - H L H L -
Start Mode
User boot mode Standard serial I/O mode User boot mode User boot mode Standard serial I/O mode Standard serial I/O mode
00h to 07h 00h (value of j) 00h to 07h 01h (value of j) - -
Other Than "UserBoot" in ASCII code
-
i=0 to 10, j=0 to 7 NOTES: 1. Do not use another combination of values apart from Table 22.4. 2. Refer to Table 22.5 ""UserBoot"in ASCII code" 3. Refer to Table 22.6 "Addresses of Selectable Ports for Entry"
Table 22.5 "UserBoot"in ASCII code
Address ASCII code
13FF0h 55h (U) Uppercase
13FF1h 73h (s)
13FF2h 65h (e)
13FF3h 72h (r)
13FF4h 42h (B) Uppercase
13FF5h 6Fh (o)
13FF6h 6Fh (o)
13FF7h 74h (t)
Lower-case
Lower-case
Table 22.6
Addresses of Selectable Ports for Entry
Port P0 P1 P2 P3 P4 P5
Address 03E0h 03E1h 03E4h 03E5h 03E8h 03E9h
Port P6 P7 P8 P9 P10
Address 03ECh 03EDh 03F0h 03F1h 03F4h
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22. Flash Memory Version
22.2
Functions to Prevent Flash Memory from Rewriting
The flash memory has a built-in ROM code protect function for parallel I/O mode and a built-in ID code check function for standard I/O mode to prevent the flash memory from reading or rewriting.
22.2.1
ROM Code Protect Function
The ROM code protect function inhibits the flash memory from being read or rewritten during parallel input/output mode. Figure 22.3 shows the OFS1 Address. The OFS1 address is located in block 0 in program ROM 1. The ROM code protect function is enabled when the ROMCP1 bit is set to 0. When exiting ROM code protect, erase block 0 including the OFS1 address by the CPU rewrite mode or the standard serial I/O mode.
22.2.2
ID Code Check Function
Use the ID code check function in standard serial I/O mode. The ID code sent from the serial programmer is compared with the ID code written in the flash memory for a match. If the ID codes do not match, commands sent from the serial programmer are not accepted. However, if the four bytes of the reset vector are "FFFFFFFFh", ID codes are not compared, allowing all commands to be accepted. The ID codes are 7-byte data stored consecutively, starting with the first byte, into addresses 0FFFDFh, 0FFFE3h, 0FFFEBh, 0FFFEFh, 0FFFF3h, 0FFFF7h, and 0FFFFBh. The flash memory must have a program with the ID codes set in these addresses. Table 22.7 shows address for ID code stored. The reserved character sequence of the ASCII codes "ALeRASE" is used for forced erase function. The reserved character sequence of the ASCII codes "Protect" is used for standard serial I/O mode disabled function. Table 22.7 lists reserved character sequence. When the ID codes stored in the ID code addresses in the user ROM area are set to the ASCII codes: "ALeRASE" as the combination table listed in Table 22.7, forced erase function becomes active. When the forced erase function or standard serial I/O mode disabled function is not used, use another combination of the ASCII codes.
Table 22.7 Reserved Character Sequence (Reserved Word)
Reserved word combination of lD Code (ASCII) ID Code Address ALeRASE Protect FFFDFh ID1 41h (A) 50h (upper-case P) FFFE3h ID2 4Ch (L) 72h (lower-case r) FFFEBh ID3 65h (e) 6Fh (lower-case o) FFFEFh ID4 52h (R) 74h (lower-case t) FFFF3h ID5 41h (A) 65h (lower-case e) FFFF7h ID6 53h (S) 63h (lower-case c) FFFFBh ID7 45h (E) 74h (lower-case t) Reserve word for forced erase function: A set of reserved characters that match all the ID code addresses in sequence as the combination table listed in Table 22.7.
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22. Flash Memory Version
22.2.3
Forced Erase Function
This function is available only in standard serial I/O mode. When the reserved characters, "ALeRASE" in ASCII code, are sent from the serial programmer as ID codes, the content of the user ROM area will be erased at once. However, if the ID codes stored in the ID code addresses in the user ROM area are set to other than a reserved word "ALeRASE" (other than the combination table listed in Table 22.7) when the ROMCP bit in the ROMCP address is set to other than 11b (ROM code protect enabled), forced erase function is ignored and ID code check is executed. Table 22.8 lists conditions and functions for forced erase function. When both the ID codes sent from the serial programmer and the ID codes stored in the ID code addresses correspond to the reserved word "ALeRASE", the user ROM area will be erased. However, when the serial programmer sends other than "ALeRASE", even if the ID codes stored in the ID code addresses are "ALeRASE", there is no ID match and any command is ignored. The user ROM area remains protected accordingly.
Table 22.8 Forced Erase Function
Condition ID code from Code in ID code serial programmer stored address ALeRASE ALeRASE Other than ALeRASE (1)
Function ROMCP1 bit in the OFS1 address - 1 (ROM code protect disabled) 0(ROM code protect enabled) - -
User ROM area all erase (forced erase function) ID code check ID code check (no ID match) ID code check
Other than ALeRASE
ALeRASE Other than ALeRASE (1)
NOTE: 1. For the combination of the stored addresses is "Protect", refer to 22.2.4 "Standard Serial I/O Mode Disable Function".
22.2.4
Standard Serial I/O Mode Disable Function
This function is available in standard serial I/O mode. When the ID codes in the ID code stored addresses are set to "Protect" in ASCII code, the MCU does not communicate with a serial programmer. Therefore, the flash memory cannot be read, written or erased by a serial programmer. User boot mode can be selected, when the ID codes set to "Protect". When the ID codes are set to "Protect" and the ROMCP1 bit in the address OFS1 is set to 0 (ROM code protect enabled), ROM code protection cannot be disabled by a serial programmer. Therefore, the flash memory cannot be read, written or erased by a serial or parallel programmer.
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22. Flash Memory Version
Optional Feature Select Address (1)
b7 b6 b5 b4 b3 b2 b1 b0
111
11
Symbol OFS1
Bit Symbol
Address FFFFFh Bit Name Watchdog timer start select bit
(3)
After Reset FFh (2) Function RW
WDTON
0 : Watchdog timer starts automatically after reset 1 : Watchdog timer is in a stopped state after reset Set to 1 0 : ROM code protection enabled 1 : ROM code protection disabled Set to 1 0 : Count source protection mode enabled after reset 1 : Count source protection mode disabled after reset
RW
-- (b2-b1)
Reserved bits
RW RW RW
ROMCP1 ROM code protection bit -- (b6-b4) Reserved bits
CSPROINI
After-reset count source protection mode select bit (3)
RW
NOTES : 1. The OFS1 address exists in flash memory. Set the values when writing a program. 2. The OFS1 address is set to FFh when a block including the OFS1 address is erased. 3. Set the WDTON bit to 0 (watchdog timer starts automatically after reset) when setting the CSPROINI bit to 0 (count source protection mode enabled after reset).
Figure 22.3
OFS1 Address
Address 0FFFDFh to 0FFFDCh 0FFFE3h to 0FFFE0h 0FFFE7h to 0FFFE4h 0FFFEBh to 0FFFE8h 0FFFEFh to 0FFFECh 0FFFF3h to 0FFFF0h 0FFFF7h to 0FFFF4h 0FFFFBh to 0FFFF8h 0FFFFFh to 0FFFFCh ID3 ID4 ID5 ID6 ID7 OFS1 ID1 ID2 Undefined instruction vector Overflow vector BRK instruction vector Address match vector Single step vector Watchdog timer vector DBC vector NMI vector Reset vector
4 bytes
Figure 22.4 Address for ID Code Stored
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22. Flash Memory Version
22.3
CPU Rewrite Mode
In CPU rewrite mode, the flash memory can be rewritten when the CPU executes software commands. Program ROM 1, program ROM 2, and data flash can be rewritten with the microcomputer mounted on a board without using a ROM programmer. The program and block erase commands are executed only in each block area of program ROM 1, program ROM 2, and data flash. Erase-write 0 (EW0) mode and erase-write 1 (EW1) mode are provided as CPU rewrite mode. Table 22.9 lists differences between erase-write 0 (EW0) and erase-write 1 (EW1) modes.
Table 22.9 EW0 Mode and EW1 Mode
Item Operating Mode
Rewrite Control Program Allocatable Area Rewrite Control Pro- The rewrite control program must be transferred to any area other than the gram Executable flash memory (e.g., RAM) before being Area executed (2) Rewritable Area * Program ROM 1 * Program ROM 2 * Data flash Software Command None Restriction
EW0 Mode * Single-chip mode * Memory expansion mode * Program ROM 1 * Program ROM 2
EW1 Mode Single-chip mode * Program ROM 1 * Program ROM 2 The rewrite control program can be executed in program ROM 1, program ROM 2, and data flash. Program ROM 1, program ROM 2, and data flash, excluding blocks with the rewrite control program * Program and block erase commands cannot be executed in a block having the rewrite control program. * Read status register command cannot be used. Read array mode Maintains hold state (I/O ports maintains the state before the command execution) (1) Read bits FMR00, FMR06, and FMR07 in the FMR0 register by program
Mode after Program Read status register mode or Erase Operating CPU State during Auto Write and Auto Erase Flash Memory Status Detection * Read bits FMR00, FMR06, and FMR07 in the FMR0 register by program * Execute the read status register command to read bits SR7, SR5, and SR4 in the status register.
NOTES: 1. Do not generate an interrupt (except NMI interrupt) or start a DMA transfer. 2. When in CPU rewrite mode, bits PM10 and PM13 in the PM1 register are set to 1. The rewrite control program can only be executed in the internal RAM or in an external area that is enabled for use when the PM13 bit = 1. When the PM13 bit = 0 and the flash memory is used in 4-Mbyte mode, the extended accessible area (40000h to BFFFFh) cannot be used.
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22. Flash Memory Version
22.3.1
EW0 Mode
The microcomputer enters CPU rewrite mode by setting the FMR01 bit in the FMR0 register to 1 (CPU rewrite mode enabled) and is ready to accept commands. EW0 mode is selected by setting the FMR60 bit in the FMR6 register to 0. Figure 22.7 shows setting and resetting of EW0 mode. The software commands control programming and erasing. The FMR0 register or the status register indicates whether a program or erase operation is completed as expected or not.
22.3.2
EW1 Mode
EW1 mode is selected by setting the FMR60 bit to 1 after setting the FMR01 bit to 1. Figure 22.8 shows setting and resetting of EW1 mode. The FMR0 register indicates whether or not a program or erase operation has been completed as expected. The status register cannot be read in EW1 mode. When a program / erase operation is initiated, the CPU halts all program execution until the operation is completed.
22.3.3
Flash Memory Control Register (Registers FMR0, FMR1, FMR2 and FMR6)
Figures 22.5 to 22.8 show the registers FMR0, FMR1, FMR2 and FMR6, respectively.
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22. Flash Memory Version
Flash Memory Control Register 0
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol FMR0
Bit Symbol
Address 0220h Bit Name Function 0 : Busy (being written or erased) (6) 1 : Ready
After Reset 00000001b RW RO RW RW
FMR00 FMR01 FMR02
RY / BY status flag
CPU rewrite mode select 0 : CPU rewrite mode disabled 1 : CPU rewrite mode enabled bit (1) Lock bit disable select bit 0 : Lock bit enabled (2) 1 : Lock bit disabled Flash memory stop bit
(3, 5, 7)
FMSTP
0 : Flash memory operation enabled 1 : Flash memory operation stopped (placed in low power mode, flash memory initialized) Set to 0 Set to 0 0 : Terminated normally 1 : Terminated in error 0 : Terminated normally 1 : Terminated in error
RW
-- (b4) -- (b5) FMR06 FMR07
Reserved bit Reserved bit Program status flag (4) Erase Status Flag (4)
RW RW RO RO
NOTES : 1. To set the FMR01 bit to 1, write a 0 and then a 1 in succession. Make sure no interrupts or DMA transfers will occur before writing a 1 after writing a 0. While in EW0 mode, write to this bit from a program in other than the flash memory. Enter read array mode, and then set this bit to 0. 2. To set the FMR02 bit to 1, write a 0 and then a 1 in succession when the FMR01 bit = 1. Make sure no interrupts or no DMA transfers will occur before writing a 1 after writing a 0. 3. Write to the FMSTP bit from a program in area other than the flash memory. 4. Bits FMR06 and FMR07 are cleared to 0 by executing the clear status command. 5. The FMSTP bit is valid when the FMR01 bit = 1 (CPU rewrite mode). If the FMR01 bit = 0, although the FMSTP bit can be set to 1 by writing 1 in a program, the flash memory is neither placed in low power mode nor initialized. 6. This status includes writing or reading with the lock bit program, block blank check, or read lock bit status command. 7. When the FMR23 bit in the FMR 2 register is set to 1 (low-current consumption), do not set the FMSTP bit to 1 (flash memory stop). Also, when the FMSTP bit is set to 1, do not set the FMR23 bit to 1.
Figure 22.5
FMR0 Register
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22. Flash Memory Version
Flash Memory Control Register 1
b7 b6 b5 b4 b3 b2 b1 b0
0
Symbol FMR1
Bit Symbol
Address 0221h Bit Name Function Read as undefined value 0 : Disabled 1 : Enabled Read as undefined value Set to 0
After Reset 00X0XX0Xb RW RO RW RO RW RW RO RW
-- (b0) FMR11 -- (b3-b2) -- (b4) -- (b5) FMR16 FMR17
Reserved bit Write to FMR6 register enable bit Reserved bits Reserved bit
No register bit. If necessary, set to 0. Read as undefined value Lock bit status flag Data flash wait bit (1) 0 : Lock 1 : Unlock 0 : 1 wait 1 : Follow the setting of the PM17 bit
NOTE : 1. When 2.7 V VCC1 3.0 V and f(BCLK) 16 MHz, or when 3.0 V < VCC1 5.5 V and f(BCLK) 20 MHz, one wait is necessary to read the data flash. Use the PM17 or FMR17 bit to set one wait.
Figure 22.6
FMR1 Register
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M16C/64 Group
22. Flash Memory Version
Flash Memory Control Register 2
b7 b6 b5 b4 b3 b2 b1 b0
00
Symbol
FMR2
Bit Symbol
Address 0222h Bit Name Function Set to 0 0 : Disabled 1 : Enabled
After Reset
XXXX0000b RW RW RW RW --
-- (b1-b0) FMR22 FMR23 -- (b7-b4)
Reserved bit Slow read mode enable bit (1, 3, 4)
Low-current consumption 0 : Disabled read mode enable bit 1 : Enabled (2, 3, 4, 5, 6, 7) No register bit. If necessary, set to 0. Read as undefined value
NOTES: 1. Slow read mode can be used when f(BCLK) 5 MHz. When f(BCLK) > 5 MHz, set the FMR22 bit to 0 (slow read mode disabled). 2. The low-current consumption read mode can be used when f(BCLK) 32.768 kHz. When f(BCLK) > 32.768 kHz, set the FMR23 bit to 0 (low-current consumption read mode disabled). 3. To set the FMR01 bit to 1, write a 0 and then a 1 in succession. Make sure no interrupts or DMA transfers will occur before writing a 1 after writing a 0. 4. This bit enables the mode to reduce the amount of current consumption when reading the flash memory. To rewrite flash memory (CPU rewrite mode), set the FMR22 and FMR23 bits to 0. 5. Set the FMR23 bit to 1 (low-current consumption read mode enabled) after the FMR22 bit is set to 1 (slow read mode enabled). Also, set the FMR22 bit to 0 (slow read mode disabled) after the FMR23 bit is set to 0 (slow read mode disabled). Do not write the FMR22 and FMR23 bits at same time. 6. When the FMR23 bit is set to 1, do not set the FMSTP bit in the FMR0 register to 1 (flash memory stopped). Also, when the FMSTP bit is set to 1, do not set the FMR23 bit to 1. 7. When the FMR23 bit in the FMR2 register is set to 1 (Low-current consumption read mode enabled), do not enter wait mode or stop mode. To enter wait mode or stop mode, set the FMR23 bit to 0 (lowcurrent consumption read mode disabled) before entering.
Figure 22.7
FMR2 Register
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22. Flash Memory Version
Flash Memory Control Register 6
b7 b6 b5 b4 b3 b2 b1 b0
0
1
Symbol FMR6
Bit Symbol
Address 0230h Bit Name Function 0 : EW0 mode 1 : EW1 mode Set to 1 Read as undefined value Set to 0 Read as undefined value
After Reset XX0XXX00b RW RW RW RO RW RO
FMR60 -- (b1) -- (b4-b2) -- (b5) -- (b7-b6)
EW1 mode select bit (1) Reserved bit Reserved bits Reserved bit Reserved bits
NOTE : 1. To set the FMR60 bit to 1, write 1 when both bits FMR01 and FMR11 are 1.
Figure 22.8
FMR6 Register
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22. Flash Memory Version
22.3.3.1
FMR00 Bit
This bit indicates the flash memory operating state. It is set to 0 while the program, block erase, lock bit program, read lock bit status command, or block blank check command is being executed; otherwise, it is set to 1.
22.3.3.2
FMR01 Bit
The microcomputer can accept commands when the FMR01 bit is set to 1 (CPU rewrite mode).
22.3.3.3
FMR02 Bit
The lock bit is disabled by setting the FMR02 bit to 1 (lock bit disabled). (Refer to 22.3.6 "Data Protect Function".) The lock bit is enabled by setting the FMR02 bit to 0 (lock bit enabled). The FMR02 bit does not change the lock bit status but disables the lock bit function. If an erase command is executed when the FMR02 bit is set to 1, the lock bit status changes 0 (locked) to 1 (unlocked) after command execution is completed.
22.3.3.4
FMSTP Bit
The FMSTP bit resets the flash memory control circuits and minimizes power consumption in the flash memory. Access to the flash memory is disabled when the FMSTP bit is set to 1 (flash memory stops). Set the FMSTP bit by program in an area other than the flash memory. Set the FMSTP bit to 1 if one of the followings occurs: * A flash memory access error occurs while erasing or programming in EW0 mode (the FMR00 bit does not switch back to 1 (ready)). * Low-power consumption mode or on-chip oscillator low-power consumption mode is entered Use the following steps to stop the flash memory. (1) Set the FMSTP bit to 1 (2) Wait tps (the wait time to stabilize the flash memory circuit) Use the following steps to restart. (1) Set the FMSTP bit to 0 (2) Wait tps (the wait time to stabilize the flash memory circuit) Figure 22.13 shows a Flow Chart Illustrating How to Start and Stop the Flash Memory Processing Before and After Low-Power Consumption Mode or On-Chip Oscillator Low-Power Consumption Mode. Follow the procedure on this flow chart. When entering stop or wait mode, the flash memory is automatically turned off. When exiting stop or wait mode, the flash memory is turned back on. The FMR0 register does not need to be set.
22.3.3.5
FMR06 Bit
This is a read-only bit indicating an auto program operation state. The FMR06 bit is set to 1 when a program error occurs; otherwise, it is set to 0. Refer to 22.3.8 "Full Status Check".
22.3.3.6
FMR07 Bit
This is a read-only bit indicating the auto erase operation status. The FMR07 bit is set to 1 when an erase error occurs; otherwise, it is set to 0. The FMR07 bit is also used for blank check. For details, refer to 22.3.8 "Full Status Check".
22.3.3.7
FMR11 Bit
The FMR11 bit enables programming to the FMR6 register.
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22. Flash Memory Version
22.3.3.8
FMR16 Bit
This is a read-only bit indicating the execution result of the read lock bit status command. When the block, where the read lock bit status command is executed, is locked, the FMR16 bit is set to 0. When the block, where the read lock bit status command is executed, is unlocked, the FMR16 bit is set to 1.
22.3.3.9
FMR17 Bit
This is a bit to select wait state for data flash.
22.3.3.10 FMR22 Bit
This bit enables the mode to reduce the amount of current consumption when reading the flash memory. When rewriting the flash memory (CPU rewrite mode), set the FMR22 bit to 0 (slow read mode disabled). Also, when f(BCLK) > 5 MHz, set the FMR22 bit to 0 (slow read mode disabled). Figure 22.9 shows setting and resetting of the slow read mode.
Slow read mode
Set the frequency of CPU clock to 5 MHz or less
Setting procedure After writing 0, write 1 (enabled) to the FMR22 bit
Process in slow read mode
Write 0 to FMR22 bit Resetting procedure
Return to the prior frequency of the CPU clock
Slow read mode is completed
Figure 22.9 Setting and Resetting of Slow Read Mode
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22. Flash Memory Version
22.3.3.11 FMR23 Bit
This bit enables the mode to reduce the amount of current consumption when reading the flash memory. When rewriting the flash memory (CPU rewrite mode), set the FMR23 bit to 0 (low-current consumption read mode disabled). This bit is effective when the FMR22 bit is enabled. When f(BCLK) > 32.768 kHz, set the FMR23 bit to 0 (low-current consumption read mode disabled). Figure 22.10 shows setting and resetting of the low-current consumption read mode.
Low-current consumption read mode
Write 1 to the CM07 bit to select the sub clock in CPU clock (1)
Set the CM05 bit to 1 (main clock oscillation stop) Setting procedure
After writing 0, write 1 (enabled) to the FMR22 bit
After writing 0, write 1 (enabled) to the FMR23 bit
Process in low-current consumption mode
Write 0 to FMR23 bit (2)
Write 0 to FMR22 bit (2)
Resetting Procedure
Return to the prior CPU clock
Slow read mode is completed
NOTES : 1. This is to use the low-power consumption mode. To use 125 kHz on-chip oscillator low power consumption mode, set the 125 kHz on-chip oscillator divided by 8 or 16 (Refer to Table 10.3 Setting Clock Related Bit and Modes). 2. Do not write the FMR22 bit and FMR23 bit at the same time.
Figure 22.10 Setting and Resetting of Low-current Consumption Read Mode
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22. Flash Memory Version
22.3.3.12 FMR60 Bit
This bit is used to select EW1 mode when the FMR01 bit is set to 1 (CPU rewrite mode enabled). Figure 22.11 shows Setting and Resetting of EW0 Mode. Figure 22.12 shows Setting and Resetting of EW1 Mode.
Procedure to Enter EW0 Mode
Rewrite control program Single-chip mode or memory expansion mode
(4)
Set the FMR01 bit to 0, and then 1 (CPU rewrite mode enabled). (2) Set the FMR11 bit to 1 (FMR6 register write enabled), and then set the FMR6 register to 02h (EW0 mode), and then set the FMR11 bit to 0 (FMR6 register write disabled).
Transfer the rewrite control program in CPU rewrite mode to an area other than the flash memory (4)
Execute the software commands
Set registers CM0, CM1, and PM1
(1)
Execute the read array command (3) Jump to the rewrite control program transferred to an area other than the flash memory. (In the following steps, use the rewrite control program in an area other than the flash memory)
Set the FMR01 bit to 0 (CPU rewrite mode disabled)
Jump to a desired address in the flash memory
NOTES : 1. In CPU rewrite mode, set the CM06 bit in the CM0 register and bits CM17 and CM16 in the CM1 register to CPU clock frequency of 10 MHz or less. Set the PM17 bit in the PM1 register to 1 (with wait state). 2. Set the FMR01 bit to 1 immmediately after setting it to 0. Do not generate an interrupt or a DMA transfer between setting the bit to 0 and setting it to 1. Set the FMR01 bit in a space other than flash memory. 3. Exit CPU rewrite mode after executing the read array command. 4. When in CPU rewrite mode, bits PM10 and PM13 in the PM1 register are set to 1. The rewrite control program can only be executed in the internal RAM or in an external area that is enabled for use when the PM13 bit = 1. When the PM13 bit = 0 and the flash memory is used in 4-Mbyte mode, the extended accessible area (40000h to BFFFFh) cannot be used.
Figure 22.11 Setting and Resetting of EW0 Mode
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22. Flash Memory Version
Procedure to Enter EW1 Mode Program in the ROM
Single-chip mode
(1)
Set registers CM0, CM1, and PM1
(2)
Set the FMR01 bit to 1 (CPU rewrite mode enabled) after writing a 0. (3) Set the FMR11 bit to 1 (FMR6 register rewrite enabled), and then set the FMR6 register to 03h (EW1 mode), and then set the FMR11 bit to 0 (FMR6 register rewrite disabled).
Execute the software commands
Set the FMR01 bit to 0 (CPU rewrite mode disabled)
NOTES: 1. In EW1 mode, do not enter memory expansion. 2. In CPU rewrite mode, set the CM06 bit in the CM0 register and bits CM17 and CM16 in the CM1 register to CPU clock frequency of 10 MHz or less. Set the PM17 bit in the PM1 register to 1 (with wait state). 3. To set the FMR01 bit to 1, write a 0 and then a 1 to the FMR01 bit. Make sure no interrupts or no DMA transfers will occur before writing a 1 after writing a 0. When setting the FMR11 bit to 1, set 1 while the FMR01 bit is set to 1.
Figure 22.12 Setting and Resetting of EW1 Mode
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22. Flash Memory Version
Transfer the low-power consumption mode or on-chip oscillator low-power consumption mode program to an area other than the flash memory
Jump to the low-power consumption mode or on-chip oscillator low-power consumption mode program transferred to an area other than the flash memory. (In the following steps, use the low-power consumption mode or on-chip oscillator lowpower consumption mode program in an area other than the flash memory.)
Low-power consumption mode or on-chip oscillator low-power consumption mode program
Set the FMR01 bit to 1 after setting to 0 (CPU rewrite mode enabled)
Set the FMSTP bit to 1 (The flash memory stops operating. In a low-power consumption state) (1)
Switch clock source of the CPU clock. The main clock stops (2)
Process in low-power consumption mode or on-chip oscillator low-power consumption mode NOTES: 1. Set the FMSTP bit to 1 after the FMR01 bit is set to 1 (CPU rewrite mode enabled). 2. Wait until clock stabilizes to switch clock source of the CPU clock to the main clock or sub clock. 3. Add tps wait time by program. Do not access the flash memory during this wait time. 4. Before entering wait mode or stop mode, be sure to set the FMR01 bit to 0.
Wait until oscillation stabilizes
(4)
Start main clock oscillation
Switch clock source of the CPU clock (2)
Set the FMSTP bit to 0 (flash memory operation)
Set the FMR01 bit to 0 (CPU rewrite mode disabled)
Wait until the flash memory stabilizes (tps) (3)
Jump to a desired address in the flash memory
Figure 22.13 Processing Before and After Low-Power Consumption Mode or On-Chip Oscillator Low-Power Consumption Mode
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22. Flash Memory Version
22.3.4 22.3.4.1
Precautions on CPU Rewrite Mode Operating Speed
Set the CM06 bit in the CM0 register and bits CM17 and CM16 in the CM1 register to a CPU clock frequency of 10 MHz or less before entering CPU rewrite mode (EW0 or EW1 mode). Also, set the PM17 bit in the PM1 register to 1 (wait state).
22.3.4.2
Prohibited Instructions
The following instructions cannot be used in EW0 mode because the CPU tries to read data in the flash memory: the UND instruction, INTO instruction, JMPS instruction, JSRS instruction, and BRK instruction.
22.3.4.3
Interrupts (EW0 mode)
* To use interrupts with vectors in a relocatable vector table, relocate the vectors to the RAM area. * The NMI and watchdog timer interrupts are available since registers FMR0 and FMR1 are forcibly reset when either interrupt occurs. Allocate the jump addresses for each interrupt routine to the fixed vector table. Flash memory rewrite operation stops when the NMI or watchdog timer interrupt occurs. Execute the rewrite program again after exiting the interrupt routine. * The address match interrupt is not available since the CPU tries to read data in the flash memory.
22.3.4.4
Interrupts (EW1 mode)
* Do not acknowledge any interrupts with vectors in a relocatable vector table or address match interrupt during the auto program or auto erase period. * Do not use the watchdog timer interrupt. * The NMI interrupt is available since registers FMR0 and FMR1 are forcibly reset when the interrupt occurs. Allocate the jump address for the interrupt routine to the fixed vector table. Flash memory rewrite operation stops when the NMI interrupt occurs. Execute the rewrite program again after exiting the interrupt routine.
22.3.4.5
How to Access
To set the FMR01 or FMR02 bit to 1, write a 1 after first setting the bit to 0. Make sure that no interrupts or no DMA transfers will occur before writing a 1 after writing a 0.
22.3.4.6
Rewrite (EW0 mode)
If the supply voltage drops while rewriting the block where the rewrite control program is stored, the rewrite control program is not correctly rewritten. This may cause the flash memory not to be rewritten. If this error occurs, use standard serial I/O mode or parallel I/O mode for rewriting.
22.3.4.7
Rewrite (EW1 mode)
Do not rewrite any block in which the rewrite control program is stored.
22.3.4.8
DMA Transfer
In EW1 mode, do not generate a DMA transfer while the FMR00 bit in the FMR0 register is set to 0 (auto programming or auto erasing).
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22. Flash Memory Version
22.3.4.9
Writing Command and Data
Write commands and data to even addresses.
22.3.4.10 Wait Mode
When entering wait mode, set the FMR01 bit to 0 (CPU rewrite mode disabled) before executing the WAIT instruction.
22.3.4.11 Stop Mode
To enter stop mode, set the FMR01 bit to 0 (CPU rewrite mode disabled), and then disable DMA transfer before setting the CM10 bit to 1 (stop mode).
22.3.4.12 Low-Power Consumption Mode and On-Chip Oscillator Low-power Consumption Mode
When the CM05 bit is set to 1 (main clock stopped), do not execute the following commands: * Program * Block erase * Lock bit program * Read lock bit status * Block blank check
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22. Flash Memory Version
22.3.5
Software Commands
Software commands are described below. Read and write the command code and data in 16-bit units, from and to even addresses in the program ROM 1, program ROM 2, and data flash. When the command code is written, the 8 high-order bits (D15 to D8) are ignored.
Table 22.10 Software Commands
Command Read Array Read Status Register Clear Status Register Program Block Erase Lock Bit Program Read Lock Bit Status Block Blank Check SRD WA0 WA1 WD0 WD1 BA x xx
First Bus Cycle Data Mode Address (D15 to D0) Write x xxFFh Write x xx70h Write x xx50h Write WA0 xx41h Write x xx20h Write BA xx77h Write x xx71h Write x xx25h
Second Bus Cycle Third Bus Cycle Data Data Mode Address (D15 to Mode Address (D15 to D0) D0) Read Write Write Write Write Write x WA0 BA BA BA BA SRD WD0 xxD0h xxD0h xxD0h xxD0h Write WA1 WD1
: Data in the status register (D7 to D0) : Address which low-order words are written (The address specified in the first bus cycle is the same even address as the address specified in the second bus cycle.) : Address which high-order words are written : Write data low-order word (16 bits) : Write data high-order word (16 bits) : Highest-order block address (even address) : Given even address in the program ROM 1, program ROM 2, and data flash : Eight high-order bits of command code (ignored)
22.3.5.1
Read Array Command
The read array command reads the flash memory. By writing the command code xxFFh in the first bus cycle, read array mode is entered. Content of a specified address can be read in 16-bit units by entering an address to be read after the next bus cycle. The microcomputer remains in read array mode until another command is written. Therefore, contents from multiple addresses can be read consecutively.
22.3.5.2
Read Status Register Command
The read status register command reads the status register. By writing the command code xx70h in the first bus cycle, the status register can be read in the second bus cycle (refer to 22.3.7 "Status Register"l). Read an even address in the program ROM 1, program ROM 2, and data flash. Do not execute this command in EW1 mode.
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22. Flash Memory Version
22.3.5.3
Clear Status Register Command
The clear status register command clears the status register. By writing xx50h in the first bus cycle, bits FMR07 and FMR06 in the FMR0 register are set to 00b, and bits SR5 and SR4 in the status register are set to 00b.
22.3.5.4
Program Command
The program command writes 2-word (4 bytes) data to the flash memory. By writing xx41h in the first bus cycle and data to the write address in the second and third bus cycles, an auto program operation (data program and verify) will start. The address value specified in the first bus cycle must be the same even address as the write address specified in the second bus cycle. The FMR00 bit in the FMR0 register indicates whether an auto program operation has been completed. The FMR00 bit is set to 0 (busy) during auto program and to 1 (ready) while in an auto program operation. After the completion of an auto program operation, the FMR06 bit in the FMR0 register indicates whether or not the auto program operation has been completed as expected. (Refer to 22.3.8 "Full Status Check".) An address that is already written cannot be altered or rewritten. Figure 22.14 shows a Flow Chart of the Program Command Programming. The lock bit protects each block from being programmed inadvertently. (Refer to 22.3.6 "Data Protect Function".) In EW1 mode, do not execute this command on the block to which the rewrite control program is allocated. In EW0 mode, the microcomputer enters read status register mode as soon as an auto program operation starts. The status register can be read. The SR7 bit in the status register is set to 0 at the same time an auto program operation starts. It is set to 1 when the auto program operation is completed. The microcomputer remains in read status register mode until the read array command is written. After completion of an auto program operation, the status register indicates whether or not the auto program operation has been completed as expected.
Start Write the command code xx41h to an address to be written Write data to an address to be written
FMR00 = 1?
YES
NO
Full status check
Program operation is completed NOTE: 1. Write the command code and data to even addresses.
Figure 22.14 Program Command
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M16C/64 Group
22. Flash Memory Version
22.3.5.5
Block Erase Command
By writing xx20h in the first bus cycle and xxD0h in the second bus cycle to the highest-order even address of a block, an auto erase operation (erase and verify) will start in the specified block. The FMR00 bit in the FMR0 register indicates whether an auto erase operation has been completed. The FMR00 bit is set to 0 (busy) during auto erase and to 1 (ready) when the auto erase operation is completed. After the completion of an auto erase operation, the FMR07 bit in the FMR0 register indicates whether or not the auto erase operation has been completed as expected. (Refer to 22.3.8 "Full Status Check".) Figure 22.15 shows a Block Erase Command. The lock bit protects each block from being erased inadvertently. (Refer to 22.3.6 "Data Protect Function".) In EW1 mode, do not execute this command on the block where the rewrite control program is allocated. In EW0 mode, the microcomputer enters read status register mode as soon as an auto erase operation starts. The status register can be read. The SR7 bit in the status register is set to 0 at the same time an auto erase operation starts. It is set to 1 when an auto erase operation is completed. The microcomputer remains in read status register mode until the read array command or read lock bit status command is written. If an erase error occurs, execute the clear status register command and then block erase command at least 3 times until an erase error is not generated.
Start Write the command code xx20h (1) Write xxD0h to the highestorder block address
FMR00 YES = 1? YES Full status check (2, 3) Block erase operation is completed
NO
NOTES: 1. Write the command code and data to even addresses. 2. Refer to Figure 22.15 Full Status Check and Handling Procedure for Each Error. 3. If an erase error occurs, execute the clear status register command and then block erase command at least 3 times until an erase error is not generated.
Figure 22.15 Block Erase Command
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M16C/64 Group
22. Flash Memory Version
22.3.5.6
Lock Bit Program Command
The lock bit program command sets the lock bit for a specified block to 0 (locked). By writing xx77h in the first bus cycle and xxD0h in the second bus cycle to the highest-order even address of a block, the lock bit for the specified block is set to 0. The address value specified in the first bus cycle must be the same highest-order address of a block specified in the second bus cycle. Figure 22.16 shows a Flow Chart of the Lock Bit Program Command Programming. Execute read lock bit status command to read lock bit state (lock bit data). The FMR00 bit in the FMR0 register indicates whether a lock bit program operation is completed. Refer to 22.3.6 "Data Protect Function" for details on lock bit functions and how to set it to 1 (unlocked).
Start
Write the command code xx77h to the highest-order block address Write xxD0h to the highestorder block address
FMR00 = 1?
YES
NO
Full status check Lock bit program operation is completed NOTE: 1. Write the command code and data to even addresses.
Figure 22.16 Lock Bit Program Command
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M16C/64 Group
22. Flash Memory Version
22.3.5.7
Read Lock Bit Status Command
The read lock bit status command reads the lock bit state of a specified block. By writing xx71h in the first bus cycle and xxD0h in the second bus cycle to the highest-order even address of a block, the FMR16 bit in the FMR1 register stores information on the lock bit status of a specified block. Read the FMR16 bit after the FMR00 bit in the FMR0 register is set to 1 (ready). Figure 22.17 shows a Flow Chart of the Read Lock Bit Status Command Programming.
Start
Write the command code xx71h Write xxD0h to the highestorder block address
NO
FMR00 = 1?
YES
FMR16 = 0?
YES
NO
Block is locked
Block is not locked
NOTE: 1. Write the command code and data to even addresses.
Figure 22.17 Read Lock Bit Status Command
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M16C/64 Group
22. Flash Memory Version
22.3.5.8
Block Blank Check
The block blank check command checks whether or not a specified block is blank (state after erase). By writing xx25h in the first bus cycle and xxD0h in the second bus cycle to the highest-order even address of a block, the check result is stored in the FMR07 bit in the FMR0 register. Read the FMR07 bit after the FMR00 bit in the FMR0 register is set to 1 (ready). The block blank check command is valid for unlocked blocks. If the block blank check command is executed to a block whose lock bit is 0 (locked), the FMR07 bit (SR5) is set to 1 (not blank) regardless of the FMR02 bit state. Figure 22.18 shows a Flow Chart of the Block Blank Check Command Programming.
Start
Write the command code xx25h Write xxD0h to the highestorder block address
NO
FMR00 = 1?
YES
FMR07 = 1?
YES
NO
Blank
Not blank
NOTE: 1. Write the command code and data to even addresses.
Figure 22.18 Block Blank Check Command
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M16C/64 Group
22. Flash Memory Version
22.3.6
Data Protect Function
Each block in the flash memory has a nonvolatile lock bit. The lock bit is enabled by setting the FMR02 bit to 0 (lock bit enabled). The lock bit allows each block to be individually protected (locked) against program and erase. This prevents data from being inadvertently written to or erased from the flash memory. A block changes its status according to the lock bit status: * When the lock bit status is set to 0, the block is locked (block is protected against program and erase). * When the lock bit status is set to 1, the block is not locked (block can be programmed or erased). The lock bit status is set to 0 (locked) by executing the lock bit program command and to 1 (unlocked) by erasing the block. No commands can set the lock bit status to 1. The lock bit status can be read by the read lock bit status command. When the FMR02 bit is set to 1, the lock bit function is disabled, and all blocks are unlocked. However, individual lock bit status remains unchanged. The lock bit function is enabled by setting the FMR02 bit to 0. Lock bit status is retained. If the block erase command is executed while the FMR02 bit is set to 1, the target block or all blocks are erased regardless of lock bit status. The lock bit status of each block is set to 1 after an erase operation is completed. Refer to 22.3.5 "Software Commands" for details on each command.
22.3.7
Status Register
The status register indicates the flash memory operation state and whether or not an erase or program operation is completed as expected. Bits FMR00, FMR06, and FMR07 in the FMR0 register indicate status register states. Table 22.11 shows the Status Register. In EW0 mode, the status register can be read when the followings occur. * Any even address in the program ROM 1, program ROM 2, or data flash is read after writing the read status register command. * Any even address in the program ROM 1, program ROM 2, or data flash is read from when the program, block erase, lock bit program, or block blank check command is executed until when the read array command is executed.
22.3.7.1
Sequence Status (Bits SR7 and FMR00)
The sequence status indicates the flash memory operation state. It is set to 0 while the program, block erase, lock bit program, block blank check, or read lock bit status command is being executed; otherwise, it is set to 1.
22.3.7.2
Erase Status (Bits SR5 and FMR07)
Refer to 22.3.8 "Full Status Check".
22.3.7.3
Program Status (Bits SR4 and FMR06)
Refer to 22.3.8 "Full Status Check".
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M16C/64 Group
22. Flash Memory Version
Table 22.11
Status Register
Bits in Status Bit in FMR0 Register Register SR0 (D0) SR1 (D1) SR2 (D2) SR3 (D3) SR4 (D4) SR5 (D5) SR6 (D6) SR7 (D7) FMR06 FMR07 FMR00
0 Reserved Reserved Reserved Reserved Program status Terminated normally Erase status Terminated normally Reserved Sequencer status Busy
Status name
Definition 1 Terminated in error Terminated in error Ready
Value after Reset 0 0 1
D0 to D7 are the data buses read when the read status register command is executed. Bits FMR07 (SR5) and FMR06 (SR4) are set to 0 when the clear status register command is executed. When the FMR07 (SR5) or FMR06 bit (SR4) is set to 1, the program, block erase, lock bit program, block blank check, and read lock bit status commands are not accepted.
REJ09B0392-0064 Rev.0.64 Page 291 of 373
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M16C/64 Group
22. Flash Memory Version
22.3.8
Full Status Check
If an error occurs when a program or erase operation is completed, bits FMR06 and FMR07 in the FMR0 register are set to 1, indicating a specific error. Therefore, execution results can be confirmed by checking these status (full status check). Table 22.12 lists Errors and FMR0 Register State. Figure 22.19 shows a Full Status Check and Handling Procedure for Each Error.
Table 22.12 Errors and FMR0 Register State
FMR00 Register (Status Register) State FMR06 FMR07 bit bit (SR5 bit) (SR4 bit) 1 1
Error
Error Occurrence Conditions
Command Sequence error
* Command is written incorrectly * A value other than xxD0h or xxFFh is written in the second bus cycle of the lock bit program or block erase command (1) * The block erase command is executed on a locked block (2) * The block erase command is executed on an unlocked block, but auto erase operation is not completed as expected * The block blank check command is executed, and the check result is not blank * The block blank check command is executed on a locked block * The program command is executed on a locked block (2) * The program command is executed on an unlocked block, but program operation is not completed as expected * The lock bit program command is executed, but the lock bit is not written as expected (2)
1
0
Erase error
0
1
Program error
NOTES: 1. The flash memory enters read array mode by writing command code xxFFh in the second bus cycle of the commands. The command code written in the first bus cycle becomes invalid. 2. When the FMR02 bit is set to 1 (lock bit disabled), no error occurs even under the conditions above.
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M16C/64 Group
22. Flash Memory Version
Full status check FMR06 =1 and FMR07=1?
NO
YES
Command sequence error
(1) Execute the clear status register command and set bits FMR06 and FMR07 to 0 (completed as expected) . (2) Rewrite command and execute again.
FMR07=0?
NO
Erase error
(1) Execute the clear status register command and set the FMR07 bit to 0. (2) Execute the read lock bit status command. Set the FMR02 bit to 1 (lock bit disabled) if the lock bit in the block where the error occurred is set to 0 (locked). (3) Execute the block erase command again. (4) Execute (1), (2), and (3) at least 3 times until an erase error is not generated. NOTE: If similar error still occurs, that block cannot be used. If the lock bit is set to 1 (unlocked) in (2) above, that block cannot be used.
YES
FMR06=0?
NO
Program error
[When a program operation is executed] (1) Execute the clear status register command and set the FMR06 bit to 0 (completed as expected) . (2) Execute the read lock bit status command and set the FMR02 bit to 1 if the lock bit in the block where the error occurred is set to 0. (3) Execute the program command again. NOTE: If similar error occurs, that block cannot be used. If the lock bit is set to 1 in (2) above, that block cannot be used. [When a lock bit program operation is executed] (1) Execute the clear status register command and set the FMR06 bit to 0. (2) Set the FMR02 bit in the FMR0 register to 1. (3) Execute the block erase command to erase the block where the error occurred. (4) Execute the lock bit program command again. NOTE: If similar error occurs, that block cannot be used.
YES
Full status check completed
NOTE: When either FMR06 or FMR07 bit is set to 1 (terminated by error), the program, block erase, lock bit program, block blank check, and read lock bit status commands cannot be accepted. Execute the clear status register command before each command.
Figure 22.19 Full Status Check and Handling Procedure for Each Error
REJ09B0392-0064 Rev.0.64 Page 293 of 373
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M16C/64 Group
22. Flash Memory Version
22.4
Standard Serial I/O Mode
In standard serial I/O mode, the serial programmer supporting the M16C/64 Group can be used to rewrite the program ROM 1, program ROM 2, and data flash in the microcomputer mounted on a board. For more information about the serial programmer, contact your serial programmer manufacturer. Refer to the user's manual included with your serial programmer for instructions. Table 22.13 lists Pin Functions (Flash Memory Standard Serial I/O Mode). Figures 22.20 and 22.21 show Pin Connections in Serial I/O Mode.
22.4.1
ID Code Check Function
The ID code check function determines whether the ID codes sent from the serial programmer match those written in the flash memory. (Refer to 22.2 "Functions to Prevent Flash Memory from Rewriting".)
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M16C/64 Group
22. Flash Memory Version
Table 22.13
Pin Functions (Flash Memory Standard Serial I/O Mode)
Pin
Name
I/O
VCC1, VCC2, Power input VSS CNVSS RESET XIN XOUT BYTE AVCC, AVSS CNVSS Reset input Clock input Clock output I I I O I
BYTE input Analog power supply input VREF Reference voltage input P0_0 to P0_7 Input port P0 P1_0 to P1_7 Input port P1 P2_0 to P2_7 Input port P2 P3_0 to P3_7 Input port P3 P4_0 to P4_7 Input port P4 P5_1 to P5_4, Input port P5 P5_6, P5_7 P5_0 CE input P5_5 EPM input P6_0 to P6_3 Input port P6 P6_4 / RTS1 BUSY output
Power Description Supply Apply the flash program and erase voltage to the VCC1 pin, and VCC2 to the VCC2 pin. The VCC apply condition is that VCC2 = VCC1. Apply 0 V to the VSS pin. VCC1 Connect to VCC1 pin. VCC1 Reset input pin. While the RESET pin is "L" level, input a 20cycle or longer clock to the XIN pin. VCC1 Connect a ceramic resonator or crystal oscillator between VCC1 pins XIN and XOUT. To input an externally generated clock, input it to the XIN pin and open the XOUT pin. VCC1 Connect this pin to VCC1 or VSS. Connect AVSS to VSS and AVCC to VCC1, respectively.
I I I I
I
I I I I I O
VCC2 VCC2 VCC2 VCC2 VCC2 VCC2
Reference voltage input pin for A/D converter. Connect to VCC1. Input "H" or "L" level signal or open. Input "H" or "L" level signal or open. Input "H" or "L" level signal or open. Input "H" or "L" level signal or open. Input "H" or "L" level signal or open. Input "H" or "L" level signal or open.
P6_5/CLK1 P6_6 / RXD1 P6_7 / TXD1
SCLK input RXD input TXD input
I I O
VCC2 Input "H" level signal. VCC2 Input "L" level signal. VCC1 Input "H" or "L" level signal or open. VCC1 Standard serial I/O mode 1: BUSY signal output pin Standard serial I/O mode 2: monitor signal output pin to check the boot program operation VCC1 Standard serial I/O mode 1: serial clock input pin Standard serial I/O mode 2: Input "L". VCC1 Serial data input pin. VCC1 Serial data output pin. (1) VCC1 Input "H" or "L" level signal or open. VCC1 Input "H" or "L" level signal or open. VCC1 Input "L" level signal. (2) VCC1 Input "H" or "L" level signal or open. VCC1 Input "H" or "L" level signal or open. VCC1 Input "H" or "L" level signal or open.
P7_0 to P7_7 Input port P7 I P8_0 to P8_3, Input port P8 I P8_6, P8_7 P8_4 P8_4 input I P8_5 / NMI P9_0 to P9_7 P10_0 to P10_7
NMI input I Input port P9 I Input port I P10
NOTES: 1. When using the standard serial I/O mode, the internal pull-up is enabled for the TXD1 (P6_7) pin while the RESET pin is "L". 2. When using the standard serial I/O mode, pins P0_0 to P0_7 and P1_0 to P1_7 may become indeterminate while the P8_4 pin is "H" and the RESET pin is "L". If this causes a program, apply "L" to the P8_4 pin. REJ09B0392-0064 Rev.0.64 Page 295 of 373 Oct 12, 2007
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M16C/64 Group
22. Flash Memory Version
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 50 49 48 47 46 45 44
VCC2
CE
M16C / 64 Group Flash Memory Version
43 42 41 40 39 38 37 36 35 34 33 32 31
EPM
BUSY SCLK RXD TXD
VSS
Mode setup method
Connect oscillator circuit RESET
Signal CNVSS EPM RESET CE
Value VCC1 VSS VSS to VCC1 VCC2
CNVSS
VCC1
Package: PRQP0100JD-B (100P6F-A)
Figure 22.20 Pin Connections for Standard Serial I/O Mode (1)
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M16C/64 Group
22. Flash Memory Version
75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 1 23 45 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 50 49 48 47 46 45 44 43 42 41 CE
VCC2
M16C / 64 Group Flash Memory Version
40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 BUSY SCLK RXD TXD
EPM
VSS
Mode setup method
Connect oscillator circuit RESET
Signal Value CNVSS VCC1 EPM VSS RESET VSS to VCC1 CE VCC2
CNVSS
VCC1
Package: PLQP0100KB-A (100P6Q-A)
Figure 22.21 Pin Connections for Standard Serial I/O Mode (2)
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M16C/64 Group
22. Flash Memory Version
22.4.2
Example of Circuit Application in the Standard Serial I/O Mode
Figures 22.22 and 22.23 show examples of Circuit Application in Standard Serial I/O Mode 1 and Mode 2, respectively. Refer to the user's manual of your serial programmer to handle pins controlled by the serial programmer.
VCC1 VCC2
Microcomputer SCLK input TXD output BUSY output RXD input
VCC1 VCC1
P6_5 / CLK1 P5_0 (CE) P6_7 / TXD1 P6_4 / RTS1 P6_6 / RXD1 CNVSS P5_5 (EPM)
VCC1
Reset input User reset signal
RESET
NOTES: 1. Control pins and external circuitry will vary according to a programmer. For more information, see the programmer manual. 2. In this example, modes are switched between single-chip mode and standard serial input / output mode by controlling the CNVSS input with a switch. 3. If in standard serial input / output mode 1 there is a possibility that the user reset signal will go low during serial input / output mode, break the connection between the user reset signal and RESET pin by using, for example, a jumper switch.
Figure 22.22 Circuit Application in Standard Serial I/O Mode 1
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M16C/64 Group
22. Flash Memory Version
Microcomputer P6_5 / CLK1 TXD output Monitor output RXD intput
VCC1
VCC2
P5_0 (CE) P5_5 (EPM)
VCC1
P6_7 / TXD1 P6_4 / RTS1 P6_6 / RXD1
CNVSS
Reset input User reset signal
RESET
NOTE: 1. In this example, modes are switched between single-chip mode and standard serial input / output mode by controlling the CNVSS input with a switch.
Figure 22.23 Circuit Application in Standard Serial I/O Mode 2
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M16C/64 Group
22. Flash Memory Version
22.5
Parallel I/O Mode
In parallel I/O mode, the program ROM 1 and program ROM 2 can be rewritten by a parallel programmer supporting the M16C/64 Group. Contact your parallel programmer manufacturer for more information on the parallel programmer. Refer to the user's manual included with your parallel programmer for instructions.
22.5.1
ROM Code Protect Function
The ROM code protect function prevents the flash memory from being read and rewritten. (Refer to 22.2 "Functions to Prevent Flash Memory from Rewriting".)
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M16C/64 Group
23. Electrical Characteristics
23. Electrical Characteristics
23.1 Electrical Characteristics
Absolute Maximum Ratings
Parameter Supply Voltage Analog Supply Voltage Input Voltage
RESET, CNVSS, BYTE, P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, P11_0 to P11_7, P14_0, P14_1, XIN
Table 23.1
Symbol VCC1, VCC2 AVCC VI
Condition VCC1=VCC2 =AVCC VCC1=AVCC
Rated Value
-0.3 to 6.5 -0.3 to 6.5 -0.3 to VCC1+0.3
Unit V V V
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P7_0, P7_1, P8_5 VO
Output Voltage P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7, XOUT
-0.3 to VCC2+0.3
V
-0.3 to 6.5 -0.3 to VCC1+0.3
V V
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7 P7_0, P7_1, P8_5 Pd Topr Power Dissipation Operating When the Microcomputer is Operating Ambient Tem- Flash Program Erase perature Storage Temperature
-40C-0.3 to VCC2+0.3
V
-0.3 to 6.5
V mW
C
300
-20 to 85 / -40 to 85
0 to 60
-65 to 150 C
Tstg
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M16C/64 Group
23. Electrical Characteristics
Table 23.2
Symbol VCC1, VCC2 AVCC VSS AVSS VIH
Recommended Operating Conditions (1)
Parameter Min. Supply Voltage (VCC1 = VCC2) Analog Supply Voltage Supply Voltage Analog Supply Voltage HIGH Input Volt- P3_1 to P3_7, P4_0 to P4_7, P5_0 to P5_7 age P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 (during single-chip mode) P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 (data input during memory expansion and microprocessor mode) P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE P7_0, P7_1, P8_5 0.8VCC2 0.8VCC2 0.5VCC2 0.8VCC1 2.7 Standard Typ. 5.0 VCC1 0 0 VCC2 VCC2 VCC2 VCC1 Max. 5.5 V V V V V V V V Unit
0.8VCC1 0 0 0 0
6.5 0.2VCC2 0.2VCC2 0.16VCC2 0.2VCC
V V V V V
VIL
LOW Input Volt- P3_1 to P3_7, P4_0 to P4_7, P5_0 to P5_7 age P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 (during single-chip mode) P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 (data input during memory expansion and microprocessor mode) P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE
IOH(peak)
HIGH Peak Output Current HIGH Average Output Current
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7 P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7,
-10.0
mA
IOH(avg)
-5.0
mA
IOL(peak)
LOW Peak Out- P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, put Current P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7 LOW Average Output Current P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7 VCC1=2.7V to 5.5V 0 32.768 125 VCC1=2.7V to 5.5V 10 0
10.0
mA
IOL(avg)
5.0
mA
f(XIN) f(XCIN) f(OCO) f(PLL) f(BCLK) tSU(PLL)
Main Clock Input Oscillation Frequency Sub-Clock Oscillation Frequency 125kHz On-chip Oscillation Frequency PLL Clock Oscillation Frequency CPU Operation Clock
20 50 25 25 20
MHz kHz kHz MHz MHz ms
PLL Frequency Synthesizer Stabilization Wait VCC1=5.5V Time
NOTES: 1. Referenced to VCC1 = VCC2 = 2.7 to 5.5V at Topr = -20 to 85C / -40 to 85C unless otherwise specified. 2. The Average Output Current is the mean value within 100ms. 3. The total IOL(peak) for ports P0, P1, P2, P8_6, P8_7, P9 and P10 must be 80mA max. The total IOL(peak) for ports P3, P4, P5, P6, P7 and P8_0 to P8_5 must be 80mA max. The total IOH(peak) for ports P0, P1, and P2 must be -40mA max. The total IOH(peak) for ports P3, P4 and P5 must be -40mA max. The total IOH(peak) for ports P6, P7_2 to P7_7 and P8_0 to P8_4 must be -40mA max.
REJ09B0392-0064 Rev.0.64 Page 302 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Table 23.3
Symbol INL
A/D Conversion Characteristics (1)
Parameter Resolution Integral Non-Linearity Error 10bit Measuring Condition Min. VREF=VCC1 VREF= AN0 to AN7 input, VCC1= AN0_0 to AN0_7 input, AN2_0 to AN2_7 input, 5.0V ANEX0, ANEX1 input VREF= AN0 to AN7 input, VCC1= AN0_0 to AN0_7 input, AN2_0 to AN2_7 input, 3.3V ANEX0, ANEX1 input VREF= AN0 to AN7 input, VCC1= AN0_0 to AN0_7 input, 3.0V AN2_0 to AN2_7 input, ANEX0, ANEX1 input Standard Typ. Max. 10 3 Bits LSB Unit
3
LSB
3
LSB
-
Absolute Accuracy
10bit
VREF= AN0 to AN7 input, VCC1= AN0_0 to AN0_7 input, 5.0V AN2_0 to AN2_7 input, ANEX0, ANEX1 input VREF= AN0 to AN7 input, VCC1 AN0_0 to AN0_7 input, =3.3V AN2_0 to AN2_7 input, ANEX0, ANEX1 input VREF= AN0 to AN7 input, VCC1 AN0_0 to AN0_7 input, =3.0V AN2_0 to AN2_7 input, ANEX0, ANEX1 input
3
LSB
3
LSB
3
LSB
DNL RLADDER tCONV tSAMP VREF VIA
NOTES:
Tolerance Level Impedance Differential Non-Linearity Error Offset Error Gain Error Ladder Resistance 10-bit Conversion Time Sampling Time Reference Voltage Analog Input Voltage 0 VREF=VCC1 VREF=VCC1=5V, AD=25MHz 10 1.60 0.60
3 1 3 3 40
k LSB LSB LSB k
s s
VCC1 VREF
V V
1.
2.
3.
Referenced to VCC1=AVCC=VREF=3.0 to 5.5V, VSS=AVSS=0V at Topr = -20 to 85C / -40 to 85C unless otherwise specified. Set AD frequency as follows: When VCC1 = 4.0 to 5.5 V, 2 MHz AD 25 MHz When VCC1 = 3.2 to 4.0 V, 2 MHz AD 16 MHz When VCC1 = 3.0 to 3.2 V, 2 MHz AD 10 MHz Use when VREF=VCC1.
REJ09B0392-0064 Rev.0.64 Page 303 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Table 23.4
Symbol tSU RO IVREF
NOTES:
D/A Conversion Characteristics (1)
Parameter Resolution Absolute Accuracy Setup Time Output Resistance Reference Power Supply Input Current (NOTE 2) 6 1.5 Measuring Condition Min. Standard Typ. Max. 8 2.5 3 Bits LSB
s
Unit
k mA
1. 2.
Referenced to VCC1=VREF=3.3 to 5.5V, VSS=AVSS=0V at Topr = -20 to 85C / -40 to 85C unless otherwise specified. This applies when using one D/A converter, with the D/A register for the unused D/A converter set to "00h". The resistor ladder of the A/D converter is not included. Also, when D/A register contents are not "00h", the IVREF will flow even if Vref id disconnected by the A/D control register.
Table 23.5
Symbol tPS -
Flash Memory Version Electrical Characteristics (1)
Parameter Min. Program and Erase Endurance (2) 2 Word Program Time (VCC1=3.3V at Topr=25C) Lock Bit Program Time (VCC1=3.3V at Topr=25C) Block Erase Time (VCC1=3.3V at Topr=25C)
Other than data flash
Standard Typ. Max. 100 100 150 300 70 140 0.20 0.20 0.20 50 10
Unit cycle cycle
s s s s
Data flash
Other than data flash
Data flash
Other than data flash
Data flash
4-Kbyte block 16-Kbyte block 64-Kbyte block
s s s
s
Flash Memory Circuit Stabilization Wait Time Data Hold Time (3)
year
NOTES: 1. Referenced to VCC1=2.7 to 5.5V at Topr = 0 to 60 C unless otherwise specified. 2. Definition of program and erase endurance The program and erase endurance refers to the number of per-block erasures. If the program and erase endurance is n (n=100), each block can be erased n times. For example, if a 4 Kbyte block is erased after writing two word data 1,024 times, each to a different address, this counts as one program and erase endurance. Data cannot be written to the same address more than once without erasing the block. (Rewrite prohibited) 3. Topr = -40 to 85 C / -20 to 85 C
Table 23.6
Flash Memory Version Program / Erase Voltage and Read Operation Voltage Characteristics (at Topr = 0 to 60 C)
Flash Read Operation Voltage VCC1=2.7 to 5.5 V VCC2 = 2.7 to 5.5 V
Flash Program, Erase Voltage
REJ09B0392-0064 Rev.0.64 Page 304 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Table 23.7
Symbol Vdet2 Vdet0
Vdet2 -Vdet0
Low Voltage Detection Circuit Electrical Characteristics
Parameter Low Voltage Detection Voltage (1) Reset Level Detection Voltage (1) 0.3 0.8 2.0 Electric potential difference of Low Voltage Detection and Reset Level Detection Low Voltage Reset Retention Voltage Low Voltage Reset Release Voltage
(2)
Measuring Condition Min. VCC1=0.8V to 5.5V 3.3
Standard Typ. 3.8 1.9 Max. 4.4
Unit V V V V V
Vdet0s Vdet0r
NOTES: 1. Vdet2 > Vdet0. 2. Vdet0r > Vdet0 is not guaranteed. 3. The voltage detection circuit is designed to use when VCC1 is set to 5V.
Table 23.8
Symbol td(P-R) td(R-S) td(W-S) td(S-R) td(E-A)
Power Supply Circuit Timing Characteristics
Parameter Time for Internal Power Supply Stabilization During Powering-On STOP Release Time Low Power Dissipation Mode Wait Mode Release Time Brown-out Detection Reset (Hardware Reset 2) Release Wait Time Low Voltage Detection Circuit Operation Start Time VCC1=Vdet3r to 5.5V VCC1=2.7V to 5.5V 6 (1) Measuring Condition Min. VCC1=2.7V to 5.5V Standard Typ. Max. 5 150 150 20 20 ms
s s
Unit
ms
s
NOTE: 1. When VCC1 = 5V.
REJ09B0392-0064 Rev.0.64 Page 305 of 373
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M16C/64 Group
23. Electrical Characteristics
td(P-R)
Recommended operation voltage VCC1 td(P-R) CPU clock
Time for Internal Power Supply Stabilization During Powering-On
td(R-S)
STOP Release Time
Interrupt for (a) Stop mode release or (b) Wait mode release
td(W-S)
Low Power Dissipation Mode Wait Mode Release Time
CPU clock (a) (b) td(R-S) td(W-S)
td(S-R)
Low Voltage Detection Reset (Hardware Reset 2) Release Wait Time
VCC1
Vdet3r td(S-R)
CPU clock
td(E-A)
Low Voltage Detection Circuit Operation Start Time
VC26, VC27 Low Voltage Detection Circuit Stop Operate
td(E-A)
Figure 23.1
Power Supply Circuit Timing Diagram
REJ09B0392-0064 Rev.0.64 Page 306 of 373
Oct 12, 2007
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Table 23.9
Symbol VOH
Electrical Characteristics (1)
Parameter
(1)
Measuring Condition Min. IOH=-5mA IOH=-5mA OH=-200A IOH=-200A IOH=-1mA IOH=-0.5mA With no load applied With no load applied IOL=5mA IOL=5mA IOL=200A IOL=200A IOL=1mA IOL=0.5mA With no load applied With no load applied 0.2 0 0 1.0 V Standard Typ. Max. VCC1 VCC2 VCC1 VCC2 VCC1 VCC1 2.9 2.2 2.0 2.0 0.45 0.45 2.0 2.0 V V V V V V V V VCC1-2.0 VCC2-2.0 VCC1-0.3 VCC2-0.3 VCC1-2.0 VCC1-2.0 Unit
HIGH Output P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7 Voltage
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7 VOH
HIGH Output P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7 Voltage
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7 VOH HIGH Output Voltage HIGH Output Voltage VOL
LOW Output Voltage
XOUT XCOUT
HIGHPOWER LOWPOWER HIGHPOWER LOWPOWER
P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7 P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7
VOL
LOW Output Voltage
P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7 P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7
VOL
LOW Output Voltage LOW Output Voltage
XOUT XCOUT
HIGHPOWER LOWPOWER HIGHPOWER LOWPOWER
VT+-VT-
Hysteresis
HOLD, RDY, TA0IN to TA4IN, TB0IN to TB5IN, INT0 to INT7, NMI, ADTRG, CTS0 to CTS2, CTS5 to CTS7, SCL0 to SCL2, SCL5 to SCL7, SDA0 to SDA2, SDA5 to SDA7, CLK0 to CLK7, TA0OUT to TA4OUT, KI0 to KI3, RXD0 to RXD2, RXD5 to RXD7, SIN3, SIN4 RESET
VT+-VTIIH
Hysteresis HIGH Input Current
0.2 VI=5V
2.5 5.0
V
A
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7
IIL
LOW Input Current
VI=0V
-5.0
A
RPULLUP Pull-Up Resistance RfXIN RfXCIN VRAM
VI=0V
30
50
170
k
Feedback Resistance XIN Feedback Resistance XCIN RAM Retention Voltage At stop mode 2.0
1.5 15
M M V
NOTES: 1. Referenced to VCC1=VCC2=4.2 to 5.5V, VSS = 0V at Topr = -20 to 85C / -40 to 85C, f(BCLK)=25MHz unless otherwise specified.
REJ09B0392-0064 Rev.0.64 Page 307 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Table 23.10
Symbol
ICC
Electrical Characteristics (2) (1)
Parameter Measuring Condition Min.
f(BCLK)=25MHz, No division, PLL operation No division, 125 kHz On-chip oscillation f(BCLK)=10MHz, VCC1=5.0V f(BCLK)=10MHz, VCC1=5.0V f(BCLK)=32kHz Low power dissipation mode, RAM (3) f(BCLK)=32kHz Low power dissipation mode, Flash Memory (3) FMR22=FMR23=1 125 kHz On-chip oscillation, Wait mode f(BCLK)=32kHz Wait mode (2), Oscillation capability High f(BCLK)=32kHz Wait mode (2), Oscillation capability Low Stop mode Topr =25C
Standard Typ.
20
Unit Max.
mA
Flash Power Supply Current In single-chip Memory (VCC1=VCC2=4.0V to 5.5V) mode, the output pins are open and other pins are VSS
450
A
Flash Memory Program Flash Memory Erase Flash Memory
20 30 45
mA mA
A
160
A
12
A
11.5
A
6.2
A
3.0 3.0 6.0
A A A
Idet2 Idet0
Low Voltage Detection Dissipation Current (4) Reset Area Detection Dissipation Current
(4)
NOTES: 1. Referenced to VCC1=VCC2=4.2 to 5.5V, VSS = 0V at Topr = -20 to 85C / -40 to 85C, f(BCLK)=25MHz unless otherwise specified. 2. With one timer operated using fC32. 3. This indicates the memory in which the program to be executed exists. 4. Idet is dissipation current when the following bit is set to "1" (detection circuit enabled). Idet2: VC27 bit in the VCR2 register Idet0: VC25 bit in the VCR2 register
REJ09B0392-0064 Rev.0.64 Page 308 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Timing Requirements (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.11
Symbol tc tw(H) tw(L) tr tf
External Clock Input (XIN input) (1)
Parameter External Clock Input Cycle Time External Clock Input HIGH Pulse Width External Clock Input LOW Pulse Width External Clock Rise Time External Clock Fall Time 50 25 25 15 15 Standard Min. Max. ns ns ns ns ns Unit
NOTE: 1. The condition is VCC1=VCC2=3.0 to 5.0V.
Table 23.12
Symbol
tac1(RD-DB) tac2(RD-DB) tac3(RD-DB) tsu(DB-RD) tsu(HOLDBCLK) th(RD-DB) th(BCLK-RDY)
Memory Expansion Mode and Microprocessor Mode
Parameter Data Input Access Time (for setting with no wait) Data Input Access Time (for setting with wait) Data Input Access Time (when accessing multiplex bus area) Data Input Setup Time
HOLD Input Setup Time
Standard Min. Max. (NOTE 1) (NOTE 2) (NOTE 3) 40 30 40 0 0 0
Unit ns ns ns ns ns ns ns ns ns
tsu(RDY-BCLK) RDY Input Setup Time
Data Input Hold Time
RDY Input Hold Time
th(BCLK-HOLD) HOLD Input Hold Time
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 45 [ ns ] f ( BCLK )
2.
Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ------------------------------------ - 45 [ ns ] f ( BCLK ) n is "2" for 1-wait setting, "3" for 2-wait setting and "4" for 3-wait setting.
3.
Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ------------------------------------ - 45 [ ns ] f ( BCLK ) n is "2" for 2-wait setting, "3" for 3-wait setting.
REJ09B0392-0064 Rev.0.64 Page 309 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Timing Requirements (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.13
Symbol tc(TA) tw(TAH) tw(TAL) TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width
Timer A Input (Counter Input in Event Counter Mode)
Parameter 100 40 40 Standard Min. Max. ns ns ns Unit
Table 23.14
Symbol tc(TA) tw(TAH) tw(TAL)
Timer A Input (Gating Input in Timer Mode)
Parameter TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 400 200 200 Standard Min. Max. ns ns ns Unit
Table 23.15
Symbol tc(TA) tw(TAH) tw(TAL)
Timer A Input (External Trigger Input in One-shot Timer Mode)
Parameter TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 200 100 100 Standard Min. Max. ns ns ns Unit
Table 23.16
Symbol tw(TAH) tw(TAL)
Timer A Input (External Trigger Input in Pulse Width Modulation Mode)
Parameter TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 100 100 Standard Min. Max. ns ns Unit
Table 23.17
Symbol tc(UP) tw(UPH) tw(UPL) tsu(UP-TIN) th(TIN-UP)
Timer A Input (Counter Increment/Decrement Input in Event Counter Mode)
Parameter TAiOUT Input Cycle Time TAiOUT Input HIGH Pulse Width TAiOUT Input LOW Pulse Width TAiOUT Input Setup Time TAiOUT Input Hold Time Standard Min. 2000 1000 1000 400 400 Max. ns ns ns ns ns Unit
Table 23.18
Symbol tc(TA)
Timer A Input (Two-phase Pulse Input in Event Counter Mode)
Parameter TAiIN Input Cycle Time Standard Min. 800 200 200 Max. ns ns ns Unit
tsu(TAIN-TAOUT) TAiOUT Input Setup Time tsu(TAOUT-TAIN) TAiIN Input Setup Time
REJ09B0392-0064 Rev.0.64 Page 310 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Timing Requirements (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.19
Symbol tc(TB) tw(TBH) tw(TBL) tc(TB) tw(TBH) tw(TBL)
Timer B Input (Counter Input in Event Counter Mode)
Parameter Min. TBiIN Input Cycle Time (counted on one edge) TBiIN Input HIGH Pulse Width (counted on one edge) TBiIN Input LOW Pulse Width (counted on one edge) TBiIN Input Cycle Time (counted on both edges) TBiIN Input HIGH Pulse Width (counted on both edges) TBiIN Input LOW Pulse Width (counted on both edges) 100 40 40 200 80 80 Standard Max. ns ns ns ns ns ns Unit
Table 23.20
Symbol tc(TB) tw(TBH) tw(TBL)
Timer B Input (Pulse Period Measurement Mode)
Parameter Min. TBiIN Input Cycle Time TBiIN Input HIGH Pulse Width TBiIN Input LOW Pulse Width 400 200 200 Standard Max. ns ns ns Unit
Table 23.21
Symbol tc(TB) tw(TBH) tw(TBL)
Timer B Input (Pulse Width Measurement Mode)
Parameter Min. TBiIN Input Cycle Time TBiIN Input HIGH Pulse Width TBiIN Input LOW Pulse Width 400 200 200 Standard Max. ns ns ns Unit
Table 23.22
Symbol tc(AD) tw(ADL)
A/D Trigger Input
Parameter Min.
ADTRG Input Cycle Time ADTRG input LOW Pulse Width
Standard Max. 1000 125
Unit ns ns
Table 23.23
Symbol tc(CK) tw(CKH) tw(CKL) td(C-Q) th(C-Q) tsu(D-C) th(C-D)
Serial Interface
Parameter Min. CLKi Input Cycle Time CLKi Input HIGH Pulse Width CLKi Input LOW Pulse Width TXDi Output Delay Time TXDi Hold Time RXDi Input Setup Time RXDi Input Hold Time 0 70 90 200 100 100 80 Standard Max. ns ns ns ns ns ns ns Unit
Table 23.24
Symbol tw(INH) tw(INL)
External Interrupt INTi Input
Parameter Min.
INTi Input HIGH Pulse Width INTi Input LOW Pulse Width
Standard Max. 250 250
Unit ns ns
REJ09B0392-0064 Rev.0.64 Page 311 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Switching Characteristics (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.25
Symbol
Memory Expansion and Microprocessor Modes (for setting with no wait)
Parameter Measuring Condition Standard Min. Max. 25 4 0 (NOTE 2) 25 4 15
-4
Unit
td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS) td(BCLK-ALE) th(BCLK-ALE) td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB) td(BCLK-HLDA)
Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) ALE Signal Output Delay Time ALE Signal Output Hold Time RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) (3) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to WR) (3)
HLDA Output Delay Time
ns ns ns ns ns ns ns ns
See Figure 23.2
25 0 25 0 40 4 (NOTE 1) (NOTE 2) 40
ns ns ns ns ns ns ns ns ns
NOTES:
1. Calculated according to the BCLK frequency as follows: 9 0.5x10 ----------------------- - 40 [ ns ] f(BCLK) is 12.5MHz or less. f ( BCLK ) Calculated according to the BCLK frequency as follows: 9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK ) This standard value shows the timing when the output is off, and does not show hold time of data bus. Hold time of data bus varies with capacitor volume and pull-up (pull-down) resistance value. Hold time of data bus is expressed in t = -CR X ln (1-VOL / VCC2) by a circuit of the right figure. For example, when VOL = 0.2VCC2, C = 30pF, R = 1k, hold time of output "L" level is t = -30pF X 1k X In(1-0.2VCC2 / VCC2) = 6.7ns.
2.
3.
R DBi C
P0 P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 P13 P14
30pF
Figure 23.2
Ports P0 to P14 Measurement Circuit
REJ09B0392-0064 Rev.0.64 Page 312 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Switching Characteristics (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.26
Symbol td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS)
td(BCLK-ALE) th(BCLK-ALE)
Memory Expansion and Microprocessor Modes (for 1- to 3-wait setting and external area access)
Parameter Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) ALE Signal Output Delay Time ALE Signal Output Hold Time RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to
HLDA Output Delay Time
(3)
Measuring Condition
Standard Min. 4 0 (NOTE 2) 25 4 15 -4 Max. 25
Unit ns ns ns ns ns ns ns ns 25 ns ns 25 ns ns 40 ns ns ns ns 40 ns
td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB)
td(BCLK-HLDA)
See Figure 23.2
0 0 4 (NOTE 1) (NOTE 2)
WR)(3)
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ----------------------------------- - 40 [ ns ] f ( BCLK ) n is "1" for 1-wait setting, "2" for 2-wait setting and "3" for 3-wait setting. (BCLK) is 12.5MHz or less.
2.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK )
3.
This standard value shows the timing when the output is off, and does not show hold time of data bus. Hold time of data bus varies with capacitor volume and pullup (pull-down) resistance value. Hold time of data bus is expressed in t = -CR X ln (1-VOL / VCC2) by a circuit of the right figure. For example, when VOL = 0.2VCC2, C = 30pF, R = 1k, hold time of output "L" level is t = -30pF X 1k X In(1-0.2VCC2 / VCC2) = 6.7ns.
R DBi C
REJ09B0392-0064 Rev.0.64 Page 313 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Switching Characteristics (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.27
Symbol td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS) th(RD-CS) th(WR-CS) td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB)
Memory Expansion and Microprocessor Modes (for 2- to 3-wait setting, external area access and multiplex bus selection)
Parameter Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) Chip Select Output Hold Time (in relation to RD) Chip Select Output Hold Time (in relation to WR) RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to WR) See Figure 23.2 0 40 4 (NOTE 2) (NOTE 1) 40 15
-4
Measuring Condition
Standard Min. 4 (NOTE 1) (NOTE 1) 25 4 (NOTE 1) (NOTE 1) 25 0 25 Max. 25
Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 8 ns
td(BCLK-HLDA) HLDA Output Delay Time
td(BCLK-ALE) ALE Signal Output Delay Time (in relation to BCLK) th(BCLK-ALE) ALE Signal Output Hold Time (in relation to BCLK) td(AD-ALE) th(AD-ALE) td(AD-RD) td(AD-WR) tdz(RD-AD) ALE Signal Output Delay Time (in relation to Address) ALE Signal Output Hold Time (in relation to Address) RD Signal Output Delay From the End of Address WR Signal Output Delay From the End of Address Address Output Floating Start Time (NOTE 3) (NOTE 4) 0 0
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK )
2.
Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ----------------------------------- - 40 [ ns ] f ( BCLK )
n is "2" for 2-wait setting, "3" for 3-wait setting.
3.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 25 [ ns ] f ( BCLK )
4.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 15 [ ns ] f ( BCLK )
REJ09B0392-0064 Rev.0.64 Page 314 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
XIN input tr tw(H) tf tc tw(L)
tc(TA) tw(TAH) TAiIN input tw(TAL) tc(UP) tw(UPH) TAiOUT input tw(UPL)
TAiOUT input (Up/down input) During event counter mode TAiIN input (When count on falling edge is selected) TAiIN input (When count on rising edge is selected) Two-phase pulse input in event counter mode TAiIN input tsu(TAIN-TAOUT) TAiOUT input tsu(TAOUT-TAIN) tc(TB) tw(TBH) TBiIN input tw(TBL) tc(AD) tw(ADL) ADTRG input tsu(TAIN-TAOUT) tsu(TAOUT-TAIN) th(TIN-UP) tsu(UP-TIN)
tc(TA)
Figure 23.3
Timing Diagram (1)
REJ09B0392-0064 Rev.0.64 Page 315 of 373
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M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
tc(CK) tw(CKH) CLKi tw(CKL) th(C-Q) TXDi td(C-Q) RXDi tw(INL) INTi input tw(INH) tsu(D-C) th(C-D)
Figure 23.4
Timing Diagram (2)
REJ09B0392-0064 Rev.0.64 Page 316 of 373
Oct 12, 2007
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Memory Expansion Mode, Microprocessor Mode
(Effective for setting with wait)
BCLK RD (Separate bus) WR, WRL, WRH (Separate bus) RD (Multiplexed bus) WR, WRL, WRH (Multiplexed bus) RDY input
tsu(RDY-BCLK) th(BCLK-RDY)
(Common to setting with wait and setting without wait)
BCLK
tsu(HOLD-BCLK) th(BCLK-HOLD)
HOLD input
HLDA input P0, P1, P2, P3, P4, P5_0 to P5_2
(1)
td(BCLK-HLDA)
Hi-Z
td(BCLK-HLDA)
NOTES: 1. These pins are set to high-impedance regardless of the input level of the BYTE pin, PM06 bit in PM0 register and PM11 bit in PM1 register.
* Measuring conditions : * VCC1=VCC2=5V * Input timing voltage : Determined with VIL=1.0V, VIH=4.0V * Output timing voltage : Determined with VOL=2.5V, VOH=2.5V
Figure 23.5
Timing Diagram (3)
REJ09B0392-0064 Rev.0.64 Page 317 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(For setting with no wait) Read timing
BCLK td(BCLK-CS)
25ns.max
VCC1=VCC2=5V
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD
tac1(RD-DB)
(0.5 x tcyc-45)ns.max Hi-Z
DBi
tsu(DB-RD)
40ns.min
th(RD-DB)
0ns.min
Write timing
BCLK td(BCLK-CS)
25ns.max
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
(0.5 x tcyc-10)ns.min
th(WR-AD)
ALE td(BCLK-WR)
25ns.max
th(BCLK-WR)
0ns.min
WR, WRL, WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
td(DB-WR) 1 tcyc= f(BCLK)
(0.5 x tcyc-40)ns.min
(0.5 x tcyc-10)ns.min
th(WR-DB)
Measuring conditions * VCC1=VCC2=5V * Input timing voltage : VIL=0.8V, VIH=2.0V * Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.6
Timing Diagram (4)
REJ09B0392-0064 Rev.0.64 Page 318 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for 1-wait setting and external area access) Read timing
BCLK td(BCLK-CS)
25ns.max
VCC1=VCC2=5V
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
0ns.min
th(RD-AD)
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD
(1.5xtcyc-45)ns.max
tac2(RD-DB)
DBi
Hi-Z
tsu(DB-RD)
th(RD-DB)
0ns.min
Write timing
BCLK td(BCLK-CS)
25ns.max
40ns.min
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
(0.5xtcyc-10)ns.min
th(WR-AD)
ALE td(BCLK-WR) WR, WRL, WRH
Hi-Z 25ns.max
th(BCLK-WR)
0ns.min
td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
td(DB-WR) tcyc= 1 f(BCLK)
(0.5xtcyc-40)ns.min
th(WR-DB)
(0.5xtcyc-10)ns.min
Measuring conditions VCC1=VCC2=5V Input timing voltage : VIL=0.8V, VIH=2.0V Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.7
Timing Diagram (5)
REJ09B0392-0064 Rev.0.64 Page 319 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for 2-wait setting and external area access) Read timing
tcyc
VCC1=VCC2=5V
BCLK td(BCLK-CS)
25ns.max
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD
(2.5xtcyc-45)ns.max
tac2(RD-DB)
DBi
Hi-Z
tsu(DB-RD)
40ns.min
0ns.min
th(RD-DB)
Write timing
tcyc
BCLK td(BCLK-CS)
25ns.max
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max -4ns.min
th(BCLK-ALE)
(0.5xtcyc-10)ns.min
th(WR-AD)
ALE td(BCLK-WR)
25ns.max
th(BCLK-WR)
0ns.min
WR, WRL WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
Tcyc=
1 f(BCLK)
(1.5xtcyc-40)ns.min
td(DB-WR)
(0.5xtcyc-10)ns.min
th(WR-DB)
Measuring conditions * VCC1=VCC2=5V * Input timing voltage : VIL=0.8V, VIH=2.0V * Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.8
Timing Diagram (6)
REJ09B0392-0064 Rev.0.64 Page 320 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for 3-wait setting and external area access) Read timing
tcyc BCLK td(BCLK-CS)
25ns.max
VCC1=VCC2=5V
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD tac2(RD-DB)
(3.5xtcyc-45)ns.max
DBi
Hi-Z
tsu(DB-RD)
40ns.min
th(RD-DB)
0ns.min
Write timing
tcyc BCLK td(BCLK-CS)
25ns.max
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(WR-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-WR)
25ns.max
th(BCLK-WR)
0ns.min
WR, WRL WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
td(DB-WR) tcyc= 1 f(BCLK)
(2.5xtcyc-40)ns.min
th(WR-DB)
(0.5xtcyc-10)ns.min
Measuring conditions * VCC1=VCC2=5V * Input timing voltage : VIL=0.8V, VIH=2.0V * Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.9
Timing Diagram (7)
REJ09B0392-0064 Rev.0.64 Page 321 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Memory Expansion Mode, Microprocessor Mode
Read timing
BCLK td(BCLK-CS)
25ns.max
(For 1- or 2-wait setting, external area access and multiplex bus selection )
tcyc
(0.5xtcyc-10)ns.min
th(RD-CS)
th(BCLK-CS)
4ns.min
CSi td(AD-ALE) ADi /DBi
(0.5xtcyc-25)ns.min
th(ALE-AD)
(0.5xtcyc-15)ns.min
Address
tdZ(RD-AD)
8ns.max (1.5xtcyc-45)ns.max
Data input
Address
tac3(RD-DB)
tsu(DB-RD)
40ns.min
th(RD-DB)
0ns.min
td(AD-RD) td(BCLK-AD)
25ns.max 0ns.min
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD
Write timing
BCLK td(BCLK-CS)
25ns.max
tcyc
th(WR-CS)
(0.5xtcyc-10)ns.min
th(BCLK-CS)
4ns.min
CSi td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
ADi /DBi
Address
Data output
Address
td(AD-ALE)
(0.5xtcyc-25)ns.min
td(DB-WR)
(1.5xtcyc-40)ns.min
th(WR-DB)
(0.5xtcyc-10)ns.min
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
td(AD-WR)
0ns.min
th(WR-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-WR)
25ns.max
th(BCLK-WR)
0ns.min
WR,WRL, WRH
Measuring conditions * VCC1=VCC2=5V * Input timing voltage : VIL=0.8V, VIH=2.0V * Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.10 Timing Diagram (8)
REJ09B0392-0064 Rev.0.64 Page 322 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=5V
Memory Expansion Mode, Microprocessor Mode
Read timing
tcyc BCLK th(RD-CS) td(BCLK-CS)
25ns.max (0.5xtcyc-10)ns.min
(For 3-wait setting, external area access and multiplex bus selection)
th(BCLK-CS)
4ns.min
CSi td(AD-ALE)
(0.5xtcyc-25)ns.min
th(ALE-AD)
(0.5xtcyc-15)ns.min Data input
ADi /DBi ADi BHE
(no multiplex)
Address
td(BCLK-AD)
25ns.max
tdZ(RD-AD) td(AD-RD)
0ns.min 8ns.max
th(RD-DB)
0ns.min
(2.5xtcyc-45)ns.max
tac3(RD-DB)
tsu(DB-RD)
40ns.min
th(BCLK-AD)
4ns.min
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-RD)
25ns.max
th(BCLK-RD)
0ns.min
RD
Write timing
tcyc BCLK td(BCLK-CS)
25ns.max (0.5xtcyc-10)ns.min
th(WR-CS)
th(BCLK-CS)
4ns.min
CSi td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
ADi /DBi td(AD-ALE)
Address
Data output
(0.5xtcyc-25)ns.min
(2.5xtcyc-40)ns.min
td(DB-WR)
th(WR-DB)
(0.5xtcyc-10)ns.min
td(BCLK-AD)
25ns.max
th(BCLK-AD)
4ns.min
ADi BHE
(no multiplex)
td(BCLK-ALE)
25ns.max
th(BCLK-ALE)
-4ns.min
th(WR-AD) td(AD-WR)
0ns.min
(0.5xtcyc-10)ns.min
ALE
th(BCLK-WR) td(BCLK-WR) WR, WRL WRH tcyc= 1 f(BCLK)
25ns.max 0ns.min
Measuring conditions * VCC1=VCC2=5V * Input timing voltage : VIL=0.8V, VIH=2.0V * Output timing voltage : VOL=0.4V, VOH=2.4V
Figure 23.11 Timing Diagram (9)
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Table 23.28
Symbol VOH HIGH Output Voltage
Electrical Characteristics (1)
Parameter
(1)
Measuring Condition Min. IOH=-1mA IOH=-1mA (2) IOH=-0.1mA IOH=-50A With no load applied With no load applied IOL=1mA IOL=1mA (2) IOL=0.1mA IOL=50A With no load applied With no load applied 0.2
Standard Typ. Max. VCC1 VCC2 VCC1 VCC1 2.9 2.2 0.5 0.5 0.5 0.5 0 0 0.8 VCC1- 0.5 VCC2- 0.5 VCC1- 0.5 VCC1- 0.5
Unit V
P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7 P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7
VOH
HIGH Output Voltage
XOUT
HIGHPOWER LOWPOWER
V
HIGH Output Voltage VOL LOW Output Voltage
XCOUT
HIGHPOWER LOWPOWER
V V
P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7 P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7
VOL
LOW Output Voltage LOW Output Voltage
XOUT XCOUT
HIGHPOWER LOWPOWER HIGHPOWER LOWPOWER
V V V
VT+-VT- Hysteresis
HOLD, RDY, TA0IN to TA4IN, TB0IN to TB5IN, INT0 to INT7, NMI, ADTRG, CTS0 to CTS2, CTS5 to CTS7, SCL0 to SCL2, SCL5 to SCL7, SDA0 to SDA2, SDA5 to SDA7, CLK0 to CLK7, TA0OUT to TA4OUT, KI0 to KI3, RXD0 to RXD2, RXD5 to RXD7, SIN3, SIN4 RESET
VT+-VT- Hysteresis IIH HIGH Input Current
0.2 VI=3V
(0.7)
1.8 4.0
V
A
P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_0 to P7_7, P8_0 to P8_7, P9_0 to P9_7, P10_0 to P10_7, XIN, RESET, CNVSS, BYTE P0_0 to P0_7, P1_0 to P1_7, P2_0 to P2_7, P3_0 to P3_7, P4_0 to P4_7, P5_0 to P5_7, P6_0 to P6_7, P7_2 to P7_7, P8_0 to P8_4, P8_6, P8_7, P9_0 to P9_7, P10_0 to P10_7
IIL
LOW Input Current
VI=0V
-4.0
A
RPULLUP
Pull-Up Resistance
VI=0V
50
100
500
k
RfXIN RfXCIN VRAM
Feedback Resistance XIN Feedback Resistance XCIN RAM Retention Voltage At stop mode 2.0
3.0 25
M M V
NOTES: 1. Referenced to VCC1 = VCC2 = 2.7 to 3.3V, VSS = 0V at Topr = -20 to 85C / -40 to 85C, f(XIN)=25MHz unless otherwise specified. 2. VCC1 for the port P6 to P10 and VCC2 for the port P0 to P5.
REJ09B0392-0064 Rev.0.64 Page 324 of 373
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Table 23.29
Symbol ICC
Electrical Characteristics (2) (1)
Parameter Measuring Condition Min. f(BCLK)=25MHz, No division No division, 125 kHz On-chip oscillation f(BCLK)=10MHz, VCC1=3.0V f(BCLK)=10MHz, VCC1=3.0V f(BCLK)=32kHz Low power dissipation mode, RAM (3) f(BCLK)=32kHz Low power dissipation mode, Flash Memory (3) FMR22=FMR23=1 125 kHz On-chip oscillation, Wait mode f(BCLK)=32kHz Wait mode (2), Oscillation capability High f(BCLK)=32kHz Wait mode (2), Oscillation capability Low Stop mode Topr =25C Standard Typ. 20 450 Max. mA
A
Unit
In single-chip mode, Flash Power Supply Current Memory (VCC1=VCC2=2.7V to 3.6V) the output pins are open and other pins are VSS Flash Memory Program Flash Memory Erase Flash Memory
20 30 40
mA mA
A
160
A
9
A
9.5
A
5.7
A
3 3 6
A A A
Idet2 Idet0
Low Voltage Detection Dissipation Current (4) Reset Area Detection Dissipation Current
(4)
NOTES: 1. Referenced to VCC1=VCC2=2.7 to 3.3V, VSS = 0V at Topr = -20 to 85C / -40 to 85C, f(BCLK)=25MHz unless otherwise specified. 2. With one timer operated using fC32. 3. This indicates the memory in which the program to be executed exists. 4. Idet is dissipation current when the following bit is set to "1" (detection circuit enabled). Idet2: VC27 bit in the VCR2 register Idet0: VC25 bit in the VCR2 register
REJ09B0392-0064 Rev.0.64 Page 325 of 373
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Timing Requirements (VCC1 = VCC2 = 3V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.30 External Clock Input (XIN input)(1)
Symbol tc tw(H) tw(L) tr tf
Parameter External Clock Input Cycle Time External Clock Input HIGH Pulse Width External Clock Input LOW Pulse Width External Clock Rise Time External Clock Fall Time
Standard Min. 50 20 20 9 9 Max.
Unit ns ns ns ns ns
NOTE: 1. The condition is VCC1=VCC2=2.7 to 3.0V.
Table 23.31
Symbol tac1(RD-DB) tac2(RD-DB) tac3(RD-DB) tsu(DB-RD)
tsu(RDY-BCLK)
Memory Expansion Mode and Microprocessor Mode
Parameter Data Input Access Time (for setting with no wait) Data Input Access Time (for setting with wait) Data Input Access Time (when accessing multiplex bus area) Data Input Setup Time
RDY Input Setup Time
Standard Min. Max. (NOTE 1) (NOTE 2) (NOTE 3) 50 40 50 0 0 0
Unit ns ns ns ns ns ns ns ns ns
tsu(HOLD-BCLK) HOLD Input Setup Time
th(RD-DB) th(BCLK-RDY)
th(BCLK-HOLD)
Data Input Hold Time
RDY Input Hold Time HOLD Input Hold Time
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 60 [ ns ] f ( BCLK )
2.
Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ----------------------------------- - 60 [ ns ] f ( BCLK ) n is "2" for 1-wait setting, "3" for 2-wait setting and "4" for 3-wait setting.
3.
Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ----------------------------------- - 60 [ ns ] f ( BCLK ) n is "2" for 2-wait setting, "3" for 3-wait setting.
REJ09B0392-0064 Rev.0.64 Page 326 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Timing Requirements (VCC1 = VCC2 = 3V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.32
Symbol tc(TA) tw(TAH) tw(TAL) TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width
Timer A Input (Counter Input in Event Counter Mode)
Parameter 150 60 60 Standard Min. Max. ns ns ns Unit
Table 23.33
Symbol tc(TA) tw(TAH) tw(TAL)
Timer A Input (Gating Input in Timer Mode)
Parameter TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 600 300 300 Standard Min. Max. ns ns ns Unit
Table 23.34
Symbol tc(TA) tw(TAH) tw(TAL)
Timer A Input (External Trigger Input in One-shot Timer Mode)
Parameter TAiIN Input Cycle Time TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 300 150 150 Standard Min. Max. ns ns ns Unit
Table 23.35
Symbol tw(TAH) tw(TAL)
Timer A Input (External Trigger Input in Pulse Width Modulation Mode)
Parameter TAiIN Input HIGH Pulse Width TAiIN Input LOW Pulse Width 150 150 Standard Min. Max. ns ns Unit
Table 23.36
Symbol tc(UP) tw(UPH) tw(UPL) tsu(UP-TIN) th(TIN-UP)
Timer A Input (Counter Increment/Decrement Input in Event Counter Mode)
Parameter TAiOUT Input Cycle Time TAiOUT Input HIGH Pulse Width TAiOUT Input LOW Pulse Width TAiOUT Input Setup Time TAiOUT Input Hold Time Standard Min. 3000 1500 1500 600 600 Max. ns ns ns ns ns Unit
Table 23.37
Symbol
tc(TA)
Timer A Input (Two-phase Pulse Input in Event Counter Mode)
Parameter TAiIN Input Cycle Time 2 500 500 Standard Min. Max.
s
Unit
tsu(TAIN-TAOUT) TAiOUT Input Setup Time tsu(TAOUT-TAIN) TAiIN Input Setup Time
ns ns
REJ09B0392-0064 Rev.0.64 Page 327 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Timing Requirements (VCC1 = VCC2 = 3V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.38
Symbol tc(TB) tw(TBH) tw(TBL) tc(TB) tw(TBH) tw(TBL)
Timer B Input (Counter Input in Event Counter Mode)
Parameter Min. TBiIN Input Cycle Time (counted on one edge) TBiIN Input HIGH Pulse Width (counted on one edge) TBiIN Input LOW Pulse Width (counted on one edge) TBiIN Input Cycle Time (counted on both edges) TBiIN Input HIGH Pulse Width (counted on both edges) TBiIN Input LOW Pulse Width (counted on both edges) 150 60 60 300 120 120 Standard Max. ns ns ns ns ns ns Unit
Table 23.39
Symbol tc(TB) tw(TBH) tw(TBL)
Timer B Input (Pulse Period Measurement Mode)
Parameter Min. TBiIN Input Cycle Time TBiIN Input HIGH Pulse Width TBiIN Input LOW Pulse Width 600 300 300 Standard Max. ns ns ns Unit
Table 23.40
Symbol tc(TB) tw(TBH) tw(TBL)
Timer B Input (Pulse Width Measurement Mode)
Parameter Min. TBiIN Input Cycle Time TBiIN Input HIGH Pulse Width TBiIN Input LOW Pulse Width 600 300 300 Standard Max. ns ns ns Unit
Table 23.41
Symbol tc(AD) tw(ADL)
A/D Trigger Input
Parameter Min.
ADTRG Input Cycle Time ADTRG Input LOW Pulse Width
Standard Max. 1500 200
Unit ns ns
Table 23.42
Symbol tc(CK) tw(CKH) tw(CKL) td(C-Q) th(C-Q) tsu(D-C) th(C-D)
Serial Interface
Parameter Min. CLKi Input Cycle Time CLKi Input HIGH Pulse Width CLKi Input LOW Pulse Width TXDi Output Delay Time TXDi Hold Time RXDi Input Setup Time RXDi Input Hold Time 0 100 90 300 150 150 160 Standard Max. ns ns ns ns ns ns ns Unit
Table 23.43
Symbol tw(INH) tw(INL)
External Interrupt INTi Input
Parameter Min.
INTi Input HIGH Pulse Width INTi Input LOW Pulse Width
Standard Max. 380 380
Unit ns ns
REJ09B0392-0064 Rev.0.64 Page 328 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Switching Characteristics (VCC1 = VCC2 = 3V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.44
Symbol td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS) td(BCLK-ALE) th(BCLK-ALE) td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB) td(BCLK-HLDA) Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) ALE Signal Output Delay Time ALE Signal Output Hold Time RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) (3) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to WR)
HLDA Output Delay Time
(3)
Memory Expansion and Microprocessor Modes (for setting with no wait)
Parameter Measuring Condition Standard Min. 4 0 (NOTE 2) 30 4 25
-4
Unit 30 ns ns ns ns ns ns ns ns 30 ns ns 30 ns ns 40 ns ns ns ns 40 ns
Max.
See Figure 23.12
0 0 4 (NOTE 1) (NOTE 2)
NOTES: 1. Calculated according to the BCLK frequency as follows: 9 0.5x10 ----------------------- - 40 [ ns ] f (BCLK) is 12.5MHz or less. f ( BCLK ) 2. Calculated according to the BCLK frequency as follows: 9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK ) This standard value shows the timing when the output is off, and does not show hold time of data bus. Hold time of data bus varies with capacitor volume and pull-up (pulldown) resistance value. Hold time of data bus is expressed in t= -CR X ln (1-VOL / VCC2) by a circuit of the right figure. For example, when VOL = 0.2VCC2, C = 30pF, R = 1k, hold time of output "L" level is t = -30pF X 1k X In(1-0.2VCC2 / VCC2) = 6.7ns.
R DBi C
P0 P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 P13 P14
30pF
Figure 23.12 Ports P0 to P14 Measurement Circuit
REJ09B0392-0064 Rev.0.64 Page 329 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Switching Characteristics (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.45
Symbol td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS)
Memory Expansion and Microprocessor Modes (for 1- to 3-wait setting and external area access)
Parameter Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) 4 25 See Figure 23.12 -4 30 0 30 0 40 4 (NOTE 1) (NOTE 2) 40
(3)
Measuring Condition
Standard Min. 4 0 (NOTE 2) 30 Max. 30
Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns
td(BCLK-ALE) ALE Signal Output Delay Time th(BCLK-ALE) ALE Signal Output Hold Time td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB) RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to WR)(3)
td(BCLK-HLDA) HLDA Output Delay Time
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 ( n - 0.5 )x10 ----------------------------------- - 40 [ ns ] f ( BCLK ) n is "1" for 1-wait setting, "2" for 2-wait setting and "3" for 3-wait setting. (BCLK) is 12.5MHz or less.
2.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK )
3.
This standard value shows the timing when the output is off, and does not show hold time of data bus. Hold time of data bus varies with capacitor volume and pull-up (pull-down) resistance value. Hold time of data bus is expressed in t=-CR X ln (1-VOL / VCC2) by a circuit of the right figure. For example, when VOL = 0.2VCC2, C = 30pF, R = 1k, hold time of output "L" level is t = -30pF X 1k X In(1-0.2VCC2 / VCC2) = 6.7ns.
R DBi C
REJ09B0392-0064 Rev.0.64 Page 330 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
Switching Characteristics (VCC1 = VCC2 = 5V, VSS = 0V, at Topr = -20 to 85C / -40 to 85C unless otherwise specified) Table 23.46
Symbol td(BCLK-AD) th(BCLK-AD) th(RD-AD) th(WR-AD) td(BCLK-CS) th(BCLK-CS) th(RD-CS) th(WR-CS) td(BCLK-RD) th(BCLK-RD) td(BCLK-WR) th(BCLK-WR) td(BCLK-DB) th(BCLK-DB) td(DB-WR) th(WR-DB)
Memory Expansion and Microprocessor Modes (for 2- to 3-wait setting, external area access and multiplex bus selection)
Parameter Address Output Delay Time Address Output Hold Time (in relation to BCLK) Address Output Hold Time (in relation to RD) Address Output Hold Time (in relation to WR) Chip Select Output Delay Time Chip Select Output Hold Time (in relation to BCLK) Chip Select Output Hold Time (in relation to RD) Chip Select Output Hold Time (in relation to WR) RD Signal Output Delay Time RD Signal Output Hold Time WR Signal Output Delay Time WR Signal Output Hold Time Data Output Delay Time (in relation to BCLK) Data Output Hold Time (in relation to BCLK) Data Output Delay Time (in relation to WR) Data Output Hold Time (in relation to WR) See Figure 23.12 0 40 0 50 4 (NOTE 2) (NOTE 1) 40 25
-4
Measuring Condition
Standard Min. 4 (NOTE 1) (NOTE 1) 50 4 (NOTE 1) (NOTE 1) 40 Max. 50
Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 8 ns
td(BCLK-HLDA) HLDA Output Delay Time
td(BCLK-ALE) ALE Signal Output Delay Time (in relation to BCLK) th(BCLK-ALE) ALE Signal Output Hold Time (in relation to BCLK) td(AD-ALE) th(AD-ALE) td(AD-RD) td(AD-WR) tdz(RD-AD) ALE Signal Output Delay Time (in relation to Address) ALE Signal Output Hold Time (in relation to Address) RD Signal Output Delay From the End of Address WR Signal Output Delay From the End of Address Address Output Floating Start Time (NOTE 3) (NOTE 4) 0 0
NOTES: 1. Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 10 [ ns ] f ( BCLK )
2.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 50 [ ns ] f ( BCLK )
n is "2" for 2-wait setting, "3" for 3-wait setting.
3.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 40 [ ns ] f ( BCLK )
4.
Calculated according to the BCLK frequency as follows:
9 0.5x10 ----------------------- - 15 [ ns ] f ( BCLK )
REJ09B0392-0064 Rev.0.64 Page 331 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
XIN input
tr tw(H) tf tc tw(L)
tc(TA) tw(TAH)
TAiIN input
tw(TAL) tc(UP) tw(UPH)
TAiOUT input
tw(UPL)
TAiOUT input (Up/down input) During Event Counter Mode TAiIN input (When count on falling edge is selected) TAiIN input (When count on rising edge is selected) Two-Phase Pulse Input in Event Counter Mode TAiIN input
tsu(TAIN-TAOUT) tsu(TAIN-TAOUT) tsu(TAOUT-TAIN) tsu(TAOUT-TAIN) tc(TB) tw(TBH) tc(TA) th(TIN-UP) tsu(UP-TIN)
TAiOUT input
TBiIN input
tw(TBL) tc(AD) tw(ADL)
ADTRG input
Figure 23.13 Timing Diagram (1)
REJ09B0392-0064 Rev.0.64 Page 332 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
VCC1=VCC2=3V
tc(CK) tw(CKH)
CLKi
tw(CKL) th(C-Q)
TXDi
td(C-Q) tsu(D-C) th(C-D)
RXDi
tw(INL)
INTi input
tw(INH)
Figure 23.14 Timing Diagram (2)
REJ09B0392-0064 Rev.0.64 Page 333 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(Effective for setting with wait)
VCC1=VCC2=3V
BCLK
RD (Separate bus) WR, WRL, WRH (Separate bus) RD (Multiplexed bus) WR, WRL, WRH (Multiplexed bus) RDY input tsu(RDY-BCLK) th(BCLK-RDY)
(Common to setting with wait and setting without wait)
BCLK
tsu(HOLD-BCLK) HOLD input
th(BCLK-HOLD)
HLDA output P0, P1, P2, P3, P4, P5_0 to P5_2 (1) td(BCLK-HLDA)
Hi-Z
td(BCLK-HLDA)
NOTES: 1. These pins are set to high-impedance regardless of the input level of the BYTE pin, PM06 bit in PM0 register and PM11 bit in PM1 register. Measuring conditions : * VCC1=VCC2=3V * Input timing voltage : Determined with VIL=0.6V, VIH=2.4V * Output timing voltage : Determined with VOL=1.5V, VOH=1.5V
Figure 23.15 Timing Diagram (3)
REJ09B0392-0064 Rev.0.64 Page 334 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for setting with no wait) Read timing
VCC1=VCC2=3V
BCLK td(BCLK-CS)
30ns.max
th(BCLK-CS)
4ns.min
CSi tcyc
td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
30ns.max
th(BCLK-RD)
0ns.min
RD tac1(RD-DB)
(0.5 x tcyc-60)ns.max
DBi
Hi-Z
tsu(DB-RD)
50ns.min
th(RD-DB)
0ns.min
Write timing
BCLK td(BCLK-CS)
30ns.max
th(BCLK-CS)
4ns.min
CSi tcyc
td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
th(WR-AD)
(0.5 x tcyc-10)ns.min
ALE td(BCLK-WR)
30ns.max
th(BCLK-WR)
0ns.min
WR, WRL, WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
td(DB-WR) tcyc= 1 f(BCLK)
(0.5 x tcyc-40)ns.min
th(WR-DB)
(0.5 x tcyc-10)ns.min
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.16 Timing Diagram (4)
REJ09B0392-0064 Rev.0.64 Page 335 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for 1-wait setting and external area access) Read timing
BCLK td(BCLK-CS)
30ns.max
VCC1=VCC2=3V
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
30ns.max
th(BCLK-RD)
0ns.min
RD tac2(RD-DB)
(1.5 x tcyc-60)ns.max
DBi
Hi-Z
tsu(DB-RD)
50ns.min
th(RD-DB)
0ns.min
Write timing
BCLK td(BCLK-CS)
30ns.max
th(BCLK-CS)
4ns.min
CSi
tcyc
td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
(0.5 x tcyc-10)ns.min
th(WR-AD)
ALE td(BCLK-WR)
30ns.max
th(BCLK-WR)
0ns.min
WR,WRL, WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
td(DB-WR) tcyc= 1 f(BCLK)
(0.5 x tcyc-40)ns.min
th(WR-DB)
(0.5 x tcyc-10)ns.min
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.17 Timing Diagram (5)
REJ09B0392-0064 Rev.0.64 Page 336 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
Read timing
BCLK td(BCLK-CS)
40ns.max
VCC1=VCC2=3V
(For 2-wait setting, external area access and multiplex bus selection)
tcyc
(0.5xtcyc-10)ns.min
th(RD-CS)
th(BCLK-CS)
4ns.min
CSi
(0.5xtcyc-40)ns.min
td(AD-ALE)
th(ALE-AD)
(0.5xtcyc-15)ns.min
ADi /DBi
Address
tdZ(RD-AD)
8ns.max (1.5xtcyc-60)ns.max
Data input
Address
tac3(RD-DB)
tsu(DB-RD)
50ns.min
th(RD-DB)
0ns.min
td(AD-RD) td(BCLK-AD)
40ns.max 0ns.min
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
(0.5xtcyc-10)ns.min
th(RD-AD)
ALE td(BCLK-RD)
40ns.max
th(BCLK-RD)
0ns.min
RD
Write timing
BCLK td(BCLK-CS)
40ns.max
tcyc
th(WR-CS)
(0.5xtcyc-10)ns.min
th(BCLK-CS)
4ns.min
CSi td(BCLK-DB)
50ns.max
th(BCLK-DB)
4ns.min
ADi /DBi
Address
Data output
Address
td(AD-ALE)
(0.5xtcyc-40)ns.min
td(DB-WR)
(1.5xtcyc-50)ns.min
th(WR-DB)
(0.5xtcyc-10)ns.min
td(BCLK-AD)
40ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
td(AD-WR)
0ns.min
th(WR-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-WR)
40ns.max
th(BCLK-WR)
0ns.min
WR,WRL, WRH
tcyc=
1 f(BCLK)
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.18 Timing Diagram (6)
REJ09B0392-0064 Rev.0.64 Page 337 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(for 3-wait setting and external area access) Read timing
tcyc BCLK td(BCLK-CS)
30ns.max
VCC1 = VCC2 = 3V
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
0ns.min
ALE td(BCLK-RD)
30ns.max
th(BCLK-RD)
0ns.min
RD tac2(RD-DB)
(3.5 x tcyc-60)ns.max
DBi
Hi-Z
tsu(DB-RD)
50ns.min
th(RD-DB)
0ns.min
Write timing
tcyc BCLK td(BCLK-CS)
30ns.max
th(BCLK-CS)
4ns.min
CSi td(BCLK-AD)
30ns.max
th(BCLK-AD)
4ns.min
ADi BHE td(BCLK-ALE)
30ns.max
th(BCLK-ALE)
-4ns.min
th(WR-AD)
(0.5 x tcyc-10)ns.min
ALE td(BCLK-WR)
30ns.max
th(BCLK-WR)
0ns.min
WR, WRL WRH td(BCLK-DB)
40ns.max
th(BCLK-DB)
4ns.min
DBi
Hi-Z
td(DB-WR) tcyc= 1 f(BCLK)
(2.5 x tcyc-40)ns.min
th(WR-DB)
(0.5 x tcyc-10)ns.min
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.19 Timing Diagram (7)
REJ09B0392-0064 Rev.0.64 Page 338 of 373
Oct 12, 2007
Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
Read timing
BCLK td(BCLK-CS)
40ns.max
VCC1=VCC2=3V
(For 2-wait setting, external area access and multiplex bus selection)
tcyc
(0.5xtcyc-10)ns.min
th(RD-CS)
th(BCLK-CS)
4ns.min
CSi
(0.5xtcyc-40)ns.min
td(AD-ALE)
th(ALE-AD)
(0.5xtcyc-15)ns.min
ADi /DBi
Address
tdZ(RD-AD)
8ns.max (1.5xtcyc-60)ns.max
Data input
Address
tac3(RD-DB)
tsu(DB-RD)
50ns.min
th(RD-DB)
0ns.min
td(AD-RD) td(BCLK-AD)
40ns.max 0ns.min
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
(0.5xtcyc-10)ns.min
th(RD-AD)
ALE td(BCLK-RD)
40ns.max
th(BCLK-RD)
0ns.min
RD
Write timing
BCLK td(BCLK-CS)
40ns.max
tcyc
th(WR-CS)
(0.5xtcyc-10)ns.min
th(BCLK-CS)
4ns.min
CSi td(BCLK-DB)
50ns.max
th(BCLK-DB)
4ns.min
ADi /DBi
Address
Data output
Address
td(AD-ALE)
(0.5xtcyc-40)ns.min
td(DB-WR)
(1.5xtcyc-50)ns.min
th(WR-DB)
(0.5xtcyc-10)ns.min
td(BCLK-AD)
40ns.max
th(BCLK-AD)
4ns.min
ADi BHE
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
td(AD-WR)
0ns.min
th(WR-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-WR)
40ns.max
th(BCLK-WR)
0ns.min
WR,WRL, WRH
tcyc=
1 f(BCLK)
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.20 Timing Diagram (8)
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23. Electrical Characteristics
Memory Expansion Mode, Microprocessor Mode
(For 3-wait setting, external area access and multiplex bus selection) Read timing
tcyc BCLK th(RD-CS) td(BCLK-CS)
40ns.max (0.5xtcyc-10)ns.min
VCC1=VCC2=3V
th(BCLK-CS)
6ns.min
CSi td(AD-ALE)
(0.5xtcyc-40)ns.min
th(ALE-AD)
ADi /DBi ADi BHE
(No multiplex) 40ns.max
(0.5xtcyc-15)ns.min Data input
Address
td(BCLK-AD)
tdZ(RD-AD) td(AD-RD)
0ns.min 8ns.max
th(RD-DB) tac3(RD-DB)
(2.5xtcyc-60)ns.max
tsu(DB-RD)
50ns.min
0ns.min
th(BCLK-AD)
4ns.min
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
th(RD-AD)
(0.5xtcyc-10)ns.min
ALE td(BCLK-RD)
40ns.max
th(BCLK-RD)
0ns.min
RD
Write timing
tcyc BCLK td(BCLK-CS)
40ns.max
th(WR-CS)
(0.5xtcyc-10)ns.min
th(BCLK-CS)
4ns.min
CSi td(BCLK-DB)
50ns.max
th(BCLK-DB)
4ns.min
ADi /DBi td(AD-ALE)
Address
(0.5xtcyc-40)ns.min
Data output
(2.5xtcyc-50)ns.min
td(DB-WR)
(0.5xtcyc-10)ns.min
th(WR-DB) th(BCLK-AD)
4ns.min
td(BCLK-AD)
40ns.max
ADi BHE
(No multiplex)
td(BCLK-ALE)
40ns.max
th(BCLK-ALE)
-4ns.min
th(WR-AD) td(AD-WR)
0ns.min
(0.5xtcyc-10)ns.min
ALE
th(BCLK-WR) WR, WRL WRH tcyc= 1 f(BCLK) td(BCLK-WR)
40ns.max 0ns.min
Measuring conditions * VCC1=VCC2=3V * Input timing voltage : VIL=0.6V, VIH=2.4V * Output timing voltage : VOL=1.5V, VOH=1.5V
Figure 23.21 Timing Diagram (9)
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24. Precautions
24. Precautions
24.1 24.1.1 SFR Register Settings
Table 24.1 lists Registers with Write-Only Bits. Set these registers with immediate values. When establishing a next value by altering the existing value, write the existing value to the RAM as well as to the register. Transfer the next value to the register after making changes in the RAM.
Table 24.1 Registers with Write-Only Bits
Register Watchdog timer reset register Watchdog timer start register Timer A1-1 register Timer A2-1 register Timer A4-1 register Dead time timer Timer B2 interrupt generation frequency set counter SI/O3 bit rate register SI/O4 bit rate register UART0 bit rate register UART1 bit rate register UART2 bit rate register UART5 bit rate register UART6 bit rate register UART7 bit rate register UART0 transmit buffer register UART1 transmit buffer register UART2 transmit buffer register UART5 transmit buffer register UART6 transmit buffer register UART7 transmit buffer register Timer A0 register Timer A1 register Timer A2 register Timer A3 register Timer A4 register
Symbol WDTR WDTS TA11 TA21 TA41 DTT ICTB2 S3BRG S4BRG U0BRG U1BRG U2BRG U5BRG U6BRG U7BRG U0TB U1TB U2TB U5TB U6TB U7TB TA0 TA1 TA2 TA3 TA4
Address 037Dh 037Eh 0303h to 0302h 0305h to 0304h 0307h to 0306h 030Ch 030Dh 0273h 0277h 0249h 0259h 0269h 0289h 0299h 02A9h 024Bh to 024Ah 025Bh to 025Ah 026Bh to 026Ah 028Bh to 028Ah 029Bh to 029Ah 02ABh to 02AAh 0327h to 0326h 0329h to 0328h 032Bh to 032Ah 032Dh to 032Ch 032Fh to 032Eh
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24. Precautions
24.2 24.2.1
Reset VCC1
When supplying power to the microcomputer, the power supply voltage applied to the VCC1 pin must meet the conditions of SVCC.
Symbol SVCC
Parameter Power supply rising gradient (VCC1) (Voltage range 0 to 2)
Standard Min. Typ. Max. 0.05
Unit V / ms
Voltage SVCC Power supply rising gradient (VCC1) 2V SVCC
0V
Figure 24.1 Timing of SVCC
Time
24.2.2
CNVSS
To start to operate in single-chip mode after reset, connect to VSS via resistor. The internal pull-up of the CNVSS pin is on immediately after hardware reset 1 or 2 is released in single-chip mode. Therefore, the CNVSS pin level becomes high for two cycles of fOCO-S maximum.
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24. Precautions
24.3
Bus
* When hardware reset 1 or brown-out reset is performed with "H" input on the CNVSS pin, contents of internal ROM cannot be read.
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24. Precautions
24.4
PLL Frequency Synthesizer
To use the PLL frequency synthesizer, stabilize supply voltage so that the standard of the power supply ripple is met.
Standard Min. Typ. Max. 10 0.5 0.3 0.3 0.3
Symbol f (ripple) VP-P (ripple) VCC (|V /T|)
Parameter Power supply ripple allowable frequency (VCC1) Power supply ripple allowable (VCC1 = 5V) amplitude voltage (VCC1 = 3V) Power supply ripple rising / falling (VCC1 = 5V) gradient (VCC1 = 3V)
Unit kHz V V V / ms V / ms
f (ripple) Power supply ripple allowable frequency (VCC1) Vp-p (ripple) Power supply ripple allowable amplitude voltage
f (ripple)
VCC1
Vp-p (ripple)
Figure 24.2
Voltage Fluctuation Timing
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24. Precautions
24.5
Power Control
* When exiting stop mode by hardware reset 1, set the RESET pin to "L" until a main clock oscillation is stabilized. * Set the MR0 bit in the TAiMR register (i = 0 to 4) to 0 (pulse is not output) to use the timer A to exit stop mode. * After the WAIT instruction, insert at least four NOP instructions. When entering wait mode, the instruction queue reads ahead the instructions following WAIT, and depending on timing, some of these may execute before the microcomputer enters wait mode. Program example when entering wait mode is shown below. FSET I ; WAIT ;Enter wait mode NOP ;More than four NOP instructions NOP NOP NOP * When entering stop mode, insert a JMP.B instruction immediately after executing an instruction which sets the CM10 bit in the CM1 register to 1, and then insert at least four NOP instructions. When entering stop mode, the instruction queue reads ahead the instructions following the instruction which sets the CM10 bit to 1 (all clock stop), and some of these may execute before the microcomputer enters stop mode or before the interrupt routine for returning from stop mode. Program example when entering stop mode Program Example: FSET BSET JMP.B NOP NOP NOP NOP I 0, CM1 L2 Program Example:
; Enter stop mode ; Insert a JMP.B instruction ; More than four NOP instructions
L2:
* The CLKOUT pin outputs high in stop mode. Therefore, when the CLKOUT pin changes state from high to low and is immediately driven in stop mode, the low level width becomes short.
Stop mode CLKOUT
* Wait until the main clock oscillation stabilizes, before switching the clock source for the CPU clock to the main clock. Similarly, wait until the sub clock oscillates stably before switching the clock source for the CPU clock to the sub clock. * Do not stop the externally-generated clock when the externally-generated clock is input to the XIN pin and the main clock is used as the clock source for the CPU clock.
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M16C/64 Group * Suggestions to reduce power consumption Refer to the following descriptions when designing a system or programming.
24. Precautions
Ports The processor retains the state of each I/O port even when it goes to wait mode or to stop mode. A current flows in active output ports. A pass current flows to input ports in high-impedance state. When entering wait mode or stop mode, set non-used ports to input and stabilize the potential. A/D converter When A/D conversion is not performed, set the ADSTBY bit in the ADCON1 register to 0 (A/D operation stop). When A/D conversion is performed, start the A/D conversion at least 1 AD cycle or longer after setting the ADSTBY bit to 1 (A/D operation enabled). D/A converter When not performing D/A conversion, set the DAiE bit (i = 0, 1) in the DACON register to 0 (output inhibited) and the DAi register to 00h. Stopping peripheral functions Use the CM02 bit in the CM0 register to stop the unnecessary peripheral functions during wait mode. Switching the oscillation-driving capacity Set the driving capacity to "L" when oscillation is stable.
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24. Precautions
24.6
Protect
Set the PRC2 bit to 1 (write enabled) and then write to given SFR address, and the PRC2 bit will be cleared to 0 (write protected). Change the registers protected by the PRC2 bit in the next instruction after setting the PRC2 bit to 1. Make sure no interrupts or DMA transfers will occur between the instruction in which the PRC2 bit is set to 1 and the next instruction.
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24. Precautions
24.7 24.7.1
Interrupt Reading address 00000h
Do not read the address 00000h in a program. When a maskable interrupt request is accepted, the CPU reads interrupt information (interrupt number and interrupt request priority level) from the address 00000h during the interrupt sequence. At this time, the IR bit for the accepted interrupt is cleared to 0. If the address 00000h is read in a program, the IR bit for the interrupt which has the highest priority among the enabled interrupts is cleared to 0. This factors a problem that the interrupt is canceled, or an unexpected interrupt request is generated.
24.7.2
SP Setting
Set any value in the SP (USP, ISP) before accepting an interrupt. The SP (USP, ISP) is cleared to 0000h after reset. Therefore, if an interrupt is accepted before setting any value in the SP (USP, ISP), the program may go out of control. Especially when using the NMI interrupt, set a value in the ISP at the beginning of the program. Only for the first instruction after reset, all interrupts including the NMI interrupt are disabled.
24.7.3
NMI Interrupt
* The NMI interrupt cannot be disabled. If this interrupt is not used, set the PM24 bit in the PM2 register to 0 (port P8_5 function). * Stop mode cannot be entered into while input on the NMI pin is low because the CM10 bit in the CM1 register is fixed to 0. * Do not enter wait mode while input on the NMI pin is low because the CPU clock remains active even though the CPU stops, and therefore, the current consumption in the chip does not drop. In this case, normal condition is restored by a subsequent interrupt generated. * Set the low and high level durations of the input signal to the NMI pin to 2 CPU clock cycles + 300 ns or more.
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24. Precautions
24.7.4
Changing an Interrupt Generate Factor
If the interrupt generate factor is changed, the IR bit in the interrupt control register for the changed interrupt may inadvertently be set to 1 (interrupt requested). To use an interrupt, change the interrupt generate factor, and then be sure to clear the IR bit for that interrupt to 0 (interrupt not requested). Changing the interrupt generate factor referred to here means any act of changing the source, polarity or timing of the interrupt assigned to each software interrupt number. Therefore, if a mode change of any peripheral function involves changing the source, polarity or timing of an interrupt, be sure to clear the IR bit for that interrupt to 0 (interrupt not requested) after making such changes. Refer to the description of each peripheral function for details about the interrupts from peripheral functions. Figure 24.3 shows the Procedure for Changing the Interrupt Generate Factor.
Change the interrupt source
Disable interrupts (2, 3)
Change the interrupt generate factor (including a mode change of peripheral function)
Use the MOV instruction to clear the IR bit to 0 (interrupt not requested) (3)
Enable interrupts (2, 3)
Change is completed IR bit: A bit in the interrupt control register for the interrupt whose interrupt generate factor is to be changed NOTES : 1. The above settings must be executed individually. Do not execute two or more settings simultaneously (using one instruction). 2. Use the I flag for the INTi interrupt (i = 0 to 5). For the interrupts from peripheral functions other than the INTi interrupt, turn off the peripheral function that is the source of the interrupt in order not to generate an interrupt request before changing the interrupt generate factor. In this case, if the maskable interrupts can all be disabled without causing a problem, use the I flag. Otherwise, use the corresponding bits ILVL2 to ILVL0 for the interrupt whose interrupt generate factor is to be changed. 3. Refer to 23.7.6 Rewrite the Interrupt Control Register for details about the instructions to use and the notes to be taken for instruction execution.
Figure 24.3
Procedure for Changing the Interrupt Generate Factor
24.7.5
INT Interrupt
* Either an "L" level of at least tw (INL) width or an "H" level of at least tw (INH) width is necessary for the signal input to pins INT0 through INT7 regardless of the CPU operation clock. * If the POL bit in registers INT0IC to INT7IC, bits IFSR7 to IFSR0 in the IFSR register, or bits IFSR31 and IFSR30 in the IFSR3A register are changed, the IR bit may inadvertently set to 1 (interrupt requested). Be sure to clear the IR bit to 0 (interrupt not requested) after changing any of those register bits.
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24. Precautions
24.7.6
Rewriting the Interrupt Control Register
(a) The interrupt control register for any interrupt should be modified in places where no requests for that interrupt may occur. Otherwise, disable the interrupt before rewriting the interrupt control register. (b) To rewrite the interrupt control register for any interrupt after disabling that interrupt, be careful with the instruction to be used.
* Changing any bit other than the IR bit
When interrupts corresponding to the register occur, the IR bit may not become 1 (interrupt requested) and the interrupts may be ignored. If this causes any troubles, use any of the following instructions to change registers. Instruction: AND, OR, BCLR, or BSET. * Changing the IR bit Depending on the instruction used, the IR bit may not always be cleared to 0 (interrupt not requested). Therefore, be sure to use the MOV instruction to clear the IR bit. (c) When using the I flag to disable an interrupt, set the I flag while referring to the sample program fragments shown below. (Refer to (b) for details about rewriting the interrupt control registers in the sample program fragments.) Examples 1 through 3 show how to prevent the I flag from being set to 1 (interrupt enabled) before the interrupt control register is rewritten, owing to the effects of the internal bus and the instruction queue buffer. Example 1: Using the NOP instruction to keep the program waiting until the interrupt control register is modified INT_SWITCH1: FCLR I ; Disable interrupts. AND.B #00h, 0055h ; Set the TA0IC register to 00h. NOP ; NOP FSET I ; Enable interrupts. The number of the NOP instructions is as follows. PM20 = 1 (1 wait) : 2, PM20 = 0 (2 waits) : 3, when using the HOLD function : 4. Example 2: Using the dummy read to keep the FSET instruction waiting INT_SWITCH2: FCLR I ; Disable interrupts. AND.B #00h, 0055h ; Set the TA0IC register to 00h. MOV.W MEM, R0 ; Dummy read. FSET I ; Enable interrupts. Example 3: Using the POPC instruction to change the I flag INT_SWITCH3: PUSHC FLG FCLR I ; Disable interrupts. AND.B #00h, 0055h ; Set the TA0IC register to 00h. POPC FLG ; Enable interrupts.
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24. Precautions
24.7.7
Watchdog Timer Interrupt
Initialize the watchdog timer after the watchdog timer interrupt occurs.
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24. Precautions
24.8 24.8.1
DMAC Write to the DMAE Bit in the DMiCON Register (i = 0 to 3)
When both of the conditions below are met, follow the steps below. Conditions * The DMAE bit is set to 1 (DMAi is in active state) again while it remains 1. * A DMA request may occur simultaneously when the DMAE bit is being written. Steps (1) Write a 1 to the DMAE bit and DMAS bit in the DMiCON register simultaneously (1). (2) Make sure that the DMAi is in initial state (2) in a program. If the DMAi is not in initial state, repeat the above steps. NOTE: 1. The DMAS bit remains unchanged even if a 1 is written. However, if a 0 is written to this bit, it is set to 0 (DMA not requested). In order to prevent the DMAS bit from being modified to 0, 1 should be written to the DMAS bit when 1 is written to the DMAE bit. In this way the state of the DMAS bit immediately before being written can be maintained. 2. Similarly, when writing to the DMAE bit with a read-modify-write instruction, 1 should be written to the DMAS bit in order to maintain a DMA request which is generated during execution. 3. Read the TCRi register to verify whether the DMAi is in initial state. If the read value is equal to a value which was written to the TCRi register before DMA transfer start, the DMAi is in initial state. (In the case a DMA request occurs after writing to the DMAE bit, the read value is a value written to the TCRi register minus one.) If the read value is a value in the middle of transfer, the DMAi is not in initial state.
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24. Precautions
24.9 24.9.1
Timers Timer A Timer A (Timer Mode)
24.9.1.1
The timer is stopped after reset. Set the mode, count source, counter value, and others using registers TAiMR, TAi, TACS0 to TACS2, and TAPOFS before setting the TAiS bit in the TABSR register to 1 (count starts) (i = 0 to 4). Always make sure registers TAiMR, TACS0 to TACS2, and TAPOFS are modified while the TAiS bit is 0 (count stops) regardless of whether after reset or not. While counting is in progress, the counter value can be read out at any time by reading the TAi register. However, if the counter is read at the same time it is reloaded, the value FFFFh is read. Also, if the counter is read before it starts counting after a value is set in the TAi register while not counting, the set value is read. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on the SD pin enabled), pins TA1OUT, TA2OUT, and TA4OUT go to high-impedance state.
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24. Precautions
24.9.1.2
Timer A (Event Counter Mode)
The timer is stopped after reset. Set the mode, count source, counter value, and others using the TAiMR register, the TAi register, the UDF register, bits TAZIE, TA0TGL, and TA0TGH in the ONSF register and the TRGSR register, and TAPOS register before setting the TAiS bit in the TABSR register to 1 (count starts) (i = 0 to 4). Always make sure the TAiMR register, the UDF register, bits TAZIE, TA0TGL, and TA0TGH in the ONSF register, the TRGSR register, and TAPOFS register are modified while the TAiS bit is 0 (count stops) regardless of whether after reset or not. While counting is in progress, the counter value can be read out at any time by reading the TAi register. However, while reloading, FFFFh can be read in underflow, and 0000h in overflow. When the counter is read before it starts counting after a value is set in the TAi register while not counting, the set value is read. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on SD pin enabled), pins TA1OUT, TA2OUT, and TA4OUT go to high-impedance state.
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24. Precautions
24.9.1.3
Timer A (One-Shot Timer Mode)
The timer is stopped after reset. Set the mode, count source, counter value, and others using the TAiMR register, the TAi register, bits TA0TGL and TA0TGH in the ONSF register, the TRGSR register, registers TACS0 to TACS2 and the TAPOFS register before setting the TAiS bit in the TABSR register to 1 (count starts) (i = 0 to 4). Always make sure the TAiMR register, bits TA0TGL and TA0TGH in the ONSF register, the TRGSR register, registers TACS0 to TACS2, and the TAPOFS register are modified while the TAiS bit is 0 (count stops) regardless of whether after reset or not. When setting the TAiS bit to 0 (count stops), the followings occur: * A counter stops counting and a content of reload register is reloaded. * The TAiOUT pin outputs "L" when the POFSi bit in the TAPOFS register is 0; outputs "H" when 1. * After one cycle of the CPU clock, the IR bit in the TAiIC register is set to 1 (interrupt requested). Output in one-shot timer mode synchronizes with a count source internally generated. When an external trigger is selected, one-and-half-cycle delay of a count source as maximum occurs between a trigger input to the TAiIN pin and output in one-shot timer mode. The IR bit is set to 1 when timer operating mode is set with any of the following procedures: * Select one-shot timer mode after reset. * Change an operating mode from timer mode to one-shot timer mode. * Change an operating mode from event counter mode to one-shot timer mode. To use the Timer Ai interrupt (the IR bit), set the IR bit to 0 after the changes listed above are made. When a trigger occurs while counting, a counter reloads the reload register to continue counting after generating a re-trigger and counting down once. To generate a trigger while counting, generate a second trigger between generating the previous trigger and operating longer than one cycle of a timer count source. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on the SD pin enabled), pins TA1OUT, TA2OUT, and TA4OUT go to high-impedance state.
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24. Precautions
24.9.1.4
Timer A (Pulse Width Modulation Mode)
The timer is stopped after reset. Set the mode, count source, counter value, and others using the TAiMR register, the TAi register, bits TA0TGL and TA0TGH in the ONSF register, the TRGSR register, registers TACS0 to TACS2, and the TAPOF register before setting the TAiS bit in the TABSR register to 1 (count starts) (i = 0 to 4). Always make sure the TAiMR register, bits TA0TGL and TA0TGH in the ONSF register, the TRGSR register, registers TACS0 to TACS2, and the TAPOFS register are modified while the TAiS bit is 0 (count stops) regardless of whether after reset or not. The IR bit is set to 1 when setting a timer operating mode with any of the following procedures: * Select PWM mode after reset. * Change an operating mode from timer mode to PWM mode. * Change an operating mode from event counter mode to PWM mode. To use the timer Ai interrupt (IR bit), set the IR bit to 0 by program after the changes listed above are made. When setting the TAiS register to 0 (count stops) during PWM pulse output, the following action occurs. When the POFSi bit in the TAPOFS register is 0: * Stop counting. * When the TAiOUT pin is output "H," output level is set to "L" and the IR bit is set to 1. * When the TAiOUT pin is output "L," both output level and the IR bit remains unchanged. When the POFSi bit in the TAPOFS register is 1: * Stop counting. * When the TAiOUT pin is output "L," output level is set to "H" and the IR bit is set to 1. * When the TAiOUT pin is output "H," both output level and the IR bit remains unchanged. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on the SD pin enabled), pins TA1OUT, TA2OUT, and TA4OUT go to high-impedance state.
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24. Precautions
24.9.2 24.9.2.1
Timer B Timer B (Timer Mode)
The timer is stopped after reset. Set the mode, count source, counter value, and others using registers TBiMR, TBi, and TBCS0 to TBCS3 before setting the TBiS bit in the TABSR or the TBSR register to 1 (count starts) (i = 0 to 5). Always make sure the TBiMR register and registers TBCS0 to TBCS3 are modified while the TBiS bit is 0 (count stops) regardless of whether after reset or not. A value of a counter while counting, can be read in the TBi register at any time. FFFFh is read while reloading. If the counter is read before it starts counting after a value is set in the TBi register while not counting, the set value is read.
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24. Precautions
24.9.2.2
Timer B (Event Counter Mode)
The timer is stopped after reset. Set the mode, count source, counter value, and others using the TBiMR register and TBi register before setting the TBiS bit in the TABSR or the TBSR register to 1 (count starts) (i = 0 to 5). Always make sure the TBiMR register is modified while the TBiS bit is 0 (count stops) regardless of whether after reset or not. While counting is in progress, the counter value can be read out at any time by reading the TBi register. However, if this register is read at the same time the counter is reloaded, the read value is always FFFFh. If the TBi register is read after setting a value in it while not counting but before the counter starts counting, the read value is the value set in the register.
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24. Precautions
24.9.2.3
Timer B (Pulse Period / Pulse Width Measurement Mode)
The timer is stopped after reset. Set the mode, count source, etc. using the TBiMR register before setting the TBiS bit in the TABSR or the TBSR register to 1 (count starts) (i = 0 to 5). Always make sure the TBiMR register and registers TBCS0 to TBCS3 are modified while the TBiS bit is 0 (count stops) regardless of whether after reset or not. To clear the MR3 bit to 0 by writing to the TBiMR register while the TBiS bit = 1 (count starts), be sure to write the same value as previously written to bits TMOD0, TMOD1, MR0, MR1, TCK0, and TCK1 and a 0 to bit 4. The IR bit in the TBiIC register goes to 1 (interrupt requested) when an effective edge of a measurement pulse is input or Timer Bi is overflowed (i = 0 to 5). The factor of interrupt request can be determined by use of the MR3 bit in the TBiMR register within the interrupt routine. If the source of interrupt cannot be identified by the MR3 bit such as when the measurement pulse input and a timer overflow occur at the same time, use another timer to count the number of times Timer B has overflowed. Use the IR bit in the TBiIC register to detect only overflows. Use the MR3 bit only to determine the interrupt factor. When a count is started and the first effective edge is input, an indeterminate value is transferred to the reload register. At this time, Timer Bi interrupt request is not generated. A value of the counter is indeterminate after reset. If a count is started in this state, the MR3 bit may be set to 1 and Timer Bi interrupt request may be generated after a count start before an effective edge input. When a value is set to the TBi register while the TBiS bit is 0 (count stops), the same value is written to the counter. For pulse width measurement, pulse widths are successively measured. Use program to check whether the measurement result is "H" level width or "L" level width.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.10 Serial Interface 24.10.1 Clock Synchronous Serial I/O 24.10.1.1 Transmission / Reception
When the RTS function is used with an external clock, RTSi pin (i = 0 to 2, 5 to 7) outputs "L," which informs the transmitting side that the MCU is ready for a receive operation. The RTSi pin outputs "H" when a receive operation starts. Therefore, a transmit timing and receive timing can be synchronized by connecting the RTSi pin to the CTSi pin of the transmitting side. The RTS function is disabled when an internal clock is selected. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on SD pin enabled), the following pins go to high-impedance state: P7_2/CLK2/TA1OUT/V, P7_3/CTS2/RTS2/TA1IN/V, P7_4/TA2OUT/W, P7_5/TA2IN/W, P8_0/ TA4OUT/RXD5/SCL5/U, P8_1/TA4IN/CTS5/RTS5/U
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.10.1.2 Transmission
If an external clock is selected, the following conditions must be met while the external clock is held "H" when the CKPOL bit in the UiC0 register (i = 0 to 2, 5 to 7) is set to 0 (transmit data output at the falling edge and receive data input at the rising edge of the serial clock), or while the external clock is held "L" when the CKPOL bit is set to 1 (transmit data output at the rising edge and receive data input at the falling edge of the serial clock). * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in the UiTB register) * If CTS function is selected, input on the CTSi pin = "L"
24.10.1.3 Reception
In clock synchronous serial I/O mode, the shift clock is generated by activating a transmitter. Set the UARTi-associated registers for a transmit operation even if the MCU is used for receive operation only. Dummy data is output from the TXDi pin (i = 0 to 2, 5 to 7) while receiving. When an internal clock is selected, the shift clock is generated by setting the TE bit in the UiC1 register to 1 (transmission enabled) and placing dummy data in the UiTB register. When an external clock is selected, set the TE bit to 1 (transmission enabled), place dummy data in the UiTB register, and input an external clock to the CLKi pin to generate the shift clock. If data is received consecutively, an overrun error occurs when the RI bit in the UiC1 register is set to 1 (data present in the UiRB register) and the next receive data is received in the UARTi receive register. And then, the OER bit in the UiRB register is set to 1 (overrun error occurred). At this time, the UiRB register is undefined. If an overrun error occurs, the IR bit in the SiRIC register remains unchanged. To receive data consecutively, set dummy data in the low-order byte in the UiTB register per each receive operation. If an external clock is selected, the following conditions must be met while the external clock is held "H" when the CKPOL bit is set to 0 (transmit data output at the falling edge and receive data input at the rising edge of the serial clock), or while the external clock is held "L" when the CKPOL bit is set to 1 (transmit data output at the rising edge and receive data input at the falling edge of the serial clock). * The RE bit in the UiC1 register = 1 (reception enabled) * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in the UiTB register)
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.10.2 UART (Clock Asynchronous Serial I/O) Mode 24.10.2.1 Transmission / Reception
When the RTS function is used with an external clock, RTSi pin (i = 0 to 2, 5 to 7) outputs "L," which informs the transmitting side that the MCU is ready for a receive operation. The RTSi pin outputs "H" when a receive operation starts. Therefore, a transmit timing and receive timing can be synchronized by connecting the RTSi pin to the CTSi pin of the transmitting side. The RTS function is disabled when an internal clock is selected. If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (threephase output forcible cutoff by input on SD pin enabled), the following pins go to high-impedance state: P7_2/CLK2/TA1OUT/V, P7_3/CTS2/RTS2/TA1IN/V, P7_4/TA2OUT/W, P7_5/TA2IN/W, P8_0/ TA4OUT/RXD5/SCL5/U, P8_1/TA4IN/CTS5/RTS5/U
24.10.2.2 Transmission
If an external clock is selected, the following conditions must be met while the external clock is held "H" when the CKPOL bit in the UiC0 register (i = 0 to 2, 5 to 7) is set to 0 (transmit data output at the falling edge and receive data input at the rising edge of the serial clock), or while the external clock is held "L" when the CKPOL bit is set to 1 (transmit data output at the rising edge and receive data input at the falling edge of the serial clock). * The TE bit in the UiC1 register = 1 (transmission enabled) * The TI bit in the UiC1 register = 0 (data present in the UiTB register) * If CTS function is selected, input on the CTSi pin = "L"
24.10.3 Special Mode 1 (I2C Mode)
When generating start, stop, and restart conditions, set the STSPSEL bit in the UiSMR4 register (i = 0 to 2, 5 to 7) to 0 and wait for more than half cycle of the transfer clock before setting each condition generation bit (STAREQ, RSTAREQ, and STPREQ) from 0 to 1.
24.10.4 Special Mode 4 (SIM Mode)
A transmit interrupt request is generated by setting bits U2IRS and U2ERE in the U2C1 register to 1 (transmission completed) and 1 (error signal output), respectively. Therefore, when using SIM mode, make sure to clear the IR bit to 0 (interrupt not requested) after setting these bits.
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Under development
Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.10.5 SI/O3, SI/O4
The SOUTi default value which is set to the SOUTi pin by the SMi7 bit approximately 10 ns may be output when changing the SMi3 bit from 0 (I/O port) to 1 (SOUTi output and CLK function) while the SMi2 bit in the SiC to 0 (SOUTi output) and the SMi6 bit is set to 1 (internal clock). And then the SOUTi pin is held high-impedance. If the output level from the SOUTi pin is a problem when changing the SMi3 bit from 0 to 1, set the default value of the SOUTi pin by the SMi7 bit. i = 3, 4
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.11 A/D Converter
Set registers ADCON0 (except bit 6), ADCON1, and ADCON2 when A/D conversion is stopped (before a trigger occurs). After A/D conversion is stopped, set the ADSTBY bit from 1 to 0. When the ADSTBY bit in the ADCON1 register is changed from 0 (A/D operation stopped) to 1 (A/D operation enabled), wait for 1 AD cycle or longer to start A/D conversion. To prevent noise-induced device malfunction or latchup, as well as to minimize conversion errors, insert capacitors between pins AVCC, VREF, analog input (ANi (i = 0 to 7), AN0_i, AN2_i), and AVSS. Similarly, insert a capacitor between pins VCC1 and VSS. Figure 24.4 shows an example connection of individual pin. Make sure the port direction bits corresponding to the pins that are used as analog inputs are set to 0 (input mode). When the TRG bit in the ADCON0 register = 1 (external trigger), make sure the port direction bit for the ADTRG pin is set to 0 (input mode). When using key input interrupts, do not use any of the four pins AN4 to AN7 as analog inputs. (A key input interrupt request is generated when the A/D input voltage goes low.) When changing an A/D operating mode, set bits CH2 to CH0 in the ADCON0 register and bits SCAN1 to SCAN0 in the ADCON1 register again to select analog input pins.
VCC1
Microcomputer VCC1 VCC1 VSS AVCC VREF C1 C2 C3 ANi VSS ANi: ANi, AN0_i, and AN2_i (i = 0 to 7) AVSS VCC2
C4
VCC1
VCC2 C5
NOTES : 1. C10.47mF, C20.47mF, C3100pF, C40.1mF, C50.1mF (reference) 2. Use thick and shortest possible wiring to connect capacitors.
Figure 24.4
Use of Capacitors to Reduce Noise
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
When A/D conversion is forcibly terminated by setting the ADST bit in the AD0CON0 register to 0 (A/D conversion stops) by program during A/D conversion, the A/D conversion result is undefined. The ADi register not performing A/D conversion may also be undefined. If the ADST bit is set to 0 by program during A/D conversion, do not use values obtained from any ADi registers. The applied intermediate potential may cause more increase in power consumption to AN4 to AN7 than to other analog input pins (AN0 to AN3, AN0_0 to AN0_7, and AN2_0 to AN2_7) since AN4 to AN7 are used with KI0 to KI3. When A/D conversion is stopped in one-shot mode or single sweep mode, the ADST bit in the ADCON0 register becomes 0 (A/D conversion stop). Also, when a trigger by ADTRG is selected, the ADST bit becomes 0. Therefore, set the ADST bit to 1 (A/D conversion start) by a program if there is a possibility that a trigger is input subsequently. Connect the VREF pin to VCC1 pin. Because the VREF pin is connected to VCC1 pin inside, current flows if potential difference occurs between the pins.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.12 Programmable I/O Ports
If a low-level signal is applied to the SD pin when the IVPCR1 bit in the TB2SC register = 1 (three-phase output forcible cutoff by input on the SD pin enabled), pins P7_2 to P7_5 and P8_0 and P8_1 go to highimpedance state. Setting the SM32 bit in the S3C register to 1 causes the P9_2 pin to go to high-impedance state. Similarly, setting the SM42 bit in the S4C register to 1 causes the P9_6 pin to go to high-impedance state.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.13 Flash Memory Version 24.13.1 Functions to Inhibit Rewriting Flash Memory
ID codes are stored in addresses 0FFFDFh, 0FFFE3h, 0FFFEBh, 0FFFEFh, 0FFFF3h, 0FFFF7h, and 0FFFFBh. If wrong data are written to theses addresses, the flash memory cannot be read or written in standard serial I/O mode. The ROMCP register is mapped in address 0FFFFFh. If wrong data is written to this address, the flash memory cannot be read or written in parallel I/O mode. In the flash memory version of microcomputer, these addresses are allocated to the vector addresses (H) of fixed vectors.
24.13.2 Stop Mode
When the microcomputer enters stop mode, execute the instruction which sets the CM10 bit in the CM1 register to 1 (stop mode) after setting the FMR01 bit in the FMR0 register to 0 (CPU rewrite mode disabled) and disabling the DMA transfer.
24.13.3 Wait Mode
When shifting to wait mode, set the FMR01 bit to 0 (CPU rewrite mode disabled) before executing the WAIT instruction.
24.13.4 Low Power Consumption Mode, On-Chip Oscillator Low Power Consumption Mode
If the CM05 bit in the CM0 register is set to 1 (main clock stop), do not execute the following commands. * Program * Block erase * Lock bit program
24.13.5 Writing Command and Data
Write the command code and data at even addresses.
24.13.6 Program Command
Write xx41h in the first bus cycle and write data to the write address in the second bus cycle, and an auto program operation (data program and verify) will start. Make sure the address value specified in the first bus cycle is the same even address as the write address specified in the second bus cycle.
24.13.7 Lock Bit Program Command
Write xx77h in the first bus cycle and write xxD0h in the second bus cycle to the highest-order even address of a block, and the lock bit for the specified block is cleared to 0. Make sure then address value specified in the first bus cycle is the same highest-order block address that is specified in the second bus cycle.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.13.8 Operation Speed
Before entering CPU rewrite mode (EW0 or EW1 mode), set the CM11 bit in the CM1 register to 0 (main clock), select 10 MHz or less for CPU clock using the CM06 bit in the CM0 register and bits CM17 and CM16 in the CM1 register. Also, set the PM17 bit in the PM1 register to 1 (with wait state).
24.13.9 Instructions Inhibited against Use
The following instructions cannot be used in EW0 mode because the flash memory internal data is referred: UND instruction, INTO instruction, JMPS instruction, JSRS instruction, and BRK instruction.
24.13.10 Interrupts
EW0 Mode * Any interrupt which has a vector in the relocatable vector table can be used providing that its vector is transferred into the RAM area. * The NMI and watchdog timer (oscillation stop, re-oscillation detect, and low voltage detect) interrupts can be used because registers FMR0 and FMR1 are initialized when one of those interrupts occurs. The jump addresses for those interrupt routines should be set in the fixed vector table. * Because the rewrite operation stops when an NMI or watchdog timer (oscillation stop, re-oscillation detect, and low voltage detect) interrupt occurs, the rewrite program must be executed again after exiting the interrupt routine. * The address match interrupt cannot be used because the flash memory internal data is referred. EW1 Mode * Make sure that any interrupt which has a vector in the relocatable vector table or address match interrupt will not be accepted during the auto program or auto erase period. * Avoid using watchdog timer (oscillation stop, re-oscillation detect, and low voltage detect) interrupts. * The NMI interrupt can be used because registers FMR0 and FMR1 are initialized when this interrupt occurs. The jump address for the interrupt routine should be set in the fixed vector table. * Because the rewrite operation is halted when an NMI interrupt occurs, execute the rewrite program again after exiting the interrupt routine.
24.13.11 How to Access
To set the FMR01, FMR02, or FMR11 bit to 1, write 0 and then 1 in succession. Ensure that no interrupts or DMA transfers will occur before writing 1 after writing 0. Perform it when the NMI pin is "H" level if the PM24 bit is 1 (NMI).
24.13.12 Writing in the User ROM Area
EW0 Mode * If the power supply voltage drops while rewriting any block in which the rewrite control program is stored, the rewrite control program may not be correctly rewritten and, consequently, the flash memory becomes unable to be rewritten thereafter. In this case, use standard serial I/O or parallel I/O mode. EW1 Mode * Avoid rewriting any block in which the rewrite control program is stored.
24.13.13 DMA transfer
In EW1 mode, make sure that no DMA transfers will occur while the FMR00 bit in the FMR0 register = 0 (during the auto program or auto erase period).
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.13.14 Programming / Erasing Endurance and Execution Time
As the number of programming / erasing times increases, so does the execution time for software commands (program, block erase, and lock bit program commands). The software commands are stopped by hardware reset 1, brown-out reset, NMI interrupt, and watchdog timer (oscillation stop, re-oscillation detect, and low voltage detect) interrupt. If a software command is stopped by such reset or interrupt, erase the block in process before reexecuting the stopped command.
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
24. Precautions
24.14 Noise
Connect a bypass capacitor (approximately 0.1 F) across pins VCC1 and VSS, and pins VCC2 and VSS using the shortest and thicker possible wiring. Figure 24.5 shows the Bypass Capacitor Connection.
Bypass Capacitor Connecting Pattern Connecting Pattern
VSS
VCC2
M16C / 64 Group
VSS
VCC1
Connecting Pattern
Connecting Pattern
Bypass Capacitor
Figure 24.5
Bypass Capacitor Connection
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Preliminary Specification Specification in this preliminary version is subject to change.
M16C/64 Group
Appendix 1. Package Dimensions
Appendix 1.Package Dimensions
JEITA Package Code P-QFP100-14x20-0.65 RENESAS Code PRQP0100JD-B Previous Code 100P6F-A MASS[Typ.] 1.8g
Under development
HD *1 80
D 51
81
50 NOTE) 1. DIMENSIONS "*1" AND "*2" DO NOT INCLUDE MOLD FLASH. 2. DIMENSION "*3" DOES NOT INCLUDE TRIM OFFSET.
*2
HE
E
Reference Symbol
Dimension in Millimeters
ZE
100
31
1
ZD
Index mark
30 F
c
A2
L e y *3 bp x Detail F
D E A2 HD HE A A1 bp c e x y ZD ZE L
Min Nom Max 19.8 20.0 20.2 13.8 14.0 14.2 2.8 22.5 22.8 23.1 16.5 16.8 17.1 3.05 0.1 0.2 0 0.25 0.3 0.4 0.13 0.15 0.2 10 0 0.65 0.13 0.10 0.575 0.825 0.4 0.6 0.8
A
JEITA Package Code P-LQFP100-14x14-0.50
RENESAS Code PLQP0100KB-A
Previous Code 100P6Q-A / FP-100U / FP-100UV
MASS[Typ.] 0.6g
HD *1 D
75
51 NOTE) 1. DIMENSIONS "*1" AND "*2" DO NOT INCLUDE MOLD FLASH. 2. DIMENSION "*3" DOES NOT INCLUDE TRIM OFFSET.
76
50
bp b1 HE E
Reference Symbol
A1
*2
Dimension in Millimeters
c1
c
Terminal cross section
1 Index mark ZD
25 F
ZE
100
26
A2
A
D E A2 HD HE A A1 bp b1 c c1
c
A1
y e
*3
bp
L L1 Detail F
x
e x y ZD ZE L L1
Min Nom Max 13.9 14.0 14.1 13.9 14.0 14.1 1.4 15.8 16.0 16.2 15.8 16.0 16.2 1.7 0.05 0.1 0.15 0.15 0.20 0.25 0.18 0.09 0.145 0.20 0.125 8 0 0.5 0.08 0.08 1.0 1.0 0.35 0.5 0.65 1.0
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M16C/64 Group
Register Index
REGISTER INDEX
A
AD0 to AD7 ............................................ 233 ADCON0, ADCON1 ...................................... ........................ 232, 235, 237, 239, 241, 243 ADCON2 ................................................ 233 ADIC .............................................. 105, 106 AIER ....................................................... 117 AIER2 ..................................................... 117
I
ICTB2 ..................................................... 169 IDB0, IDB1 ............................................. 169 IFSR ....................................................... 113 IFSR2A, IFSR3A .................................... 114 INT0IC to INT7IC ................................... 106 INVC0 ..................................................... 167 INVC1 ..................................................... 168
K
KUPIC .................................................... 105
B
BCNIC ............................................ 105, 106
O
OFS1 .............................................. 120, 269 ONSF ..................................................... 140
C
CM0 ......................................................... 76 CM1 ......................................................... 77 CM2 ......................................................... 78 CPSRF ........................................... 141, 156 CRCD ..................................................... 248 CRCIN .................................................... 248 CSE .......................................................... 62 CSPR ..................................................... 120 CSR ......................................................... 55
P
P0 to P10 ............................................... 257 PCLKR ..................................................... 79 PCR ................................................ 114, 259 PD0 to PD10 .......................................... 256 PLC0 ........................................................ 80 PM0 .......................................................... 48 PM1 .......................................................... 49 PM2 .......................................................... 79 PRCR ....................................................... 98 PRG2C ..................................................... 50 PUR0, PUR1 .......................................... 258 PUR2 ...................................................... 259
D
D4INT ....................................................... 39 DA0, DA1 ............................................... 247 DACON .................................................. 247 DAR0 to DAR3 ....................................... 128 DBR ......................................................... 67 DM0CON to DM3CON ........................... 127 DM0IC .................................................... 106 DM0IC to DM3IC .................................... 105 DM0SL to DM3SL .................................. 125 DTT ........................................................ 169
R
RMAD0 to RMAD3 ................................. 117 RSTFR ..................................................... 46
S
S0RIC to S2RIC, S5RIC to S7RIC ......... 105 S0TIC to S2TIC, S5TIC to S7TIC .......... 105 S34C2 .................................................... 225 S3BRG, S4BRG ..................................... 224 S3C, S4C ............................................... 224 S3IC, S4IC ............................................. 106 S3TRR, S4TRR ...................................... 224 SAR0 to SAR3 ....................................... 128
F
FMR0 ..................................................... 272 FMR1 ..................................................... 273 FMR6 ..................................................... 275
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M16C/64 Group
Register Index
T
TA0 to TA4 ............................................. 138 TA0IC to TA4IC ...................................... 105 TA0MR to TA4MR .. 138, 143, 145, 150, 152 TA1, TA2 ................................................ 170 TA11 ....................................................... 170 TA1MR, TA2MR ..................................... 172 TA21 ....................................................... 170 TA2MR to TA4MR .................................. 147 TA4 ......................................................... 170 TA41 ....................................................... 170 TA4MR ................................................... 172 TABSR ................................... 139, 156, 171 TACS0, TACS1 ...................................... 141 TACS2 .................................................... 142 TAPOFS ................................................. 142 TB0 to TB5 ............................................. 155 TB0IC to TB5IC ...................................... 105 TB0MR to TB5MR .......... 155, 159, 161, 163 TB2 ........................................................ 171 TB2MR ................................................... 172 TB2SC ................................................... 170 TBCS0 to TBCS3 ................................... 157 TBSR ..................................................... 156 TCR0 to TCR3 ....................................... 128 TRGSR .......................................... 140, 171
U
U0BCNIC, U1BCNIC, U5BCNIC to U7BCNIC ................................................................ 105 U0BRG to U2BRG ................................. 180 U0C0 to U2C0 ........................................ 181 U0C1 to U2C1 ........................................ 182 U0MR to U2MR ...................................... 180 U0RB to U2RB ....................................... 179 U0SMR to U2SMR ................................. 183 U0SMR2 to U2SMR2 ............................. 184 U0SMR3 to U2SMR3 ............................. 184 U0SMR4 to U2SMR4 ............................. 185 U0TB to U2TB ........................................ 179 U1BCNIC ............................................... 106 U5BCNICAU7BCNIC ............................ 106 U5BRG to U7BRG ................................. 180 U5C0 to U7C0 ........................................ 181 U5C1 to U7C1 ........................................ 182 U5MR to U7MR ...................................... 180 U5RB to U7RB ....................................... 179 U5SMR to U7SMR ................................. 183 U5SMR2 to U7SMR2 ............................. 184 U5SMR3 to U7SMR3 ............................. 184 U5SMR4 to U7SMR4 ............................. 185 U5TB to U7TB ........................................ 179 UCON ..................................................... 183 UDF ........................................................ 139
V
VCR1 ........................................................ 38 VCR2 ........................................................ 38 VW0C ....................................................... 40
W
WDTS ..................................................... 119
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Revision History
Rev. 0.51 0.61 0.62 Date Jun 06, 2007 Jun 22, 2007 Jul 04, 2007 Page 3 4 17 32 51 75 163 186 220 224 256 260 267 264 287 265 290 267 268 319 320 321 322 343 362 3 5 29 79 92 114 234 238 259 263
M16C/64 Group Hardware Manual
Description Summary First Edition issued. Table 1.2 Specifications (2) is partly revised. Table 1.3 Product List is partly revised. 3. Memory (including the figure) is partly revised. Figure 5.1 Example Reset Circuit is partly revised. 7.3 Internal Memory is partly revised. Figure 10.1 System Clock Generation Circuit is partly revised. Figure 15.24 TBiMR Register in Pulse Period and Pulse Width Measurement Mode is partly revised. Table 17.1 Clock Synchronous Serial I/O Mode Specifications is partly revised. Figure 17.33 Transmit and Receive Timing in SIM Mode is partly revised. Figure 17.38 Registers S3C, S4C, S3BRG, S4BRG, S3TRR, and S4TRR is partly revised. Table 19.2 One-Shot Mode Specifications is partly revised. Table 19.4 Single Sweep Mode Specifications is partly revised. Figure 19.9 Analog Input Pin and External Sensor Equivalent Circuit is 22.1 Memory Map is partly revised. 23.1.1 Boot Mode is partly revised. 22.1.2 User Boot Function is added. 23.2.4 Standard Serial I/O Mode Disable Function is added. 22.2.2 ID Code Check Function is added. 22.2.3 Forced Erase Function is added. Figure 23.20 Pin Connections for Standard Serial I/O Mode (1) is partly revised. Figure 23.21 Pin Connections for Standard Serial I/O Mode (2) is partly revised. Figure 23.22 Circuit Application in Standard Serial I/O Mode 1 is partly revised. Figure 23.23 Circuit Application in Standard Serial I/O Mode 2 is partly revised. 24.5 Power Control is partly revised. 24.11 A/D Converter is partly revised. Table 1.2 Specifications (2) is partly revised. Figure 1.2 Marking Diagram of Flash Memory Version (Top View) is partly revised. Table 4.12 SFR Information (12) is partly revised. Figure 10.5 PM2 Register is partly revised. Table 10.7 Pin Status in Stop Mode is partly revised. Figure 12.12 Registers IFSR2A, IFSR3A, and PCR is partly revised. Table 18.2 One-Shot Mode Specifications is partly revised. Table 18.4 Single Sweep Mode Specifications is partly revised. Figure 21.11 PCR Register is partly revised. Table 22.1 Flash Memory Version Specifications is partly revised. A- 1
0.63
Sep 21, 2007
Revision History
Rev. Date Page 263 268 268 272 274 303 304 3 11 13 32 92 230 231 233 234 235 236 237 238 239 240 241 242 243 260 261 262 295 301 302 303 307 342 342 364 365
M16C/64 Group Hardware Manual
Description Summary Table 22.2 Flash Memory Rewrite Modes Overview is partly revised. 22.1.3 Standard Serial I/O Mode Disable Function is moved to 22.2.4. Table 22.8 Forced Erase Function is partly revised Figure 22.5 FMR0 Register is partly revised. Figure 22.7 FMR2 Register is partly revised. Figure 23.3 A/D Conversion Characteristics is partly revised. Table 23.5 Flash Memory Version Electrical Characteristics is partly revised. Table 1.2 Specifications (2) is partly revised. Table 1.6 Pin Functions (1) is partly revised. Table 1.8 Pin Functions (3) is parly revised. Figure 5.1 Example Reset Circuit is partly revised. 10.4.3 Stop Mode is partly revised. Table 18.1 A/D Converter Specifications is partly revised. Figure 18.1 A/D Converter Block Diagram is partly revised. Figure 18.3 Registers ADCON2 and AD0 to AD7 is partly revised. Table 18.2 One-Shot Mode Specifications is partly revised. Figure 18.4 Registers ADCON0 and ADCON1 (One-shot Mode) is partly revised. Table 18.3 Repeat Mode Specifications is partly revised. Figure 18.5 Registers ADCON0 and ADCON1 (Repeat Mode) is partly revised. Table 18.4 Single Sweep Mode Specifications is partly revised. Figure 18.6 Registers ADCON0 and ADCON1 (Single Sweep Mode) is partly revised. Table 18.5 Repeat Sweep Mode 0 Specifications is partly revised. Figure 18.7 Registers ADCON0 and ADCON1 (Repeat Sweep Mode 0) is partly revised. Table 18.6 Repeat Sweep Mode 1 Specifications is partly revised. Figure 18.8 Registers ADCON0 and ADCON1 (Repeat Sweep Mode 1) is partly revised. Table 21.1 Unassigned Pin Handling in Single-chip Mode is partly revised. Table 21.2 Unassigned Pin Handling in Memory Expansion Mode and Microprocessor Mode is partly revised. Figure 21.12 Unassigned Pin Handling is partly revised. Table 22.13 Pin Functions (Flash Memory Standard Serial I/O Mode) is partly revised. Table 23.1 Absolute Maximum Ratings is partly revised. Table 23.2 Recommended Operating Conditions is partly revised. Table 23.3 A/D Conversion Characteristics is partly revised. Table 23.9 Electrical Characteristics (1) is partly revised. 24.2.1 VCC1 is added. 24.2.2 CNVSS is added. Figure 24.4 Use of Capacitors to Reduce Noise is partly revised. 24.11 A/D Converter is partly revised. A- 2
0.64
Oct 12, 2007
M16C/64 Group Hardware Manual Publication Date: Feb 28, 2007 Oct 12, 2007 Published by: Rev.0.20 Rev.0.64
Sales Strategic Planning Div. Renesas Technology Corp. 2-6-2, Otemachi, Chiyoda-ku, Tokyo 100-0004
(c) 2007. Renesas Technology Corp., All rights reserved. Printed in Japan.
M16C/64 GROUP Hardware Manual
2-6-2, Ote-machi, Chiyoda-ku, Tokyo, 100-0004, Japan

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