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| PRELIMINARY PRODUCT SPECIFICATION 1 Z86E72/73 OTP IR MICROCONTROLLERS FEATURES Part Z86E73 Z86E72 ROM (KB) 32 16 RAM* (Bytes) 256 768 I/O 31 31 Voltage Range 3.0V to 5.5V 3.0V to 5.5V s 1 Five Priority Interrupts - Three External - Two Assigned to Counter/Timers Two Independent Comparators with Programmable Interrupt Polarity On-Chip Oscillator that Accepts a Crystal, Ceramic Resonator, LC, RC (mask option), or External Clock Drive Software Selectable 200 kOhms Pull-Ups on Ports 0 and Port 2 - All Eight Port 2 Bits at One Time or Not Pull-Ups Automatically Disabled Upon Selecting Individual Pins as Outputs. Software Mouse/Trackball Interface on P00 Through P03 s Note: *General-Purpose s s Low Power Consumption - 60 mW (Typical) Two Standby Modes (Typical) - STOP - 2 A - HALT - 0.8 mA Special Architecture to Automate Both Generation and Reception of Complex Pulses or Signals: - One Programmable 8-Bit Counter/Timer with Two Capture Registers - One Programmable 16-Bit Counter/Timer with One Capture Register - Programmable Input Glitch Filter for Pulse Reception s s s s GENERAL DESCRIPTION The Z86E7X family of IR (Infrared) CCPTM (Consumer Controller Processor) are OTP-based members of the Z8(R) single-chip microcontroller family with 256 or 768 bytes of general-purpose RAM. The only differentiating factor between the E72/73 versions is the availability of RAM and ROM. This EPROM Microcontroller family of OTP IR controllers also offer the use of external memory which enables this Z8 microcontroller to be used where code flexibility is required. Zilog's CMOS microcontrollers offer fast execution, efficient use of memory, sophisticated interrupts, input/output bit manipulation capabilities, automated pulse generation/reception, and easy hardware/software system expansion along with cost-effective and low power consumption. The Z86E7X architecture is based on Zilog's 8-bit microcontroller core with an Expanded Register File to allow access to register mapped peripherals, I/O circuits, and powerful counter/timer circuitry. The CCP offers a flexible I/O scheme, an efficient register and address space structure, and a number of ancillary features that are useful in many consumer, automotive, computer peripheral, and battery operated hand-held applications. CCPTM applications demand powerful I/O capabilities. The Z86L7X family fulfills this with five package options in which the E72/73/L74 versions provide 31 pins of dedicated input and output. These lines are grouped into four ports. Each port consists of eight lines (Port 3 has seven lines of I/O and one Pref comparator input) and is config- DS96LVO1100 PRELIMINARY 1-1 Z86E72/E73 OTP IR Microcontrollers GENERAL DESCRIPTION (Continued) urable under software control to provide timing, status signals, parallel I/O with or without handshake, and an address/data bus for interfacing external memory. There are five basic address spaces available to support a wide range of configurations: Program Memory, Register FIle, Expanded Register File, Extended Data RAM and External Memory. The register file is composed of 256 bytes of RAM. It includes four I/O port registers, 16 control and status registers and the rest are General Purpose registers. The Extended Data RAM adds 512 (E72) of usable general-purpose registers. The Expanded Register File consists of two additional register groups (F and D). To unburden the program from coping with such real-time problems as generating complex waveforms or receiving and demodulating complex waveform/pulses, the Z86E7X family offers a new intelligent counter/timer architecture with 8-bit and 16-bit counter/timers (Figure 1). Also included are a large number of user-selectable modes, and two on-board comparators to process analog signals with separate reference voltages (Figure 2). Notes: All Signals with a preceding front slash, "/", are active Low, e.g., B//W (WORD is active Low); /B/W (BYTE is active Low, only). Power connections follow conventional descriptions below: Connection Power Ground Circuit VCC GND Device VDD VSS HI16 8 LO16 8 16-Bit T16 1248 8 SCLK Clock Divider TC16H 16 8 TC16L And/Or Logic Timer 16 Timer 8/16 HI8 8 Input Glitch Filter Edge Detect Circuit 8 TC8H 8-Bit T8 LO8 8 Timer 8 8 TC8L Figure 1. Z86E7X Counter/Timer Block Diagram 1-2 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers P00 P01 P02 P03 P04 P05 P06 P07 P10 P11 P12 P13 P14 P15 P16 P17 P20 P21 P22 P23 P24 P25 P26 P27 4 Register File 256 or 768 x 8-Bit Port 0 Register Bus Port 3 Internal Address Bus ROM 16K/32K x 8 Internal Data Bus Z8 Core P31 P32 P33 P34 P35 P36 P37 1 4 8 Port 1 Expanded Register File Expanded Register Bus Machine Timing & Instruction Control XTAL /AS /DS R/W /RESET I/O Bit Programmable Port 2 Counter/Timer 8 8-Bit Counter/Timer 16 16-Bit Power VDD VSS Figure 2. Z86E7X Functional Block Diagram PIN DESCRIPTION 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 R//W P25 P26 P27 P04 P05 P06 P14 P15 P07 VDD P16 P17 XTAL2 XTAL1 P31 P32 P33 P34 /AS Z86E72/73 DIP 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 /DS P24 P23 P22 P21 P20 P03 P13 P12 VSS P02 P11 P10 P01 P00 Pref1 P36 P37 P35 /RESET Figure 3. 40-Pin DIP Pin Assignments (Standard Mode) DS96LVO1100 PRELIMINARY 1-3 Z86E72/E73 OTP IR Microcontrollers PIN DESCRIPTION (Continued) NC A13 A14 /PGM A4 A5 A6 D4 D5 A7 VDD D6 D7 NC NC /OE EPM VPP NC NC 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Z86E72/73 DIP 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 NC A12 A11 A10 A9 A8 A3 D3 D2 VSS A2 D1 D0 A1 A0 /CE NC NC NC NC Figure 4. 40-Pin DIP Pin Assignments (EPROM Mode) P21 P22 P23 P24 /DS R//RL R//W P25 P26 P27 P04 6 7 8 9 10 11 12 13 14 15 16 17 18 P20 P03 P13 P12 VSS VSS P02 P11 P10 P01 P00 4 1 42 Z86E72/73 PLCC 20 22 24 26 40 39 38 37 36 35 34 33 32 31 30 29 28 Pref1 P36 P37 P35 /RESET VSS /AS P34 P33 P32 P31 Figure 5. 44-Pin PLCC Pin Assignments (Standard Mode) 1-4 P05 P06 P14 P15 P07 VDD VDD P16 P17 XTAL2 XTAL1 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers A9 A10 A11 A12 NC NC NC A13 A14 /PGM A4 6 7 8 9 10 11 12 13 14 15 16 17 18 A8 A3 D3 D2 VSS VSS A2 D1 D0 A2 A0 1 /CE NC NC NC NC SCC NC NC VPP EPM /OE 4 1 42 Z86E72/73 PLCC 20 22 24 26 40 39 38 37 36 35 34 33 32 31 30 29 28 Figure 6. 44-Pin PLCC Pin Assignments (EPROM Mode) P21 P22 P23 P24 /DS R//RL R//W P25 P26 P27 P04 33 34 35 36 37 38 39 40 41 42 43 44 1 P20 P03 P13 P12 VSS VSS P02 P11 P10 P01 P00 31 29 27 25 23 22 21 20 19 18 17 16 15 14 13 12 11 P05 P06 P14 P15 P07 VDD VDD P16 P17 XTAL2 XTAL1 Z86E72/73 QFP Pref1 P36 P37 P35 /RESET VSS /AS P34 P33 P32 P31 3 5 7 9 Figure 7. 44-Pin QFP Pin Assignments (Standard Mode) DS96LVO1100 P05 P06 P14 P15 P07 VDD VDD P16 P17 XTAL2 XTAL1 PRELIMINARY 1-5 Z86E72/E73 OTP IR Microcontrollers PIN DESCRIPTION (Continued) A9 A10 A11 A12 N/C N/C N/C A13 A14 /PGM A4 33 34 35 36 37 38 39 40 41 42 43 44 1 A8 A3 D3 D2 VSS VSS A2 D1 D0 A1 A0 31 29 27 25 23 22 21 20 19 18 17 16 15 14 13 12 11 Z86E72/73 QFP /CE N/C N/C N/C N/C VSS N/C N/C VPP EPM /OE 3 5 7 9 Figure 8. 44-Pin QFP Pin Assignments (EPROM Mode) Table 1. Pin Identification (Standard Mode) 40-Pin DIP # 26 27 30 34 5 6 7 10 28 29 44-Pin PLCC # 40 41 44 5 17 18 19 22 42 43 44-Pin QFP # 23 24 27 32 44 1 2 5 25 26 Symbol P00 P01 P02 P03 P04 P05 P06 P07 P10 P11 Direction Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Description Port 0 is Nibble Programmable. Port 0 can be configured as A15-A8 external program ROM Address Bus. Port 0 can be configured as a mouse/trackball input. A5 A6 D4 D5 A7 VDD VDD D6 D7 XTAL2 XTAL1 Port 1 is byte programmable. Port 1 can be configured as multiplexed A7-A0/D7-D0 external program ROM Address/Data Bus 32 33 8 9 12 13 3 4 20 21 25 26 30 31 3 4 8 9 P12 P13 P14 P15 P16 P17 Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output . 1-6 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Table 1. Pin Identification (Standard Mode) 40-Pin DIP # 35 36 37 38 39 2 3 4 16 17 18 19 22 24 23 20 40 1 21 15 14 11 31 25 NC 44-Pin PLCC # 6 7 8 9 10 14 15 16 29 30 31 32 36 38 37 33 11 13 35 28 27 23, 24 1, 2, 34 39 12 44-Pin QFP # 33 34 35 36 37 41 42 43 12 13 14 15 19 21 20 16 38 40 18 11 10 6, 7 17, 28, 29 22 39 Symbol P20 P21 P22 P23 P24 P25 P26 P27 P31 P32 P33 P34 P35 P36 P37 /AS /DS R//W /RESET XTAL1 XTAL2 VDD VSS Pref1 R//RL Input Input Direction Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input/Output Input Input Input Output Output Output Output Output Output Output Input Input Output Description Port 2 pins are individually configurable as input or output IRQ2/Modulator input IRQ0 IRQ1 T8 output T16 output T8/T16 output Address Strobe Data Strobe Read/Write Reset Crystal, Oscillator Clock Crystal, Oscillator Clock Power Supply Ground Comparator 1 Reference ROM//ROMless 1-7 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers PIN DESCRIPTION (Continued) Table 2. Z86E72/73 40-Pin DIP Identification (EPROM Mode) 40-Pin # 1 2-3 4 5-7 8-9 10 11 12-13 14-15 16 17 18 19-24 25 26-27 28-29 30 31 32-33 34 35-39 40 Symbol N/C A13-14 /PGM A4-A6 D4-D5 A7 VDD D6-D7 N/C /OE EPM VPP N/C /CE A0-A1 D0-D1 A2 VSS D2-D3 A3 A8-A12 N/C Function Not Connected Address 13,14 Program Mode Address 4,5,6 Data 4,5 Address 7 Power Supply Data 6,7 Not Connected Output Enable EPROM Prog.Mode Prog. Voltage Not Connected Chip Enable Address 0,1 Data 0, 1 Address 2 Ground Data 2,3 Address 3 Address 8,9,10,11,12 Not Connected Direction Input Input Input Input/Output Input Input/Output Input Input Input Input Input Input/Output Input Input/Output Input Input 1-8 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Table 3. Z86E72/73 44-Pin QFP/PLCC Pin Identification(EPROM Mode) 44-Pin QFP 1-2 3-4 5 6-7 8-9 10 11 12 13 14 15-16 17 18-21 22 23-24 25-26 27 28-29 30-31 32 33-37 38-40 41-42 43 44 44-Pin PLCC 18-19 20-21 22 23-24 25-26 27 28 29 30 31 32-33 34 35-38 39 40-41 42-43 44 1-2 3-4 5 6-10 11-13 14-15 16 17 Symbol A5-A6 D4-D5 A7 VDD D6-D7 XTAL2 XTAL1 /OE EPM VPP N/C VSS N/C /CE A0-A1 D0-D1 A2 VSS D2-D3 A3 A8-A12 N/C A13-A14 /PGM A4 Function Address 5,6 Data 4,5 Address 7 Power Supply Data 6,7 Crystal Oscillator Clock Crystal Oscillator Clock Output Enable EPROM Prog. Mode Prog. Voltage Not Connected Ground Not Connected Chip Select Address 0,1 Data 0,1 Address 2 Ground Data 2, 3 Address 3 Address 8,9,10,11,12 Not Connected Address 13,14 Prog. Mode Address 4 Input Input Input/Output Input Input/Output Input Input Input Input Input Direction Input Input/Output Input Input/Output 1 Input Input Input DS96LVO1100 PRELIMINARY 1-9 Z86E72/E73 OTP IR Microcontrollers ABSOLUTE MAXIMUM RATINGS Symbol VCC TSTG TA Description Supply Voltage (*) Storage Temp. Oper. Ambient Temp. Min -0.3 -65 Max +7.0 +150 Units V C C Stresses greater than those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; operation of the device at any condition above those indicated in the operational sections of these specifications is not implied. Exposure to absolute maximum rating conditions for an extended period may affect device reliability. Notes: * Voltage on all pins with respect to GND. See Ordering Information. STANDARD TEST CONDITIONS The characteristics listed below apply for standard test conditions as noted. All voltages are referenced to GND. Positive current flows into the referenced pin (Figure 13). From Output Under T est I 150 pF Figure 9. Test Load Diagram CAPACITANCE TA = 25C, VCC = GND = 0V, f = 1.0 MHz, unmeasured pins returned to GND. Parameter Input capacitance Output capacitance I/O capacitance Max 12 pF 12 pF 12 pF 1-10 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers DC CHARACTERISTICS Preliminary TA = 0C to +70C Min Max 7 7 0.9 VCC 0.9 VCC VSS -0.3 VSS -0.3 0.7 VCC 0.7 VCC VSS -0.3 VSS -0.3 VCC -0.4 VCC -0.4 VCC 0.7 VCC 0.7 0.4 0.4 0.8 0.8 0.8 0.8 0.8 VCC 0.8 VCC VSS -0.3 VSS -0.3 VCC VCC 0.2 VCC 0.2 VCC 25 25 1 1 1 1 -230 -400 10 15 0.1 0.2 0.5 0.3 0.3 0.2 1.5 2.5 0.9 1.8 10 10 <1 <1 <1 <1 -50 -80 4 10 mV mV A A A A A A mA mA VCC + 0.3 VCC + 0.3 0.2 VCC 0.2 VCC VCC + 0.3 VCC + 0.3 0.2 VCC 0.2 VCC 0.5 VCC 0.5 VCC 0.5 VCC 0.5 VCC 2.9 5.4 Typical @ 25C 1 Units V V V V V V V V V V V V V V V V V V V V V V IOH = -0.5 mA IOH = -0.5 mA IOH = -7 mA IOH = -7 mA IOL = 1.0 mA IOL = 4.0 mA IOL = 5.0 mA IOL = 7.0 mA IOL = 10 mA IOL = 10 mA Conditions IIN 250 A IIN 250 A Driven by External Clock Generator Driven by External Clock Generator Sym. Parameter Max Input Voltage VCC 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V VCH VCL VIH VIL Clock Input High Voltage Clock Input Low Voltage Input High Voltage Input Low Voltage VOH1 Output High Voltage VOH2 Output High Voltage (P00,P01,P36, P37) VOL1 Output Low Voltage VOL2* Output Low Voltage VOL2 Output Low Voltage (P00, P01, P36,P37) VRH VRl Reset Input High Voltage Reset Input Low Voltage VOFFSET Comparator Input Offset Voltage IIL Input Leakage IOL IIR ICC Output Leakage Reset Input Current Supply Current (WDT off) -1 -1 -1 -1 VIN = 0V, VCC VIN = 0V, VCC VIN = 0V, VCC VIN = 0V, VCC @ 8.0 MHz @ 8.0 MHz DS96LVO1100 PRELIMINARY 1-11 Z86E72/E73 OTP IR Microcontrollers DC CHARACTERISTICS (Continued) TA = 0C to +70C Sym. ICC1 Parameter Standby Current (WDT Off) VCC 3.0V Min Max 3 Typical @ 25C 1 Units Conditions mA HALT Mode VIN = 0V, VCC @ 8.0 MHz HALT Mode VIN = 0V, VCC @ 8.0 MHz Clock Divide-by-16 @ 8.0 MHz Clock Divide-by-16 @ 8.0 MHz STOP Mode VIN = OV, VCC WDT is not Running STOP Mode VIN = 0V, VCC WDT is not Running STOP Mode VIN = 0V, VCC WDT is Running Notes 1,2 5.5V 5 4 mA 1,2 3.0V 5.5V ICC2 Standby Current 3.0V 2 4 8 0.8 2.5 2 mA mA A 1,2 1,2 3,5 5.5V 3.0V 5.5V TPOR Vram Power-On Reset 3.0V 5.5V Vram 12 5 0.8 10 500 800 75 20 3 310 600 18 7 0.5 1.7 Frequency 8.0 MHz 8.0 MHz A A A ms ms V V 3,5 3,5 Static RAM Data Retention Voltage VLV VCC Low Voltage (Vbo) Protection Notes: ICC1 Crystal/Resonator External Clock Drive 6 8 MHz max Ext. CLK Freq. 4 2.15 Typ 3.0 mA 0.3 mA Max 5 5 Unit mA mA 1. All outputs unloaded, inputs at rail. 2. CL1 = CL2 = 100 pF 3. Same as note [4] except inputs at VCC. 4. The VLV increases as the temperature decreases. 5. Oscillator stopped. 6. Oscillator stops when VCC falls below Vlv limit 7. 32 kHz clock driver input. * All Outputs excluding P00, P01, P36, and P37. 1-12 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS External I/O or Memory Read and Write Timing 1 R//W 13 12 19 Port 0, /DM 16 18 3 20 Port 1 A7 - A0 1 2 D7 - D0 IN 9 /AS 8 4 5 6 11 /DS (Read) 17 10 Port 1 A7 - A0 14 D7 - D0 OUT 15 7 /DS (Write) Figure 10. External I/O or Memory Read/Write Timing DS96LVO1100 PRELIMINARY 1-13 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS Preliminary External I/O or Memory Read and Write Timing Table TA = 0C to +70C 16 MHz Min. Max. 55 55 70 70 400 400 80 80 0 0 300 300 165 165 260 260 0 0 85 95 60 70 70 70 70 70 80 80 70 80 475 475 100 100 55 55 70 70 70 70 No. Symbol 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 TdA(AS) TdAS(A) TdAS(DR) TwAS Td TwDSR TwDSW TdDSR(DR) ThDR(DS) TdDS(A) TdDS(AS) Parameter Address Valid to /AS Rising Delay /AS Rising to Address Float Delay /AS Rising to Read Data Required Valid /AS Low Width Address Float to /DS Falling /DS (Read) Low Width /DS (Write) Low Width /DS Falling to Read Data Required Valid Read Data to /DS Rising Hold Time /DS Rising to Address Active Delay VCC 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V Units ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns Notes 2 2 1,2 1,2 2 2 1,2 1,2 1,2 2 2 2 2 2 2 1,2 2 2 2 /DS Rising to /AS Falling Delay TdR/W(AS) R//W Valid to /AS Rising Delay TdDS(R/W) /DS Rising to R//W Not Valid TdDW(DSW) Write Data Valid to /DS Falling (Write) Delay TdDS(DW) /DS Rising to Write Data Not Valid Delay TdA(DR) Address Valid to Read Data Required Valid TdAS(DS) /AS Rising to /DS Falling Delay TdDM(AS) /DM Valid to /AS Falling Delay TdDS(DM) /DS Rise to /DM Valid Delay ThDS(A) /DS Rise to Address Valid Hold Time Notes: 1. When using extended memory timing add 2 TpC. 2. Timing numbers given are for minimum TpC. Standard Test Load All timing references use 0.9 VCC for a logic 1 and 0.1 VCC for a logic 0. 1-14 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS Additional Timing Diagram 1 1 3 Clock 2 7 7 2 3 T IN 4 6 5 IRQ N 8 9 Clock Setup 11 Stop Mode Recovery Source 10 Figure 11. Additional Timing DS96LVO1100 PRELIMINARY 1-15 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS Preliminary Additional Timing Table TA = 0C to +70C No 1 2 3 4 5 6 7 8A 8B 9 10 Symbol TpC TrC,TfC TwC TwTinL TwTinH TpTi Parameter Input Clock Period Clock Input Rise and Fall Times Input Clock Width Timer Input Low Width Timer Input High Width Timer Input Period VCC 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 4.5V 5.5V 4.5V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V 3.0V 5.5V Min 121 121 Max DC DC 25 25 Units ns ns ns ns ns ns ns ns Notes 1 1 1 1 1 1 1 1 ns ns ns ns 1 1 1,2 1,2 1,3 1,3 1,2 1,2 7 7 6 6 4 TrTin,TfTi Timer Input Rise and Fall Timers TwIL TwIL TwIH Twsm Interrupt Request Low Time Int. Request Low Time Interrupt Request Input High Time Stop-Mode Recovery Width Spec 37 37 100 70 3TpC 3TpC 8TpC 8TpC 100 70 100 70 3TpC 5TpC 5TpC 5TpC 12 12 5TpC 5TpC 5TpC 5TpC 75 20 150 40 300 80 1200 320 ns ns 11 12 Tost Twdt Oscillator Start-up Time Watch-Dog Timer Delay Time (5 ms) (10 ms) (20 ms) (80 ms) 12 5 25 10 50 20 225 80 ms ms ms ms ms ms ms ms Notes: 1. Timing Reference uses 0.9 VCC for a logic 1 and 0.1 VCC for a logic 0. 2. Interrupt request through Port 3 (P33-P31). 3. Interrupt request through Port 3 (P30). 4. SMR - D5 = 0 5. Reg. WDTMR 6. Reg. SMR - D5 = 0 7. Reg. SMR - D5 = 1 1-16 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS Handshake Timing Diagrams 1 Data In Data In Valid 2 1 3 Next Data In Valid /DAV (Input) 4 Delayed DAV 5 6 RDY (Output) Delayed RDY Figure 12. Input Handshake Timing Data Out Data Out Valid Next Data Out Valid 7 /DAV (Output) 8 9 10 Delayed DAV 11 RDY (Input) Delayed RDY Figure 13. Output Handshake Timing DS96LVO1100 PRELIMINARY 1-17 Z86E72/E73 OTP IR Microcontrollers AC CHARACTERISTICS Preliminary Handshake Timing Table TA = 0C to +70C 16 MHz Min Max 0 0 0 155 110 160 115 120 80 0 0 63 63 0 0 160 115 110 80 110 80 No 1 2 3 4 5 6 7 8 9 10 11 Symbol TsDI(DAV) ThDI(DAV) TwDAV TdDAVI(RDY) TdDAVId(RDY) TdRDYO(DAV) TdDO(DAV) TdDAV0(RDY) TdRDY0(DAV) TwRDY TdRDY0d(DAV) Parameter Data In Setup Time Data In Hold Time Data Available Width DAV Falling to RDY Falling Delay DAV Rising to RDY Falling Delay RDY Rising to DAV Falling Delay Data Out to DAV Falling Delay DAV Falling to RDY Falling Delay RDY Falling to DAV Rising Delay RDY Width RDY Rising to DAV Falling Delay VCC 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V 4.0V 5.5V Data Direction IN IN IN IN IN IN IN IN IN IN IN IN OUT OUT OUT OUT OUT OUT OUT OUT OUT 1-18 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers PIN FUNCTIONS /DS (Output, active Low). Data Strobe is activated once for each external memory transfer. For a READ operation, data must be available prior to the trailing edge of /DS. For WRITE operations, the falling edge of /DS indicates that output data is valid. /AS (Output, active Low). Address Strobe is pulsed once at the beginning of each machine cycle. Address output is through Port 0/Port 1 for all external programs. Memory address transfers are valid at the trailing edge of /AS. Under program control, /AS is placed in the high-impedance state along with Ports 0 and 1, Data Strobe, and Read/Write. XTAL1 Crystal 1 (time-based input). This pin connects a parallel-resonant crystal, ceramic resonator, LC, or RC network or an external single-phase clock to the on-chip oscillator input. XTAL2 Crystal 2 (time-based output). This pin connects a parallel-resonant, crystal, ceramic resonant, LC, or RC network to the on-chip oscillator output. R//W Read/Write (output, write Low). The R//W signal is Low when the CCP is writing to the external program or data memory. R//RL (input). This pin, when connected to GND, disables the internal ROM and forces the device to function as a ROMless Z8. (Note that, when left unconnected or pulled high to VCC, the part functions normally as a Z8 ROM version.) Port 0 (P07-P00). Port 0 is an 8-bit, bidirectional, CMOS compatible port. These eight I/O lines are configured under software control as a nibble I/O port, or as an address port for interfacing external memory. The output drivers are push-pull. Port 0 is placed under handshake control. In this configuration, Port 3, lines P32 and P35 are used as the handshake control /DAV0 and RDY0. Handshake signal direction is dictated by the I/O direction to Port 0 of the upper nibble P07-P04. The lower nibble must have the same direction as the upper nibble. For external memory references, Port 0 can provide address bits A11-A8 (lower nibble) or A15-A8 (lower and upper nibble) depending on the required address space. If the address range requires 12 bits or less, the upper nibble of Port 0 can be programmed independently as I/O while the lower nibble is used for addressing. If one or both nibbles are needed for I/O operation, they must be configured by writing to the Port 0 mode register. After a hardware reset, Port 0 is configured as an input port. Port 0 is set in the high-impedance mode if selected as an address output state along with Port 1 and the control signals /AS, /DS, and R//W (Figure 8). A software option is available to program 0.4 VDD CMOS trip inputs on P00-P03. This allows direct interface to mouse/trackball IR sensors. An optional 200 kOhm pull-up is available as a software option of all Port 0 bits with nibble select. These pull-ups are disabled when configured (bit by bit) as an output. 1 DS96LVO1100 PRELIMINARY 1-19 Z86E72/E73 OTP IR Microcontrollers PIN FUNCTIONS (Continued) 4 Port 0 (I/O or A15 - A8) Z86LXX MCU 4 Optional Handshake Controls /DAV0 and RDY0 (P32 and P35) OEN Mask Option 200 k PAD Out In In * Note: On P00 and P07 only. ** POIM, DI, DO Mask Selectable. *** Refer to the Z86C17 specification for application information in utilizing these inputs in a mouse or trackball application. 0.4 VDD Trip Point Buffer Figure 14. Port 0 Configuration 1-20 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Port 1 (P17-P10). Port 1 is a multiplexed Address (A7-A0) and Data (D7-D0), CMOS compatible port. Port 1 is dedicated to the Zilog ZBus(R)-compatible memory interface. The operations of Port 1 are supported by the Address Strobe (/AS) and Data Strobe (/DS) lines, and by the Read/Write (R//W) and Data Memory (/DM) control lines. Data memory read/write operations are done through this port (Figure 20). If more than 256 external locations are required, Port 0 outputs the additional lines. Port 1 can be placed in the high-impedance state along with Port 0, /AS, /DS, and R//W, allowing the Z86L7X to share common resources in multiprocessor and DMA applications. Port1 can also be configured for standard port output mode. 1 8 Z86LXX MCU Port 1 (I/O or AD7 - AD0) Optional Handshake Controls /DAV1 and RDY1 (P33 and P34) OEN PAD Out In Auto Latch R 500 K Figure 15. Port 1 Configuration DS96LVO1100 PRELIMINARY 1-21 Z86E72/E73 OTP IR Microcontrollers PIN FUNCTIONS (Continued) Port 2 (P27-P20). Port 2 is an 8-bit, bidirectional, CMOS compatible I/O port. These eight I/O lines can be independently configured under software control as inputs or outputs. Port 2 is always available for I/O operation. A software option is available to connect eight 200 kOhms (50%) pull-up resistors on this port. Bits programmed as outputs are globally programmed as either push-pull or open-drain. Port 2 may be placed under handshake control. In this configuration, Port 3 lines, P31 and P36 are used as the handshake controls lines /DAV2 and RDY2. The handshake signal assignment for Port 3, lines P31 and P36 is dictated by the direction (input or output) assigned to Bit 7, Port 2 (Figure 10). The CCP wakes up with the eight bits of Port 2 configured as inputs with open-drain outputs. Port 2 also has an 8-bit input OR and an AND gate which can be used to wake up the part. P20 can be programmed to access the edge selection circuitry (Figure 21). Port 2 (I/O) Z86LXX MCU Optional Handshake Controls /DAV2 and RDY2 (P31 and P36) (L72/E72 Only) VCC Open-Drain 200 k OEN Mask Option PAD Out In Figure 16. Port 2 Configuration 1-22 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Port 3 (P37-P31). Port 3 is a 7-bit, CMOS compatible three fixed input and four fixed output port. Port 3 consists of three fixed input (P33-P31) and four fixed output (P37P34), and can be configured under software control for Input/Output, Interrupt, Port handshake, Data Memory functions and output from the counter/timers. P31, P32, and P33 are standard CMOS inputs; outputs are push-pull. Two on-board comparators process analog signals on P31 and P32 with reference to the voltage on Pref1 and P33. The analog function is enabled by programming the Port 3 Mode Register (bit 1). P31 and P32 are programmable as rising, falling, or both edge triggered interrupts (IRQ register bits 6 and 7). Pref1 and P33 are the comparator reference voltage inputs. Access to the Counter Timer edge detection circuit is through P31 or P20 (see CTR1 description). Port 3 provides the following control functions: handshake for Ports 0, 1, and 2 (/DAV and RDY); three external interrupt request signals (IRQ2-IRQ0); Data Memory Select (/DM) (Table 8). Port 3 also provides output for each of the counter/timers and the AND/OR Logic. Control is performed by programming bits D5-D4 of CTRI, bit 0 of CTR0 and bit 0 of CTR2. P34 PAD 1 Counter/Timer T8 P34 OUT P34 OUT P31 + COMP1 CTR0 D0 PREF1 0 Normal Control 1 8-bit Timer output active P37 P37 OUT P32 + COMP2 PAD P33 (PREF2) PCON D0 0 = P34, P37 Standard Output * 1 = P34, P37 Comparator Output * Reset condition. Figure 17. Port 3 Configuration DS96LVO1100 PRELIMINARY 1-23 Z86E72/E73 OTP IR Microcontrollers PIN FUNCTIONS (Continued) Table 4. Pin Assignments Pin Pref1 P31 P32 P33 P34 P35 P36 P37 P20 I/O IN IN IN IN OUT OUT OUT OUT I/O C/T IN Comp. RF1 AN1 AN2 RF2 A01 Int. IRQ2 IRQ0 IRQ1 P0 HS P1 HS P2 HS D/R D/R D/R R/D R/D R/D A02 IN D/M Ext T8 T16 T8/16 Notes: HS = Handshake Signals D = /DAV R = RDY Comparator Inputs. In Analog Mode, Port 3 (P31 and P32) have a comparator front end. The comparator reference is supplied to P33 and Pref1. In this mode, the P33 internal data latch and its corresponding IRQ1 is diverted to the SMR sources (excluding P31, P32, and P33) as shown in Figure 37. In digital mode, P33 is used as D3 of the Port 3 input register which then generates IRQ1 as shown in Figure 23. Notes: Comparators are disabled/powered down by entering STOP mode. For P31-P33 to be used as a Stop-Mode recovery source, these inputs must be placed into digital mode. Comparator Outputs. These may be programmed to be outputted on P34 and P37 through the PCON register (Figure 22). /RESET (Input, active Low). Initializes the MCU. Reset is accomplished either through Power-On, Watch-Dog Timer, Stop-Mode Recovery, Low Voltage detection, or external reset. During Power-On Reset and Watch-Dog Timer Reset, the internally generated reset drives the reset pin Low for the POR time. Any devices driving the reset line should be open-drain in order to avoid damage from a possible conflict during reset conditions. Pull-up is provided internally. There is no condition internal to the L7X that will not allow an external reset to occur. 1-24 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers After the POR time, /RESET is a Schmitt-triggered input. To avoid asynchronous and noisy reset problems, the Z86L7X is equipped with a reset filter of four external clocks (4TpC). If the external reset signal is less than 4TpC in duration, no reset occurs. On the fifth clock after the reset is detected, an internal RST signal is latched and held for an internal register count of 18 external clocks, or for the duration of the external reset, whichever is longer. During the reset cycle, /DS is held active Low while /AS cycles at a rate of TpC/2. Program execution begins at location 000CH, 5-10 TpC cycles after the RST is released. For Power-On Reset, the typical reset output time is 5 ms. The Z86E7X devices do not have internal pull resistors on Port 3 inputs. 1 Pref1 200 K P31 P32 Z86LXX MCU P33 P34 P35 P36 P37 Note: P31, 32, 33 have a 200 K mask option called Mask option 3 similar to Mask options 1 and 2. Port 3 (I/O or Handshake) Mask Option R247 = P3M D1 1 = Analog 0 = Digital DIG. P31 (AN1) + PREF1 COMP1 AN. IRQ2, P31 Data Latch P32 (AN2) IRQ0, P32 Data Latch + P33 (REF2) COMP2 From Stop-Mode Recovery Source IRQ1, P33 Data Latch Figure 18. Port 3 Configuration DS96LVO1100 PRELIMINARY 1-25 Z86E72/E73 OTP IR Microcontrollers PIN FUNCTIONS (Continued) CTR0, D0 VDD Out 34 T8_Out MUX Pad P34 CTR2, D0 VDD Out 35 MUX T16_Out Pad P35 CTR1, D6 VDD Out 36 T8/16_Out MUX Pad P36 Figure 19. Port 3 Configuration 1-26 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers FUNCTIONAL DESCRIPTION The Z8(R) CCP incorporates special functions to enhance the Z8's functionality in consumer and battery operated applications. Reset. The device is reset in one of the following conditions: 65535 Note: The Extended Data RAM cannot be used as STACK or instruction/code memory. Accessing the Extended Data RAM has the following condition: P01M register bits D4-D3 cannot be set to 11. 1 1. Power-On Reset 2. Watch-Dog Timer 3. Stop-Mode Recovery Source 4. Low Voltage Detection 5. External Reset 10 16384 Location of First Byte of Instruction Executed After RESET 12 11 External ROM On-Chip ROM Reset Start Address Reserved Reserved IRQ4 IRQ4 IRQ3 IRQ3 IRQ2 IRQ2 IRQ1 IRQ1 IRQ0 IRQ0 Program Memory. The Z86E72/73 addresses up to 16K/32 Kbytes of internal program memory, with the remainder being external memory (Figure 26). The first 12 bytes of program memory are reserved for the interrupt vectors. These locations contain five 16-bit vectors that correspond to the five available interrupts. Addresses of 16K/32K consist of on-chip OTP. At addresses 16K or 32K and greater, the E72/73 executes external program memory fetches (refer to external memory timing specifications). RAM. The Z86E72 has a 768-byte RAM, 256 bytes make up the Register file. The remaining 512 bytes make up the Extended Data RAM. The Z86E73 has just the 256 bytes of the Register file. Extended Data RAM. The Extended Data RAM of the Z86E72 occupies the address range FE00H-FFFFH (512 bytes). This range of addresses FD00H-FFFFH cannot be used to directly read from or write to external memory. Accessing the Extended Data RAM is accomplished by using LDE, LDEI, LDC, or LDCI instructions. Port 1 and Port 0 are free to be set as I/O or ADDR/DATA modes; except high-impedance when accessing Extended Data RAM. In addition, if the External Memory uses the same address range of the Extended Data RAM it can be used as the External Stack only. 9 8 7 Interrupt Vector (Lower Byte) 6 5 4 3 2 1 0 Interrupt Vector (Upper Byte) Figure 20. Program Memory Map DS96LVO1100 PRELIMINARY 1-27 Z86E72/E73 OTP IR Microcontrollers FUNCTIONAL DESCRIPTION (Continued) 65535 Bits 7-4 of register RP select the working register group. Bits 3-0 of register RP select the expanded register file bank. Note that expanded register bank is also referred to as expanded register group (Figure 24). The upper nibble of the register pointer (Figure 24) selects which working register group of 16 bytes in the register file, out of the possible 256, will be accessed. The lower nibble selects the expanded register file bank and, in the case of the Z86LXX family, banks 0, F, and D are implemented. A 0h in the lower nibble will allow the normal register file (bank 0) to be addressed, but any other value from 1h to Fh will exchange the lower 16 registers to an expanded register bank. For example: Z86E73: (See Figure 23) R253 RP = 00H R0 = Port0 R1 = Port1 R2 = Port2 R3 = Port3 But if: R253 RP = 0DH R0 = CTRL0 R1 = CTRL1 R2 = CTRL2 R3 = Reserved The counter/timers are mapped into ERF group D. Access is easily done using the following example: LD RP,#0DH Select ERF D for access and register Bank 0 as the working register group. access CTRL0 access CTRL1 Select expanded register group (ERF) group D for access and register Bank 7 as the working register bank. CTRL2 register 71H External Data Memory 32,768 Not Addressable 0 Figure 21. External Memory Map External Memory. The Z86E72/73 addresses up to 32 Kbytes (minus FD00H-FFFFH) of External Memory beginning at address 8000H (32K+1), (Figure 27). External data memory is included with, or separated from, the external program memory space. /DM, an optional I/O function that is programmed to appear on P34, is used to distinguish between data and program memory space. The state of the /DM signal is controlled by the type of instruction being executed. An LDC opcode references PROGRAM (/DM inactive) memory, and an LDE instruction references data (/DM active Low) memory. Expanded Register File. The register file has been expanded to allow for additional system control registers, and for mapping of additional peripheral devices into the register address area. The Z8 register address space R0 through R15 has been implemented as 16 banks of 16 registers per bank. These register groups are known as the ERF (Expanded Register File). LD LD LD R0,#xx 1,#xx RP,#7DH LD R1,2 1-28 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Z8(R) ST ANDARD CONTROL REGISTERS RESET CONDITION D7 D6 D5 D4 D3 D2 D1 D0 REGISTER** REGISTER POINTER 7 6 5 4 3 2 1 0 FF FE FD SPL SPH RP FLAGS IMR IRQ IPR P01M P3M P2M Reserved Reserved Reserved Reserved Reserved Reserved U U 0 U 0 0 U 0 0 1 U U U U 0 0 U U 0 U U 0 U 1 0 1 U U U U 0 U U U 0 U U 0 U 0 0 1 U U U U 0 U U U 0 U U 0 U 0 0 1 U U U U 0 0 U U 0 U U 0 U 1 0 1 U U U U 0 0 U U 0 U U 0 U 1 0 1 U U U U 0 0 U U 0 U U 0 U 0 0 1 U U U U 0 0 U U 0 U U 0 U 1 0 1 U U U U 0 0 1 Working Register Group Pointer Expanded Register Bank/Group Pointer FC FB FA F9 F8 * * Z8 Register File** FF FO F7 F6 F5 F4 F3 F2 F1 F0 EXP ANDED REG. BANK/GROUP (F) REGISTER** RESET CONDITION * 7F Reserved (F) 0F (F) 0E (F) 0D (F) 0C WDTMR OPT SMR2 Reserved SMR Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved PCON U 0 U U 0 0 U 0 U 0 0 0 1 0 0 1 0 0 0 0 U 1 0 U (F) 0B (F) 0A (F) 09 (F) 08 0 0 1 0 0 0 U 0 Reserved 0F 00 (F) 07 (F) 06 (F) 05 (F) 04 (F) 03 (F) 02 (F) 01 * (F) 00 U U U U U U U 0 EXPANDED REG. BANK/GROUP (D) REGISTER** RESET CONDITION Reserved HI8 L08 HI16 L016 TC16H TC16L TC8H TC8L Reserved CTR2 CTR1 CTR0 0 0 0 U 0 U U U U U U U U U U U U U U U U U 0 U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U U EXP ANDED REG. GROUP (0) REGISTER** RESET CONDITION P3 P2 P1 P0 0 U U U 0 U U U 0 U U U 0 U U U U U U U U U U U U U U U U U U U (D) 0C (D) 0B (D) 0A (D) 09 (D) 08 (D) 07 (D) 06 * * (0) 03 (0) 02 (0) 01 (0) 00 U = Unknown (D) 05 (D) 04 (D) 03 (D) 02 (D) 01 (D) 00 * Will not be reset with a Stop-Mode Recovery ** All addresses are in Hexadecimal Will not be reset with a Stop-Mode Recovery, except Bit 0. Figure 22. Expanded Register File Architecture DS96LVO1100 PRELIMINARY 1-29 Z86E72/E73 OTP IR Microcontrollers FUNCTIONAL DESCRIPTION (Continued) R253 RP D7 D6 D5 D4 D3 D2 D1 D0 r7 r 6 r5 r 4 Expanded Register File Pointer Working Register Pointer Default Setting After Reset = 0000 0000 r3 r 2 r1 r 0 R253 The upper nibble of the register file address provided by the register pointer specifies the active working-register group FF R15 to R0 F0 Figure 23. Register Pointer Register File. The register file (bank 0) consists of four I/O port registers, 236 general-purpose registers, and 16 control and status registers (R0-R3, R4-R239, and R240R255, respectively), Plus two expanded registers groups (Banks D and F). Instructions can access registers directly or indirectly through an 8-bit address field. This allows a short, 4-bit register address using the Register Pointer (Figure 23). In the 4-bit mode, the register file is divided into 16 working register groups, each occupying 16 continuous locations. The Register Pointer addresses the starting location of the active working register group. Note: Working register group E0-EF of Bank 0 are only accessed through working registers and indirect addressing modes. Stack. The Z86E7X external data memory or the internal register file is used for the stack. An 8-bit Stack Pointer (R255) is used for the internal stack that resides in the general-purpose registers (R4-R239). SPH is used as a general-purpose register only when using internal stacks. Note: When SPH is used as a general-purpose register and Port 0 is in address mode, the contents of SPH will be loaded into Port 0 whenever the internal stack is accessed. Specified Working Register Group 2F 20 1F Register Group 1 10 0F Register Group 0 I/O Ports The lower nibble of the register file address provided by the instruction points to the specified register R15 to R0 R15 to R4 R3 to R0 00 Figure 24. Register Pointer 1-30 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION Table 5. Expanded Register Group D (D) %0C (D) % 0B (D) % 0A (D) %09 (D) %08 (D) %07 (D) %06 (D) %05 (D) %04 (D) %03 (D) %02 (D) %01 (D) %00 Reserved HI8 LO8 HI16 LO16 TC16H TC16L TC8H TC8L Reserved CTR2 CTR1 CTR0 L016(D)%08: Holds the captured data from the output of the 16-bit Counter/Timer16. This register holds the LSByte of the data. Field Bit Position Value R/W Description Captured Data No Effect 1 T16_Capture_LO 76543210 TC16H(D)%07: Counter/Timer2 MS-Byte Hold Register. Field T16_Data_HI Bit Position 76543210 Value R/W Description Data TC16L(D)%06: Counter/Timer2 LS-Byte Hold Register. Field Bit Position 76543210 Value R/W Description Data Register Description HI8(D)%0B: Holds the captured data from the output of the 8-bit Counter/Timer0. This register is typically used to hold the number of counts when the input signal is 1. Field Bit Position Value R/W Description Captured Data No Effect T16_Data_LO TC8H(D)%05: Counter/Timer8 High Hold Register. Field T8_Level_HI Bit Position 76543210 Value R/W Description Data T8_Capture_HI 76543210 TC8L(D)%04: Counter/Timer8 Low Hold Register. Field T8_Level_LO Bit Position 76543210 Value R/W Description Data L08(D)%0A: Holds the captured data from the output of the 8-bit Counter/Timer0. This register is typically used to hold the number of counts when the input signal is 0. Field T8_Capture_L0 Bit Position 76543210 Value R/W Description Captured Data No Effect HI16(D)%09: Holds the captured data from the output of the 16-bit Counter/Timer16. This register holds the MSByte of the data. Field T16_Capture_HI Bit Position 76543210 Value R/W Description Captured Data No Effect DS96LVO1100 PRELIMINARY 1-31 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) CTR0 (D)00: Counter/Timer8 Control Register. Field T8_Enable Bit Position 7------R W Single/Modulo Time_Out -6-------5-----R/W R Value 0* 1 0 1 0 1 0 1 0 1 00 01 10 11 0 1 0 1 0* 1 Description Counter Disabled Counter Enabled Stop Counter Enable Counter Modulo-N Single Pass No Counter Time-Out Counter Time-Out Occurred No Effect Reset Flag to 0 SCLK SCLK/2 SCLK/4 SCLK/8 Disable Data Capture Int. Enable Data Capture Int. Disable Time-Out Int. Enable Time-Out Int. P34 as Port Output T8 Output on P34 T8 _Clock ---43--- W R/W Capture_INT_MASK Counter_INT_Mask P34_Out -----2-------1-------0 R/W R/W R/W Note: *Indicates the value upon Power-On Reset CTR0: Counter/Timer8 Control Register Description T8 Enable. This field enables T8 when set (written) to 1. Single/Modulo-N. When set to 0 (modulo-n), the counter reloads the initial value when the terminal count is reached. When set to 1 (single pass), the counter stops when the terminal count is reached. Time-Out. This bit is set when T8 times out (terminal count reached). To reset this bit, a 1 should be written to this location. This is the only way to reset this status condition, therefore, care should be taken to reset this bit prior to using/enabling the counter/timers. Note: Care must be taken when utilizing the OR or AND commands to manipulate CTR0, bit 5 and CTR1, bits 0 and 1 (Demodulation Mode). These instructions use a Read-Modify-Write sequence in which the current status from the CTR0 and CTR1 registers will be ORed or ANDed with the designated value and then written back into the registers. Example: When the status of bit 5 is 1, a reset condition will occur. T8 Clock. Defines the frequency of the input signal to T8. Capture_INT_Mask. Set this bit to allow interrupt when data is captured into either LO8 or HI8 upon a positive or negative edge detection in demodulation mode. Counter_INT_Mask. Set this bit to allow interrupt when T8 has a time out. P34_Out. This bit defines whether P34 is used as a normal output pin or the T8 output 1-32 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers CTR1(D)%01: Controls the functions in common with the T8 and T16. Field Mode P36_Out/ Demodulator_Input Bit Position 7-------6-----R/W R/W 0* 1 0 1 T8/T16_Logic/ Edge _Detect --54---R/W 00 01 10 11 00 01 10 11 Transmit_Submode/ Glitch_Filter ----32-R/W 00 01 10 11 00 01 10 11 Initial_T8_Out/ Rising_Edge ------1R/W 0 1 0 1 0 1 0 1 0 1 0 1 Value 0* 1 Description Transmit Mode Demodulation Mode Transmit Mode Port Output T8/16 Output Demodulation Mode P31 P20 Transmit Mode AND OR NOR NAND Demodulation Mode Falling Edge Rising Edge Both Edges Reserved Transmit Mode Normal Operation Ping-Pong Mode T16_OUT = 0 T16_OUT = 1 Demodulation Mode No Filter 4 SCLK Cycle 8 SCLK Cycle 16 SCLK Cycle Transmit Mode T8_OUT is 0 Initially T8_OUT is 1 Initially Demodulation Mode No Rising Edge Rising Edge Detected No Effect Reset Flag to 0 Transmit Mode T16_OUT is 0 Initially T16_OUT is 1 Initially Demodulation Mode No Falling Edge Falling Edge Detected No Effect Reset Flag to 0 1 R W Initial_T16_Out/ Falling _Edge -------0 R/W R W Note: * Indicates the value upon Power-On Reset. DS96LVO1100 PRELIMINARY 1-33 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) CTR1 Register Description Mode. If it is 0, the Counter/Timers are in the transmit mode, otherwise they are in the demodulation mode. P36_Out/Demodulator_Input. In Transmit Mode, this bit defines whether P36 is used as a normal output pin or the combined output of T8 and T16. In Demodulation Mode, this bit defines whether the input signal to the Counter/Timers is from P20 or P31. T8/T16_Logic/Edge _Detect. In Transmit Mode, this field defines how the outputs of T8 and T16 are combined (AND, OR, NOR, NAND). In Demodulation Mode, this field defines which edge should be detected by the edge detector. Transmit_Submode/Glitch Filter. In Transmit Mode, this field defines whether T8 and T16 are in the "Ping-Pong" mode or in independent normal operation mode. Setting this field to "Normal Operation Mode" terminates the "PingPong Mode" operation. When set to 10, T16 is immediately forced to a 0. When set to 11, T16 is immediately forced to a 1. In Demodulation Mode, this field defines the width of the glitch that should be filtered out. Initial_T8_Out/Rising_Edge. In Transmit Mode, if 0, the output of T8 is set to 0 when it starts to count. If 1, the output of T8 is set to 1 when it starts to count. When this bit is set to 1 or 0, T8_OUT will be set to the opposite state of this bit. This insures that when the clock is enabled a transition occurs to the initial state set by CTR1, D1. In Demodulation Mode, this bit is set to 1 when a rising edge is detected in the input signal. In order to reset it, a 1 should be written to this location. Initial_T16 Out/Falling _Edge. In Transmit Mode, if it is 0, the output of T16 is set to 0 when it starts to count. If it is 1, the output of T16 is set to 1 when it starts to count. This bit is effective only in Normal or Ping-Pong Mode (CTR1, D3, D2). When this bit is set, T16_OUT will be set to the opposite state of this bit. This insures that when the clock is enabled a transition occurs to the initial state set by CTR1, D0. In Demodulation Mode, this bit is set to 1 when a falling edge is detected in the input signal. In order to reset it, a 1 should be written to this location. Note: Modifying CTR1, (D1 or D0) while the counters are enabled will cause un-predictable output from T8/T16 out. 1-34 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers CTR2 (D)%02: Counter/Timer16 Control Register. Field T16_Enable Bit Position 7------R W Submode/Modulo-N -6-----R/W 0 1 0 1 0 1 0 1 00 01 10 11 0 1 0 1 0* 1 Value 0* 1 0 1 Description Counter Disabled Counter Enabled Stop Counter Enable Counter Transmit Mode Modulo-N Single Pass Demodulation Mode T16 Recognizes Edge T16 Does Not Recognize Edge No Counter Time-Out Counter Time-Out Occurred No Effect Reset Flag to 0 SCLK SCLK/2 SCLK/4 SCLK/8 Disable Data Capture Int. Enable Data Capture Int. Disable Time-Out Int. Enable Time-Out Int. P35 as Port Output T16 Output on P35 1 Time_Out --5----- R W T16 _Clock ---43--- R/W Capture_INT_Mask Counter_INT_Mask P35_Out -----2-------1-------0 R/W R/W R/W Note: * Indicates the value upon Power-On Reset. CTR2 Description T16_Enable. This field enables T16 when set to 1. Single/Modulo-N. In Transmit Mode, when set to 0, the counter reloads the initial value when terminal count is reached. When set to 1, the counter stops when the terminal count is reached. In Demodulation Mode, when set to 0 , T16 captures and reloads on detection of all the edges; when set to 1, T16 captures and detects on the first edge, but ignores the subsequent edges. For details, see the description of T16 Demodulation Mode. Time_Out. This bit is set when T16 times out (terminal count reached). In order to reset it, a 1 should be written to this location. T16_Clock. Defines the frequency of the input signal to Counter/Timer16. Capture_INT_Mask. Set this bit to allow interrupt when data is captured into LO16 and HI16. Counter_INT_Mask. Set this bit to allow interrupt when T16 times out. P35_Out. This bit defines whether P35 is used as a normal output pin or T16 output. DS96LVO1100 PRELIMINARY 1-35 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) SMR2(F) %0D: Stop-Mode Recovery Register 2. Field Reserved Recovery Level Reserved Source Bit Position 7-------6-------5-------432-W Value 0 0* 1 0 000* 001 010 011 100 101 110 111 00 Description Reserved (Must be 0) Low High Reserved (Must be 0) A. POR Only B. NAND of P23-P20 C. NAND or P27-P20 D. NOR of P33-P31 E. NAND of P33-P31 F. NOR of P33-P31, P00,P07 G. NAND of P33-P31,P00,P07 H. NAND of P33-P31,P22-P20 Reserved (Must be 0) W Reserved ------10 Note: * Indicates the value upon Power-On Reset. Counter/Timer Functional Blocks CTR1 D5,D4 P31 MUX P20 Glitch Filter Edge Detector Pos Edge Neg Edge CTR1 D6 CTR1 D3,D2 Figure 25. Glitch Filter Circuitry 1-36 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Z8 Data Bus CTR0 D2 Pos Edge Neg Edge HI8 CTR0 D4, D3 Clock LO8 IRQ4 1 CTR0 D1 Clock Select 8-Bit Counter T8 SCLK T8_OUT TC8H TC8L Z8 Data Bus Figure 26. 8-Bit Counter/Timer Circuits Input Circuit The edge detector monitors the input signal on P31 or P20. Based on CTR1 D5-D4, a pulse is generated at the Pos Edge or Neg Edge line when an edge is detected. Glitches in the input signal which have a width less than specified (CTR1 D3, D2) are filtered out. T8 Transmit Mode When T8 is enabled, the output of T8 depends on CTR1, D1. If it is 0, T8_OUT is 1. If it is 1, T8_OUT is 0. When T8 is enabled, the output T8_OUT switches to the initial value (CTR1 D1). If the initial value (CTR1 D1) is 0, TC8L is loaded, otherwise TC8H is loaded into the counter. In Single-Pass Mode (CTR0 D6), T8 counts down to 0 and stops, T8_OUT toggles, the time-out status bit (CTR0 D5) is set, and a time-out interrupt can be generated if it is enabled (CTR0 D1) (Figure 33). In Modulo-N Mode, upon reaching terminal count, T8_OUT is toggled, but no interrupt is generated. Then T8 loads a new count (if the T8_OUT level now is 0), TC8L is loaded; if it is 1, TC8H is loaded. T8 counts down to 0, toggles T8_OUT, sets the time-out status bit (CTR0 D5) and generates an interrupt if enabled (CTR0 D1) (Figure 34). This completes one cycle. T8 then loads from TC8H or TC8L according to the T8_OUT level, and repeats the cycle. The user can modify the values in TC8H or TC8L at any time. The new values take effect when they are loaded. Care must be taken not to write these registers at the time the values are to be loaded into the counter/timer, to ensure known operation. An initial count of 1 is not allowed (a non-function will occur). An initial count of 0 will cause TC8 to count from 0 to %FF to %FE (Note, % is used for hexadecimal values). Transition from 0 to %FF is not a time-out condition. Note: Using the same instructions for stopping the counter/timers and setting the status bits is not recommended. Two successive commands, first stopping the counter/timers, then resetting the status bits is necessary. This is required because it takes one counter/timer clock interval for the initiated event to actually occur. DS96LVO1100 PRELIMINARY 1-37 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) TC8H Counts "Counter Enable" Command, T8_OUT Switches To Its Initial Value (CTR1 D1) T8_OUT Toggles, Time-Out Interrupt Figure 27. T8_OUT in Single-Pass Mode T8_OUT Toggles T8_OUT TC8L TC8H TC8L TC8H TC8L "Counter Enable" Command, T8_OUT Switches To Its Initial Value (CTR1 D1) Time-Out Interrupt Time-Out Interrupt Figure 28. T8_OUT in Modulo-N Mode 1-38 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers T8 Demodulation Mode The user should program TC8L and TC8H to %FF. After T8 is enabled, when the first edge (rising, falling, or both depending on CTR1 D5, D4) is detected, it starts to count down. When a subsequent edge (rising, falling, or both depending on CTR1 D5, D4) is detected during counting, the current value of T8 is one's complemented and put into one of the capture registers. If it is a positive edge, data is put into LO8, if negative edge, HI8. One of the edge detect status bits (CTR1 D1, D0) is set, and an interrupt can be generated if enabled (CTR0 D2). Meanwhile, T8 is loaded with %FF and starts counting again. Should T8 reach 0, the time-out status bit (CTR0 D5) is set, an interrupt can be generated if enabled (CTR0 D1), and T8 continues counting from %FF (Figure 35). 1 T8 (8-Bit) Count Capture No T8_Enable (Set By User) Yes Edge Present No Yes What Kind Of Edge Pos Neg T8 L08 T8 HI8 %FF T8 Figure 29. Demodulation Mode Count Capture Flowchart DS96LVO1100 PRELIMINARY 1-39 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) T8 (8-Bit) Transmit Mode No T8_Enable Bit Set CTR0, D7 Yes Reset T8_Enable Bit 0 T8_OUT Value 1 Load TC8L Reset T8_OUT Load TC8H Set T8_OUT Set Time-out Status Bit (CTR0 D5) and Generate Timeout_Int If Enabled Enable T8 No T8_Timeout Yes Single Pass Single Pass? Modulo-N 1 T8_OUT Value 0 Load TC8L Reset T8_OUT Load TC8H Set T8_OUT Enable T8 Set Time-out Status Bit (CTR0 D5) and Generate Timeout_Int If Enabled No T8_Timeout Yes Disable T8 Figure 30. Transmit Mode Flowchart 1-40 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers T8 (8-Bit) Demodulation Mode 1 No T8_Enable CTR0, D7 Yes %FF TC8 Edge Present No Yes Disable T8 Enable TC8 T8_Enable Bit Set Yes No Edge Present Yes Set Edge Present Status Bit And Trigger Data Capture Int. If Enabled T8 Time Out No Yes Set Time-out Status Bit And Trigger Time Out Int. If Enabled Continue Counting Figure 31. Demodulation Mode Flowchart DS96LVO1100 PRELIMINARY 1-41 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) Z8 Data Bus CTR2 D2 Pos Edge Neg Edge HI16 CTR2 D4, D3 Clock 16-Bit Counter T16 LO16 IRQ3 CTR2 D1 Clock Select SCLK T16_OUT TC16H TC16L Z8 Data Bus Figure 32. 16-Bit Counter/Timer Circuits T16 Transmit Mode In Normal or Ping-Pong Mode, the output of T16 when not enabled is dependent on CTR1, D0. If it is a 0, T16_OUT is a 1; if it is a 1, T16_OUT is 0. The user can force the output of T16 to either a 0 or 1 whether it is enabled or not by programming CTR1 D3, D2 to a 10 or 11. When T16 is enabled, TC16H * 256 + TC16L is loaded, and T16_OUT is switched to its initial value (CTR1 D0). When T16 counts down to 0, T16_OUT is toggled (in Normal or Ping-Pong Mode), an interrupt is generated if enabled (CTR2 D1), and a status bit (CTR2 D5) is set. Note that global interrupts will override this function as described in the interrupts section. If T16 is in Single-Pass Mode, it is stopped at this point. If it is in Modulo-N Mode, it is loaded with TC16H * 256 + TC16L and the counting continues. The user can modify the values in TC16H and TC16L at any time. The new values take effect when they are loaded. Care must be taken not to load these registers at the time the values are to be loaded into the counter/timer, to ensure known operation. An initial count of 1 is not allowed. An initial count of 0 will cause T16 to count from 0 to %FF FF to %FFFE. Transition from 0 to %FFFF is not a time-out condition. 1-42 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers TC16H*256+TC16L Counts 1 "Counter Enable" Command, T16_OUT Switches To Its Initial Value (CTR1 D0) T16_OUT Toggles, Time-Out Interrupt Figure 33. T16_OUT in Single-Pass Mode TC16H*256+TC16L TC16H*256+TC16L T16_OUT TC16H*256+TC16L "Counter Enable" Command, T16_OUT Switches To Its Initial Value (CTR1 D0) T16_OUT Toggles, Time-Out Interrupt T16_OUT Toggles, Time-Out Interrupt Figure 34. T16_OUT in Modulo-N Mode T16 Demodulation Mode The user should program TC16L and TC16H to %FF. After T16 is enabled, when the first edge (rising, falling or both depending on CTR1, D5, D4) is detected. T16 captures HI16 and LO16, reloads and begins counting. If D6 of CTR2 is 0: When a subsequent edge (rising, falling, or both depending on CTR1 D5, D4) is detected during counting, the current count in T16 is one's complemented and put into HI16 and LO16. When data is captured, one of the edge detect status bits (CTR1 D1, D0) is set and an interrupt is generated if enabled (CTR2 D2). T16 is loaded with %FFFF and starts again. If D6 of CTR2 is 1: T16 ignores the subsequent edges in the input signal and continues counting down. A time out of T8 will cause T16 to capture its current value and generate an interrupt if enabled (CTR2, D2). In this case, T16 does not reload and continues counting. If D6 bit of CTR2 is toggled (by writing a 0 then a 1 to it), T16 will capture and reload on the next edge (rising, falling, or both depending on CTR1 D5, D4) but continue to ignore subsequent edges. Should T16 reach 0, it continues counting from %FFFF; meanwhile, a status bit (CTR2 D5) is set and an interrupt time-out can be generated if enabled (CTR2 D1). DS96LVO1100 PRELIMINARY 1-43 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) Ping-Pong Mode This operation mode is only valid in Transmit Mode. T8 and T16 need to be programmed in Single-Pass Mode (CTR0 D6, CTR2 D6) and Ping-Pong Mode needs to be programmed in CTR1 D3, D2. The user can begin the operation by enabling either T8 or T16 (CTR0 D7 or CTR2 D7). For example, if T8 is enabled, T8_OUT is set to this initial value (CTR1 D1). According to T8_OUT's level, TC8H or TC8L is loaded into T8. After the terminal count is reached, T8 is disabled and T16 is enabled. T16_OUT switches to its initial value (CTR1 D0), data from TC16H Enable TC8 and TC16L is loaded, and T16 starts to count. After T16 reaches the terminal count it stops, T8 is enabled again, and the whole cycle repeats. Interrupts can be allowed when T8 or T16 reaches terminal control (CTR0 D1, CTR2 D1). To stop the Ping-Pong operation, write 00 to bits D3 and D2 of CTR1. Note: Enabling Ping-Pong operation while the counter/timers are running may cause intermittent counter/timer function. Disable the counter/timers, then reset the status flags prior to instituting this operation. Time-Out Enable Ping-Pong CTR1 D3,D2 TC16 Time-Out Figure 35. Ping-Pong Mode To Initiate Ping-Pong Mode First, make sure both counter/timers are not running. Then set T8 into Single-Pass Mode (CTR0 D6), set T16 into Single-Pass Mode (CTR2 D6), and set Ping-Pong Mode (CTR1 D2, D3). These instructions do not have to be in any particular order. Finally, start Ping-Pong Mode by enabling either T8 (CTR0 D7) or T16 (CTR2 D7). During Ping-Pong Mode The enable bits of T8 and T16 (CTR0 D7, CTR2 D7) will alternately be set and cleared by hardware. The time-out bits (CTR0 D5, CTR2 D5) will be set every time the counter/timers reach the terminal count. 1-44 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers P34_INTERNAL MUX P34_EXT 1 P36_EXT CTR0 D0 P36_INTERNAL T8_OUT T16_OUT CTR1, D2 AND/OR/NOR/NAND Logic MUX CTR1 D6 CTR1 D5,D4 CTR1 D3 P35_INTERNAL MUX P35_EXT MUX CTR2 D0 Figure 36. Output Circuit DS96LVO1100 PRELIMINARY 1-45 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) Interrupts. The Z86E7X has five different interrupts. The interrupts are maskable and prioritized (Figure 42). The five sources are divided as follows: three sources are claimed by Port 3 lines P33-P31, the remaining two by the counter/timers (Table 10). The Interrupt Mask Register globally or individually enables or disables the five interrupt requests. IRQ0 IRQ 1, 3, 4 IRQ2 Interrupt Edge Select IRQ Register (D6, D7) IRQ IMR 5 IPR Global Interrupt Enable Interrupt Request Priority Logic Vector Select Figure 37. Interrupt Block Diagram 1-46 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Table 6. Interrupt Types, Sources, and Vectors Name IRQ0 Source /DAV0, IRQ0 Vector Location 0, 1 Comments External (P32), Rising Falling Edge Triggered External (P33), Falling Edge Triggered External (P31), Rising Falling Edge Triggered Internal Internal Programming bits for the Interrupt Edge Select are located in the IRQ Register (R250), bits D7 and D6 . The configuration is shown in Table 11. Table 7. IRQ Register IRQ D7 0 0 1 1 D6 0 1 0 1 Interrupt Edge IRQ2 (P31) IRQ0 (P32) F F F R/F F R F R/F 1 IRQ1, IRQ1 2, 3 IRQ2 /DAV2, IRQ2, TIN 4,5 IRQ3 IRQ4 T16 T8 6, 7 8, 9 Notes: F = Falling Edge R = Rising Edge In analog mode, the Stop-Mode Recovery sources selected by the SMR register are connected to the IRQ1 input. Any of the Stop-Mode Recovery sources for SMR (except P31, P32, and P33) can be used to generate IRQ1 (falling edge triggered). When more than one interrupt is pending, priorities are resolved by a programmable priority encoder controlled by the Interrupt Priority register. An interrupt machine cycle is activated when an interrupt request is granted. This disables all subsequent interrupts, saves the Program Counter and Status Flags, and then branches to the program memory vector location reserved for that interrupt. All Z86E7X interrupts are vectored through locations in the program memory. This memory location and the next byte contain the 16-bit address of the interrupt service routine for that particular interrupt request. To accommodate polled interrupt systems, interrupt inputs are masked and the Interrupt Request register is polled to determine which of the interrupt requests need service. An interrupt resulting from AN1 is mapped into IRQ2, and an interrupt from AN2 is mapped into IRQ0. Interrupts IRQ2 and IRQ0 may be rising, falling, or both edge triggered, and are programmable by the user. The software can poll to identify the state of the pin. Clock. The Z86E7X on-chip oscillator has a high-gain, parallel-resonant amplifier for connection to a crystal, LC, ceramic resonator, or any suitable external clock source (XTAL1 = Input, XTAL2 = Output). The crystal should be AT cut, 1 MHz to 8 MHz maximum, with a series resistance (RS) less than or equal to 100 Ohms. The Z86L7X on-chip oscillator may be driven with a cost-effective RC network or other suitable external clock source. The crystal should be connected across XTAL1 and XTAL2 using the recommended capacitors (capacitance greater than or equal to 22 pF) from each pin to ground. The RC oscillator configuration is an external resistor connected from XTAL1 to XTAL2, with a frequency-setting capacitor from XTAL1 to ground (Figure 44). DS96LVO1100 PRELIMINARY 1-47 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) Power-On Reset (POR). A timer circuit clocked by a dedicated on-board RC oscillator is used for the Power-On Reset (POR) timer function. The POR time allows VCC and the oscillator circuit to stabilize before instruction execution begins. The POR timer circuit is a one-shot timer triggered by one of three conditions: 1. Power Fail to Power OK status. 2. Stop-Mode Recovery (if D5 of SMR = 1). 3. WDT Time-Out. The POR time is a nominal 5 ms. Bit 5 of the Stop-Mode Register determines whether the POR timer is bypassed after Stop-Mode Recovery (typical for external clock, RC, LC oscillators). XTAL1 C1 C1 L XTAL1 C1 R XTAL1 C1 Rf XTAL1 XTAL1 XTAL2 C2 C2 XTAL2 XTAL2 C2 Rd XTAL2 XTAL2 Ceramic Resonator or Crystal C1, C2 = 47 pF TYP * f = 8 MHz * Preliminary value including pin parasitics LC C1, C2 = 22 pF L = 130 H * f = 3 MHz * RC @ 3V VCC (TYP) C1 = 33 pF * R = 1K * 32 kHz XTAL C1 = 20 pF, C = 33 pF Rd = 56 - 470K Rf =10 M External Clock Figure 38. Oscillator Configuration 1-48 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers HALT. HALT turns off the internal CPU clock, but not the XTAL oscillation. The counter/timers and external interrupts IRQ0, IRQ1, IRQ2, IRQ3, and IRQ4 remain active. The devices are recovered by interrupts, either externally or internally generated. An interrupt request must be executed (enabled) to exit HALT mode. After the interrupt service routine, the program continues from the instruction after the HALT. STOP. This instruction turns off the internal clock and external crystal oscillation and reduces the standby current to 10 A (typical) or less. STOP mode is terminated only by a reset, such as WDT time-out, POR, SMR, or external reset. This causes the processor to restart the application program at address 000CH. In order to enter STOP (or HALT) mode, it is necessary to first flush the instruction pipeline to avoid suspending execution in mid-instruction. To do this, the user must execute a NOP (opcode = FFH) immediately before the appropriate sleep instruction, i.e., FF 6F FF 7F NOP STOP or NOP HALT ; clear the pipeline ; enter STOP mode ; clear the pipeline ; enter HALT mode 1 Port Configuration Register (PCON). The PCON register configures the comparator output on Port 3. It is located in the expanded register file at Bank F, location 00 (Figure 44). PCON (0F) 0H D7 D6 D5 D4 D3 D2 D1 D0 Comparator Output Port 3 0 P34, P37 Standard Output* 1 P34, P37 Comparator Output Reserved (Must be 1) * Default Setting After Reset Figure 39. Port Configuration Register (PCON) (Write Only) Comparator Output Port 3 (D0). Bit 0 controls the comparator used in Port 3. A 1 in this location brings the comparator outputs to P34 and P37, and a 0 releases the Port to its standard I/O configuration. Stop-Mode Recovery Register (SMR). This register selects the clock divide value and determines the mode of Stop-Mode Recovery (Figure 46). All bits are write only except bit 7, which is read only. Bit 7 is a flag bit that is hardware set on the condition of STOP recovery and reset by a power-on cycle. Bit 6 controls whether a low level or a high level is required from the recovery source. Bit 5 controls the reset delay after recovery. Bits D2, D3, and D4, of the SMR register, specify the source of the Stop-Mode Recovery signal. Bit D0 determines if SCLK/TCLK are divided by 16 or not. The SMR is located in Bank F of the Expanded Register Group at address 0BH DS96LVO1100 PRELIMINARY 1-49 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) SMR D4 D3 D2 000 VCC VCC SMR2 D4 D3 D2 000 SMR D4 D3 D2 010 P20 P31 S1 P23 SMR2 D4 D3 D2 001 SMR D4 D3 D2 011 P20 P32 S2 SMR D4 D3 D2 100 P33 S3 To IRQ1 S4 SMR D4 D3 D2 101 P27 SMR D4 D3 D2 110 P20 P23 P31 P32 P33 P31 P32 P33 P27 SMR2 D4 D3 D2 010 SMR2 D4 D3 D2 011 SMR2 D4 D3 D2 100 P31 P32 P33 P00 P07 SMR2 D4 D3 D2 101 SMR D4 D3 D2 111 P20 P27 SMR D6 P31 P32 P33 P00 P07 SMR2 D4 D3 D2 110 P31 P32 P33 P20 P21 P22 SMR2 D4 D3 D2 111 To RESET and WDT Circuitry (Active Low) SMR2 D6 Figure 40. Stop-Mode Recovery Register 1-50 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Stop-Mode Recovery Delay Select (D5). This bit, if low, disables the 5 ms /RESET delay after Stop-Mode Recovery. The default configuration of this bit is one. If the "fast" wake up is selected, the Stop-Mode Recovery source needs to be kept active for at least 5TpC. Stop-Mode Recovery Edge Select (D6). A 1 in this bit position indicates that a High level on any one of the recovery sources wakes the Z86E7X from STOP mode. A 0 indicates Low level recovery. The default is 0 on POR (Figure 36). Cold or Warm Start (D7). This bit is set by the device upon entering STOP mode. It is a Read Only Flag bit. A 1 in D7 (warm) indicates that the device will awaken from a SMR source or a WDT while in STOP mode. A 0 in this bit (cold) indicates that the device will be reset by a POR or WDT while not in STOP. Stop-Mode Recovery Register 2 (SMR2). This register determines the mode of STOP mode recovery for SMR2. (Figure 49) If SMR2 is used in conjunction with SMR, either of the specified events will cause a Stop-Mode Recovery. Note: Port pins configured as outputs are ignored as a SMR or SMR2 recovery source. For example, if the NAND of P23-P20 is selected as the recovery source and P20 is configured as an output then the remaining SMR pins (P23-P21) form the NAND equation. OSC 1 /2 / 16 SCLK SMR, D0 TCLK Figure 41. SCLK Circuit SCLK/TCLK Divide-by-16 Select (D0). D0 of the SMR controls a Divide-by-16 prescaler of SCLK/TCLK. The purpose of this control is to selectively reduce device power consumption during normal processor execution (SCLK control) and/or HALT mode (where TCLK sources interrupt logic). After Stop-Mode Recovery, this bit is set to a 0. Stop-Mode Recovery Source (D2, D3, and D4). These three bits of the SMR specify the wake up source of the STOP recovery (Figure 49 and Table 12). Table 8. Stop-Mode Recovery Source SMR:432 D4 D3 D2 0 0 0 0 0 1 Operation Description of Action POR and/or external reset recovery Reserved P27 transition Logical NOR of P20 through P23 Logical NOR of P20 through P27 0 0 1 1 1 1 1 1 0 0 1 1 0 1 0 1 0 1 Note: Any Port 2 bit defined as an output will drive the corresponding input to the default state to allow the remaining inputs to control the AND/OR function. Refer to SMR2 register for other recover sources. DS96LVO1100 PRELIMINARY 1-51 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) SMR2 (0F) DH D7 D6 D5 D4 D3 D2 D1 D0 Reserved (Must be 0) Reserved (Must be 0) Stop-Mode Recovery Source 2 000 POR only* 001 NAND P20, P21, P22, P23 010 NAND P20, P21, P22, P23, P24, P25, P26, P27 011 NOR P31, P32, P33 100 NAND P31, P32, P33 101 NOR P31, P32, P33, P00, P07 110 NAND P31, P32, P33, P00, P07 111 NAND P31, P32, P33, P20, P21, P22 Reserved (Must be 0) Recovery Level 0 Low* 1 High Reserved (Must be 0) Note: If used in conjunction with SMR, either of the two specified events will cause a Stop-Mode Recovery. *Default Setting After Reset Figure 42. Stop-Mode Recovery Register 2 ((0F) DH: D2-D4, D6 Write Only) Watch-Dog Timer Mode Register (WDTMR). The WDT is a retriggerable one-shot timer that resets the Z8 if it reaches its terminal count. The WDT must initially be enabled by executing the WDT instruction and refreshed on subsequent executions of the WDT instruction. The WDT circuit is driven by an on-board RC oscillator or external oscillator from the XTAL1 pin. The WDT instruction affects the Zero (Z), Sign (S), and Overflow (V) flags. The POR clock source is selected with bit 4 of the WDT register. Bit 0 and 1 control a tap circuit that determines the time-out period. Bit 2 determines whether the WDT is active during HALT and Bit 3 determines WDT activity during STOP. Bits 5 through 7 are reserved (Figure 48). This register is accessible only during the first 64 processor cycles (128 XTAL clocks) from the execution of the first instruction after Power-On-Reset, Watch-Dog Reset, or a Stop-Mode Recovery (Figure 40). After this point, the register cannot be modified by any means, intentional or otherwise. The WDTMR cannot be read and is located in Bank F of the Expanded Register Group at address location 0FH. It is organized as follows: 1-52 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers WDTMR (0F) FH D7 D6 D5 D4 D3 D2 D1 D0 1 WDT TAP 00 01 * 10 11 INT RC OSC External Clock 5 ms 256 TpC 10 ms 512 TpC 20 ms 1024 TpC 80 ms 4096 TpC WDT During HALT 0 OFF 1 ON * WDT During STOP 0 OFF 1 ON * XTAL1/INT RC Select for WDT 0 On-Board RC * 1 XTAL Reserved (Must be 0) * Default Setting After Reset Figure 43. Watch-Dog Timer Mode Register (Write Only) WDT Time Select (D0, D1). Selects the WDT time period. It is configured as shown in Table 13. Table 9. WDT Time Select Time-Out of Internal RC Time-Out of OSC XTAL Clock 5 ms min 10 ms mi 20 ms mi 80 ms mi 256 TpC 512 TpC 1024 TpC 4096 TpC WDTMR During STOP (D3). This bit determines whether or not the WDT is active during STOP mode. Since the XTAL clock is stopped during STOP mode, the on-board RC has to be selected as the clock source to the WDT/POR counter. A 1 indicates active during STOP. The default is 1. Clock Source for WDT (D4). This bit determines which oscillator source is used to clock the internal POR and WDT counter chain. If the bit is a 1, the internal RC oscillator is bypassed and the POR and WDT clock source is driven from the external pin, XTAL1. The default configuration of this bit is 0, which selects the RC oscillator. D1 0 0 1 1 D0 0 1 0 1 Notes: TpC = XTAL clock cycle The default on reset is 10 ms WDTMR During HALT (D2). This bit determines whether or not the WDT is active during HALT mode. A 1 indicates active during HALT. The default is 1. DS96LVO1100 PRELIMINARY 1-53 Z86E72/E73 OTP IR Microcontrollers COUNTER/TIMER REGISTER DESCRIPTION (Continued) /RESET 5 Clock Filter * /CLR 2 CLK 18 Clock RESET Generator RESET Internal RESET Active High WDT TAP SELECT CK Source Select (WDTMR) XTAL INTERNAL RC OSC. Low Operating Voltage Det. M U X POR 3 4 WDT1 2 CLK WDT/POR Counter Chain *CLR1 VDD VBO/VLV 2V REF . + - WDT From Stop Mode Recovery Source Stop Delay Select (SMR) * /CLR1 and /CLR2 enable the WDT/POR and 18 Clock Reset timers upon a Low to High input translation. VCC 12 ns Glitch Filter Figure 44. Resets and WDT 1-54 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Low Voltage Protection. An on-board Voltage Comparator checks that VCC is at the required level to ensure correct operation of the device. Reset is globally driven if VCC is below VLV (Low Voltage). The minimum operating voltage varies with the temperature and operating frequency, while VLV varies with temperature only. Software Selectable Options. There are four Software Selectable Options to choose from which corresponds to the ROM based parts mask options. Register (F0) EH OTP byte is where these options are controlled; these options are: Bit Name Port 0 Pull-ups (lower nibble) Port 0 Pull-ups (upper nibble) Port 2 Pull-ups Mouse/Normal Reg(0F)EH On/Off On/Off On/Off M/N Note: The RC oscillator Xtal1/2 option is invoked during OTP programming as a user-selectable item. The Low Voltage trip voltage (VLV) is less than 3.0V under the following conditions: Maximum (VLV) Conditions: TA = 0C, +70C Internal clock frequency equal to or less than 8.0 MHz Note: The internal clock frequency is one-half the external clock frequency. The device functions normally above 3.0V under all conditions. The minimum functionality point below 3V is to be defined. The VLV is a function of temperature and process parameters. 1 VLV T B D VLV 0 15 35 25 Temperature 45 55 Figure 45. Typical Z86E7X Low Voltage vs Temperature at 8 MHz DS96LVO1100 PRELIMINARY 1-55 Z86E72/E73 OTP IR Microcontrollers EPROM PROGRAMMING Table 10. Programming and Testmode Device Pins User/Test Mode Device Pin # User Modes EPROM Read Program Program Verify RC Option Margin Read Shadow Row Rd Shadow Row Prg Shadow Row Ver Shadow Col Rd Shadow Col Prg Shadow Col Ver Page Prg 2 Byte Page Prg 4 Byte Page Prg 8 Byte Page Prg 16 Byte Notes: 1. All test modes are entered by first setting up the corresponding test address and then latching the address by bringing the /OE to VH and then to VIL, except for the margin read which requires /OE to be kept at VH. VVA = Variable from VCC to VPP VPP = 12.5V 0.5V VH = 12.5V 0. 5V VIH = 3V VIL = 0V XX = Irrelevant IPP during programming = 40 mA maximum ICC during programming, verify, or read = 40 mA maximum. P33 VPP VCC VPP VPP VPP VVA VCC VPP VPP VCC VPP VPP VPP VPP VPP VPP P32 EPM VH VCC VCC VCC VH VH VH VH VH VH VH VH VH VH VH Pref1 /CE VIL VIL VIL VH VIL VIL VIL VIL VIL VIL VIL VIL VIL VIL VIL P31 /OE VIL VIH VIL VIH VH VIL VIH VIL VIL VIH VIL VIH VIH VIH VIH P20 /PGM VIH VIL VIH VIL VIH VIH VIL VIH VIH VIL VIH VIL VIL VIL VIL Addr Addr Addr Addr XX Addr COL COL COL ROW ROW ROW TBD TBD TBD TBD VCC 3.0V 6.0V 6.0V 6.0V 6.0V 3.0V 6.0V 6.0V 3.0V 6.0V 6.0V 6.0V 6.0V 6.0V 6.0V Port 1 CNFG DATA Out In Out XX Out Out In Out Out In Out In In In In Test ADDR A0-A3 XX XX XX XX 00 01 01 01 02 03 02 04 05 06 07 Note 1 1 1 1 1 1 1 1 1 1 1 1-56 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Table 11. Timing of Programming Waveform Parameters 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Name Address Setup Time Data Setup Time VPP Setup Time VCC Setup Time Chip Enable Setup Time Program Pulse Width Data Hold Time /OE Setup Time Data Access Time Data Output Float Time Overprogram Pulse Width EPM Setup Time /PGM Setup Time Address to /OE Setup Time Option Program Pulse Width Min 2 2 2 2 2 0.95 2 2 200 100 2.85 2 2 2 78 Max Units s s s s s s s s ns ns ms s s s ms 1 DS96LVO1100 PRELIMINARY 1-57 Z86E72/E73 OTP IR Microcontrollers EPROM PROGRAMMING (Continued) VIH Address VIL VIH Data VIL VH VPP VIL VH EPM VIL 12 0 Min Address Stable Address Stable Invalid 9 Valid Invalid Valid 5.5V VCC 4.5V VIH /CE VIL VIH 0 Min /OE VIL VIH /PGM VIL 3 Figure 46. EPROM Read 1-58 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers VIH Address VIL VIH Data VIL 1 Address Stable 1 Data Out Valid Data Stable 2 9 10 VH VPP VIH 3 VH EPM VIL 6V VCC 4.5V VIH /CE VIL 5 4 7 VIH /OE VIL VIH /PGM VIL 6 11 Program Cycle Verify Cycle 8 Figure 47. EPROM Program and Verify DS96LVO1100 PRELIMINARY 1-59 Z86E72/E73 OTP IR Microcontrollers EPROM PROGRAMMING (Continued) VIH Address VIL VIH Data VIL VH VPP VIH 3 6V VCC 4.5V 4 VH /CE VIH 5 /OE VIH VIL VH VIL EPM VIH VIL VIH 12 VIL 12 12 VIH /PGM VIL 15 15 15 EPROM Protect RC Oscillator RAM Protect Figure 48. Programming EPROM, RAM Protect and 16K Size Selection 1-60 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Start 1 Addr = First Location Vcc = 6.0V Vpp = 12.5V N=0 Program 1 ms Pulse Increment N Yes N = 25 ? No Fail Verify One Byte Pass Prog. One Pulse 3xN ms Duration Fail Verify Byte Pass Increment Address No Last Addr ? Yes * Vcc = Vpp = 4.5V Note: * To ensure proper operations during the spec., Zilog recommends verification over the V cc range of the device V cc spec. Verify All Bytes Pass Vcc = Vpp = 5.5V * Fail Device Failed Verify All Bytes Pass Device Passed Fail Figure 49. Programming Flowchart DS96LVO1100 PRELIMINARY 1-61 Z86E72/E73 OTP IR Microcontrollers EXPANDED REGISTER FILE CONTROL REGISTERS (0D) CTR0 (0D) 0H D7 D6 D5 D4 D3 D2 D1 D0 0 P34 as Port Output* 1 Timer8 Output 0 Disable T8 Time Out Interrupt 1 Enable T8 Time Out Interrupt 0 Disable T8 Data Capture Interrupt 1 Enable T8 Data Capture Interrupt 00 01 10 11 R R W W SCLK on T8 SCLK/2 on T8 SCLK/4 on T8 SCLK/8 on T8 0 No T8 Counter Time Out 1 T8 Counter Time Out Occured 0 No Effect 1 Reset Flag to 0 0 Modulo-N 1 Single Pass R R W W 0 1 0 1 T8 Disabled * T8 Enabled Stop T8 Enable T8 * Default Setting After Reset Figure 50. TC8 Control Register ((0D) 0H: Read/Write Except Where Noted) 1-62 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers CTR1 (0D) 1H D7 D6 D5 D4 D3 D2 D1 D0 Transmit Mode R/W 0 T16_OUT is 0 Initially 1 T16_OUT is 1 Initially Demodulation Mode R 0 No Falling Edge Detection R 1 Falling Edge Detection W W 0 No Effect 1 Reset Flag to 0 1 Transmit Mode R/W 0 T8_OUT is 0 Initially 1 T8_OUT is 1 Initially Demodulation Mode 0 No Rising Edge Detection R 1 Rising Edge Detection R 0 No Effect W 1 Reset Flag to 0 W Transmit Mode 0 0 Normal Operation 0 1 Ping-Pong Mode 1 0 T16_OUT = 0 1 1 T16_OUT = 1 Demodulation Mode 0 0 No Filter 0 1 4 SCLK Cycle Filter 1 0 8 SCLK Cycle Filter 1 1 16 SCLK Cycle Filter Transmit Mode/T8/T16 Logic 0 0 AND 0 1 OR 1 0 NOR 1 1 NAND Demodulation Mode 0 0 Falling Edge Detection 0 1 Rising Edge Detection 1 0 Both Edge Detection 1 1 Reserved Transmit Mode 0 P36 as Port Output* 1 P36 as T8/T16_OUT Demodulation Mode 0 P31 as Demodulator Input 1 P20 as Demodulator Input Transmit/Demodulation Modes 0 Transmit Mode* 1 Demodulation Mode Note: Care must be taken in differentiating Transmit Mode from Demodulation Mode. Depending on which of these two modes is operating, the CTR1 bit will have different functions. *Note: Changing from one mode to another cannot be done without disabling the counter/timers. Figure 51. T8 and T16 Common Control Functions ((0D) 1H: Read/Write) DS96LVO1100 PRELIMINARY 1-63 Z86E72/E73 OTP IR Microcontrollers EXPANDED REGISTER FILE CONTROL REGISTERS (0D) (Continued) CTR2 (0D) 02H D7 D6 D5 D4 D3 D2 D1 D0 0 1 0 1 P35 is Port Output* P35 is TC16 Output Disable T16 Time-Out Interrupt Enable T16 Time-Out Interrupt 0 Disable T16 Data Capture Interrupt 1 Enable T16 Data Capture Interrupt 00 01 10 11 R R W W 0 1 0 1 SCLK on T16 SCLK/2 on T16 SCLK/4 on T16 SCLK/8 on T16 No T16 Time Out T16 Time Out Occurs No Effect Reset Flag to 0 Transmit Mode 0 Modulo-N for T16 1 Single Pass for T16 Demodulator Mode 0 T16 Recognizes Edge 1 T16 Does Not Recognize Edge R R W W 0 1 0 1 T16 Disabled * T16 Enabled Stop T16 Enable T16 * Default Setting After Reset Figure 52. T16 Control Register ((0D) 2H: Read/Write Except Where Noted) 1-64 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers EXPANDED REGISTER FILE CONTROL REGISTERS (0F) SMR (0F) 0B D7 D6 D5 D4 D3 D2 D1 D0 SCLK/TCLK Divide-by-16 0 OFF ** 1 ON Reserved (Must be 0) Stop-Mode Recovery Source 000 POR Only * 001 Reserved 010 P31 0 11 P32 100 P33 101 P27 11 0 P2 NOR 0-3 111 P2 NOR 0-7 Stop Delay 0 OFF 1 ON * Stop Recovery Level 0 Low * 1 High Stop Flag 0 POR * 1 Stop Recovery** * Default Setting After Reset ** Default Setting After Reset and Stop-Mode Recovery 1 Figure 53. Stop-Mode Recovery Register ((F) 0BH: D6-D0 = Write Only, D7 = Read Only) DS96LVO1100 PRELIMINARY 1-65 Z86E72/E73 OTP IR Microcontrollers SMR2 (0F) DH D7 D6 D5 D4 D3 D2 D1 D0 Reserved (Must be 0) Reserved (Must be 0) Stop-Mode Recovery Source 2 000 POR only* 001 NAND P20, P21, P22, P23 010 NAND P20, P21, P22, P23, P24, P25, P26, P27 011 NOR P31, P32, P33 100 NAND P31, P32, P33 101 NOR P31, P32, P33, P00, P07 110 NAND P31, P32, P33, P00, P07 111 NAND P31, P32, P33, P20, P21, P22 Reserved (Must be 0) Recovery Level 0 Low* 1 High Reserved (Must be 0) Note: If used in conjunction with SMR, either of the two specified events will cause a Stop-Mode Recovery. *Default Setting After Reset Figure 54. Stop-Mode Recovery Register 2 ((0F) DH: D2-D4, D6 Write Only) OPT (0F) EH D7 D6 D5 D4 D3 D2 D1 D0 Port 0 (0-3) Pull-up 1 pull-up active 0 pull-up inactive Port 0 (7-4) Pull-up 1 pull-up active 2 pull-up inactive Port 2 pull-up option 1 pull-up active 0 pull-up inactive Reserved (Must be 0.) Mask option for mouse trackball interface P00-P03 1 For mouse trackball interface 0 Normal Reserved (Must be 0) Figure 55. Option Bit Register 1-66 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers EXPANDED REGISTER FILE CONTROL REGISTERS (0F) (Continued) WDTMR (0F) FH D7 D6 D5 D4 D3 D2 D1 D0 WDT TAP 00 01 * 10 11 INT RC OSC External Clock 5 ms 256 TpC 10 ms 512 TpC 20 ms 1024 TpC 80 ms 4096 TpC WDT During HALT 0 OFF 1 ON * WDT During STOP 0 OFF 1 ON * XTAL1/INT RC Select for WDT 0 On-Board RC * 1 XTAL Reserved (Must be 0) * Default Setting After Reset Figure 56. Watch-Dog Timer Mode Register ((F) 0FH: Write Only) PCON (0F) 0H D7 D6 D5 D4 D3 D2 D1 D0 Comparator Output Port 3 0 P34, P37 Standard Output* 1 P34, P37 Comparator Output Reserved (Must be 1) * Default Setting After Reset P37 comparator output only on E72 R246 P2M D7 D6 D5 D4 D3 D2 D1 D0 P27-P20 I/O Definition 0 Defines Bit as OUTPUT 1 Defines Bit as INPUT* *Default Setting After Reset Figure 57. Port Configuration Register (PCON) ((0F) 0H: Write Only) Figure 58. Port 2 Mode Register (F6H: Write Only) 1-67 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers Z8(R) STANDARD CONTROL REGISTER DIAGRAMS R247 P3M D7 D6 D5 D4 D3 D2 D1 D0 0 Port 2 Open Drain* 1 Port 2 Push-pull 0 = P31, P32 Digital Mode 1 = P31, P32 Analog Mode 0 P32 = Input P35 = Output * 1 P32 = /DAV0/RDY0 P35 = RDY0//DAV0 00 01 10 11 P33 = Input P34 = Output * P33 = Input P34 = /DM P33 = /DAV1/RDY1 P34 = RDY1//DAV1 0 P31 = Input (TIN) P36 = Output (TOUT) 1 P31 = /DAV2/RDY2 P36 = RDY2//DAV2 0 1 P30 = Input P37 = Output P30 = Serial In P37 = Serial Out * Default Setting After Reset 0 Parity Off 1 Parity On Figure 59. Port 3 Mode Register (F7H: Write Only) 1-68 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers R248 P01M D7 D6 D5 D4 D3 D2 D1 D0 1 P00-P03 Mode 00 Output 01 Input* 1X A11-A8 Stack Selection 0 External 1 Internal* P17-P10 Mode 00 Byte Output 01 Reserved 10 AD7-AD0 11 High-Impedance AD7AD0, /AS, /DS, /R//W, A11-A8, A15-A12, If Selected External Memory Timing 0 Normal* 1 Extended P07-P04 Mode 00 Output 01 Input* 1X A15-A12 * Default Setting After Reset. Figure 60. Port 0 and 1 Mode Register (F8H: Write Only) DS96LVO1100 PRELIMINARY 1-69 Z86E72/E73 OTP IR Microcontrollers Z8(R) STANDARD CONTROL REGISTER DIAGRAMS (Continued) R249 IPR D7 D6 D5 D4 D3 D2 D1 D0 R251 IMR D7 D6 D5 D4 D3 D2 D1 D0 Interrupt Group Priority 000 Reserved 001 C > A > B 010 A > B > C 011 A > C > B 100 B > C > A 101 C > B > A 110 B > A > C 111 Reserved IRQ1, IRQ4 Priority (Group C) 0 IRQ1 > IRQ4 1 IRQ4 > IRQ1 IRQ0, IRQ2 Priority (Group B) 0 IRQ2 > IRQ0 1 IRQ0 > IRQ2 IRQ3, IRQ5 Priority (Group A) 0 IRQ5 > IRQ3 1 IRQ3 > IRQ5 Reserved (Must be 0) 1 Enables IRQ4-IRQ0 (D0 = IRQ0) Reserved (Must be 0) Reserved (Must be 0) 0 Master Interrupt Disable* 1 Master Interrupt Enable * Default Setting After Reset Figure 63. Interrupt Mask Register ((0) FBH: Read/Write) R252 Flags D7 D6 D5 D4 D3 D2 D1 D0 Figure 61. Interrupt Priority Registers ((0) F9H: Write Only) User Flag F1 User Flag F2 Half Carry Flag Decimal Adjust Flag Overflow Tag R250 IRQ D7 D6 D5 D4 D3 D2 D1 D0 Sign Flag Zero Flag IRQ0 = P32 Input IRQ1 = P33 Input IRQ2 = P31 Input IRQ3 = T16 IRQ4 = T8 Reserved (Must be 0) Inter Edge P31 P32 = 00 P31 P32 = 01 P31 P32 = 10 P31 P32 = 11 Carry Flag Figure 64. Flag Register ((0) FCH: Read/Write Default Setting After Reset = 0000 0000 R253 RP D7 D6 D5 D4 D3 D2 D1 D0 Expanded Register (Bank) Pointer Figure 62. Interrupt Request Register ((0) FAH: Read/Write) Default Setting After Reset = 0000 Working Register Pointer Figure 65. Register Pointer ((0) FDH: Read/Write) 1-70 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers R254 SPH D7 D6 D5 D4 D3 D2 D1 D0 Stack Pointer Upper Byte (SP15-SP8) R255 SPL D7 D6 D5 D4 D3 D2 D1 D0 Stack Pointer Lower Byte (SP7-SP0) 1 Figure 66. Stack Pointer High ((0) FEH: Read/Write) Figure 67. Stack Pointer Low ((0) FFH: Read/Write) DS96LVO1100 PRELIMINARY 1-71 Z86E72/E73 OTP IR Microcontrollers PACKAGE INFORMATION Figure 68. 40-Pin DIP Package Diagram 1-72 PRELIMINARY DS96LVO1100 Z86E72/E73 OTP IR Microcontrollers 1 Figure 69. 44-Pin QFP Package Diagram Figure 70. 44-Pin PLCC Package Diagram DS96LVO1100 PRELIMINARY 1-73 Z86E72/E73 OTP IR Microcontrollers ORDERING INFORMATION Z86E72/E73 16 MHz 44-Pin PLCC Z86E7216VSC Z86E7316VSC 40-Pin DIP Z86E7216PSC Z86E7316PSC 44-Pin QFP Z86E7216FSC Z86E7316FSC For fast results, contact your local Zilog sales office for assistance in ordering the part desired. Package P = Plastic DIP F = Plastic Quad Flat Pack V = Plastic Chip Carrier Temperature S = 0C to +70C Speed 16 = 16 MHz Environmental C = Plastic Standard Example: Z 86E73 16 P S C is an Z86E73, 16 MHz, DIP, 0C to +70C, Plastic Standard Flow Environmental Flow T emperature Package Speed Product Number Zilog Prefix 1-74 PRELIMINARY DS96LVO1100 |
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