 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE TOSHIBA RISC PROCESSOR TMPR4925XB (64-bit RISC MICROPROCESSOR) 1. GENERAL DESCRIPTION The TMPR4925XB, to be referred as TX4925 MIPS RISC micro-controller is a highly integrated ASSP solution based on Toshiba's TX49/H2 processor core, a 64-bit MIPS I,II,III ISA Instruction Set Architecture (ISA) compatible with additional instructions. The TX4925 is a highly integrated device with integrated peripherals such as SDRAM memory controller, NAND Flash memory controller, PCI controller, AC-Link controller, PIO, SIO, SPI, CHI, PCMCIA I/F and Timer. This class of product is targeted for applications that require a high performance and cost-effective solution such as networking, digital consumer and Internet appliance. 2. FEATURES * * * * * * * * * * * * * * * * * * TX49/H2 core with an integrated IEEE 754-compliant FPU for single- and double-precision operations 4-channel SDRAM Controller ( 32bit/80MHz ) and support SyncFlash(R) memory NAND Flash memory Controller 6-channel External Bus Controller 32-bit PCI Controller (33 MHz) 4-channel Direct Memory Access (DMA) Controller 2-channel Serial I/O Port Parallel I/O Port (up to 32-bit) AC-Link Controller ( AC97 Interface ) PCMCIA Interface (2-slot) SPI (Serial Peripheral Interface) CHI (high-speed serial Concentration Highway Interface) Interrupt Controller 3-channel Timer/Counter and 44-bit up-counter RTC Low power dissipation The TX4925 operates with the 1.5V core and the 3.3V I/O, while supporting a low-power (Halt) mode. CPU maximum operating frequency: 200 MHz IEEE1149.1 (JTAG) support: Debug Support Unit (Enhanced JTAG) 256-pin PBGA package - The products described in this document are subject to foreign exchange and foreign trade control laws. - The information contained herein is subject to change without notice. - TOSHIBA is continually working to improve the quality and the reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to observe standards of safety, and to avoid situations in which a malfunction or failure of a TOSHIBA product could cause loss of human life, bodily injury or damage to property. In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent products specifications. Also, please keep in mind the precautions and conditions set forth in the TOSHIBA Semiconductor Reliability Handbook. EJC-TMPR4925XB-1 - The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by 26/Dec/01 Rev 0.1 TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by TOSHIBA CORPORATION implication or otherwise under any patent or patent rights of TOSHIBA or others. INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 2.1 Internal Block Diagram Figure 1 shows the TX4925 internal block diagram. PLL Debug (DSU) G D$(16K) NAND Flash C SDRAMC DMAC 32bit Gbus IU MMU I$(16K) GPR MAC BIU WB FPU TX49/H2 CPU Core | B U S External BUS Controller External BUS Interface (32bit) PCIC CHI IM bus bridge IM bus SIO PIO IRC ACLC SPI RTC Timer Figure 2.1 TX4925 Internal Block Diagram EJC-TMPR4925XB-2 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 2.2 System Block Diagram Figure 2.2 shows the system block diagram with TX4925. 32bit Gbus PLL NAND Flash C SDRAMC G I B U S DMAC External BUS Controller Command/Data/ Address signals SDRAM Control signals NAND Flash Memory SDRAM Memory Devices Debug (DSU) D$(16K) GPR MAC IU MMU WB FPU I$(16K) BIU External System Bus (Data=32bit, Address=20bit) External BUS Interface TX49/H2 CPU Core PCIC CHI AC Control Signals ROM/ Flash/ SRAM External I/O Devices IM bus bridge IM bus SIO PIO IRC ACLC SPI RTC Timer 32 PCI Bus PCI Devices User logic PCIC Figure 2.2 Typical TX4925 System Block Diagram EJC-TMPR4925XB-3 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 2.3 TX49/H2 Core Block Diagram Figure 3 shows the internal block diagram of the TX49/H2 core TX49/H2 Core Integer Unit GPR Data Path MAC FPU Pipeline Control CP0 CP0 Registers MMU/TLB Exception Unit CP1 Debug Support Unit 16KB 4-way set Instruction Cache Write Buffer 16KB 4-way set Data Cache Figure 2.3 TX49/H2 Core Block Diagram 2.4 TX49/H2 CORE FEATURES The TX49/H2 Core is high performance and low-power 64-bit RISC processor core developed by Toshiba. * * * * * * * * * * 64-bit operation 32, 64-bit integer general purpose registers 32-bit physical address space and 64-bit virtual address space Optimized 5-stage pipeline Instruction Set MIPS I, II , III compatible ISA PREF (Prefetch) and MAC (Multiply/Accumulate) instructions. 16k Byte Instruction Cache, and 16k Byte Data Cache 4-way set associative with lock function MMU (Memory Management Unit): 48-entry fully associative JTLB The on-chip FPU supports both single- and double-precision arithmetic, as specified in IEEE Std 754. On-chip 4-deep write buffer Enhanced JTAG debug feature Built-in Debug Support Unit (DSU) EJC-TMPR4925XB-4 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 2.5 TX4925 Peripheral Circuit FEATURES n External Bus Controller ( EBUSC ) The External Bus Controller generates necessary signals to control external memory and I/O devices. . * 6 channels of chip select signals, enabling control of up to six devices (shared chip select signals of 2 channels) * Supports access to ROM ( including mask ROM, page mode ROM, EPROM and EEPROM), SRAM, flash ROM, and I/O devices * Supports 32-bit, 16-bit and 8-bit data bus sizing on a per channel basis * Supports selection among full speed (up to 80MHz ), 1/2 speed ( up to 40MHz), 1/3 speed ( up tp 27MHz ) and 1/4 speed ( up to 20MHz) on a per channel basis * Support specification of timing on a per channel basis * The user can specify setup and hold times for address, chip enable, write enable, and output enable signals * Supports memory sizes of 1M byte to 1G byte for devices with 32-bit data bus, 1M byte to 512M bytes for devices with 16-bit data bus, and 1M byte to 256M bytes for devices with 8-bit data bus n DMA Controller ( DMAC ) The TX4925 contains a 4-channel DMA controller that executes DMA transfer to memory and I/O devices. * * * * * * * * 4-channel independently handling internal / external DMA requests (Usable only 2 channels by external DMA requests) Supports DMA transfer with built-in serial I/O controller and AC-link controller based on internal DMA requests Supports signal address ( fly-by DMA ) and dual address transfers in external I/O DMA transfer mode using external DMA requests Supports transfer between memory and external I/O devices having 32 / 16 / 8-bit data bus Supports memory-to-memory copy mode, with no address boundary restrictions Supports burst transfer of up to 8 double words for a single read / write Supports memory fill mode, writing double-word data to specified memory area Supports chained DMA transfer EJC-TMPR4925XB-5 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE n SDRAM Controller ( SDRAMC ) The SDRAM Controller generates necessary control signals for the SDRAM interface. It has four channels and can handle up to 2G bytes ( 512 MB/channel ) of memory by supporting a variety of memory configurations. * * * * * * * * * Memory clock frequency : 80MHz (divided by 2.5) 4 sets of independent memory channels Supports 16M / 64M / 128M / 256M / 512M-bit SDRAM with 2/4 bank size availability Supports Single Data Rate (SDR) SDRAM and SyncFlash(R) memory Supports use of Registered DIMM Supports 32 / 16-bit data bus sizing on a per channel basis Supports specification of SDRAM timing on a per channel basis Supports critical word first access of TX49/H2 core Low power mode : selectable between self-refreshing and pre-charge power-down n PCI Controller ( PCIC ) The TX4925 contains a PCI Controller that complies with PCI Local Bus Specification Revision 2.2. * * * * * * * Compliance with PCI Local Bus Specification Revision 2.2 (Partly supports power management as optional function) 32-bit PCI interface featuring maximum PCI bus clock frequency of 33MHz Supports both target and initiator functions Supports change of address mapping between internal bus and PCI bus PCI bus arbiter enables connection of up 4 external bus masters Supports booting of TX4925 from memory on PCI bus 1 channel of DMA controller dedicated to PCI controller ( PDMAC ) n Serial I/O Controller ( SIO ) The TX4925 contains a 2-channels asynchronous serial I/O interface ( full duplex UART ). * * * * * * 2-channel full duplex UART Built-in baud rate generator FIFOs 8-bit x 8 transmitter FIFO 13-bit ( 8 data bits and 5 status bits ) x 16 receiver FIFO Supports DMA tranfer EJC-TMPR4925XB-6 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE n Timers / Counters Controller ( TMR ) The TX4925 contains 3-channel timer / counters. * * * * 3-channel 32-bit up-counter Supports three modes : interval timer mode, pulse generator mode, and watchdog timer mode 2 timer output pins 1 count clock input pin n Parallel I/O Ports ( PIO ) The TX4925 contains 32-bit parallel I/O ports * Independent selection of direction of pins and output port type ( totem-pole or open-drain outputs ) on a per bit basis. (PIO[4,2,0] are input-only pins.) n AC-link controller ( ACLC ) The TX4925 contains an AC-link controller, which can be operated using any audio and / or modem CODECs described in Audio CODEC'97 Revision 2.1 ( AC'97 ). * * * * * * * Supports up to two CODECs Supports recording and playback for right and left 16-bit PCM channels Supports playback for 16-bit surround, center, and LFE channels Supports audio recording and layback at variable rate Supports Line1 and GPIO slots for modem CODEC Supports AC-link low power mode, wakeup, and warm reset Supports input / output of sample data by DMA transfer EJC-TMPR4925XB-7 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE n Interrupt Controller ( IRC ) The TX4925 contains an interrupt controller, which receives interrupt requests sent by both the TX4925's built-in peripherals and external devices and issues interrupt requests to the TX49/H2 core. It has a 32-bit flag register to generate interrupt requests to external devices or the TX49/H2 core. * * * * Supports 21 internal interrupt sources from built-in peripherals and 8 external interrupt signal inputs 8 interrupt priority levels for each interrupt source Supports selection between edge- and level-triggered interrupt detection for each external interrupt 32-bit read / write flag register for interrupt requests, making it possible to issue interrupt request to external devices and to the TX49/H2 core ( IRC interrupts ) n high-speed serial Concentration Highway Interface ( CHI ) The TX4925 has a high-speed serial Concentration Highway Interface. * * * * Contents logic for interfacing to external full-duplex serial time-division-multiplexed (TDM) communication peripherals Supports ISDN line interface chips and other PCM/TDM serial devices Programmable CHI Interface (numbers of channels, frame rate, bit rate, etc.) supports data rates up to 4.096Mbps n Serial Peripheral Interface ( SPI ) The TX4925 has a Serial Peripheral Interface. * * * full-duplex, synchronous serial data transfers (data in/out, and clock signals) 8-bit or 16-bit data word lengths Programmable SPI baud rate n NAND Flash memory Controller ( NDFMC ) The TX4925 has a NAND Flash memory Controller. * * Controlled NAND Flash I/F by Setting Register Supports ECC (Error Correct Circuit) control flow EJC-TMPR4925XB-8 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE n PCMCIA Interface ( PCMCIA I/F ) The TX4925 has a 2 identical full PCMCIA ports. * * Provide the control signals and accepts the status signals which conform to the PCMCIA version 2.1 standard Appropriate connector keying and level-shifting buffers required for 3.3V versus 5V PCMCIA interface implementations n Real Time Clock ( RTC ) The TX4925 has a Real Time Clock. * * * 44-bit up-counter Interrupts on alarm, timer, and prior to RTC roll-over Date managed by software n Power-down mode The TX4925 contains support for implementation of power-down mode. * * * HALT mode (stopping CPU core clock) for TX49/H2 core block Power-down mode (stopping input clock) for individual internal peripheral modules RF(Reduced Frequency) Function (1/1,1/2,1/4,1/8) n Extended EJTAG Interface The TX4925 contains an Extended Enhanced Joint Test Action Group ( Extended EJTAG ) interface, which provides two functions : JTAG boundary scan test that complies with IEEE1149.1 and real-time debugging using a debug support unit ( DSU ) built into the TX49/H2 core. * * IEEE 1149.1 JTAG Boundary Scan Real-time debugging functions using special emulation probe : execution control ( execution, break, step, and register / memory access ) and PC trace EJC-TMPR4925XB-9 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 3. Pins 3.1 Pin designations A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 A20 B1 B2 B3 B4 B5 B6 B7 B8 B9 PCICLKIO TMS TDI* PIO[26] PIO[24] PIO[27] PIO[22] PIO[19] SDCLKIN* SDCLK[1] SDCLK[0] SDCS [2]* ADDR[18] SADDR10 ADDR[13] ADDR[10] ADDR[8] ADDR[6] SDCS [1]* RAS* PCICLK[1] GNT [0]* TCK TDO PIO[31] PIO[29] PIO[21] PIO[18] PIO[20] B11 B12 B13 B14 B15 B16 B17 B18 B19 B20 C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 C11 C12 C13 C14 C15 C16 C17 C18 C19 SDCS [3]* CKE ADDR[19] ADDR[14] ADDR[12] ADDR[9] ADDR[7] ADDR[5] DQM[3]* SDCS [0]* PCICLK[2] REQ [0]* VDDS VDDC PIO[25] PIO[28] VDDC PIO[23] TRST VDDC SCANENB ADDR[17] ADDR[16] VDDC ADDR[11] VDDC Vss VDDS DQM[2]* D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 D16 D17 D18 D19 D20 E1 E2 E3 E4 E17 E18 E19 E20 F1 GNT [2]* REQ [1]* GNT [1]* Vss VDDC PIO[30] Vss VDDS PON* Vss VDDS Vss VDDS Vss Vss VDDS Vss WE* CAS* DQM[0]* PCIAD[31] REQ [3]* GNT [3]* REQ [2]* Vss VDDS DATA[31] RP* PCIAD[28] F3 F4 F17 F18 F19 F20 G1 G2 G3 G4 G17 G18 G19 G20 H1 H2 H3 H4 H17 H18 H19 H20 J1 J2 J3 J4 J17 J18 J19 PCIAD[30] VDDS Vss DATA[14] DATA[30] DATA[15] PCIAD[26] PCIAD[27] VDDC Vss Vss VDDC DATA[13] DATA[29] C BE[3] PCIAD[24] PCIAD[25] VDDS Vss VDDS DATA[12] DATA[28] PCIAD[22] PCIAD[23] IDSEL Vss Vss VDDC DATA[11] K1 K2 K3 K4 K17 K18 K19 K20 L1 L2 L3 L4 L17 L18 L19 L20 M1 M2 M3 M4 M17 M18 M19 M20 N1 N2 N3 N4 N17 PCIAD[19] PCIAD[20] PCIAD[21] VDDS Vss VDDC DATA[10] DATA[26] PCIAD[17] PCIAD[18] VDDC Vss VDDS DATA[24] DATA[9] DATA[25] FRAME* C BE[2] PCIAD[16] VDDS Vss DATA[7] DATA[23] DATA[8] STOP* DEVSEL* TRDY* IRDY* Vss EJC-TMPR4925XB-10 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE B10 RESET* C20 DQM[1]* F2 PCIAD[29] J20 DATA[27] N18 VDDS EJC-TMPR4925XB-11 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE N19 N20 P1 P2 P3 P4 P17 P18 P19 P20 R1 R2 R3 R4 R17 R18 R19 R20 T1 T2 T3 T4 DATA[6] DATA[22] SERR* PERR* VDDC Vss Vss VDDC DATA[5] DATA[21] PCIAD[15] C BE[1] PAR VDDC Vss DATA[19] DATA[4] DATA[20] PCIAD[12] PCIAD[13] PCIAD[14] VDDS T17 T18 T19 T20 U1 U2 U3 U4 U5 U6 U7 U8 U9 U10 U11 U12 U13 U14 U15 U16 U17 U18 VDDS DATA[2] DATA[18] DATA[3] PCIAD[9] PCIAD[10] PCIAD[11] Vss VDDS BWE [2]* Vss VDDS ROMCE [3] PIO[0] Vss VDDS PIO[6] Vss PIO[7] Vss Vss DATA[16] U19 U20 V1 V2 V3 V4 V5 V6 V7 V8 V9 V10 V11 V12 V13 V14 V15 V16 V17 V18 V19 V20 DATA[1] DATA[17] C BE[0] PCIAD[8] VDDS VDDC BWE [0]* BWE [3]* VDDC ADDR[2] ROMCE [2] PIO[2] VDDC PIO[1] PIO[5] VDDC PIO[13] PIO[16] TEST* VDDS DATA[0] Vss W1 W2 W3 W4 W5 W6 W7 W8 W9 W10 W11 W12 W13 W14 W15 W16 W17 W18 W19 W20 Y1 Y2 PCIAD[4] PCIAD[5] PCIAD[6] PCIAD[7] BWE [1]* UAE ADDR[0] ADDR[3] ADDR[15] ROMCE [1] PIO[4] PIO[3] PIO[10] PIO[9] PIO[17] PIO[15] NMI* C32KOUT PLLVDD MSTRCLK PCIAD[0] PCIAD[1] Y3 Y4 Y5 Y6 Y7 Y8 Y9 Y10 Y11 Y12 Y13 Y14 Y15 Y16 Y17 Y18 Y19 Y20 PCIAD[2] PCIAD[3] SYSCLK* SWE* ADDR[1] ADDR[4] OE* ROMCE [0] BUSSPRT* ACK* PIO[11] PIO[8] PIO[12] PIO[14] BC32K C32KIN PLLVSS Vss EJC-TMPR4925XB-12 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 3.2 Pin layout A 20 RAS* B SDCS [0]* C DQM[1]* DQM[2]* VDDS Vss VDDC ADDR[11] VDDC ADDR[16] ADDR[17] D DQM[0]* CAS* WE* Vss VDDS Vss Vss VDDS Vss RP* E F DATA[15] DATA[30] DATA[14] Vss G DATA[29] DATA[13] VDDC Vss H DATA[28] DATA[12] VDDS Vss J DATA[27] DATA[11] VDDC Vss K DATA[26] DATA[10] VDDC Vss 19 SDCS [1]* DQM[3]* 18 ADDR[6] 17 ADDR[8] 16 ADDR[10] 15 ADDR[13] ADDR[5] ADDR[7] ADDR[9] ADDR[12] DATA[31] VDDS Vss 14 SADDR10 ADDR[14] 13 ADDR[18] ADDR[19] 12 SDCS [2]* CKE 11 SDCLK[0] 10 SDCLK[1] 9 SDCLKIN* 8 PIO[19] 7 PIO[22] 6 PIO[27] 5 PIO[24] 4 PIO[26] 3 TDI* 2 TMS 1 PCICLKIO SDCS [3]* RESET* PIO[20] PIO[18] PIO[21] PIO[29] PIO[31] TDO TCK GNT [0]* PCICLK[1] SCANENB VDDS VDDC TRST PIO[23] VDDC PIO[28] PIO[25] VDDC VDDS REQ [0]* PCICLK[2] Vss PON* VDDS Vss PIO[30] VDDC Vss GNT [1]* REQ [1]* GNT [2]* TOP View REQ [2]* GNT [3]* REQ [3]* PCIAD[31] VDDS PCIAD[30] PCIAD[29] PCIAD[28] Vss VDDC PCIAD[27] PCIAD[26] VDDS PCIAD[25] PCIAD[24] C BE[3] Vss IDSEL PCIAD[23] PCIAD[22] VDDS PCIAD[21] PCIAD[20] PCIAD[19] EJC-TMPR4925XB-13 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE L DATA[25] DATA[9] DATA[24] VDDS M DATA[8] DATA[23] DATA[7] Vss N DATA[22] DATA[6] VDDS Vss P DATA[21] DATA[5] VDDC Vss R DATA[20] DATA[4] DATA[19] Vss T DATA[3] DATA[18] DATA[2] VDDS U DATA[17] DATA[1] DATA[16] Vss Vss PIO[7] Vss PIO[6] VDDS Vss PIO[0] Vss V W MSTRCLK PLLVDD C32KOUT NMI* PIO[15] PIO[17] PIO[9] PIO[10] PIO[3] PIO[4] Vss Y 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 DATA[0] VDDS TEST* PIO[16] PIO[13] VDDC PIO[5] PIO[1] VDDC PIO[2] PLLVSS C32KIN BC32K PIO[14] PIO[12] PIO[8] PIO[11] ACK* BUSSPRT* ROMCE [1] ROMCE [0] OE* ADDR[4] ADDR[1] SWE* SYSCLK* PCIAD[3] PCIAD[2] PCIAD[1] PCIAD[0] ROMCE [3] ROMCE [2] ADDR[15] VDDS Vss ADDR[2] VDDC ADDR[3] ADDR[0] UAE BWE [1]* PCIAD[7] PCIAD[6] PCIAD[5] PCIAD[4] BWE [2]* BWE [3]* TOP View Vss VDDC PCIAD[18] PCIAD[17] VDDS PCIAD[16] C BE[2] FRAME* IRDY* TRDY* DEVSEL* STOP* Vss VDDC PERR* SERR* VDDC PAR C BE[1] PCIAD[15] VDDS PCIAD[14] PCIAD[13] PCIAD[12] VDDS Vss PCIAD[11] PCIAD[10] PCIAD[9] BWE [0]* VDDC VDDS PCIAD[8] C BE[0] EJC-TMPR4925XB-14 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 3.3 Pin signal description Note: In the I/O columns, "PU" indicates an I/O pin with a pull-up resistor, and the term "PD" indicates an I/O pin with a pull-down resistor. * denotes an active-low signal when used as a suffix to a signal name. Common Memory Interface Signal Name ADDR[19:0] Type Input/ou tput PU Function Address Address signals. For SDRAM, ADDR[19:16 , 14:5] and SADDR10 are used. When the external bus controller uses these pins, the meaning of each bit varies with the data bus width. The ADDR signals are also used as boot configuration signals (input) during a reset. For details of configuration signals. The ADDR signals are input signals only when the RESET* signal is asserted and become output signals after the RESET* signal is deasserted. Address10 for SDRAM. Address single for SDRAM. This signal is also used as a boot configuration input signal for testing. Because this signal is used for testing, ensure that it will not pulled Low during a reset sequence. For details of configuration signals. This signal is used as an input signal while the RESET* signal is asserted. It becomes an output signal once the RESET* signal has been deasserted. Data 32-bit data bus Bus Separate Controls the connection and separation of devices controlled by the external bus controller to or from a high-speed device, such as SDRAM. H: Separate devices other than SDRAM from the data bus. L: Connect devices other than SDRAM to the data bus. Separation and connection are performed using external bidirectional bus buffers (such as the 74xx245). This signal can control either the QuickSwitch or 74xx245. These devices differ in that the signal is also pulled Low during a write cycle with the QuickSwitch. Boot configuration signal ADDR[19] determines w hich device is used. For details of configuration signals. Initial State Input SADDR10 Input/ou tput PU Input DATA[31:0] BUSSPRT* Input/ou tput PU Output Input High EJC-TMPR4925XB-15 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE SDRAM / SyncFlash Memory Interface Signal Name SDCLK[1:0] Type Output Function SDRAM Controller Clock Clock signals used by SDRAM/SyncFlash. The clock frequency is the same as the G-Bus clock (GBUSCLK) frequency. When these clock signals are not used, the pins can be set to L using the SDCLK Enable field of the pin configuration register (PCFG.SDCLKEN[1:0]). SDRAM Feedback Clock input Feedback clock signal for SDRAM controller input signals. Clock Enable CKE signal for SDRAM/SyncFlash. Synchronous Memory Device Chip Select Chip select signals for SDRAM/SyncFlash. Row Address Strobe RAS signal for SDRAM/SyncFlash. Column Address Strobe CAS signal for SDRAM/SyncFlash. Write Enable WR signal for SDRAM/SyncFlash. Data Mask During a write cycle, the DQM signals function as a data mask. During a read cycle, they control the SDRAM output buffers. The bits correspond to the following data bus signals: DQM[3]:DATA[31:24], DQM[2]:DATA[23:16] DQM[1]:DATA[15:8], DQM[0]:DATA[7:0] Initialize/Power Down RP* signal for SyncFlash. Initial State All High SDCLKIN CKE SDCS[3:0]* RAS* CAS* WE* DQM[3:0] Input/out put Output Output Output Output Output Output Input High All High High High High All High RP* Output Low EJC-TMPR4925XB-16 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE External Bus Interface Signal Name SYSCLK Type Output Function System Clock Clock for external I/O devices. Outputs a clock in full speed mode (at the same frequency as the G-Bus clock (GBUSCLK) frequency), half speed mode (at one half the GBUSCLK frequency), third speed mode (at one third the GBUSCLK frequency), or quarter speed mode (at one quarter the GBUSCLK frequency). The boot configuration signals on the ADDR[4:3] pins select which speed mode will be used. When this clock signal is not used, the pin can be set to L using the SYSCLK Enable bit of the configuration register (PCFG.SYSCLKEN). Upper Address Enable Latch enable signal for the high-order address bits of ADDR. The enable polarity can be selected. This signal is also used as a boot configuration input signal for testing. Because this signal is used for testing, ensure that it will not pulled Low during a reset sequence. For details of configuration signals. This signal is used as an input signal while the RESET* signal is asserted. It becomes an output signal once the RESET* signal has been deasserted. Chip Enable Chip select signals for ROM, SRAM, and I/O devices. The pins are shared with other functions. Chip Enable Chip select signals for ROM, SRAM, and I/O devices. Output Enable Output enable signal for ROM, SRAM, and I/O devices. Write Enable Write enable signal for SRAM and I/O devices. Byte Enable/Byte Write Enable BE[3:0]* indicate a valid data position on the data bus DATA[31:0] during read and write bus operation. In 16-bit bus mode, only BE[1:0]* are used. In 8-bit bus mode, only BE[0]* is used. BWE[3:0]* indicate a valid data position on the data bus DATA[31:0] during write bus operation. In 16-bit bus mode, only BWE[1:0]* are used. In 8-bit bus mode, only BWE[0]* is used. The following shows the correspondence between BE[3:0]*/BWE[3:0]* and the data bus signals. BE[3]*/BWE[3]*: DATA[31:24] BE[2]*/BWE[2]*: DATA[23:16] BE[1]*/BWE[1]*: DATA[15:8] BE[0]*/BWE[0]*: DATA[7:0] The boot configuration signal on the ADDR[11] pin and the EBCCRn.BC bit of the external bus controller determine whether the signals are used as BE[3:0]* or BWE[3:0]*. Data Acknowledge/Ready Flow control signal. Initial State High UAE Output PU Input CE[5:4]* Output PU Output Output Output Output All High CE[3:0]* OE* SWE* BWE[3:0]* /BE[3:0]* All High High High All High ACK*/ READY Input/out put PU Input EJC-TMPR4925XB-17 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE Signal Name CARD1CSH* CARD1CSL* CARD2CSH* CARD2CSL* CARDREG* Type Output PU Output PU Output PU Output PU Output PU Output PU Function PCMCIA card slot 1 chip select Chip select signals for PCMCIA card slot 1. The pins are shared with other functions. PCMCIA card slot 2 chip select Chip select signals for PCMCIA card slot 2. The pins are shared with other functions. PCMCIA card register REG* signal for a PCMCIA card. The pin is shared with other functions. PCMCIA card I/O read IORD* signal for a PCMCIA card. The pin is shared with other functions. PCMCIA card I/O write IOWR* signal for a PCMCIA card. The pin is shared with other functions. PCMCIA card directory Controls the direction of the bidirectional buffer used for a PCMCIA slot. This signal is asserted during a read transaction when any of CARD2CSH*, CARD2CSL*, CARD1CSH* and CARD1CSL* are asserted. The pin is shared with other functions. PCMCIA card slot 1 wait Card wait signal from PCMCIA card slot 1. The pin is shared with other functions. PCMCIA card slot 2 wait Card wait signal from PCMCIA card slot 2. The pin is shared with other functions. Initial State PIO input PIO input PIO input CARDIORD* PIO input CARDIOWR* PIO input CARDDIR* PIO input CARD1WAIT* Input PU Input PU PIO input CARD2WAIT* PIO input EJC-TMPR4925XB-18 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE DMA Interface Signal Name DMAREQ [1:0] Type Input PU Output Function DMA Request DMA transfer request signals from an external I/O device. The pins are shared with other functions. DMA Acknowledge DMA transfer acknowledge signals to an external I/O device. The pins are shared with other functions. DMA Done DMADONE* is either used as an output signal that reports the termination of DMA transfer or as an input signal that causes DMA transfer to terminate. The pin is shared with other functions. Initial State PIO input DMAACK [1:0] PIO input DMADONE* Input/out put PU PIO input PCI Interface Signal Name PCICLK [2:1] Type Output Function PCI Clock PCI bus clock signals. A boot configuration signal (ADDR[18]) can determine whether the clock internally generated in the TX4925 is used as PCICLK. If the TX4925 internal clock is selected, the clock signals are output from these pins. When these clock signals are not used, the pins can be set to Hi-Z using the PCICLK Enable field of the pin configuration register (PCFG.PCICLKEN[2:1]). PCI Feedback Clock PCI feedback clock input. A boot configuration signal (ADDR[18]) can determine whether the clock internally generated in the TX4925 is used as PCICLK. If the TX4925 internal clock is selected, the clock signals are output and simultaneously fed back to the internal PCI block. When using the PCI block, therefore, do not set the PCICLK Enable field of the pin configuration register (PCFG.PCICLKIOEN) to 0. PCI Address and Data Multiplexed address and data bus. Command and Byte Enable Command and byte enable signals. Parity Even parity signal for PCIAD[31:0] and C_BE[3:0]*. Cycle Frame Indicates that bus operation is in progress. Initiator Ready Indicates that the initiator is ready to complete data transfer. Target Ready Indicates that the target is ready to complete data transfer. Stop The target sends this signal to the initiator to request termination of data transfer. Initial State Selected by ADDR[18] H: High L: L PCICLKIO Input/out put Selected by ADDR[18] H: High L: Input PCIAD [31:0] C_BE [3:0] PAR FRAME* IRDY* TRDY* STOP* Input/out put Input/out put Input/out put Input/out put Input/out put Input/out put Input/out put Input Input Input Input Input Input Input EJC-TMPR4925XB-19 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE Signal Name ID_SEL DEVSEL* REQ [3:2] * Type Input Input/out put Input Function Initialization Device Select Chip select signal used for configuration access. Device Select The target asserts this signal in response to access from the initiator. Request Signals used by the master to request bus mastership. The boot configuration signal on the ADDR[1] pin determines whether the built-in PCI bus arbiter is used. In internal arbiter mode, REQ[3:2]* are PCI bus request input signals. In external arbiter mode, REQ[3:2]* are not used. Because the pins are still placed in the input state, they must be pulled up externally. Request Signal used by the master to request bus mastership. The boot configuration signal on the ADDR[1] pin determines whether the built-in PCI bus arbiter is used. In internal arbiter mode, this signal is a PCI bus request input signal. In external arbiter mode, this signal is an external interrupt output signal (INTOUT). Request Signal used by the master to request bus mastership. The boot configuration signal on the ADDR[1] pin determines whether the built-in PCI bus arbiter is used. In internal arbiter mode, this signal is a PCI bus request input signal. In external arbiter mode, this signal is a PCI bus request output signal. Grant Indicates that bus mastership has been granted to the PCI bus master. The boot configuration signal on the ADDR[1] pin determines whether the built-in PCI bus arbiter is used. In internal arbiter mode, all of GNT[3:0]* are PCI bus grant output signals. In external arbiter mode, GNT[0]* is a PCI bus grant input signal. Because GNT[3:1]* also become input signals, they must be pulled up externally. Data Parity Error Indicates a data parity error in a bus cycle other than special cycles. System Error Indicates an address parity error, a data parity error in a special cycle, or a fatal error. In host mode, SERR* is an input signal. In satellite mode, SERR* is an open-drain output signal. The mode is determined by the boot configuration signal on the ADDR[19] pin. Initial State Input Input Input REQ [1] * Input/out put/OD Selected by ADDR[1] H: Input L: Hi-Z Selected by ADDR[1] H: Input L: High Selected by ADDR[1] H: All High L: Input REQ [0] * Input/out put GNT [3:0] * Input/out put PERR* SERR* Input/out put Input/OD Input Input EJC-TMPR4925XB-20 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE SIO Interface Signal Name CTS [1:0]* Type Input PU*1 Output PU*1 Input PU*1 3-state Output PU*1 Input PU *1: Function SIO Clear to Send CTS* signals. The pins are shared with other functions. SIO Request to Send RTS* signals. The pins are shared with other functions. SIO Receive Data Serial data input signals. The pins are shared with other functions. SIO Transmit Data Serial data output signals. The pins are shared with other functions. External Serial Clock SIO clock input signal. SIO0 and SIO1 share this signal. The pin is shared with other functions. Initial State PIO input RTS [1:0]* PIO input RXD[1:0] PIO input TXD[1:0] PIO input SCLK PIO input These signals are pulled up for channel 0 only. No pull-up resistor is provided for channel 1. Timer Interface Signal Name TIMER[1:0] Type Output PU Input PU Function Timer Output Timer output signals. The pins are shared with other functions. External Timer Clock Timer input clock signal. TMR0, TMR1, and TMR2 share this signal. The pin is shared with other functions. Initial State PIO input TCLK PIO input PIO Interface Signal Name PIO[31:20] Type Input/out put PU Function PIO Ports[31:20] Parallel I/O signals. The pins are shared with other functions, including PC trace. The boot configuration signal on the TDO pin determines whether the signals are used for PC trace. Initial State Selected by TDO H: PIO input L: Output (PC trace function) Input PIO[19:0] Input/out put PU*1 *1: PIO Ports[19:0] Parallel I/O signals. The pins are shared with other functions. PIO[17:12] do not have pull-up resistors. EJC-TMPR4925XB-21 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE AC Link Interface Signal Name ACRESET* SYNC SDOUT SDIN]1] SDIN[0] BITCLK Type Output Output Output Input Input Input Function AC '97 Master H/W Reset The pin is shared with other functions. 48 kHz Fixed Rate Sample Sync The pin is shared with other functions. Serial, Time Division Multiplexed, AC '97 Output Stream The pin is shared with other functions. Serial, Time Division Multiplexed, AC `97 Input Stream The pin is shared with other functions. Serial, Time Division Multiplexed, AC '97 Input Stream The pin is shared with other functions. 12.288 MHz Serial Data Clock The pin is shared with other functions. Initial State PIO input PIO input PIO input PIO input PIO input PIO input Interrupt Signals Signal Name NMI* INT[7:0]* Type Input PU Input PU Function Non-Maskable Interrupt Non-maskable interrupt signal. External Interrupt Requests External interrupt request signals. The pins are shared with other functions. Initial State Input PIO input EJC-TMPR4925XB-22 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE CHI Interface Signal Name CHIFS Type Input/out put PU Function CHI Frame synchronization CHI frame synchronization signal. This pin can be used in either output or input mode. In output mode, the pin allows the TX4925 to become the master CHI synchronization source. In input mode, the pin allows the external peripheral device to become the master CHI synchronization source. In that case, the TX4925 CHI module becomes a slave for external synchronization. The pin is shared with other functions. CHI Clock CHI clock signal. This pin can be used in either output or input mode. In output mode, the pin allows the TX4925 to become the master CHI clock source. In input mode, the pin allows the external peripheral device to become the master CHI clock source. In that case, the TX4925 CHI module becomes a slave for the external clock. The pin is shared with other functions. CHI Data Output CHI serial data output signal. The pin is shared with other functions. CHI Data Input CHI serial data input signal. The pin is shared with other functions. Initial State PIO input CHICLK Input/out put PU PIO input CHIDOUT Output PU Input PU PIO input CHIDIN PIO input SPI Interface Signal Name SPICLK Type Output PU Output PU Input PU Function SPI Clock This pin is used for a data clock to or from an SPI slave device. The pin is shared with other functions. SPI Data Output This signal contains data to be shifted to an SPI slave device. The pin is shared with other functions. SPI Data Input This signal contains data to be shifted from an SPI slave device. The pin is shared with other functions. Initial State PIO input SPIOUT PIO input SPIIN PIO input EJC-TMPR4925XB-23 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE NAND Flash Memory Interface Signal Name ND_ALE Type Output Function NAND Flash Address Latch Enable ALE signal for NAND flash memory. The pin is shared with other functions. NAND Flash Command Latch Enable CLE signal for NAND flash memory. The pin is shared with other functions. NAND Flash Chip Enable CE signal for NAND flash memory. The pin is shared with other functions. NAND Flash Read Enable RE signal for NAND flash memory. The pin is shared with other functions. NAND Flash Write Enable WE signal for NAND flash memory. The pin is shared with other functions. NAND Flash Ready/Busy Ready/Busy signal for NAND flash memory. The pin is shared with other functions. Initial State PIO input ND_CLE Output PIO input ND_CE* Output PIO input ND_RE* Output PIO input ND_WE* Output PIO input ND_R/B* Input PIO input EJC-TMPR4925XB-24 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE EJTAG Interface Signal Name TCK Type Input PU Input PU Function JTAG Test Clock Input Clock input signal for JTAG. TCK is used to execute JTAG instructions and input/output data. JTAG Test Data Input/Debug Interrupt When PC trace mode is not selected, this signal is a JTAG data input signal. It is used to input serial data to JTAG data/instruction registers. When PC trace mode is selected, this signal is an interrupt input signal used to cancel PC trace mode for the debug unit. JTAG Test Data Output/PC Trace Output When PC trace mode is not selected, this signal is a JTAG data output signal. Data is output by means of serial scan. When PC trace mode is selected, this signal outputs the value of the noncontiguous program counter in sync with the debug clock (DCLK). PC Trace Output TPC[3:1] output the value of the noncontiguous program counter in sync with DCLK. The pins are shared with other functions. Initial State Input TDI/DINT* Input TDO/TPC[0] Output Input TPC[3:1] Output TMS TRST* Input PU Input DCLK Output PCST[8:0] Output JTAG Test Mode Select Input TMS mainly controls state transition in the TAP controller state machine. Test Reset Input Asynchronous reset input for the TAP controller and debug support unit (DSU). When an EJTAG probe is not connected, this pin must be fixed to low. When connecting an EJTAG probe, prevent floating, for example, by connecting a pull-up resistor. When this signal is deasserted, G-Bus timeout detection is disabled. Debug Clock Clock output signal for the real-time debugging system. When PC trace mode is selected, the TPC[3:1] and PCST signals are output synchronously. This clock is the TX49/H2 core operating clock (CPUCLK) divided by 3. The pin is shared with other functions. PC Trace Status Information Outputs PC trace status and other information. The pins are shared with other functions. Selected by TDO H: PIO input L: All High Input Input Selected by TDO H: PIO input L: Low Selected by TDO H: PIO input (PCST[8:1 ]) BC32K(PC ST[0]) L: All Low EJC-TMPR4925XB-25 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE Clock signals Signal Name MASTERCLK Type Input Function Master Clock Input pin for the TX4925 operating clock. A crystal resonator cannot be connected to this pin because the pin does not contain an oscillator. 32 KHz Crystal Input Connect this pin and C32KOUT to a 32.768 kHz crystal. 32 KHz Crystal output Connect this pin and C32KIN to a 32.768 kHz crystal. Buffer output of 32 KHz Crystal Buffer output for a 32.768 kHz clock. Initial State Input C32KIN C32KOUT BC32K Input Output Output PU Input Output Selected by TDO H: Output (BC32K) L: Low Reset signals Signal Name RESET* PON* Type Input SMT Input SMT Reset Reset signal. Power On Reset Initializes the CG. For timing. Function Initial State Input Input Test Signals Signal Name TEST* SCANENB* Type Input Input Function Test Mode Setting Test pin. This pin must be fixed to High. Scan Mode Test Control Test pin. This pin must be fixed to High. Initial State Input Input EJC-TMPR4925XB-26 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE Power Supply Pins Signal Name PLL1VDD_A Type Function PLL Power Pins PLL analog power supply pins. PLL1VDD_A = 1.5 V PLL Ground Pins PLL analog ground pins. PLL1VSS_A = 0 V Internal Power Pins Digital power supply pins for internal logic. VccInt = 1.5 V. I/O Power Pins Digital power supply pins for input/output pins. VccIO = 3.3 V. Ground Pins Digital ground pins. Vss = 0 V. Initial State - PLL1VSS_A - - VccInt VccIO Vss - - EJC-TMPR4925XB-27 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 4. Pin Multiplexing A total of 33 pins of the TX4925 have multiplexed functions. Table 4.1 shows the multiplexed pins. The function of a given pin is selected in various ways, depending on the pin(s) involved. Table 4.1 Pin Multiplexing Pin num Signal name PIO[31] PIO[30] PIO[29] PIO[28] PIO[27] PIO[26] PIO[25] PIO[24] PIO[23] PIO[22] PIO[21] PIO[20] PIO[19] PIO[18] PIO[17] PIO[16] PIO[15] PIO[14] PIO[13] PIO[12] PIO[11] PIO[10] PIO[9] PIO[8] PIO[7] PIO[6] PIO[5] PIO[4] PIO[3] PIO[2] PIO[1] PIO[0] BC32K BE[3]*/BWE[3]* BE[2]*/BWE[2]* *6 *6 Multiplexed Function PIO[31] / CADDIR* / BCLK / TPC[2] PIO[30] / CARDREG* / PCST[8] PIO[29] / CARD2CSH* / CE5* / INT[7] *2 / PCST[6] PIO[28] / CARD2CSL* / CE4* / INT[6] *2 / PCST[7] PIO[27] / CARD2WAIT* *3 / CHIOUT / PCST[5] PIO[26] / CARD1CSH* / DCLK PIO[25] / CARD1CSL* / TPC[3] PIO[24] / CARD1WAIT* *3 / TPC[1] PIO[23] / SPICLK / PCST[2] PIO[22] / SPIIN / PCST[3] PIO[21] / SPIOUT / PCST[4] PIO[20] / TIMER[0] / CHIFS / PCST[1] PIO[19] / TIMER[1] / CHICLK PIO[18] / TCLK *4 / CHIDIN PIO[17] / AC_SDIN[0] / ND_WE* / TXD[1] PIO[16] / AC_SDOUT / ND_RB* / RXD[1] PIO[15] / AC_BITCLK / ND_CLE / RTS[1] / INT[5] *2 PIO[14] / AC_SYNC / ND_RE* / CTS[1] / INT[4] *2 PIO[13] / AC_SDIN[1] / ND_ALE PIO[12] / AC_RST* / ND_CE* PIO[11] / TXD[0] PIO[10] / RXD[0] PIO[9] / RTS [0] * / INT[3] *2 PIO[8] / CTS [0] * / INT[2] *2 PIO[7] / INT[1] *2 PIO[6] / INT[0] *2 PIO[5] / SCLK *5 PIO[4] *1 / DMAACK[1] PIO[3] / DMAREQ[1] PIO[2] *1 / DMAACK[0] PIO[1] / DMAREQ[0] PIO[0] *1 / DMADONE PCST[0] CARDIOWR* CARDIORD* *6 *6 EJC-TMPR4925XB-28 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE Note 1 : PIO[4], PIO[2], and PIO[0] are only input ports. Note 2 : Not enable the interrupt in IRC if these signals are used other function because INT[7:0] are directly connected to IRC. Note 3 : CARD1WAIT* and CARD2WAIT* are directly connected to PCMCIA controller. So PCFG register has not the control bit that be enable CADRWAIT* and CARD2WAIT* function. Note 4 : TCLK are directly connected to Timer ch0, ch1 and ch2. Thus, Timer should not enable the use of external clock unless that is the desired function of this pin. Note 5 : SCLK are directly connected to SIO ch0 and ch1. Thus, SIO should not enable the use of external clock unless that is the desired function of this pin. Note 6 : BE[3]*/BWE[3]* operates as CARDIOWR* when TX4925 access to PCMCIA device, and as BE[3]*/BWE[3]* when it access to any other devices. BE[2]*/BWE[2]* operates as CARDIORD* when TX4925 access to PCMCIA device, and as BE[2]*/BWE[2]* when it access to any other devices, too. EJC-TMPR4925XB-29 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 5. ELECTRICAL CHARACTERISTICS T.B.D EJC-TMPR4925XB-30 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 6. Package Package type (Package code) : 256-pin PBGA / PBGA[4L] (P-BGA256-2727-1.27A4) Reference symbol A A1 A2 b c D D1 E E1 e s aaa min. 2.20 0.5 0.60 26.8 26.8 typ. 2.33 0.6 1.17 0.75 0.56 27.0 24.13 27.0 24.13 1.27 0.635 0.15 max. 2.46 0.7 0.90 27.2 27.2 EJC-TMPR4925XB-31 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION INTEGRATED CIRCUIT TOSHIBA RISC PROCESSOR TMPR4925XB TENTATIVE 7. HISTORY -19/Feb/01 -10/Apl/01 -18/Apl/01 -21/May/01 -29/Aug/01 -26/Dec/01 (Rev 0.1) The first edition Modify the description for all Add the Clock Signals in 3.1 Pin signal description Add the export regulation on first page Add the 3.1 Pin designations and 3.2 Pin layout Modify the description for all EJC-TMPR4925XB-32 26/Dec/01 Rev 0.1 TOSHIBA CORPORATION |
Price & Availability of TMPR4925XB
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |