RC32434 IDTTM InterpriseTM Integrated Communications Processor Device Overview PCI Interface – 32-bit PCI revision 2.2 compliant – Supports host or satellite operation in both master and target modes – Support for synchronous and asynchronous operation – PCI clock supports frequencies from 16 MHz to 66 MHz – PCI arbiter in Host mode: supports 6 external masters, fixed priority or round robin arbitration – I2O “like” PCI Messaging Unit ◆ Ethernet Interface – 10 and 100 Mb/s ISO/IEC 8802-3:1996 compliant – Supports MII or RMII PHY interface – Supports 64 entry hash table based multicast address filtering – 512 byte transmit and receive FIFOs – Supports flow control functions outlined in IEEE Std. 802.3x1997 ◆ DDR Memory Controller – Supports up to 256MB of DDR SDRAM – 1 chip select supporting 4 internal DDR banks – Supports a 16-bit wide data port using x8 or x16 bit wide DDR SDRAM devices – Supports 64 Mb, 128 Mb, 256 Mb, 512 Mb, and 1Gb DDR SDRAM devices – Data bus multiplexing support allows interfacing to standard DDR DIMMs and SODIMMs – Automatic refresh generation ◆ The RC32434 is a member of the IDT™ Interprise™ family of PCI integrated communications processors. It incorporates a high performance CPU core and a number of on-chip peripherals. The integrated processor is designed to transfer information from I/O modules to main memory with minimal CPU intervention, using a highly sophisticated direct memory access (DMA) engine. All data transfers through the RC32434 are achieved by writing data from an on-chip I/O peripheral to main memory and then out to another I/O module. Features ◆ 32-bit CPU Core – MIPS32 instruction set – Cache Sizes: 8KB instruction and data caches, 4-Way set associative, cache line locking, non-blocking prefetches – 16 dual-entry JTLB with variable page sizes – 3-entry instruction TLB – 3-entry data TLB – Max issue rate of one 32x16 multiply per clock – Max issue rate of one 32x32 multiply every other clock – CPU control with start, stop, and single stepping – Software breakpoints support – Hardware breakpoints on virtual addresses – ICE Interface that is compatible with v2.5 of the EJTAG Specification Block Diagram MII/RMII MIPS-32 CPU Core ICE EJTAG MMU D. Cache I. Cache Interrupt Controller I2C Bus : : I2C Controller 1 Ethernet 10/100 Interface 3 Counter Timers DMA Controller PMBus DDR (16-bit) IPBusTM DDR Controllers Memory & I/O Controller Bus/System Integrity Monitor Memory & Peripheral Bus (8-bit) 1 UART (16550) Serial Channel GPIO Interface GPIO Pins Arbiter SPI Controller SPI Bus PCI Master/Target Interface PCI Arbiter (Host Mode) PCI Bus IDT and the IDT logo are trademarks of Integrated Device Technology, Inc. 1 of 53 2005 Integrated Device Technology, Inc. January 19, 2006 DSC 6214 IDT RC32434 Memory and Peripheral Device Controller – Provides “glueless” interface to standard SRAM, Flash, ROM, dual-port memory, and peripheral devices – Demultiplexed address and data buses: 8-bit data bus, 26-bit address bus, 4 chip selects, control for external data bus buffers Automatic byte gathering and scattering – Flexible protocol configuration parameters: programmable number of wait states (0 to 63), programmable postread/postwrite delay (0 to 31), supports external wait state generation, supports Intel and Motorola style peripherals – Write protect capability per chip select – Programmable bus transaction timer generates warm reset when counter expires – Supports up to 64 MB of memory per chip select ◆ DMA Controller – 6 DMA channels: two channels for PCI (PCI to Memory and Memory to PCI), two channels for the Ethernet interface, and two channels for memory to memory DMA operations – Provides flexible descriptor based operation – Supports unaligned transfers (i.e., source or destination address may be on any byte boundary) with arbitrary byte length ◆ Universal Asynchronous Receiver Transmitter (UART) – Compatible with the 16550 and 16450 UARTs – 16-byte transmit and receive buffers – Programmable baud rate generator derived from the system clock – Fully programmable serial characteristics: – 5, 6, 7, or 8 bit characters – Even, odd or no parity bit generation and detection – 1, 1-1/2 or 2 stop bit generation – Line break generation and detection – False start bit detection – Internal loopback mode ◆ 2 I C-Bus – Supports standard 100 Kbps mode as well as 400 Kbps fast mode – Supports 7-bit and 10-bit addressing – Supports four modes: master transmitter, master receiver, slave transmitter, slave receiver ◆ Additional General Purpose Peripherals – Interrupt controller – System integrity functions – General purpose I/O controller – Serial peripheral interface (SPI) ◆ Counter/Timers – Three general purpose 32-bit counter timers – Timers may be cascaded – Selectable counter/timer clock source ◆ JTAG Interface – Compatible with IEEE Std. 1149.1 - 1990 ◆ CPU Execution Core Core The 32-bit CPU core is 100% compatible with the MIPS32 instruction set architecture (ISA). Specifically, this device features the 4Kc CPU core developed by MIPS Technologies Inc. (www.mips.com). This core issues a single instruction per cycle, includes a five stage pipeline and is optimized for applications that require integer arithmetic. The CPU core includes 8 KB instruction and 8 KB data caches. Both caches are 4-way set associative and can be locked on a per line basis, which allows the programmer control over this precious on-chip memory resource. The core also features a memory management unit (MMU). The CPU core also incorporates an enhanced joint test access group (EJTAG) interface that is used to interface to in-circuit emulator tools, providing access to internal registers and enabling the part to be controlled externally, simplifying the system debug process. The use of this core allows IDT's customers to leverage the broad range of software and development tools available for the MIPS architecture, including operating systems, compilers, and in-circuit emulators. PCI Interface The PCI interface on the RC32434 is compatible with version 2.2 of the PCI specification. An on-chip arbiter supports up to six external bus masters, supporting both fixed priority and rotating priority arbitration schemes. The part can support both satellite and host PCI configurations, enabling the RC32434 to act as a slave controller for a PCI add-in card application or as the primary PCI controller in the system. The PCI interface can be operated synchronously or asynchronously to the other I/O interfaces on the RC32434 device. Ethernet Interface The RC32434 has one Ethernet Channel supporting 10Mbps and 100Mbps speeds to provide a standard media independent interface (MII or RMII), allowing a wide range of external devices to be connected efficiently. Double Data Rate Memory Controller The RC32434 incorporates a high performance double data rate (DDR) memory controller which supports x16 memory configurations up to 256MB. This module provides all of the signals required to interface to discrete memory devices, including a chip select, differential clocking outputs and data strobes. Memory and I/ I/O Controller Controller The RC32434 uses a dedicated local memory/IO controller including a de-multiplexed 8-bit data and 26-bit address bus. It includes all of the signals required to interface directly to a maximum of four Intel or Motorola-style external peripherals. 2 of 53 January 19, 2006 IDT RC32434 DMA Controller The DMA controller consists of 6 independent DMA channels, all of which operate in exactly the same manner. The DMA controller off-loads the CPU core from moving data among the on-chip interfaces, external peripherals, and memory. The controller supports scatter/gather DMA with no alignment restrictions, making it appropriate for communications and graphics systems. UART Interface April 19, 2004: Added the I2C feature. In Table 20, pin L1 becomes SDA and pin L2 becomes SCL. May 25, 2004: In Table 9, signals MIIRXCLK and MIITXCLK, the Min and Max values for Thigh/Tlow_9c were changed to 140 and 260 respectively and the Min and Max values for Thigh/Tlow_9d were changed to 14.0 and 26.0 respectively. December 8, 2005: In Table 18, corrected error for Capacitance Max value from 8.0 to 10.5. The RC32434 contains a serial channel (UART) that is compatible with the industry standard 16550 UART. January 19, 2006: Removed all references to NVRAM. I2C Interface The standard I2C interface allows the RC32434 to connect to a number of standard external peripherals for a more complete system solution. The RC32434 supports both master and slave operations. General Purpose I/O Controller The RC32434 has 14 general purpose input/output pins. Each pin may be used as an active high or active low level interrupt or nonmaskable interrupt input, and each signal may be used as a bit input or output port. System Integrity Functions The RC32434 contains a programmable watchdog timer that generates a non-maskable interrupt (NMI) when the counter expires and also contains an address space monitor that reports errors in response to accesses to undecoded address regions. Thermal Thermal Considerations The RC32434 is guaranteed in an ambient temperature range of 0° to +70° C for commercial temperature devices and - 40° to +85° for industrial temperature devices. Revision History Histor y November 3, 2003: Initial publication. Preliminary Information. December 15, 2003: Final version. In Table 7, changed maximum value for Tskew in 266MHz category and changed values for Tdo in all speed grades for signals DDRADDR, etc. In Table 8, changed minimum values in all speed grades for all Tdo signals and for Tsu and Tzd in MDATA[7:0]. In Table 16, added reference to Power Considerations document. In Table 17, added 2 rows under PCI and Notes 1 and 2. January 5, 2004: In Table 19, Pin F6 was changed from Vcc I/O to Vss. In Table 23, pin F6 was deleted from the Vcc I/O row and added to the Vss row. January 27, 2004: In Table 3, revised description for MADDR[3:0] and changed 4096 cycles to 4000 for MADDR[7]. (Note: MADDR was incorrectly labeled as MDATA in previous data sheet.) March 29, 2004: Added Standby mode to Table 16, Power Consumption. 3 of 53 January 19, 2006 IDT RC32434 Pin Description Table The following table lists the functions of the pins provided on the RC32434. Some of the functions listed may be multiplexed onto the same pin. The active polarity of a signal is defined using a suffix. Signals ending with an “N” are defined as being active, or asserted, when at a logic zero (low) level. All other signals (including clocks, buses, and select lines) will be interpreted as being active, or asserted, when at a logic one (high) level. Signal Type Name/Description Memory and Peripheral Bus BDIRN O External Buffer Direction. Controls the direction of the external data bus buffer for the memory and peripheral bus. If the RC32434 memory and peripheral bus is connected to the A side of a transceiver, such as an IDT74FCT245, then this pin may be directly connected to the direction control (e.g., BDIR) pin of the transceiver. BOEN O External Buffer Enable. This signal provides an output enable control for an external buffer on the memory and peripheral data bus. WEN O Write Enables. This signal is the memory and peripheral bus write enable signal. CSN[3:0] O Chip Selects. These signals are used to select an external device on the memory and peripheral bus. MADDR[21:0] O Address Bus. 22-bit memory and peripheral bus address bus. MADDR[25:22] are available as GPIO alternate functions. MDATA[7:0] I/O Data Bus. 8-bit memory and peripheral data bus. During a cold reset, these pins function as inputs that are used to load the boot configuration vector. OEN O Output Enable. This signal is asserted when data should be driven by an external device on the memory and peripheral bus. RWN O Read Write. This signal indicates whether the transaction on the memory and peripheral bus is a read transaction or a write transaction. A high level indicates a read from an external device. A low level indicates a write to an external device. WAITACKN I Wait or Transfer Acknowledge. When configured as wait, this signal is asserted during a memory and peripheral bus transaction to extend the bus cycle. When configured as a transfer acknowledge, this signal is asserted during a transaction to signal the completion of the transaction. DDRADDR[13:0] O DDR Address Bus. 14-bit multiplexed DDR address bus. This bus is used to transfer the addresses to the DDR devices. DDRBA[1:0] O DDR Bank Address. These signals are used to transfer the bank address to the DDRs. DDRCASN O DDR Column Address Strobe. This signal is asserted during DDR transactions. DDRCKE O DDR Clock Enable. The DDR clock enable signal is asserted during normal DDR operation. This signal is negated following a cold reset or during a power down operation. DDRCKN O DDR Negative DDR clock. This signal is the negative clock of the differential DDR clock pair. DDR Bus Table 1 Pin Description (Part 1 of 6) 4 of 53 January 19, 2006 IDT RC32434 Signal Type Name/Description DDRCKP O DDR Positive DDR clock. This signal is the positive clock of the differential DDR clock pair. DDRCSN O DDR Chip Selects. This active low signal is used to select DDR device(s) on the DDR bus. DDRDATA[15:0] I/O DDR Data Bus. 16-bit DDR data bus is used to transfer data between the RC32434 and the DDR devices. Data is transferred on both edges of the clock. DDRDM[1:0] O DDR Data Write Enables. Byte data write enables are used to enable specific byte lanes during DDR writes. DDRDM[0] corresponds to DDRDATA[7:0] DDRDM[1] corresponds to DDRDATA[15:8] DDRDQS[1:0] I/O DDR Data Strobes. DDR byte data strobes are used to clock data between DDR devices and the RC32434. These strobes are inputs during DDR reads and outputs during DDR writes. DDRDQS[0] corresponds to DDRDATA[7:0] DDRDQS[1] corresponds to DDRDATA[15:8] DDRRASN O DDR Row Address Strobe. The DDR row address strobe is asserted during DDR transactions. DDRVREF I DDR Voltage Reference. SSTL_2 DDR voltage reference is generated by an external source. DDRWEN O DDR Write Enable. DDR write enable is asserted during DDR write transactions. PCIAD[31:0] I/O PCI Multiplexed Address/Data Bus. Address is driven by a bus master during initial PCIFRAMEN assertion. Data is then driven by the bus master during writes or by the bus target during reads. PCICBEN[3:0] I/O PCI Multiplexed Command/Byte Enable Bus. PCI commands are driven by the bus master during the initial PCIFRAMEN assertion. Byte enable signals are driven by the bus master during subsequent data phase(s). PCI Bus PCICLK I PCI Clock. Clock used for all PCI bus transactions. PCIDEVSELN I/O PCI Device Select. This signal is driven by a bus target to indicate that the target has decoded the address as one of its own address spaces. PCIFRAMEN I/O PCI Frame. Driven by a bus master. Assertion indicates the beginning of a bus transaction. Negation indicates the last data. PCIGNTN[3:0] I/O PCI Bus Grant. In PCI host mode with internal arbiter: The assertion of these signals indicates to the agent that the internal RC32434 arbiter has granted the agent access to the PCI bus. In PCI host mode with external arbiter: PCIGNTN[0]: asserted by an external arbiter to indicate to the RC32434 that access to the PCI bus has been granted. PCIGNTN[3:1]: unused and driven high. In PCI satellite mode: PCIGNTN[0]: This signal is asserted by an external arbiter to indicate to the RC32434 that access to the PCI bus has been granted. PCIGNTN[3:1]: unused and driven high. PCIIRDYN I/O PCI Initiator Ready. Driven by the bus master to indicate that the current datum can complete. Table 1 Pin Description (Part 2 of 6) 5 of 53 January 19, 2006 IDT RC32434 Signal Type Name/Description PCILOCKN I/O PCI Lock. This signal is asserted by an external bus master to indicate that an exclusive operation is occurring. PCIPAR I/O PCI Parity. Even parity of the PCIAD[31:0] bus. Driven by the bus master during address and write Data phases. Driven by the bus target during the read data phase. PCIPERRN I/O PCI Parity Error. If a parity error is detected, this signal is asserted by the receiving bus agent 2 clocks after the data is received. PCIREQN[3:0] I/O PCI Bus Request. In PCI host mode with internal arbiter: These signals are inputs whose assertion indicates to the internal RC32434 arbiter that an agent desires ownership of the PCI bus. In PCI host mode with external arbiter: PCIREQN[0]: asserted by the RC32434 to request ownership of the PCI bus. PCIREQN[3:1]: unused and driven high. In PCI satellite mode: PCIREQN[0]: this signal is asserted by the RC32434 to request use of the PCI bus. PCIREQN[1]: function changes to PCIIDSEL and is used as a chip select during configuration read and write transactions. PCIREQN[3:2]: unused and driven high. PCIRSTN I/O PCI Reset. In host mode, this signal is asserted by the RC32434 to generate a PCI reset. In satellite mode, assertion of this signal initiates a warm reset. PCISERRN I/O PCI System Error. This signal is driven by an agent to indicate an address parity error, data parity error during a special cycle command, or any other system error. Requires an external pull-up. PCISTOPN I/O PCI Stop. Driven by the bus target to terminate the current bus transaction. For example, to indicate a retry. PCITRDYN I/O PCI Target Ready. Driven by the bus target to indicate that the current data can complete. General Purpose Input/Output GPIO[0] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: U0SOUT Alternate function: UART channel 0 serial output. GPIO[1] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: U0SINP Alternate function: UART channel 0 serial input. GPIO[2] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: U0RTSN Alternate function: UART channel 0 request to send. GPIO[3] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: U0CTSN Alternate function: UART channel 0 clear to send. Table 1 Pin Description (Part 3 of 6) 6 of 53 January 19, 2006 IDT RC32434 Signal Type Name/Description GPIO[4] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: MADDR[22] Alternate function: Memory and peripheral bus address. GPIO[5] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: MADDR[23] Alternate function: Memory and peripheral bus address. GPIO[6] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: MADDR[24] Alternate function: Memory and peripheral bus address. The value of this pin may be used as a counter timer clock input (see Counter Timer Clock Select Register in Chapter 14, Counter/Timers, of the RC32434 User Manual). GPIO[7] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: MADDR[25] Alternate function: Memory and peripheral bus address. The value of this pin may be used as a counter timer clock input (see Counter Timer Clock Select Register in Chapter 14, Counter/Timers, of the RC32434 User Manual). GPIO[8] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: CPU Alternate function: CPU or DMA debug output pin. GPIO[9] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: PCIREQN[4] Alternate function: PCI Request 4. GPIO[10] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: PCIGNTN[4] Alternate function: PCI Grant 4. GPIO[11] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: PCIREQN[5] Alternate function: PCI Request 5. GPIO[12] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: PCIGNTN[5] Alternate function: PCI Grant 5. GPIO[13] I/O General Purpose I/O. This pin can be configured as a general purpose I/O pin. Alternate function pin name: PCIMUINTN Alternate function: PCI Messaging unit interrupt output. I/O Serial Clock. This signal is used as the serial clock output. This pin may be used as a bit input/output port. SPI Interface SCK Table 1 Pin Description (Part 4 of 6) 7 of 53 January 19, 2006 IDT RC32434 Signal Type Name/Description SDI I/O Serial Data Input. This signal is used to shift in serial data. This pin may be used as a bit input/output port. SDO I/O Serial Data Output. This signal is used shift out serial data. SCL I/O I2C Clock. I2C-bus clock. SDA I/O I2C Data Bus. I2C-bus data bus. 2 I C Bus Interface Ethernet Interfaces MIICL I Ethernet MII Collision Detected. This signal is asserted by the ethernet PHY when a collision is detected. MIICRS I Ethernet MII Carrier Sense. This signal is asserted by the ethernet PHY when either the transmit or receive medium is not idle. MIIRXCLK I Ethernet MII Receive Clock. This clock is a continuous clock that provides a timing reference for the reception of data. This pin also functions as the RMII REF_CLK input. MIIRXD[3:0] I Ethernet MII Receive Data. This nibble wide data bus contains the data received by the ethernet PHY. This pin also functions as the RMII RXD[1:0] input. MIIRXDV I Ethernet MII Receive Data Valid. The assertion of this signal indicates that valid receive data is in the MII receive data bus. This pin also functions as the RMII CRS_DV input. MIIRXER I Ethernet MII Receive Error. The assertion of this signal indicates that an error was detected somewhere in the ethernet frame currently being sent in the MII receive data bus. This pin also functions as the RMII RX_ER input. MIITXCLK I Ethernet MII Transmit Clock. This clock is a continuous clock that provides a timing reference for the transfer of transmit data. MIITXD[3:0] O Ethernet MII Transmit Data. This nibble wide data bus contains the data to be transmitted. This pin also functions as the RMII TXD[1:0] output. MIITXENP O Ethernet MII Transmit Enable. The assertion of this signal indicates that data is present on the MII for transmission. This pin also functions as the RMII TX_EN output. MIITXER O Ethernet MII Transmit Coding Error. When this signal is asserted together with MIITXENP, the ethernet PHY will transmit symbols which are not valid data or delimiters. MIIMDC O MII Management Data Clock. This signal is used as a timing reference for transmission of data on the management interface. MIIMDIO I/O MII Management Data. This bidirectional signal is used to transfer data between the station management entity and the ethernet PHY. EJTAG / JTAG JTAG_TMS I JTAG Mode. The value on this signal controls the test mode select of the boundary scan logic or JTAG Controller. When using the EJTAG debug interface, this pin should be left disconnected (since there is an internal pull-up) or driven high. Table 1 Pin Description (Part 5 of 6) 8 of 53 January 19, 2006 IDT RC32434 Signal Type Name/Description EJTAG_TMS I EJTAG Mode. The value on this signal controls the test mode select of the EJTAG Controller. When using the JTAG boundary scan, this pin should be left disconnected (since there is an internal pull-up) or driven high. JTAG_TRST_N I JTAG Reset. This active low signal asynchronously resets the boundary scan logic, JTAG TAP Controller, and the EJTAG Debug TAP Controller. An external pull-up on the board is recommended to meet the JTAG specification in cases where the tester can access this signal. However, for systems running in functional mode, one of the following should occur: 1) actively drive this signal low with control logic 2) statically drive this signal low with an external pull-down on the board 3) clock JTAG_TCK while holding EJTAG_TMS and/or JTAG_TMS high. JTAG_TCK I JTAG Clock. This is an input test clock used to clock the shifting of data into or out of the boundary scan logic, JTAG Controller, or the EJTAG Controller. JTAG_TCK is independent of the system and the processor clock with a nominal 50% duty cycle. JTAG_TDO O JTAG Data Output. This is the serial data shifted out from the boundary scan logic, JTAG Controller, or the EJTAG Controller. When no data is being shifted out, this signal is tri-stated. JTAG_TDI I JTAG Data Input. This is the serial data input to the boundary scan logic, JTAG Controller, or the EJTAG Controller. CLK I Master Clock. This is the master clock input. The processor frequency is a multiple of this clock frequency. This clock is used as the system clock for all memory and peripheral bus operations. EXTBCV I Load External Boot Configuration Vector. When this pin is asserted (i.e., high) the boot configuration vector is loaded from an externally supplied value during a cold reset. EXTCLK O External Clock. This clock is used for all memory and peripheral bus operations. COLDRSTN I Cold Reset. The assertion of this signal initiates a cold reset. This causes the processor state to be initialized, boot configuration to be loaded, and the internal PLL to lock onto the master clock (CLK). I/O Reset. The assertion of this bidirectional signal initiates a warm reset. This signal is asserted by the RC32434 during a warm reset. System RSTN Table 1 Pin Description (Part 6 of 6) Pin Characteristics Note: Some input pads of the RC32434 do not contain internal pull-ups or pull-downs. Unused inputs should be tied off to appropriate levels. This is especially critical for unused control signal inputs (such as WAITACKN) which, if left floating, could adversely affect the RC32434’s operation. Also, any input pin left floating can cause a slight increase in power consumption. 9 of 53 January 19, 2006 IDT RC32434 Function Memory and Peripheral Bus DDR Bus PCI Bus Interface General Purpose I/O Serial Peripheral Interface I2C-Bus Interface Pin Name Type Buffer I/O Type BDIRN BOEN WEN CSN[3:0] MADDR[21:0] MDATA[7:0] OEN RWN WAITACKN DDRADDR[13:0] DDRBA[1:0] DDRCASN DDRCKE O O O O I/O I/O O O I O O O O High Drive High Drive High Drive High Drive High Drive High Drive High Drive High Drive STI DDRCKN DDRCKP DDRCSN DDRDATA[15:0] DDRDM[1:0] DDRDQS[1:0] DDRRASN DDRVREF DDRWEN PCIAD[31:0] PCICBEN[3:0] PCICLK PCIDEVSELN PCIFRAMEN PCIGNTN[3:0] PCIIRDYN PCILOCKN PCIPAR PCIPERRN PCIREQN[3:0] PCIRSTN PCISERRN PCISTOPN PCITRDYN GPIO[8:0] GPIO[13:9] SCK SDI SDO SCL SDA O O O I/O O I/O O I O I/O I/O I I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL SSTL_2 SSTL_2 SSTL_2 SSTL_2 / LVCMOS SSTL_2 SSTL_2 SSTL_2 SSTL_2 SSTL_2 SSTL_2 SSTL_2 Analog SSTL_2 PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI PCI LVTTL PCI LVTTL LVTTL LVTTL LVTTL LVTTL Internal Resistor Notes1 pull-up pull-up on board pull-up on board pull-up on board pull-up on board pull-up on board pull-down on board pull-up on board pull-up on board pull-up on board Open Collector High Drive pull-up High Drive High Drive High Drive Low Drive/STI Low Drive/STI pull-up pull-up pull-up pull-up on board pull-up on board pull-up on board pull-up on board pull-up on board2 pull-up on board2 Table 2 Pin Characteristics (Part 1 of 2) 10 of 53 January 19, 2006 IDT RC32434 Function Ethernet Interfaces EJTAG / JTAG System Pin Name Type Buffer I/O Type MIICL MIICRS MIIRXCLK MIIRXD[3:0] MIIRXDV MIIRXER MIITXCLK MIITXD[3:0] MIITXENP MIITXER MIIMDC MIIMDIO JTAG_TMS EJTAG_TMS JTAG_TRST_N JTAG_TCK JTAG_TDO JTAG_TDI CLK EXTBCV EXTCLK COLDRSTN RSTN I I I I I I I O O O O I/O I I I I O I I I O I I/O LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL STI STI STI STI STI STI STI Low Drive Low Drive Low Drive Low Drive Low Drive STI STI STI STI Low Drive STI STI STI High Drive STI Low Drive / STI Internal Resistor Notes1 pull-down pull-down pull-up pull-up pull-down pull-down pull-up pull-up pull-up pull-up pull-up pull-up pull-up pull-down pull-up pull-up on board Table 2 Pin Characteristics (Part 2 of 2) 1. External pull-up required in most system applications. Some applications 2. may require additional pull-ups not identified in this table. Use a 2.2K pull-up resistor for I2C pins. 11 of 53 January 19, 2006 IDT RC32434 Boot Configuration Vector The encoding of the boot configuration vector is described in Table 3, and the vector input is illustrated in Figure 4. The value of the boot configuration vector read in by the RC32434 during a cold reset may be determined by reading the Boot Configuration Vector (BCV) Register. Signal Name/Description MADDR[3:0] CPU Pipeline Clock Multiplier. This field specifies the value by which the PLL multiplies the master clock input (CLK) to obtain the processor clock frequency (PCLK). For master clock input frequency constraints, refer to Table 3.2 in the RC32434 User Manual. 0x0 - PLL Bypass 0x1 - Multiply by 3 0x2 - Multiply by 4 0x3 - Multiply by 5 - Reserved 0x4 - Multiply by 5 0x5 - Multiply by 6 - Reserved 0x6 - Multiply by 6 0x7 - Multiply by 8 0x8 - Multiply by 10 0x9 through 0xF - Reserved MADDR[5:4] External Clock Divider. This field specifies the value by which the IPBus clock (ICLK), which is always 1/2 PCLK, is divided in order to generate the external clock output on the EXTCLK pin. 0x0 - Divide by 1 0x1 - Divide by 2 0x2 - Divide by 4 0x3 - reserved MADDR[6] Endian. This bit specifies the endianness. 0x0 - little endian 0x1 - big endian MADDR[7] Reset Mode. This bit specifies the length of time the RSTN signal is driven. 0x0 - Normal reset: RSTN driven for minimum of 4000 clock cycles. If the internal boot configuration vector is selected, the expiration of an 18-bit counter operating at the master clock input (CLK) frequency is used as the PLL stabilization delay. 0x1 - Reserved MADDR[10:8] PCI Mode. This bit controls the operating mode of the PCI bus interface. The initial value of the EN bit in the PCIC register is determined by the PCI mode. 0x0 - Disabled (EN initial value is zero) 0x1 - PCI satellite mode with PCI target not ready (EN initial value is one) 0x2 - PCI satellite mode with suspended CPU execution (EN initial value is one) 0x3 - PCI host mode with external arbiter (EN initial value is zero) 0x4 - PCI host mode with internal arbiter using fixed priority arbitration algorithm (EN initial value is zero) 0x5 - PCI host mode with internal arbiter using round robin arbitration algorithm (EN initial value is zero) 0x6 - reserved 0x7 - reserved Table 3 Boot Configuration Encoding (Part 1 of 2) 12 of 53 January 19, 2006 IDT RC32434 Signal Name/Description MADDR[11] Disable Watchdog Timer. When this bit is set, the watchdog timer is disabled following a cold reset. 0x0 - Watchdog timer enabled 0x1 - Watchdog timer disabled MADDR[13:12] Reserved. These pins must be driven low during boot configuration. MADDR[15:14] Reserved. Must be set to zero. Table 3 Boot Configuration Encoding (Part 2 of 2) 13 of 53 January 19, 2006 IDT RC32434 Logic Diagram — RC32434 System Signals Ethernet EJTAG / JTAG Signals General Purpose I/O CLK COLDRSTN RSTN EXTCLK EXTBCV MIIMDC MIIMDIO MIICL MIICRS MIIRXCLK MIIRXD[3:0] MIIRXDV MIIRXER MIITXCLK MIITXD[3:0] MIITXENP MIITXER 4 22 8 14 2 4 4 2 2 JTAG_TRST_N JTAG_TCK JTAG_TDI JTAG_TDO JTAG_TMS EJTAG_TMS GPIO[13:0] SPI SDO SCK SDI I2C-Bus SDA SCL 16 BDIRN BOEN WEN CSN[3:0] MADDR[21:0] MDATA[7:0] OEN RWN WAITACKN Memory and Peripheral Bus DDRADDR[13:0] DDRBA[1:0] DDRCASN DDRCKE DDRCKN DDRCKP DDRCSN DDRDATA[15:0] DDRDM[1:0] DDRDQS[1:0] DDRRASN DDRVREF DDRWEN DDR Bus PCIAD[31:0] PCICBEN[3:0] PCICLK PCIDEVSELN PCIFRAMEN PCIGNTN[3:0] PCIIRDYN PCILOCKN PCIPAR PCIPERRN PCIREQN[3:0] PCIRSTN PCISERRN PCISTOPN PCITRDYN PCI Bus RC32434 32 4 4 14 4 VccCore VccI/O Vss VccPLL VssPLL Power/Ground Figure 1 Logic Diagram 14 of 53 January 19, 2006 IDT RC32434 AC Timing Definitions Below are examples of the AC timing characteristics used throughout this document. Tlow Tper Thigh clock Tdo Tdo Tzd Tdz Tjitter Trise Tfall Output signal 1 Output signal 2 Tsu Thld Input Signal 1 Tpw Signal 1 Signal 2 Tskew Signal 3 Figure 2 AC Timing Definitions Waveform Symbol Definition Tper Clock period. Tlow Clock low. Amount of time the clock is low in one clock period. Thigh Clock high. Amount of time the clock is high in one clock period. Trise Rise time. Low to high transition time. Tfall Fall time. High to low transition time. Tjitter Jitter. Amount of time the reference clock (or signal) edge can vary on either the rising or falling edges. Tdo Data out. Amount of time after the reference clock edge that the output will become valid. The minimum time represents the data output hold. The maximum time represents the earliest time the designer can use the data. Tzd Z state to data valid. Amount of time after the reference clock edge that the tri-stated output takes to become valid. Tdz Data valid to Z state. Amount of time after the reference clock edge that the valid output takes to become tri-stated. Tsu Input set-up. Amount of time before the reference clock edge that the input must be valid. Thld Input hold. Amount of time after the reference clock edge that the input must remain valid. Tpw Pulse width. Amount of time the input or output is active for asynchronous signals. Tslew Slew rate. The rise or fall rate for a signal to go from a high to low, or low to high. X(clock) Timing value. This notation represents a value of ‘X’ multiplied by the clock time period of the specified clock. Using 5(CLK) as an example: X = 5 and the oscillator clock (CLK) = 25MHz, then the timing value is 200. Tskew Skew. The amount of time two signal edges deviate from one another. Table 4 AC Timing Definitions 15 of 53 January 19, 2006 IDT RC32434 System Clock Parameters (Values based on systems running at recommended supply voltages and operating temperatures, as shown in Tables 15 and 16.) 266MHz 300MHz 350MHz 400MHz Parameter Symbol Reference Edge Min Max Min Max Min Max Min Max PCLK1 Frequency none 200 266 200 300 200 350 200 400 MHz 3.8 5.0 3.3 5.0 2.85 5.0 2.5 5.0 ns 100 133 100 150 100 175 100 200 MHz 7.5 10.0 6.7 10.0 5.7 10.0 5.0 10.0 ns 25 125 25 125 25 125 25 125 MHz Tper_5a 8.0 40.0 8.0 40.0 8.0 40.0 8.0 40.0 ns Thigh_5a, Tlow_5a 40 60 40 60 40 60 40 60 % of Tper_5a Trise_5a, Tfall_5a — 3.0 — 3.0 — 3.0 — 3.0 ns Tjitter_5a — 0.1 — 0.1 — 0.1 — 0.1 ns Tper ICLK2,3,4 Frequency none Tper CLK5 Frequency none Units Timing Diagram Reference See Figure 3. Table 5 Clock Parameters 1. The CPU pipeline clock (PCLK) speed is selected during cold reset by the boot configuration vector (see Table 3). Refer to Chapter 3, Clocking and Initialization, in the RC32434 User Reference Manual for the allowable frequency ranges of CLK and PCLK. 2. ICLK is the internal IPBus clock. It is always equal to PCLK divided by 2. This clock cannot be sampled externally. 3. The ethernet clock (MIIxRXCLK and MIIxTXCLK) frequency must be equal to or less than 1/2 ICLK (MIIxRXCLK and MIIxTXCLK <= 1/2(ICLK)). 4. PCICLK must be equal to or less than two times ICLK (PCICLK <= 2(ICLK)) with a maximum PCICLK of 66 MHz. 5. The input clock (CLK) is input from the external oscillator to the internal PLL. Thigh_5a Tper_5a Tlow_5a CLK Tjitter_5a Tjitter_5a Trise_5a Tfall_5a Figure 3 Clock Parameters Waveform 16 of 53 January 19, 2006 IDT RC32434 AC Timing Characteristics (Values given below are based on systems running at recommended operating temperatures and supply voltages, shown in Tables 15 and 16.) Signal Symbol Reference Edge 266MHz 300MHz 350MHz 400MHz Min Max Min Max Min Max Min Max Tpw_6a2 none OSC — OSC — OSC — OSC — ms Cold reset Trise_6a none — 5.0 — 5.0 — 5.0 — 5.0 ns Cold reset 2 none 2(CLK) — 2(CLK) — 2(CLK) — 2(CLK) — ns Warm reset Unit Conditions Timing Diagram Reference Reset COLDRSTN1 3 RSTN (input) Tpw_6b RSTN3 Tdo_6c COLDRSTN falling — 15.0 — 15.0 — 15.0 — 15.0 ns Cold reset Tdz_6d2 COLDRSTN falling — 30.0 — 30.0 — 30.0 — 30.0 ns Cold reset Tdz_6d2 RSTN falling — 5(CLK) — 5(CLK) — 5(CLK) — 5(CLK) ns Warm reset 2 RSTN rising 2(CLK) — 2(CLK) — 2(CLK) — 2(CLK) — ns Warm reset (output) MADDR[15:0] (boot vector) Tzd_6d See Figures 4 and 5. Table 6 Reset and System AC Timing Characteristics 1. The COLDRSTN minimum pulse width is the oscillator stabilization time (OSC) with Vcc stable. 2. The values 3. for this symbol were determined by calculation, not by testing. RSTN is a bidirectional signal. It is treated as an asynchronous input. 17 of 53 January 19, 2006 IDT RC32434 1 2 3 4 5 6 CLK COLDRSTN * RSTN MADDR[15:0] Boot Configuration Vector MADDR[21:16] Driven Driven EXTCLK EXTBCV ≥ 4000 CLK * COLDRSTN sampled negated (high) by the RC32434 1. clock cycles ≥ 4000 CLK clock cycles EXTBCV is asserted (i.e., pulled-up). COLDRSTN is asserted by external logic. The RC32434 responds by immediately tri-stating the bottom 16-bits of the memory and peripheral address bus (MADDR[15:0]), driving the remaining address bus signals (i.e., MADDR[21:16]), and asserting RSTN. EXTCLK is undefined at this point. 2. External logic drives the boot configuration vector on MADDR[15:0]. 3. External logic negates COLDRSTN and tri-states the boot configuration vector on MADDR[15:0]. In response, the RC32434 stops sampling the boot configuration vector and retains the boot configuration vector value seen two clock cycles earlier (i.e., the value on the MADDR[15:0] lines two rising edges of CLK earlier). Within 16 CLK clock cycles after COLDRSTN is sampled negated, the RC32434 begins driving MADDR[15:0]. 4. The RC32434 waits for the PLL to stabilize. 5. The RC32434 then begins generating EXTCLK. 6. After at least 4000 CLK clock cycles, the RC32434 tri-states RSTN. 7. At least 4000 CLK clock cycles after negating RSTN, the RC32434 samples RSTN. If RSTN is negated, cold reset has completed and the RC32434 CPU begins executing by taking MIPS reset exception. Figure 4 COLD Reset Operation with External Boot Configuration Vector AC Timing Waveform Note: For a diagram showing the COLD Reset Operation with Internal Boot Configuration Vector, see Figure 3.6 in the RC32434 User Reference Manual. 18 of 53 January 19, 2006 IDT RC32434 1 3 2 4 5 6 CLK COLDRSTN RSTN FFFF_FFFF MDATA[7:0] Mem Control Signals Active Deasserted Active ≥ 4000 CLK ≥ 4000 CLK clock Cycles clock Cycles 1. Warm reset condition caused by assertion of RSTN by an external agent. 2. The RC32434 tri-states the data bus, MDATA[7:0], negates all memory control signals, and itself asserts RSTN. The RC32434 continues to drive the address bus throughout the entire warm reset. 3. The RC32434 negates RSTN after 4000 master clock (CLK) clock cycles. 4. External logic negates RSTN. 5. The RC32434 samples RSTN negated at least 4000 master clock (CLK) clock cycles after step 3 and starts driving the data bus, MDATA[7:0]. 6. CPU begins executing by taking a MIPS soft reset exception. The assertion of CSN[0] will occur no sooner than 16 clock cycles after the RC32434 samples RSTN negated (i.e., step 5). Figure 5 Externally Initiated Warm Reset AC Timing Waveform Signal Symbol 266MHz 300MHz 350MHz 400MHz Reference Edge Min Max Min Max Min Max Min Max DDRDQSx 0 0.9 0 0.81 0 0.7 0.0 0.6 ns 1.2 1.9 1.0 1.7 0.7 1.5 0.5 1.4 ns Unit Timing Diagram Reference Memory Bus - DDR Access DDRDATA[15:0] Tskew_7g Tdo_7k 2 DDRDM[1:0] Tdo_7l DDRDQSx 1.2 1.9 1.0 1.7 0.7 1.5 0.5 1.4 ns DDRDQS[1:0] Tdo_7i DDRCKP -0.75 0.75 -0.75 0.75 -0.7 0.7 -0.7 0.7 ns DDRADDR[13:0], DDRBA[1:0], DDRCASN, DDRCKE, DDRCSN, DDRRASN, DDRWEN Tdo_7m DDRCKP 1.0 4.0 1.0 4.3 1.0 4.0 1.0 4.0 ns See Figures 6 and 7. Table 7 DDR SDRAM Timing Characteristics 1. Meets DDR timing requirements for 150MHz clock rate DDR SDRAMs with 300 ps remaining margin to compensate for PCB propagation mismatches, which is adequate to guarantee functional timing, provided the RC32434 DDR layout guidelines are adhered to. 2. Setup times are calculated as applicable clock period - Tdo max. For example, if the DDR is running at 266MHz, it uses a 133MHz input clock. The period for a 133MHz clock is 7.5ns. If the Tdo max value is 4.6ns, the TIS parameter is 7.5ns minus 4.6ns = 2.9ns. The DDR spec for this parameter is 1ns, so there is 1.9ns of slack left over for board propagation. Calculations for TDS are similar, but since this parameter is taken relative to the DDRDQS signals, which are referenced on both edges, the effective period with a 133MHz input clock is only 3.75ns. So, if the max Tdo is 1.9ns, we have 3.75ns minus 1.9ns = 1.85ns for TDS. The DDR data sheet specs a value of 0.5ns for 266MHz, so this leaves 1.35ns slack for board propagation delays. 19 of 53 January 19, 2006 IDT RC32434 DDRCKP DDRCKN Tdo_7m DDRCSN Tdo_7m RowA DDRADDR[13:0] DDRCMD1 NOP Tdo_7m ACTV Col A0 NOP Col A2 RD RD BNKx BNKx RowB NOP NOP PRECHG NOP ACTV NOP DDRCKE Tdo_7m DDRBA[1:0] BNKx BNKx BNKx DDRDM[1:0] DDRDQSx (ideal) D0 DDRDATA[15:0]2 (ideal) D1 D2 D3 Tskew_7g D0 D1 D2 D3 Tskew_7g D0 D1 D2 D3 Tac (min) DDRDQSx (min) DDRDATA[15:0]2 Tac (max) DDRDQSx (max) DDRDATA[15:0]2 1 DDRCMD contains DDRRASN, DDRCASN and DDRWEN. 2 DDRDATA is either 32-bits or 16-bits wide depending on the DBW control bit in DDRC Register (see Chapter 7, DDR Controller, in the RC32434 User Reference Manual). Figure 6 DDR SDRAM AC Timing Waveform - SDRAM Read Access 20 of 53 January 19, 2006 IDT RC32434 DDRCKP DDRCKN Tdo_7m DDRCSN Tdo_7m DDRADDR[13:0] RowA DDRCMD1 Tdo_7m ACTV NOP NOP Col A0 Col A2 WR WR NOP NOP NOP NOP NOP DDRCKE Tdo_7m BNKx DDRBA[1:0] BNKx DDRDQSx Tdo_7l Tdo_7l DM0 DM1 FF DDRDM[1:0] DM3 DM2 FF DDRDQSx Tdo_7k Tdo_7k D0 DDRDATA[15:0]2 1 D1 D2 D3 DDRCMD contains DDRRASN, DDRCASN and DDRWEN. 2 DDRDATA is either 32-bits or 16-bits wide depending on the DBW control bit in DDRC Register (see Chapter 7, DDR Controller, in the RC32434 User Reference Manual). Figure 7 DDR SDRAM Timing Waveform — Write Access Signal Symbol Reference Edge 266MHz Min Max 300MHz Min Max 350MHz Min Max 400MHz Min Max Unit Memory and Peripheral Bus1 MADDR[21:0] MADDR[25:22] Tdo_8a 0.4 4.5 0.4 4.5 0.4 4.5 0.4 4.5 ns Tdz_8a2 — — — — — — — — ns Tzd_8a2 — — — — — — — — ns Tdo_8b EXTCLK rising 0.4 4.5 0.4 4.5 0.4 4.5 0.4 4.5 ns Tdz_8b2 EXTCLK rising — — — — — — — — ns Tzd_8b2 — — — — — — — — ns Conditions Timing Diagram Reference See Figures 8 and 9. Table 8 Memory and Peripheral Bus AC Timing Characteristics (Part 1 of 2) 21 of 53 January 19, 2006 IDT RC32434 Signal MDATA[7:0] 266MHz 300MHz 350MHz 400MHz Symbol Reference Edge Min Max Min Max Min Max Min Max Tsu_8c EXTCLK rising 6.0 — 6.0 — 6.0 — 6.0 — ns Thld_8c 0 — 0 — 0 — 0 — ns Tdo_8c 0.4 4.5 0.4 4.5 0.4 4.5 0.4 4.5 ns Tdz_8c2 0 0.5 0 0.5 0 0.5 0 0.5 ns Tzd_8c2 0.4 3.3 0.4 3.3 0.4 3.3 0.4 3.3 ns Unit EXTCLK3 Tper_8d none 7.5 — 6.66 — 6.66 — 6.66 — ns BDIRN Tdo_8e EXTCLK rising BOEN WAITACKN4 0.4 3.8 0.4 3.8 0.4 3.8 0.4 3.8 ns Tdz_8e2 — — — — — — — — ns Tzd_8e2 — — — — — — — — ns Tdo_8f 0.4 3.8 0.4 3.8 0.4 3.8 0.4 3.8 ns Tdz_8f2 — — — — — — — — ns Tzd_8f2 — — — — — — — — ns 6.5 — 6.5 — 6.5 — 6.5 — ns 0 — 0 — 0 — 0 — ns Tsu_8h EXTCLK rising EXTCLK rising Thld_8h CSN[3:0] RWN OEN WEN Tpw_8h2 none 2(EXTCLK) — 2(EXTCLK) — 2(EXTCLK) — 2(EXTCLK) — ns Tdo_8i EXTCLK rising 0.4 4.0 0.4 4.0 0.4 4.0 0.4 4.0 ns Tdz_8i2 — — — — — — — — ns Tzd_8i2 — — — — — — — — ns Tdo_8j 0.4 3.8 0.4 3.8 0.4 3.8 0.4 3.8 ns Tdz_8j2 — — — — — — — — ns Tzd_8j2 — — — — — — — — ns Tdo_8k EXTCLK rising 0.4 4.0 0.4 4.0 0.4 4.0 0.4 4.0 ns Tdz_8k2 — — — — — — — — ns Tzd_8k2 — — — — — — — — ns Tdo_8l EXTCLK rising 0.4 3.7 0.4 3.7 0.4 3.7 0.4 3.7 ns Tdz_8l2 EXTCLK rising — — — — — — — — ns Tzd_8l2 — — — — — — — — ns Conditions Timing Diagram Reference See Figures 8 and 9 (cont.). Table 8 Memory and Peripheral Bus AC Timing Characteristics (Part 2 of 2) 1. The RC32434 provides bus turnaround cycles to prevent bus contention when going from read to write, write to read, and during external bus ownership. For example, there are no cycles where an external device and the RC32434 are both driving. See Chapter 6, Device Controller, in the RC32434 User Reference Manual. 2. The values for this symbol were determined by calculation, not by testing. 3. The frequency of EXTCLK is programmable. See the External Clock Divider (MDATA[5:4]) description in Table 3 of this data sheet. 4. WAITACKN must meet the setup and hold times if it is synchronous or the minimum pulse width if it is asynchronous. 22 of 53 January 19, 2006 IDT RC32434 Tper_8d Thigh_8d EXTCLK Tdo_8a Tlow_8d Addr[21:0] MADDR[21:0] Tdo_8b MADDR[25:22] Addr[25:22] RWN Tdo_8i Tdo_8i CSN[3:0] 1111 WEN Tdo_8k Tdo_8k OEN Thld_8c Tdz_8c Tsu_8c Tzd_8c Data MDATA[7:0] RC32434 samples read data Tdo_8e BDIRN Tdo_8f Tdo_8e Tdo_8f BOEN WAITACKN Figure 8 Memory and Peripheral Bus AC Timing Waveform — Read Access 23 of 53 January 19, 2006 IDT RC32434 EXTCLK Tdo_8a Addr[21:0] MADDR[21:0] Tdo_8b MADDR[25:22] Addr[25:22] Tdo_8j RWN Tdo_8i CSN[3:0] Tdo_8l WEN 1111 Byte Enables 1111 OEN Tdo_8c Data MDATA[7:0] BDIRN BOEN Tdo_8f WAITACKN Figure 9 Memory and Peripheral Bus AC Timing Waveform — Write Access 24 of 53 January 19, 2006 IDT RC32434 Signal 266MHz 300MHz 350MHz 400MHz Symbol Reference Edge Min Max Min Max Min Max Min Max Tper_9a None 30.0 — 30.0 — 30.0 — 30.0 — ns 12.0 — 12.0 — 12.0 — 12.0 — ns 10.0 — 10.0 — 10.0 — 10.0 — ns Thld_9b 0.0 — 0.0 — 0.0 — 0.0 — ns 1 10 300 10 300 10 300 10 300 ns 399.96 400.4 399.96 400.4 399.96 400.4 399.96 400.4 ns Thigh_9c, Tlow_9c 140 260 140 260 140 260 140 260 ns Trise_9c, Tfall_9c — 3.0 — 3.0 — 3.0 — 3.0 ns 39.9 40.0 39.9 40.0 39.9 40.0 39.9 40.0 ns Thigh_9d, Tlow_9d 14.0 26.0 14.0 26.0 14.0 26.0 14.0 26.0 ns Trise_9d, Tfall_9d — 2.0 — 2.0 — 2.0 — 2.0 ns 10.0 — 10.0 — 10.0 — 10.0 — ns 10.0 — 10.0 — 10.0 — 10.0 — ns MIIxTXCLK rising 0.0 25.0 0.0 25.0 0.0 25.0 0.0 25.0 ns None 19.9 20.1 19.9 20.1 19.9 20.1 19.9 20.1 ns 7.0 13.0 7.0 13.0 7.0 13.0 7.0 13.0 ns 2.0 — 2.0 — 2.0 — 2.0 — ns 5.5 14.5 5.5 14.5 5.5 14.5 5.5 14.5 ns Unit Conditions Timing Diagram Reference Ethernet MIIMDC Thigh_9a, Tlow_9a MIIMDIO Tsu_9b Tdo_9b MIIMDC rising See Figure 10. Ethernet — MII Mode MIIRXCLK, MIITXCLK2 Tper_9c Tper_9d MIIRXCLK, MIITXCLK2 MIIRXD[3:0], MIIRXDV, MIIRXER Tsu_9e Thld_9e MIITXD[3:0], MIITXENP, MIITXER Tdo_9f None None MIIxRXCLK rising 10 Mbps See Figure 10. 100 Mbps Ethernet — RMII Mode RMIIREFCLK Tper_9i Thigh_9i, Tlow_9i RMIITXEN, RMIITXD[1:0] Tdo_9j RMIICRSDV, RMIIRXER, RMIIRXD[1:0] Tsu_9k MIIRXCLK rising See Figure 10. Table 9 Ethernet AC Timing Characteristics 1. The values 2. for this symbol were determined by calculation, not by testing. The ethernet clock (MIIRXCLK and MIITXCLK) frequency must be equal to or less than 1/2 ICLK (MIIRXCLK and MIITXCLK <= 1/2(ICLK)). 25 of 53 January 19, 2006 IDT RC32434 Tlow_9a Thigh_9a Tper_9a MIIMDC Tdo_9b Tdo_9b MIIMDIO (output) Thld_9b Tsu_9b MIIMDIO (input) Thigh_9d Tlow Tlow_9d Tper_9d MIIRXCLK Thld_9e Tsu_9e MIIRXDV, MIIRXD[3:0], MIIRXER Thigh_9d Tper_9d Tlow Tlow_9d MIITXCLK Tdo_9f Tdo_9f MIITXEN, MIITXD[3:0], MIITXER Thigh_9i Tper_9i Tlow_9i RMII REFCLK RMII TXEN, RMII TXD[1:0] Tdo_9j Tdo_9j Tper_9i Thigh_9i Tlow_9i RMII REFCLK Tsu_9k RMII CRS_DV, RMII RXER RMII RXD[1:0] Figure 10 Ethernet AC Timing Waveform 26 of 53 January 19, 2006 IDT RC32434 Signal Symbol Reference Edge 266MHz 300MHz 350MHz 400MHz Min Max Min Max Min Max Min Max Tper_10a none 15.0 30.0 15.0 30.0 15.0 30.0 15.0 30.0 ns Thigh_10a, Tlow_10a 6.0 — 6.0 — 6.0 — 6.0 — ns Tslew_10a 1.5 4.0 1.5 4.0 1.5 4.0 1.5 4.0 V/ns 3.0 — 3.0 — 3.0 — 3.0 — ns Thld_10b 0 — 0 — 0 — 0 — ns Tdo_10b 2.0 6.0 2.0 6.0 2.0 6.0 2.0 6.0 ns Tdz_10b3 — 14.0 — 14.0 — 14.0 — 14.0 ns Tzd_10b3 2.0 — 2.0 — 2.0 — 2.0 — ns 5.0 — 5.0 — 5.0 — 5.0 — ns Thld_10c 0 — 0 — 0 — 0 — ns Tdo_10c 2.0 6.0 2.0 6.0 2.0 6.0 2.0 6.0 ns Unit Conditions Timing Diagram Reference PCI1 PCICLK2 PCIAD[31:0], PCIBEN[3:0], PCIDEVSELN, PCIFRAMEN,PCIIRDYN, PCILOCKN, PCIPAR, PCIPERRN, PCISTOPN, PCITRDY PCIGNTN[3:0], PCIREQN[3:0] Tsu_10b Tsu_10c PCICLK rising PCICLK rising PCIRSTN (output)4 Tpw_10d3 None 4000 (CLK) — 4000 (CLK) — 4000 (CLK) — 4000 (CLK) — ns PCIRSTN (input)4,5 Tpw_10e3 None 2(CLK) — 2(CLK) — 2(CLK) — 2(CLK) — ns Tdz_10e3 PCIRSTN falling 6(CLK) — 6(CLK) — 6(CLK) — 6(CLK) — ns Tsu_10f PCICLK rising 3.0 — 3.0 — 3.0 — 3.0 — ns Thld_10f 0 — 0 — 0 — 0 — ns Tdo_10f 2.0 6.0 2.0 6.0 2.0 6.0 2.0 6.0 ns 4.7 11.1 4.7 11.1 4.7 11.1 4.7 11.1 ns PCISERRN6 PCIMUINTN6 Tdo_10g PCICLK rising 66 MHz PCI See Figure 11. See Figures 15 and 16 See Figure 11 Table 10 PCI AC Timing Characteristics 1. This PCI interface conforms to the PCI Local Bus Specification, Rev 2.2. 2. PCICLK must be equal to or less than two times ICLK (PCICLK <= 2(ICLK)) with a maximum PCICLK of 66 MHz. 3. The values for this symbol were determined by calculation, not by testing. 4. PCIRSTN is an output in host mode and an input in satellite mode. 5. To meet the PCI delay specification from reset asserted to outputs floating, the PCI reset should be logically combined with the COLDRSTN input, instead of input on PCIRSTN. 6. PCISERRN and PCIMUINTN use open collector I/O types. 27 of 53 January 19, 2006 IDT RC32434 Tlow_10a Thigh_10a Tper_10a PCICLK Tdo_10b Tdz_10b Tzd_10b Bussed output Tdo_10c Point to point output Thld_10b Tsu_10b Bussed input valid Thld_10c Tsu_10c Point to point input valid Figure 11 PCI AC Timing Waveform COLDRSTN PCIRSTN (output) cold reset (tri-state) PCI interface enabled Tpw_10d RSTN warm reset Note: During and after cold reset, PCIRSTN is tri-stated and requires a pull-down to reach a low state. After the PCI interface is enabled in host mode, PCIRSTN will be driven either high or low depending on the reset state of the RC32434. Figure 12 PCI AC Timing Waveform — PCI Reset in Host Mode 28 of 53 January 19, 2006 IDT RC32434 CLKP Tpw_10e PCIRSTN (input) RSTN warm reset Tdz_10e MDATA[15:0] PCI bus signals Figure 13 PCI AC Timing Waveform — PCI Reset in Satellite Mode Signal Symbol 266MHz Reference Edge Min Max Frequency none 300MHz 350MHz 400MHz Min Max Min Max Min Max Unit Conditions Timing Diagram Reference 100 KHz See Figure 14. I2C1 SCL SDA Start or repeated start condition Stop condition 0 100 0 100 0 100 0 100 kHz Thigh_12a, Tlow_12a 4.0 — 4.0 — 4.0 — 4.0 — µs Trise_12a — 1000 — 1000 — 1000 — 1000 ns Tfall_12a — 300 — 300 — 300 — 300 ns 250 — 250 — 250 — 250 — ns Thld_12b 0 3.45 0 3.45 0 3.45 0 3.45 µs Trise_12b — 1000 — 1000 — 1000 — 1000 ns Tfall_12b — 300 — 300 — 300 — 300 ns 4.7 — 4.7 — 4.7 — 4.7 — µs 4.0 — 4.0 — 4.0 — 4.0 — µs 4.0 — 4.0 — 4.0 — 4.0 — µs 4.7 — 4.7 — 4.7 — 4.7 — µs 0 400 0 400 0 400 0 400 kHz Thigh_12a, Tlow_12a 0.6 — 0.6 — 0.6 — 0.6 — µs Trise_12a — 300 — 300 — 300 — 300 ns Tfall_12a — 300 — 300 — 300 — 300 ns 100 — 100 — 100 — 100 — ns Thld_12b 0 0.9 0 0.9 0 0.9 0 0.9 µs Trise_12b — 300 — 300 — 300 — 300 ns Tfall_12ba — 300 — 300 — 300 — 300 ns Tsu_12b Tsu_12c SDA falling Thld_12c Tsu_12d Bus free time between a stop and start condition Tdelay_12e SCL Frequency SDA SCL rising Tsu_12b SDA rising none SCL rising Table 11 I2C AC Timing Characteristics 29 of 53 400 KHz (Part 1 of 2) January 19, 2006 IDT RC32434 Signal Symbol Start or repeated start condition Tsu_12c Stop condition 300MHz 350MHz 400MHz Min Max Min Max Min Max SDA falling Thld_12c Tsu_12d Bus free time between a stop and start condition 266MHz Reference Edge Min Max SDA rising Tdelay_12e Unit Conditions Timing Diagram Reference 400 KHz See Figure 14. 0.6 — 0.6 — 0.6 — 0.6 — µs 0.6 — 0.6 — 0.6 — 0.6 — µs 0.6 — 0.6 — 0.6 — 0.6 — µs 1.3 — 1.3 — 1.3 — 1.3 — µs Table 11 I2C AC Timing Characteristics (Part 2 of 2) 1. 2 For more information, see the I C-Bus specification by Philips Semiconductor. Tdelay_12e SDA Thld_12b Tlow_12a Thld_12c Tsu_12c Thld_12c Tsu_12d Tsu_12b Thigh_12a SCL Figure 14 I2C AC Timing Waveform Signal 266MHz 300MHz 350MHz 400MHz Symbol Reference Edge Min Max Min Max Min Max Min Max Tpw_13b1 None 2(ICLK) — 2(ICLK) — 2(ICLK) — 2(ICLK) — Unit Conditions Timing Diagram Reference GPIO GPIO[13:0] ns See Figure 15. Table 12 GPIO AC Timing Characteristics 1. The values for this symbol were determined by calculation, not by testing. \ GPIO (asynchronous input) Tpw_13b Figure 15 GPIO AC Timing Waveform 30 of 53 January 19, 2006 IDT RC32434 Signal 266MHz 300MHz 350MHz 400MHz Unit Conditions 166667 ns SPI 40 83353 ns SPI — 60 — ns SPI 60 — 60 — ns SPI Symbol Reference Edge Min Max Min Max Min Max Min Max Tper_15a None 100 166667 100 166667 100 166667 100 40 83353 40 83353 40 83353 SCK rising or falling 60 — 60 — 60 60 — 60 — Timing Diagram Reference SPI1 SCK Thigh_15a, Tlow_15a SDI Tsu_15b Thld_15b SDO Tdo_15c SCK rising or falling 0 60 0 60 0 60 0 60 ns SPI SCK, SDI, SDO Tpw_15e None 2(ICLK) — 2(ICLK) — 2(ICLK) — 2(ICLK) — ns Bit I/O See Figures 16, 17, and 18. See Figures 16, 17, and 18. Table 13 SPI AC Timing Characteristics 1. In SPI mode, the SCK period and sampling edge are programmable. In PCI mode, the SCK period is fixed and the sampling edge is rising. Thigh_15a Tlow_15a Tper_15a SCK Thld_15b Tsu_15b SDI MSB bit 6 bit 5 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 LSB bit 3 bit 2 bit 1 LSB Tdo_15c SDO MSB bit 4 Control bits CPOL = 0, CPHA = 0 in the SPI Control Register, SPC. Figure 16 SPI AC Timing Waveform — Clock Polarity 0, Clock Phase 0 Thigh_15a Tper_15a Tlow_15a SCK Thld_15b Tsu_15b SDI MSB bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 LSB bit 3 bit 2 bit 1 LSB Tdo_15c SDO MSB bit 6 bit 5 bit 4 Control bits CPOL = 0, CPHA = 1 in the SPI Control Register, SPC. Figure 17 SPI AC Timing Waveform — Clock Polarity 0, Clock Phase 1 31 of 53 January 19, 2006 IDT RC32434 SCK, SDI, SDO (input) Tpw_15e Figure 18 SPI AC Timing Waveform — Bit I/O Mode 266MHz 300MHz 350MHz 400MHz Reference Edge Min Max Min Max Min Max Min Max none 25.0 50.0 25.0 50.0 25.0 50.0 25.0 50.0 ns 10.0 25.0 10.0 25.0 10.0 25.0 10.0 25.0 ns JTAG_TCK rising 2.4 — 2.4 — 2.4 — 2.4 — ns 1.0 — 1.0 — 1.0 — 1.0 — ns JTAG_TCK falling — 11.3 — 11.3 — 11.3 — 11.3 ns — 11.3 — 11.3 — 11.3 — 11.3 ns JTAG_TRST_ Tpw_16d2 N none 25.0 — 25.0 — 25.0 — 25.0 — ns EJTAG_TMS1 Tsu_16e JTAG_TCK rising 2.0 — 2.0 — 2.0 — 2.0 — ns 1.0 — 1.0 — 1.0 — 1.0 — ns Signal Symbol Unit Conditions Timing Diagram Reference EJTAG and JTAG JTAG_TCK Tper_16a Thigh_16a, Tlow_16a JTAG_TMS1, Tsu_16b JTAG_TDI Thld_16b JTAG_TDO Tdo_16c Tdz_16c2 Thld_6e See Figure 19. Table 14 JTAG AC Timing Characteristics 1. The JTAG specification, IEEE 1149.1, recommends that both JTAG_TMS and EJTAG_TMS should be held at 1 while the signal applied at JTAG_TRST_N changes from 0 to 1. Otherwise, a race may occur if JTAG_TRST_N is deasserted (going from low to high) on a rising edge of JTAG_TCK when either JTAG_TMS or EJTAG_TMS is low, because the TAP controller might go to either the Run-Test/Idle state or stay in the Test-Logic-Reset state. 2. The values for this symbol were determined by calculation, not by testing. 32 of 53 January 19, 2006 IDT RC32434 Tlow_16a Tper_16a Thigh_16a JTAG_TCK Thld_16b Tsu_16b JTAG_TDI Thld_16b Tsu_16b JTAG_TMS Thld_16e Tsu_16e EJTAG_TMS Tdo_16c Tdz_16c JTAG_TDO Tpw_16d JTAG_TRST_N Figure 19 JTAG AC Timing Waveform The IEEE 1149.1 specification requires that the JTAG and EJTAG TAP controllers be reset at power-up whether or not the interfaces are used for a boundary scan or a probe. Reset can occur through a pull-down resistor on JTAG_TRST_N if the probe is not connected. However, on-chip pull-up resistors are implemented on the RC32434 due to an IEEE 1149.1 requirement. Having on-chip pull-up and external pull-down resistors for the JTAG_TRST_N signal requires special care in the design to ensure that a valid logical level is provided to JTAG_TRST_N, such as using a small external pull-down resistor to ensure this level overrides the on-chip pull-up. An alternative is to use an active power-up reset circuit for JTAG_TRST_N, which drives JTAG_TRST_N low only at power-up and then holds JTAG_TRST_N high afterwards with a pull-up resistor. Figure 20 shows the electrical connection of the EJTAG probe target system connector. Pull-up RC32434 Pull-up VDD TRST* JTAG_TRST_N JTAG_TDI JTAG_TDO Series-res. EJTAG_TMS JTAG_TCK Other reset sources Target System Reset Circuit GND TDI GND TDO GND TMS GND TCK GND GND RST* Pull-down DINT no connect Reset (soft/hard) 1 VccIO VccIO voltage reference GND Figure 20 Target System Electrical EJTAG Connection 33 of 53 January 19, 2006 IDT RC32434 Using the EJTAG Probe In Figure 20, the pull-up resistors for JTAG_TDO and RST*, the pull-down resistor for JTAG_TRST_N, and the series resistor for JTAG_TDO must be adjusted to the specific design. However, the recommended pull-up/down resistor is 1.0 kΩ because a low value reduces crosstalk on the cable to the connector, allowing higher JTAG_TCK frequencies. A typical value for the series resistor is 33 Ω. Recommended resistor values have ± 5% tolerance. If a probe is used, the pull-up resistor on JTAG_TDO must ensure that the JTAG_TDO level is high when no probe is connected and the JTAG_TDO output is tri-stated. This requirement allows reliable connection of the probe if it is hooked-up when the power is already on (hot plug). The pull-up resistor value of around 47 kΩ should be sufficient. Optional diodes to protect against overshoot and undershoot voltage can be added on the signals of the chip with EJTAG. If a probe is used, the RST* signal must have a pull-up resistor because it is controlled by an open-collector (OC) driver in the probe, and thus is actively pulled low only. The pull-up resistor is responsible for the high value when not driven by the probe of 25pF. The input on the target system reset circuit must be able to accept the rise time when the pull-up resistor charges the capacitance to a high logical level. Vcc I/O must connect to a voltage reference that drops rapidly to below 0.5V when the target system loses power, even with a capacitive load of 25pF. The probe can thus detect the lost power condition. For additional information on EJTAG, refer to Chapter 17 of the RC32434 User Reference Manual. Phase-Locked Loop (PLL) The phase-locked loop (PLL) multiplies the external oscillator input (pin CLK) according to the parameter provided by the boot configuration vector to create the processor clock (PCLK). Inherently, PLL circuits are only capable of generating clock frequencies within a limited range. PLL Filters It is recommended that the system designer provide a filter network of passive components for the PLL analog and digital power supplies. The PLL circuit power and PLL circuit ground should be isolated from power and ground with a filter circuit such as the one shown in Figure 21. Because the optimum values for the filter components depend upon the application and the system noise environment, these values should be considered as starting points for further experimentation within your specific application. RC32434 10 ohm1 Vcc 10 µF 0.1 µF 100 pF VccPLL VccPLL VssPLL VssPLL Vss Figure 21 PLL Filter Circuit for Noisy Environments 34 of 53 January 19, 2006 IDT RC32434 Recommended Operating Supply Voltages Symbol Parameter Vss Common ground VssPLL PLL ground VccI/O I/O supply except for SSTL_21 1 Minimum Typical Maximum Unit 0 0 0 V 3.135 3.3 3.465 V 2.375 2.5 2.625 V VccSI/O (DDR) I/O supply for SSTL_2 VccPLL PLL supply (digital) 1.1 1.2 1.3 V VccAPLL PLL supply (analog) 3.135 3.3 3.465 V VccCore Internal logic supply 1.1 1.2 1.3 V DDRVREF2 SSTL_2 input reference voltage 0.5(VccSI/O) 0.5(VccSI/O) 0.5(VccSI/O) V VTT3 SSTL_2 termination voltage DDRVREF - 0.04 DDRVREF DDRVREF + 0.04 V Table 15 RC32434 Operating Voltages 1. SSTL_2 I/Os are used to connect to DDR SDRAM. 2. Peak-to-peak AC noise on DDRVREF may not exceed ± 2% DDRVREF (DC). 3. V TT of the SSTL_2 transmitting device must track DDRVREF of the receiving device. Recommended Operating Temperatures Grade Temperature Commercial 0°C to +70°C Ambient Industrial -40°C to +85°C Ambient Table 16 RC32434 Operating Temperatures Capacitive Load Deration Refer to the 79RC32434 IBIS Model on the IDT web site (www.idt.com). 35 of 53 January 19, 2006 IDT RC32434 Power-on Sequence Three power-on sequences are given below. Sequence #1 is recommended because it will prevent I/O conflicts and will also allow the input signals to propagate when the I/O powers are brought up. Note: The ESD diodes may be damaged if one of the voltages is applied and one of the other voltages is at a ground level. A. Recommended Sequence t2 > 0 whenever possible (VccCore) t1 - t2 can be 0 (VccSI/O followed by VccI/O) V 3.3V ccI/O VccI/O -- 3.3V V2.5V ccSI/O VccSI/O -- 2.5V VccCore 1.2V VccCore -- 1.2V t2 Time t1 B. Reverse Voltage Sequence If sequence A is not feasible, then Sequence B can be used: t1 <50ms and t2 <50ms to prevent damage. VccI/O -- 3.3V Vcc3.3 VccI/O VccSI/O -- 2.5V Vcc2.5 VccSI/O VccCore -- 1.2V VccCore Vcc1.2 t1 Time t2 C. Simultaneous Power-up VccI/O, VccSI/O, and VccCore can be powered up simultaneously. 36 of 53 January 19, 2006 IDT RC32434 Power Consumption Consumption Parameter 266MHz 300MHz 350MHz 400MHz Unit Typ. Max. Typ. Max. Typ. Max. Typ. Max. Icc I/O 215 270 220 275 225 280 230 285 mA Icc SI/O (DDR) 70 85 75 90 85 100 95 110 mA Icc Core, Icc PLL Normal mode 325 510 350 550 400 610 450 670 mA Standby mode1 220 — 240 — 260 — 280 — mA Normal mode 1.27 1.82 1.36 1.90 1.45 2.02 1.54 2.15 W Standby mode1 0.73 — 0.78 — 0.84 — 0.90 — W Power Dissipation Conditions CL = 35 pF Tambient = 25oC Max. values use the maximum voltages listed in Table 15. Typical values use the typical voltages listed in that table. Note: For additional information, see Power Considerations for IDT Processors on the IDT web site www.idt.com. Table 17 RC32434 Power Consumption 1. The RC32434 enter Standby mode by executing WAIT instructions. Minimal I/O switching is assumed. On-chip logic outside the CPU core continues to function. Power Curve The following graph contains a power curve that shows power consumption at various core frequencies. Typical Power Curve 1.60 1.55 Power (W) 1.50 1.45 1.40 1.35 1.30 1.25 266 300 350 400 Core Frequency (MHz) Figure 22 RC32434 Typical Power Usage 37 of 53 January 19, 2006 IDT RC32434 DC Electrical Characteristics Values based on systems running at recommended supply voltages, as shown in Table 15. Note: See Table 2, Pin Characteristics, for a complete I/O listing. I/O Type LOW Drive Output HIGH Drive Output Schmitt Trigger Input (STI) SSTL_2 (for DDR SDRAM) PCI Parameter Min. Typical Max. Unit Conditions IOL — 14.0 — mA VOL = 0.4V IOH — -12.0 — mA VOH = 1.5V IOL — 41.0 — mA VOL = 0.4V IOH — -42.0 — mA VOH = 1.5V VIL -0.3 — 0.8 V — VIH 2.0 — VccI/O + 0.5 V — IOL 7.6 — — mA VOL = 0.5V IOH -7.6 — — mA VOH = 1.76V VIL -0.3 — 0.5(VccSI/O) - 0.18 V VIH 0.5(VccSI/O) + 0.18 — VccSI/O + 0.3 V IOH(AC) Switching -12(VccI/O) — — mA 0 < VOUT < 0.3(VccI/O) -17.1(VccI/O - VOUT) — — mA 0.3(VccI/O) < VOUT < 0.9(VccI/O) — — -32(VccI/O) — 0.7(VccI/O) 16(VccI/O) — See Note 1 mA 0.7(VccI/O) < VOUT < VccI/O +16(VccI/O) — — mA VccI/O > VOUT > 0.6(VccI/O) +26.7(VOUT) — — mA 0.6(VccI/O) > VOUT > 0.1(VccI/O) — — +38(VccI/O) mA VOUT = 0.18(VccI/O) — — See Note 2 mA 0.18(VccI/O) > VOUT > 0 VIL -0.3 — 0.3(VccI/O) V VIH 0.5(VccI/O) — 5.5 V CIN — — 10.5 pF — Inputs — — + 10 µA Vcc (max) I/OLEAK W/O Pull-ups/ downs — — + 10 µA Vcc (max) I/OLEAK WITH Pull-ups/ downs — — + 80 µA Vcc (max) IOL(AC) Switching Capacitance Leakage Table 18 DC Electrical Characteristics Note 1: IOH(AC) max = (98/VCCI/O) * (VOUT - VCCI/O) * (VOUT + 0.4VCCI/O) Note 2: IOL(AC) max = (256/VCCI/O) * VOUT * (VCCI/O - VOUT) 38 of 53 January 19, 2006 IDT RC32434 AC Test Conditions Input Reference Voltage 50 Ω RC32434 Output . Parameter Input pulse levels Input rise/fall Input reference level Output reference levels AC test load Test Point 50 Ω Value Units SSTL I/O Other I/O 0 to 2.5 0 to 3.3 V 0.8 1.0 ns 0.5(VccSI/O) 0.5(VccI/O) V 1.25 1.5 V 35 35 pF Figure 23 AC Test Conditions 39 of 53 January 19, 2006 IDT RC32434 Absolute Maximum Ratings Symbol VCCI/O Parameter I/O supply except for SSTL_22 2 Min1 Max1 Unit -0.6 4.0 V -0.6 4.0 V VCCSI/O (DDR) I/O supply for SSTL_2 VCCCore Core Supply Voltage -0.6 2.0 V VCCPLL PLL supply (digital) -0.6 2.0 V VCCAPLL PLL supply (analog) -0.6 4.0 V VinI/O I/O Input Voltage except for SSTL_2 -0.6 VccI/O+ 0.5 V VinSI/O I/O Input Voltage for SSTL_2 -0.6 VccSI/O+ 0.5 V Ta Industrial Ambient Operating Temperature -40 +85 °C Ta Commercial Ambient Operating Temperature 0 +70 °C Ts Storage Temperature -40 +125 °C Table 19 Absolute Maximum Ratings 1. Functional and tested operating conditions are given in Table 15. Absolute maximum ratings are stress ratings only, and functional operation at the maximums is not guaranteed. Stresses beyond those listed may affect device reliability or cause permanent damage to the device. 2. SSTL_2 I/Os are used to connect to DDR SDRAM. 40 of 53 January 19, 2006 IDT RC32434 Package Pin-out — 256-BGA S Signal ignal Pinout for the RC32434 The following table lists the pin numbers, signal names, and number of alternate functions for the RC32434 device. Signal names ending with an “_n” or “n” are active when low. Pin Function Alt Pin Function Alt Pin Function A1 RWN E1 MIIRXD[3] J1 GPIO[3] A2 OEN E2 MIIRXD[2] J2 JTAG_TCK A3 CSN[2] E3 MIITXD[0] J3 GPIO[2] A4 CSN[0] E4 MIITXD[1] J4 A5 MADDR[10] E5 Vcc I/0 A6 MDATA[6] E6 A7 GPIO[7] 1 A8 GPIO[4] 1 A9 Alt Function N1 PCIAD[29] N2 PCIAD[28] N3 PCIAD[30] EJTAG_TMS N4 PCIAD[18] J5 Vcc CORE N5 PCIREQN[1] Vcc I/0 J6 Vss N6 PCIREQN[2] E7 Vcc I/0 J7 Vss N7 PCIIRDYN E8 Vcc CORE J8 Vss N8 PCILOCKN MADDR[16] E9 Vcc CORE J9 Vss N9 PCIPERRN A10 MADDR[13] E10 Vcc I/0 J10 Vss N10 PCIAD[15] A11 Vss PLL E11 Vcc DDR J11 Vcc CORE N11 PCIAD[11] A12 JTAG_TDI E12 Vcc DDR J12 Vcc CORE N12 PCICBEN[0] A13 MADDR[9] E13 DDRDATA[6] J13 DDRCKN N13 DDRADDR[5] A14 MADDR[7] E14 DDRDATA[5] J14 DDRVREF N14 DDRADDR[4] A15 MADDR[5] E15 DDRADDR[13] J15 DDRCKP N15 DDRADDR[3] A16 MADDR[2] E16 DDRDATA[4] J16 DDRDQS[0] N16 DDRBA[0] B1 BOEN F1 MIITXD[2] K1 JTG_TDO P1 PCIAD[27] B2 RSTN F2 MIIRXCLK K2 SCK P2 PCIAD[26] B3 CSN[3] F3 MIITXD[3] K3 Reserved P3 GPIO[10] B4 CSN[1] F4 MIITXENP K4 SDO P4 PCIAD[20] B5 MADDR[11] F5 Vcc I/0 K5 Vcc I/0 P5 PCIREQN[3] B6 MDATA[1] F6 Vss K6 Vcc I/0 P6 PCIREQN[0] B7 MDATA[4] F7 Vss K7 Vss P7 PCIFRAMEN B8 GPIO[5] F8 Vss K8 Vss P8 PCISTOPN B9 MADDR[17] F9 Vcc CORE K9 Vss P9 PCISERRN B10 MADDR[12] F10 Vss K10 Vss P10 PCIAD[14] B11 Vcc PLL F11 Vss K11 Vss P11 PCIAD[10] B12 Vss APLL F12 Vcc DDR K12 Vcc DDR P12 PCIAD[7] B13 MADDR[8] F13 DDRDATA[9] K13 DDRCKE P13 PCIAD[4] B14 MADDR[6] F14 DDRDATA[8] K14 DDRADDR[11] P14 DDRADDR[0] B15 MADDR[3] F15 DDRDM[0] K15 DDRADDR[10] P15 DDRADDR[2] B16 MADDR[1] F16 DDRDATA[7] K16 DDRADDR[12] P16 DDRCSN C1 EXTCLK G1 MIIRXDV L1 SDA R1 PCIAD[25] 1 1 Pin 1 Alt 1 Table 20 RC32434 Pinout (Part 1 of 2) 41 of 53 January 19, 2006 IDT RC32434 Pin Function Alt Pin Function Alt Pin Function C2 BDIRN G2 MIITXER L2 SCL C3 COLDRSTN G3 MIIRXER L3 GPIO[8] C4 WEN G4 MIITXCLK L4 C5 MDATA[3] G5 Vcc I/0 C6 MDATA[5] G6 C7 GPIO[6] C8 Alt Pin Function R2 PCICBEN[3] R3 PCIAD[23] SDI R4 PCIAD[21] L5 Vcc I/0 R5 PCIAD[17] Vss L6 Vss R6 PCIRSTN G7 Vss L7 Vss R7 PCICBEN[2] MADDR[21] G8 Vss L8 Vcc CORE R8 PCITRDYN C9 MADDR[18] G9 Vss L9 Vss R9 PCICBEN[1] C10 MADDR[14] G10 Vss L10 Vss R10 PCIAD[12] C11 JTAG_TMS G11 Vss L11 Vss R11 PCIAD[8] C12 Vcc APLL G12 Vcc DDR L12 Vcc DDR R12 PCIAD[5] C13 CLK G13 DDRDM[1] L13 DDRADDR[9] R13 PCIAD[3] C14 MADDR[4] G14 DDRDQS[1] L14 DDRWEN R14 PCIAD[0] C15 MADDR[0] G15 DDRDATA[10] L15 DDRCASN R15 PCIGNTN[2] C16 DDRDATA[0] G16 DDRDATA[11] L16 DDRADDR[8] R16 DDRADDR[1] D1 MIIRXD[0] H1 MIIMDIO M1 GPIO[12] T1 PCIAD[24] D2 MIICL H2 MIIMDC M2 PCIAD[31] T2 GPIO[13] D3 MIICRS H3 GPIO[0] 1 M3 GPIO[11] 1 T3 PCIAD[22] D4 MIIRXD[1] H4 GPIO[1] 1 M4 GPIO[9] 1 T4 PCIAD[19] D5 MDATA[7] H5 Vcc CORE M5 Vcc I/0 T5 PCIAD[16] D6 MDATA[2] H6 Vcc CORE M6 Vcc I/0 T6 PCICLK D7 MDATA[0] H7 Vss M7 Vcc I/0 T7 PCIGNTN[0] D8 MADDR[20] H8 Vss M8 Vcc CORE T8 PCIDEVSELN D9 MADDR[19] H9 Vss M9 Vcc CORE T9 PCIPAR D10 MADDR[15] H10 Vss M10 Vcc I/0 T10 PCIAD[13] D11 EXTBCV H11 Vss M11 Vcc DDR T11 PCIAD[9] D12 JTAG_TRSTN H12 Vcc CORE M12 Vcc DDR T12 PCIAD[6] D13 WAITACKN H13 DDRDATA[15] M13 DDRRASN T13 PCIAD[2] D14 DDRDATA[2] H14 DDRDATA[14] M14 DDRBA[1] T14 PCIAD[1] D15 DDRDATA[3] H15 DDRDATA[12] M15 DDRADDR[6] T15 PCIGNTN[1] D16 DDRDATA[1] H16 DDRDATA[13] M16 DDRADDR[7] T16 PCIGNTN[3] 1 1 1 Alt 1 Table 20 RC32434 Pinout (Part 2 of 2) 42 of 53 January 19, 2006 IDT RC32434 RC32434 Alternate Signal Functions Pin GPIO Alternate Pin GPIO Alternate A7 GPIO[7] MADDR[25] J3 GPIO[2] U0RTSN A8 GPIO[4] MADDR[22] L3 GPIO[8] CPU B8 GPIO[5] MADDR[23] M1 GPIO[12] PCIGNTN[5] C7 GPIO[6] MADDR[24] M3 GPIO[11] PCIREQN[5] H3 GPIO[0] U0SOUT M4 GPIO[9] PCIREQN[4] H4 GPIO[1] U0SINP P3 GPIO[10] PCIGNTN[4] J1 GPIO[3] U0CTSN T2 GPIO[13] PCIMUINTN Table 21 RC32434 Alternate Signal Functions RC32434 P Power ower Pins Pins Vcc I/O Vcc DDR Vcc Core Vcc PLL Vcc APLL E5 E11 E8 B11 C12 E6 E12 E9 E7 F12 F9 E10 G12 H5 F5 K12 H6 G5 L12 H12 K5 M11 J5 K6 M12 J11 L5 J12 M5 L8 M6 M8 M7 M9 M10 Table 22 RC32434 Power Pins 43 of 53 January 19, 2006 IDT RC32434 RC32434 Ground Ground Pins Vss Vss Vss PLL F6 J6 A11, B12 F7 J7 F8 J8 F10 J9 F11 J10 G6 K7 G7 K8 G8 K9 G9 K10 G10 K11 G11 L6 H7 L7 H8 L9 H9 L10 H10 L11 H11 Table 23 RC32434 Ground Pins RC32434 S Signals ignals Listed Alphabetically The following table lists the RC32434 pins in alphabetical order. Signal Name I/O Type Location Signal Category BDIRN O C2 Memory and Peripheral Bus BOEN O B1 CLK I C13 COLDRSTN I C3 CSN[0] O A4 CSN[1] O B4 CSN[2] O A3 CSN[3] O B3 System Memory and Peripheral Bus Table 24 RC32434 Alphabetical Signal List (Part 1 of 7) 44 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category DDRADDR[0] O P14 DDR Bus DDRADDR[1] O R16 DDRADDR[2] O P15 DDRADDR[3] O N15 DDRADDR[4] O N14 DDRADDR[5] O N13 DDRADDR[6] O M15 DDRADDR[7] O M16 DDRADDR[8] O L16 DDRADDR[9] O L13 DDRADDR[10] O K15 DDRADDR[11] O K14 DDRADDR[12] O K16 DDRADDR[13] O E15 DDRBA[0] O N16 DDRBA[1] O M14 DDRCASN O L15 DDRCKE O K13 DDRCKN O J13 DDRCKP O J15 DDRCSN O P16 DDRDATA[0] I/O C16 DDRDATA[1] I/O D16 DDRDATA[2] I/O D14 DDRDATA[3] I/O D15 DDRDATA[4] I/O E16 DDRDATA[5] I/O E14 DDRDATA[6] I/O E13 DDRDATA[7] I/O F16 DDRDATA[8] I/O F14 DDRDATA[9] I/O F13 DDRDATA[10] I/O G15 DDRDATA[11] I/O G16 DDRDATA[12] I/O H15 DDRDATA[13] I/O H16 DDRDATA[14] I/O H14 Table 24 RC32434 Alphabetical Signal List (Part 2 of 7) 45 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category DDRDATA[15] I/O H13 DDR Bus DDRDM[0] O F15 DDRDM[1] O G13 DDRDQS[0] I/O J16 DDRDQS[1] I/O G14 DDRRASN O M13 DDRVREF I J14 DDRWEN O L14 EJTAG_TMS I J4 JTAG / EJTAG EXTBCV I D11 System EXTCLK O C1 GPIO[0] I/O H3 GPIO[1] I/O H4 GPIO[2] I/O J3 GPIO[3] I/O J1 GPIO[4] I/O A8 GPIO[5] I/O B8 GPIO[6] I/O C7 GPIO[7] I/O A7 GPIO[8] I/O L3 GPIO[9] I/O M4 GPIO[10] I/O P3 GPIO[11] I/O M3 GPIO[12] I/O M1 GPIO[13] I/O T2 JTAG_TCK I J2 JTAG_TDI I A12 JTAG_TDO O K1 JTAG_TMS I C11 JTAG_TRSTN I D12 General Purpose Input/Output JTAG / EJTAG Table 24 RC32434 Alphabetical Signal List (Part 3 of 7) 46 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category MADDR[0] O C15 Memory and Peripheral Bus MADDR[1] O B16 MADDR[2] O A16 MADDR[3] O B15 MADDR[4] O C14 MADDR[5] O A15 MADDR[6] O B14 MADDR[7] O A14 MADDR[8] O B13 MADDR[9] O A13 MADDR[10] O A5 MADDR[11] O B5 MADDR[12] O B10 MADDR[13] O A10 MADDR[14] O C10 MADDR[15] O D10 MADDR[16] O A9 MADDR[17] O B9 MADDR[18] O C9 MADDR[19] O D9 MADDR[20] O D8 MADDR[21] O C8 MDATA[0] I/O D7 MDATA[1] I/O B6 MDATA[2] I/O D6 MDATA[3] I/O C5 MDATA[4] I/O B7 MDATA[5] I/O C6 MDATA[6] I/O A6 MDATA[7] I/O D5 Table 24 RC32434 Alphabetical Signal List (Part 4 of 7) 47 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category MIICL I D2 Ethernet Interface MIICRS I D3 MIIMDC O H2 MIIMDIO I/O H1 MIIRXCLK I F2 MIIRXD[0] I D1 MIIRXD[1] I D4 MIIRXD[2] I E2 MIIRXD[3] I E1 MIIRXDV I G1 MIIRXER I G3 MIITXCLK I G4 MIITXD[0] O E3 MIITXD[1] O E4 MIITXD[2] O F1 MIITXD[3] O F3 MIITXENP O F4 MIITXER O G2 OEN O A2 Memory and Peripheral Bus PCIAD[0] I/O R14 PCI Bus Interface PCIAD[1] I/O T14 PCIAD[2] I/O T13 PCIAD[3] I/O R13 PCIAD[4] I/O P13 PCIAD[5] I/O R12 PCIAD[6] I/O T12 PCIAD[7] I/O P12 PCIAD[8] I/O R11 PCIAD[9] I/O T11 PCIAD[10] I/O P11 PCIAD[11] I/O N11 PCIAD[12] I/O R10 PCIAD[13] I/O T10 PCIAD[14] I/O P10 PCIAD[15] I/O N10 PCIAD[16] I/O T5 Table 24 RC32434 Alphabetical Signal List (Part 5 of 7) 48 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category PCIAD[17] I/O R5 PCI Bus Interface PCIAD[18] I/O N4 PCIAD[19] I/O T4 PCIAD[20] I/O P4 PCIAD[21] I/O R4 PCIAD[22] I/O T3 PCIAD[23] I/O R3 PCIAD[24] I/O T1 PCIAD[25] I/O R1 PCIAD[26] I/O P2 PCIAD[27] I/O P1 PCIAD[28] I/O N2 PCIAD[29] I/O N1 PCIAD[30] I/O N3 PCIAD[31] I/O M2 PCIBEN[0] I/O N12 PCIBEN[1] I/O R9 PCIBEN[2] I/O R7 PCIBEN[3] I/O R2 I T6 PCIDEVSELN I/O T8 PCIFRAMEN I/O P7 PCIGNTN[0] I/O T7 PCIGNTN[1] I/O T15 PCIGNTN[2] I/O R15 PCIGNTN[3] I/O T16 PCIIRDYN I/O N7 PCILOCKN I/O N8 PCIPAR I/O T9 PCIPERRN I/O N9 PCIREQN[0] I/O P6 PCIREQN[1] I/O N5 PCIREQN[2] I/O N6 PCIREQN[3] I/O P5 PCIRSTN I/O R6 PCISERRN I/O P9 PCICLK Table 24 RC32434 Alphabetical Signal List (Part 6 of 7) 49 of 53 January 19, 2006 IDT RC32434 Signal Name I/O Type Location Signal Category PCISTOPN I/O P8 PCI Bus Interface PCITRDYN I/O R8 RSTN I/O B2 System RWN O A1 Memory and Peripheral Bus SCK I/O K2 Serial Peripheral Interface SCL I/O L2 I2C SDA I/O L1 SDI I/O L4 SDO I/O K4 Vcc APLL C12 Vcc Core E8, E9, F9, H5, H6, H12, J5, J11, J12, L8, M8, M9 Vcc DDR E11, E12, F12, G12, K12, L12, M11, M12 Vcc I/O E5, E6, E7, E10, F5, G5, K5, K6, L5, M5, M6, M7, M10 Vcc PLL B11 Vss F6, F7, F8, F10, F11, G6, G7, G8, G9, G10, G11, H7, H8, H9, H10, H11, J6, J7, J8, J9, J10, K7, K8, K9, K10, K11, L6, L7, L9, L10, L11 Vss APLL B12 Vss PLL A11 WAITACKN I D13 WEN O C4 Reserved Serial Peripheral Interface Power Ground Memory and Peripheral Bus K3, L1, L2 Table 24 RC32434 Alphabetical Signal List (Part 7 of 7) 50 of 53 January 19, 2006 IDT RC32434 RC32434 Package Package Drawing — 256-pin CABGA CABGA 51 of 53 January 19, 2006 IDT RC32434 RC32434 P Package ackage Drawing — Page Two 52 of 53 January 19, 2006 IDT RC32434 Ordering Information 79RCXX Product Type YY Operating Voltage XXXX 999 Device Type Speed A A Package Temp range/ Process Blank Commercial Temperature (0°C to +70°C Ambient) I Industrial Temperature (-40° C to +85° C Ambient) BC 256-pin CABGA 266 300 350 400 266 MHz Pipeline Clk 300 MHz Pipeline Clk 350 MHz Pipeline Clk 400 MHz Pipeline Clk 434 Integrated Core Processor H 1.2V +/- 0.1V Core Voltage 79RC32 32-bit Embedded Microprocessor Valid Combinations 79RC32H434 - 266BC, 300BC, 350BC, 400BC 256-pin CABGA package, Commercial Temperature 79RC32H434 - 266BCI, 300BCI, 350BCI 256-pin CABGA package, Industrial Temperature CORPORATE HEADQUARTERS 6024 Silver Creek Valley Road San Jose, CA 95138 for SALES: 800-345-7015 or 408-284-8200 fax: 408-284-2775 www.idt.com 53 of 53 for Tech Support: email: [email protected] phone: 408-284-8208 January 19, 2006