IDT IDT79RC32V134DS

RISCore32300TM Family
System Controller Chip
Features
IDT79RC32134
– 8/16/ or 32-bit interface per bank
– Supports Flash ROM, SRAM, dual-port memory, and peripheral devices
– Intel or Motorola style IO supports external wait-state generation
◆ 4 DMA Channels
– 4 general purpose DMA, each with Endianness swappers and
byte lane data alignment
– Any channel can be used for PCI
– Supports memory-to-memory, memory-to-I/O,memory-toPCI, PCI-to-PCI, I/O-to-I/O transfers, and I/O support of
scatter/gather
– Supports chaining via linked lists of records
– Supports unaligned transfers
– Supports burst transfers
– Programmable burst size
◆
PCI Bridge
– 32-bit PCI, up to 33 MHz
– Revision 2.1 compliant
– Target and master
– Host or satellite
– Three slot PCI arbiter, on-chip
– Serial EEPROM support, for loading configuration
registers
◆ 3.3V core operation
◆
3.3V I/O operation with 5V tolerant I/O
◆
208 pin PQFP package
RC32300-family System Controller
– Direct connection between RC32364 and RC32134
– Up to 75 MHz operation
– Drives latched address bus to memory and peripherals
– Direct control of optional external data buffers
– Programmable system watch-dog timers
– Big or Little endian support
◆
Interrupt Control
– Provides services for internal and external sources
– Allows status of each interrupt to be read and masked
◆
Three general purpose 32-bit timer/counters
◆ Programmable IO (PIO)
– Input/Output/Interrupt source
– Individually programmable
◆ SDRAM/EDODRAM Controller (32-bit memory only)
– 4 banks, non-interleaved, 256 MB total
– Automatic refresh generation
◆ UART Interface
– Two 16550 Compatible UARTs
– Baud rate support up to 1.5M
◆ 8/16/32-bit boot PROM support
◆
Boundary Scan JTAG Interface (IEEE Std. 1149.1
compatible)
◆
Memory & Peripheral Controller
– 6 banks, up to 8MB per bank
◆
Block Diagram
Data & Address bus
CPU I/F
Timer, UART,
Interrupt Modules
EDO/SDRAM
Control
Memory I/O
Control
DMA Channels
RC32134
SDRAM/EDODRAM Control
Memory &
I/O Control
PCI I/F and Bridge
PCI Bus
The IDT logo is a registered trademark. RC64145, RC64474, RC64475, RC32134, RC4600, RC4640, RC4650, RC4700, RC3041, RC3051, RC3052, RC3081, RISController, and RISCore are trademarks of Integrated Device Technology, Inc.
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 2000 Integrated Device Technology, Inc.
April 9, 2001
DSC 5602
IDT79RC32134
Description
The IDT79RC32134 is a high performance system controller chip
that supports IDT’s RISCore32300 CPU family. The RC32134 offers a
direct connection to IDT’s RC32364 32-bit embedded microprocessor.
The RC32134 provides the system logic for boot memory, main memory,
I/O, and PCI. It also includes on-chip peripherals such as DMA channels, reset circuitry, interrupts, timers, and UARTs. Together, the
RC32364 CPU and the RC32134 system controller form a complete
CPU subsystem for embedded designs.
Figure 1 illustrates the typical system implementation, based on the
RC32364 CPU and the RC32134 system controller. The RC32134 interfaces directly to the RC32364 and provides all of the necessary control
and address signals to drive the external memory and I/O. Note that,
depending on the loading of the CPU data bus, external data buffers
could be used to reduce the loading and isolate different memory
regions. As illustrated in the system block diagram, the memory and I/O
data path is external to the RC32134.
Device Overview
The RC32134 interfaces directly to the RC32364’s system bus. The
RC32134 latches the address from the RC32364 internally and decodes
it to detect which memory, I/O, or on-chip peripheral is being accessed,
per the internal address map of the RC32134. The RC32134 generates
all necessary control signals and address buses to the external memory
and I/O. For main memory, I/O, on-chip peripherals, registers, and PCI,
the RC32134 divides the physical address space into 14 different
regions.
The data path for the local memory and peripherals (with the exception of PCI) is external to the RC32134. The data path from the PCI bus
and from the internal peripherals and registers is internal to the
RC32134.
Memory Controller. The Memory Controller on the RC32134
provides all of the address buses and control signals for interfacing the
RC32364 CPU to standard SRAM, PROM, FLASH, and I/O and
includes the boot PROM interface. The memory controller provides six
individual chip selects and supports 8,16, and 32-bit wide memory and I/
Os. Two chip selects have highly configurable memory address ranges,
allowing selection of various memory types and widths to be supported.
The RC32134 provides controls for optional external data transceivers
for systems that require fast signalling with large loads.
SDRAM Controller. The SDRAM controller optimization provides
higher throughput while using available DRAM technology. The SDRAM
control register directly manages four banks of 32-bit physical non-interleaved memory. Each bank is 32-bits wide and supports a maximum of
64 MB per bank. Total memory support is 256 MB. The SDRAM
controller has a built in refresh generator.
EDO DRAM Controller. The RC32134 EDO DRAM Controller
supports up to 4 banks of non-interleaved 32-bit wide EDO DRAMs.
Most of the EDO DRAM pins are shared with the SDRAM controller, and
as such, the two operations can not be simultaneously enabled. Selection between SDRAM or EDO DRAM is made at boot-time through
system software operations. The EDO supports 256 MB total of EDO
DRAM. The EDO controller has a built in refresh generator.
PCI Interface. To transfer data between main memory and the PCI
bus, the RC32134 incorporates a PCI interface. At reset time the PCI
interface can be configured as either a host or satellite interface. The
PCI interface supports 32-bit PCI at up to 33MHz and is PCI Specification, Revision 2.1 compliant.
RC32364
Clock
32-bit Data
Bus
RC32134
CPU I/F
Serial
PIO
Timers,
UART,
Interrupt Ctl
DRAM Ctl
DMA
Channels
Memory &
I/O Ctl
SDRAM
Address &
Control
Memory
& I/O
PCI Bridge with Arbiter
32-bit, 33Mhz PCI Bus
Figure 1 System Block Diagram
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IDT79RC32134
As a PCI master, the RC32134 can generate memory, I/O, or configuration cycles for direct local-to-PCI bus accesses. The PCI interface
incorporates a 3-slot PCI bus arbiter, which includes fixed and round
robin arbitration modes.
As a PCI target, the RC32134 allows access to its internal registers
and to the RISCore32300 local bus through the PCI I/O read and write,
or Memory read and write commands. The RC32134 PCI interface
supports swapping little endian data to big endian, when the CPU
subsystem is configured as a big endian system. For more information
on the PDCI interface, please refer to the PCI Specification, Revision
2.1.
DMA Controller. Four general purpose DMA channels move data
between source and destination ports. Source and destination ports can
be system memory, PCI or I/O devices. Any of the four channels can be
used for PCI initiator reads or writes. All four channels support a
descriptor structure, to allow efficient data scatter/gather. The DMA
controller supports swapping of data between big and little endian
memory and I/O subsystems by memory region. It also supports quadword burst transfers. All external 16 and 8-bit memory I/Os are treated
as memory-mapped, word-aligned devices.
Expansion Interrupt Controller. The Expansion Interrupt Controller
provides the interrupt logic for software to analyze the various RC32134
generated system interrupts and adds to the control already provided
through the CP0 registers of the RC32364. Each system interrupt is
registered and the pending status provided through this feature. The
pending status can then be used to automatically generate a hardware
interrupt to the CPU via individual mask bits. The pending interrupt
status can also be optionally set or cleared by a direct software write.
PIO. Programmable I/O (PIO) pins are provided on the RC32134 so
that any unused peripheral pins can be programmed for use as general
purpose discrete I/O pins. These PIO pins can be software programmed
as bidirectional lines, allowing pin values to be software programmed in
output mode and software readable while in the input mode. The PIO
pins can also be used as a source of interrupts to the CPU. Maximum
Interfacing flexibility is thus provided without requiring extensive modifications to the board.
UART. The RC32134 incorporates two 16550 (an enhanced version
of the 16450) compatible UARTs. To relieve the CPU of software overhead, the 16550 UART can be put into FIFO mode, allowing execution
of either 16450 or 16550 compatible software. Two sets of 16-byte
FIFOs are enabled during the 16550 mode: one set in the receive data
path and one set in the transmit data path. A baud rate generator is
included that divides the system clock by 1 to 64K and provides a 16X
clock for driving the transmitter and receiver logic.
Timers/Counters. Three on-chip 32-bit general purpose Timers are
provided on the RC32134. Each timer consists of both a count and a
compare register. The count register resets to zero and then counts
upward until it equals the compare register. When the count and
compare registers are equal, the TC_n output is asserted and the count
is then reset to zero.
JTAG. Board-level manufacturing debugging is facilitated through
implementation of a fully compliant IEEE std. 1149.1 JTAG Boundary
Scan interface.
Thermal Considerations
The RC32134 is guaranteed in a case temperature range of 0°C to
+90°C, for commercial temperature devices; - 40°C to +90°C for industrial temperature devices. The speed (power) of the device and airflow
conditions affect the equivalent ambient temperature conditions that will
meet this specification. The equivalent allowable ambient temperature,
TA, can be calculated using the thermal resistance from case to ambient
(∅CA) of the given package. The following equation relates ambient and
case temperatures:
TA = TC - P * ∅CA
where P is the maximum power consumption at hot temperature,
calculated by using the maximum ICC specification for the device.
Typical values for ∅CA at various airflows are shown in Table 1
∅CA
Airflow (ft/min)
0
200
400
600
800
1000
208 PQFP
18
14
11
9
8
7
Table 1 Thermal Resistance (∅CA) at Various Airflows
Revision History:
July 21, 1999:
Changed the following: Thermal Resistance values; Table 2, Pin
Descriptions; Logic diagram - RC32134; Clock parameter temperature
from 85 to 90 degrees; AC timing characteristics - RC32134; DC electrical characteristics; Power consumption - RC32134; Absolute
maximum ratings diagram; Pin-out 208-PQFP table; RC32134 alternate
signal functions.
September 2, 1999: Corrected package drawing from 144-pin to
208-pin.
November 1, 1999: Removed Maximum column from Power
Consumption table.
November 9, 1999: Moved pin 208 (sdram_245_oe_n) from Low
drive to High drive in DC Electrical Characteristics Table.
April 28, 2000: Added Mode Configuration Interface Reset
Sequence figure on page 14.
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IDT79RC32134
January 6, 2000:
– Reordered Alternate Signals for the PIO Interface in Table 2
and changed pci_eeprom_mdi to pci_eeprom_mdo.
– Switched alternate pin signals for pci_eeprom_mdo and
pci_eeprom_mdi in PCI Interface section of Table 2.
– Switched alternate pin signals for uart_rx and uart_tx in UART
Interface section of Table 2.
– In RC32134 Alternate Signal Functions table, changed pin
designations under Alt #1 column for pins 22 - 29.
– Changed 64145 references to 32134 in the Note section of the
AC Timing Characteristics table.
– Updated the User Manual Timing Diagram Reference column
in the AC Timing Characteristics table.
March 20, 2000: Changed PCI speed to 33 MHz.
June 20, 2000: Values were revised for three local memory/peripheral bus signals in the AC Timing Characteristics table.
July 12, 2000: Revised Tsu and Thld symbol numbers in UART
section of AC Timing Characteristics table and revised reference to
timing diagram.
April 9, 2001: In the Local Memory/Peripheral bus section of the AC
Timing Characteristics table, deleted cpu_coldreset_n associated with
Tsu4.
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IDT79RC32134
Pin Description Table
The following table lists the pins provided on the RC32134. Note that several pins are multiplexed and have been assigned alternate functions.
These pins are designated and defined accordingly throughout this table. Also note that those pin names followed by _n are active-low signals.
Pin Name
Type Alternate Signal(s)
Description
Local Memory and Peripheral Pins
cpu_ad[31:0]
I/O
Not applicable
CPU Address/Data Bus
This is the RC32134’s primary multiplexed and bidirectional address and data bus. The RC32134
latches this bus internally and uses it to generate the necessary address lines to the external memory
and peripherals. If the transaction is a write, the CPU then drives data on cpu_ad(31:0). During CPU
generated transactions, the CPU drives Address(31:4) into the cpu_ad bus, during its address phase.
During DMA generated transactions (or RC32134 internal register reads), the address phase is
unused and the chip drives data during a write.
cpu_addr[3:2]
I
Not applicable
CPU LSB Address Bus
During CPU generated transactions, the CPU drives Address(3:2) onto the cpu_addr bus. The
RC32134 does not internally use the cpu_addr bus during the data phase. However, 8- or 16-bit
memory or I/O systems must attach these two pins instead of mem_addr(3:2).
cpu_ale
I
Not applicable
CPU Address Latch Enable
During CPU generated transactions, this signal indicates that the cpu_ad (31:0) is driving a valid
address and can be latched internally by the RC32134.
cpu_cip_n
I
Not applicable
CPU Cycle In Progress
During CPU generated transactions, this active-low signal indicates that a bus transaction is active.
An external pullup resistor is required.
cpu_wr_n
I
Not applicable
CPU Write Status
During CPU generated transactions, this active-low signal indicates whether or not a write is occurring. If a write is not occurring, then the implication is that a read is in progress.
cpu_be_n[3:0]
I
Not applicable
CPU Byte Enable Bus
During CPU generated transactions, these active-low signals indicate which byte lanes are in use.
Note: The table below indicates which cpu_be_n signal corresponds to which byte lane, whether or
not the system is in big or little endian mode
Data Bits
cpu_be_n[0]
7:0
cpu_be_n[1]
15:8
cpu_be_n[2]
23:16
cpu_be_n[3]
31:24
cpu_ack_n
O
Not applicable
CPU Acknowledge
During CPU generated transactions, this active-low signal is generated by the RC32134 to indicate
that the present data have been accepted.
cpu_last_n
I
Not applicable
CPU Last Data
During CPU generated transactions, this active-low signal indicates during the data phase that the
present data is the last data.
cpu_buserr_n
O
Not applicable
CPU Bus Error
During both CPU and DMA generated transactions, this active-low signal indicates that a bus error
has occurred. This signal can also be optionally attached to an interrupt line.
Table 2 RC32134 Pin Descriptions (Page 1 of 8)
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IDT79RC32134
Pin Name
Type Alternate Signal(s)
Description
cpu_masterclk
I
sdram_clk
CPU Master System Clock
Provides the basic system clock. This clock must be the same clock that is provided to the RC32364
and also, if used, to SDRAM.
cpu_coldreset_n
I
Not applicable
CPU Cold Reset
This active-low signal is asserted to the RC32364 CPU and RC32134 after Vcc becomes valid on the
initial power-up. The Reset initialization vectors, for both the RC32364 and the RC32134, are latched
by cold reset.
cpu_reset_n
O
Not applicable
CPU Warm Reset
This active-low signal is a secondary reset signal asserted to the CPU at least 256 clocks after cold
reset, allowing, for instance, stabilization of RC32364’s PLL.
cpu_busreq_n
O
Not applicable
CPU Bus Request
This active-low signal requests the CPU bus from the RC32364, for instance, by RC32134 to perform
a DMA operation.
cpu_busgnt_n
I
Not applicable
CPU Bus Grant
This active-low signal is a CPU bus grant from the RC32364, indicating that the local CPU bus has
been released to the RC32134.
cpu_int_n
O
interrupt_n
CPU Interrupt
This active-low signal is an interrupt indication to the CPU from RC32134’s Interrupt Controller. Note:
This pin is typically hooked up to the CPU’s interrupt 3.
cpu_dt_r_n
O
mem_245_dt_r_n,
sdram_245_dt_r_n,
edodram_245_dt_r_n
CPU Direction Transmit/Receive
This active-low signal controls the DT/R pin of an optional FCT245 transceiver bank. It is asserted
during DMA read operations. This signal is tri-stated during CPU accesses (when the CPU owns the
bus) and driven during DMA generated accesses. Note: An external pull-up resistor is required.
pci_ad[31:0]
I/O
Not applicable
PCI Multiplexed Address/Data Bus
This address is driven by the Bus Master during initial frame_n assertion. The Data is then driven by
the Bus Master during writes; or the Data is driven by the Bus Slave during reads.
pci_cbe_n[3:0]
I/O
Not applicable
PCI Multiplexed Command/Byte Enable Bus
The Command bus (active high) is driven by the Bus Master during the initial frame_n assertion.
The Byte Enable bus (active low) is driven by the Bus Master during the data phase(s).
Note: The table below indicates which cpu_be_n signal corresponds to which byte lane, whether or
not the system is in big or little endian mode.
PCI Interface
Data Bits
pci_be[0]
7:0
pci_be[1]
15:8
pci_be[2]
23:16
pci_be[3]
31:24
pci_par
I/O
Not applicable
PCI Parity
This signal indicates even parity of the pci_ad[31:0] bus and is driven by the Bus Master during
Address and Write Data phases. During the Read data phase, this signal is driven by the Bus Slave.
pci_frame_n
I/O
Not applicable
PCI Frame Negated
This active-low signal is driven by the Bus Master and indicates the duration of a PCI transfer. Assertion indicates the beginning of a bus transaction. De-assertion indicates the last data.
Table 2 RC32134 Pin Descriptions (Page 2 of 8)
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IDT79RC32134
Pin Name
Type Alternate Signal(s)
Description
pci_trdy_n
I/O
Not applicable
PCI Target Ready Negated
This active-low signal is driven by the Bus Slave and indicates that the current data can complete (the
bus slave can accept/drive data).
pci_irdy_n
I/O
Not applicable
PCI Initiator Ready Negated
Driven by the Bus Master, this active-low signal indicates that the current data can complete (PCI initiator is ready to accept/drive data).
pci_stop_n
I/O
Not applicable
PCI Stop Negated
Driven by the Bus Slave this active-low signal terminates the current bus transaction.
pci_idsel
I
pci_req_n[2]
PCI Initialization Device Select
Host mode: pci_req_n[2] is an input indicating a request from an external device.
Satellite mode: used as pci_idsel pin which selects this device during a configuration read or write.
pci_perr_n
I/O
Not applicable
PCI Parity Error Negated
Driven by the receiving Bus Agent 2 clocks after the data is received, if a parity error occurs.
pci_serr_n
I/O
Not applicable
System Error
Driven by any agent, this active-low signal indicates an address parity error, data parity during a Special Cycle command, or any other system error. An external 2.7K (5V) ohm or 8.2K (3.3V) ohm pullup resistor is required, per the PCI revision 2.1 specifications.
pci_clk
I
Not applicable
PCI Clock
Clock for PCI bus transactions that uses the rising edge for all timing references. Note that the PCI
clock does not need to be synchronized to the cpu_masterclk.
pci_rst_n
I
Not applicable
PCI Reset Negated
In Host mode, this active-low signal resets all PCI related logic. In Satellite mode, with boot from
PCI mode, this signal resets all PCI related logic and also asserts the warm reset, cpu_rst_n, to the
RC32134. and the RC32364.
pci_devsel_n
I/O
Not applicable
PCI Device Select Negated
This active-low signal is driven by the target to indicate that the target has decoded the present
address as a target address.
pci_req_n[2]
I
pci_idsel
PCI Bus Request #2 Negated
This is an active-low signal that in Host mode is an input indicating a request from an external
device. In Satellite mode pci_req_n[2] is used as the pci_idsel pin, which selects this device during a
configuration read or write.
pci_req_n[1]
I
Not applicable
PCI Bus Request #1 Negated
In Host mode, pci_req_n[1] is an input indicating a request from an external device. In Satellite
mode pci_req_n[1] is unused.
pci_req_n[0]
I/O
Not applicable
PCI Bus Request #0 Negated
In Host mode, this active-low signal is an input indicating a request from an external device. In Satellite mode, pci_req_n[0] is an output indicating a request from this device.
pci_gnt_n[2]
O
pci_inta_n
PCI Bus Grant #2 Negated
In Host mode, this active-low signal is an output indicating a grant to an external device. In Satellite
mode, pci_gnt_n[2] is used as the pci_inta_n output pin. An external 5k ohm pull-up resistor is
required, per the PCI revision 2.1 specifications.
Note: In host mode, int_n[1] on the RC32364 can be used for a pci_inta_n input and pci_int[d:c:b]_n
uses int_n[5:4:2] on the RC32364 Bus Interface.
pci_gnt_n[1]
O
pci_eeprom_cs
PCI Bus Grant #1 Negated
In Host mode, this active-low signal is an output indicating grants to external devices. In Satellite
mode, pci_gnt_n[1] is used as the pci_eeprom_cs output pin for Serial Chip Select, for loading PCI
Configuration Registers in the RC32134 Reset Initialization Vector PCI boot mode.
Table 2 RC32134 Pin Descriptions (Page 3 of 8)
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IDT79RC32134
Pin Name
Type Alternate Signal(s)
Description
pci_gnt_n[0]
I/O
Not applicable
PCI Bus Grant #0 Negated
In Host mode, this active-low signal is an output indicating a grant to an external device. In Satellite
mode, pci_gnt_n[0] is an input indicating a grant to this device.
pci_inta_n
I/O
pci_gnt_n[2]
PCI Interrupt #A Negated
In Host mode,pci_gnt_n[2] is an output indicating a grant to an external device. In Satellite mode,
pci_gnt_n[2] is used as the pci_inta_n output pin. An external pull-up is required, per the PCI revision
2.1 specifications.
Note: In host mode, int_n[1] on the RC32364 can be used for a pci_inta_n input and pci_int[d:c:b]_n
uses int_n[5:4:2] on the RC32364 Bus Interface.
pci_lock_n
I
Not applicable
PCI Lock Negated
This active-low signal is driven by the Bus Master and indicates that an exclusive operation is occurring.
pci_eeprom_mdo
I/O
pio[11]
PCI EEPROM Master Data Out
In Serial mode, this signal is an output pin from RC32134 that connects as an Input to a Serial Chip
for the Serial data input stream. In PCI satellite mode, it is an output pin from RC32134 that connects as an Input to a Serial Chip for the Serial data input stream for loading PCI Configuration Registers in the RC32134 Reset Initialization Vector PCI boot mode. This pin is also multiplexed as a PIO
pin.
pci_eeprom_mdi
I/O
pio[8]
PCI EEPROM Master Data In
The Serial mode provides an input pin to RC32134 from the Output of a Serial Chip for the Serial
data output stream. The PCI satellite mode provides an input pin to RC32134 from the Output of a
Serial Chip for the Serial data output stream, for PCI Configuration Registers in the RC32134 Reset
Initialization Vector PCI boot mode. This pin is also multiplexed as a PIO pin.
pci_eeprom_cs
I/O
pci_gnt_n[1]
PCI EEPROM Chip Select
Host mode: pci_gnt_n[1] is an output indicating grants to external devices.
Satellite mode: Used as pci_eeprom_cs output pin for SPI Chip Select for loading PCI Configuration
Registers in the RC32134 Reset Initialization Vector PCI boot mode.
pci_eeprom_sk
I/O
pio[10]
PCI EEPROM Serial Clock
Serial mode: Output pin for Serial Clock.
PCI satellite mode: Output pin for Serial Clock for loading PCI Configuration Registers in the
RC32134 Reset Initialization Vector PCI boot mode. This pin is also multiplexed as a PIO pin.
I/O
edodram_addr[15:2]
sdram_addr[15:13]
sdram_addr[11:2]
Memory Address Bus
These signals provide the Memory or DRAM address, during a Memory or DRAM bus transactiion.
During each word data, the address increments either in linear or sub-block ordering, depending on
the transaction type. For 32-bit system, use mem_addr[3:2] for the least significant address bits [3:2].
For 8 or 16-bit wide ports, to provide the least significant address bits [3:0], use cpu_addr[3:2] and
cpu_be_n[1:0].
Memory/I/O Controller
mem_addr[22:2]
mem_addr subsets
mem_cs_n[5:0]
O
Not applicable
mem_addr[22:20]
I/O
reset_boot_mode[1:0]
reset_pci_host_mode
mem_addr[15:2]
I/O
sdram_addr[15:13]
sdram_addr[11:2]
edodram_addr[15:2]
Memory Chip Select Negated
This active-low signal indicates that a Memory or I/O Bank is actively selected.
Table 2 RC32134 Pin Descriptions (Page 4 of 8)
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IDT79RC32134
Pin Name
Type Alternate Signal(s)
Description
mem_oe_n
O
Not applicable
Memory Output Enable Negated
This active-low signal indicates that either a Memory or I/O Bank can output its data lines onto the
cpu_ad bus.
mem_we_n[3:0]
O
Not applicable
Memory Write Enable Negated Bus
These active-low signals indicate which bytes are to be written during a memory or I/O transaction.
mem_wait_n
I
edo_dram_wait_n
Memory Wait Negated
In MEM, IOI, IOM modes this active-low signal allows external wait-states to be injected during the
last cycle before data is sampled. In DPM (dual-port) mode, this signal allows dual-port busy signal
to restart memory transaction.
mem_245_oe_n
O
Not applicable
Memory FCT245 Output Enable Negated
This active-low signal controls output enable to optional FCT245 transceiver bank by asserting during
both reads and writes to a memory or I/O bank.
mem_245_dt_r_n
O
cpu_dt_r_n
Memory FCT245 Direction Xmit/Rcv Negated
Uses the cpu_dt_r_n pin.
edodram_addr[15:2]
O
mem_addr[15:2]
Edodram_addr/sdram_addr mode
These are output signals that provide a DRAM address during a DRAM transaction. The DRAM
address multiplexes between Row and Column Addresses. During each word data, the column
address increments either in linear or sub-block ordering, depending on the type of transaction.
Allows an external memory debug emulator to inject wait-states. For more detail, see the user’s manual.
edodram_ras_n[3:0]
O
sdram_cs_n[3:0]
DRAM Row Address Strobe Negated Bus
SDRAM mode: Provides chip select to each SDRAM bank.
EDODRAM mode: Used as edodram_ras_n[3:0] pins to provide a RAS signal for each EDODRAM
bank.
edodram_cas_n[3:0]
O
sdram_bemask_n[3:0]
DRAM Column Address Strobe Negated Bus
In the EDODRAM mode these signals are used as edodram_cas_n[3:0] to provide a CAS signal for
each byte lane. In the SDRAM mode, these signals provide byte enables for each byte lane of all
DRAM banks.
edodram_oe_n
O
sdram_ras_n,
sdram_245_oe_n
DRAM EDO Output Enable Negated
In the EDODRAM mode, this active-low signal provides an output enable signal for reads for particular OE types of EDODRAM. This signal also controls the output enable to an optional FCT245 transceiver bank by asserting during both reads and writes to any DRAM bank. This signal also controls
the output enable to each EDO DRAM chip. Alternatively, because the EDODRAM controller always
uses Early Writes and CAS controlled non-interleaved Reads, the OE_n pin, on each EDO DRAM
chip, can simply be tied to ground. The SDRAM RAS mode is a control signal to all SDRAM banks. In
SDRAM mode, this signal controls the output enable to an optional FCT245 transceiver bank by
asserting during both reads and writes to any DRAM bank.
edodram_we_n
O
sdram_we_n
DRAM EDO Write Enable Negated
In EDODRAM mode, this active-low signal is used as the edodram_we_n pin to provide a write
enable signal for EDODRAM. Write enable is valid at all times and high during refresh. In SDRAM
mode, this signal provides the SDRAM WE control signal to all SDRAM banks.
edodram_wait_n
I
mem_wait_n
DRAM Wait Negated
In the EDO DRAM mode, this active-low signal allows external wait-states to be injected at any time
during the EDO DRAM cycle. In the MEM, IOI, IOM modes, this active-low signal allows external
wait-states to be injected during the last cycle before data is sampled. The DPM (dual-port) mode
allows the dual-port busy signal to restart memory transactions.
EDODRAM Controller
Table 2 RC32134 Pin Descriptions (Page 5 of 8)
9 of 25
April 9, 2001
IDT79RC32134
Pin Name
edodram_245_oe_n
Type Alternate Signal(s)
O
edodram_245_dt_r_n O
Description
sdram_245_oe_n
DRAM FCT245 Output Enable Negated
In the SDRAM mode this active-low signal controls the output enable to an optional FCT245 transceiver bank by asserting during both reads and writes to any DRAM bank. In the EDODRAM mode
this signal controls the output enable to an optional FCT245 transceiver bank by asserting during
both reads and writes to any DRAM bank. This signal also controls the output enable to each EDO
DRAM chip. Alternatively, because the EDODRAM controller always uses Early Writes and CAS controlled non-interleaved Reads, the OE_n pin, on each EDO DRAM chip, can simply be tied to ground.
cpu_dt_r_n
DRAM/Mem FCT245 Direct Xmit/Rcv Negated
This active-low signal controls the DT/R pin of an optional FCT245 transceiver bank. It is asserted
during DMA read operations. This signal is tri-stated during CPU accesses (when the CPU owns the
bus) and drives during DMA generated accesses.
SDRAM Controller Interface
sdram_addr[15:13]
sdram_addr[11:2]
O
mem_addr[15:13]
mem_addr[11:2]
SDRAM Address Bus
These signals are outputs providing a DRAM address during a DRAM transaction. The DRAM
address multiplexes between Row and Column Addresses. During each word data, the column
address increments either in linear or sub-block ordering, depending on the type of transaction.
sdram_addr_12
O
PIO[9]
SDRAM Address line 12
This SDRAM address is dedicated to the SDRAM and multiplexes between the row address; and during the precharge command, the "all bank" indicator.
sdram_ras_n
O
edodram_oe_n
SDRAM RAS Negated
SDRAM mode: Provides SDRAM RAS control signal to all SDRAM banks.
EDODRAM mode: Provides an output enable signal for reads for particular OE types of EDODRAM.
sdram_cas_n
O
Not applicable
SDRAM CAS Negated
This active-low signal provides an SDRAM CAS control signal to all SDRAM banks.
sdram_we_n
O
edodram_we_n
SDRAM WE Negated
SDRAM mode: Provides SDRAM WE control signal to all SDRAM banks.
EDODRAM mode: Used as edodram_we_n pin to provide a write enable signal for EDODRAM.
Write enable is valid at all times and high during refresh.
sdram_clk
I
cpu_masterclk
SDRAM Clock
This signal provides the basic system clock and must be the same clock that is provided to the
RC32364 and also, if used, to SDRAM.
sdram_cke
O
Not applicable
SDRAM Clock Enable
In the SDRAM mode this signal provides the clock enable to all SDRAM banks.
sdram_cs_n[3:0]
O
edodram_ras_n[3:0]
SDRAM Chip Select Negated Bus
In SDRAM mode, these active-low signals provide chip select to each SDRAM bank. In EDODRAM
mode they are used as the edodram_ras_n[3:0] pins and provide a RAS signal for each EDODRAM
bank.
sdram_bemask_n[3:0] O
edodram_cas_n[3:0]
SDRAM Byte Enable Mask Negated Bus
The SDRAM mode provides byte enables for each byte lane of all DRAM banks. To provide a CAS
signal for each byte lane, the EDODRAM mode is used as edodram_cas_n[3:0].
sdram_245_oe_n
edodram_245_oe_n,
edodram_oe_n
SDRAM FCT245 Output Enable Negated
In SDRAM mode, this active-low signal controls output enable to optional FCT245 transceiver bank
by asserting during both reads and writes to any DRAM bank. In EDODRAM mode this signal controls output enable to optional FCT245 transceiver bank by asserting during both reads and writes to
any DRAM bank. Also controls output enable to each EDO DRAM chip. Alternatively, because the
EDODRAM controller always uses Early Writes and CAS controlled non-interleaved Reads, the
OE_n pin on each EDO DRAM chip can simply be tied to ground.
O
Table 2 RC32134 Pin Descriptions (Page 6 of 8)
10 of 25
April 9, 2001
IDT79RC32134
Pin Name
sdram_245_dt_r_n
Type Alternate Signal(s)
Description
O
cpu_dt_r_n
SDRAM FCT245 Direction Transmit/Receive
This active-low signal controls the DT/R pin of an optional FCT245 transceiver bank and is asserted
during DMA read operations. This signal is tri-stated during CPU accesses (when the CPU owns the
bus) and drives during DMA generated accesses.
dma_ready_n[1:0]
I/O
dma_done_n[1:0]
pio[1:0]
DMA Ready Negated Bus
Input pin for general purpose DMA channels[1:0] that can initiate the next datum in the current DMA
descriptor frame. dma_ready_n[1:0] pins are not synchronized internally by the RC32134 and thus
must meet the specified setup and hold time with respect to the input clock.
dma_done_n[1:0]
I/O
dma_ready_n[1:0]
DMA Done
Input pin for general purpose DMA channels[1:0] that can terminate the current DMA descriptor
frame.
I/O
cpu_int_n
Interrupt Negated
Uses cpu_int_n. This active-low signal is an interrupt indication to the CPU from RC32134’s Interrupt
Controller.
I/O
pci_eeprom_mdo
pci_eeprom_sk
sdram_addr_12
pci_eeprom_mdi
uart _rx[0], uart_tx[0]
uart_rx[1], uart_tx[1]
timer_tc_n[0], timer_tc_n[1]
dma_ready_n[0]
dma_ready_n[1]
Programmable Input/Output
General purpose pins that can each be configured as a general purpose input or general purpose
output.
The pci_eeprom_mdo, pci_eeprom_sk, and sdram_addr12 default to outputs. The rest default to
inputs.
timer_tc_n[1:0]
O
timer_gate_n[1:0], pio[3:2]
Timer Terminal Count Overflow Negated
Output indicating that the timer has reached its count compare value and has overflowed back to 0.
timer_gate_n[1:0]
I
timer_tc_n[1:0], pio[3:2]
Timer Gate Negated
Input indicating that the timer may count one tick on the next clock edge.
uart_rx[1:0]
I/O
pio[7]
pio[5]
UART Receive Data Bus
UART mode: Each UART channel receives data on their respective input pin.
uart_tx[1:0]
I/O
pio[6]
pio[4]
UART Transmit Data Bus
UART mode: Each UART channel sends data on their respective output pin. Note that these pins
default to inputs at reset time and must be programmed via the PIO interface before being used as
UART outputs.
DMA Interface
Interrupt Controller
interrupt_n
PIO Interface
pio[11:0]
Timer/Counter
UART Interface
Table 2 RC32134 Pin Descriptions (Page 7 of 8)
11 of 25
April 9, 2001
IDT79RC32134
Pin Name
Type Alternate Signal(s)
Description
Reset
reset_boot_mode[1:0] I/O
mem_addr[22:21]
Reset Initialization Vector
Used as Reset Initialization. Vector input pins that are latched by coldreset_n de-asserting.
Value
reset_pci_host_mode I/O
mem_addr[20]
Description
11
Non-boot mode. Idle at reset. This RC32134 does not
supply boot code control.
10
Reserved.
01
PCI-boot mode. (pci_host_mode must be in satellite
mode). RC32134 will reset either from a cold reset or from
a PCI reset. Boot code is provided via PCI.
00
Standard-boot mode. Boot from this RC32134’s memory
controller (typical system).
Reset PCI Host Mode
Used as Reset Initialization. Vector input pins that are latched by coldreset_n de-asserting. Programming for this signal is as indicated below:
Value
Description
1
PCI is in satellite mode.
0
PCI is in host mode (typical system).
JTAG
jtag_tck
I
Not applicable
JTAG Test Clock
Provides clock for boundary scan test cells. Note: Must be either dynamically driven or an external
pull-up or pull-down resistor is required, if JTAG is not being used.
jtag_tms
I
Not applicable
JTAG Test Mode
This signal provides command/mode input for boundary scan test cells. An external pull-up resistor is
required.
jtag_tdi
I
Not applicable
JTAG Test Data Input
Provides data input for boundary scan test cells. An external pull-up resistor is required.
jtag_tdo
O
Not applicable
JTAG Test Data Out
Provides data output for boundary scan test cells.
jtag_trst_n
I
Not applicable
JTAG Test Reset Negated
This active-low signal provides reset to boundary scan test cells. Note: An external pull-up resistor is
required. This pin must be driven low to reset the JTAG tap controller, or held low if JTAG is not being
used.
Table 2 RC32134 Pin Descriptions (Page 8 of 8)
12 of 25
April 9, 2001
IDT79RC32134
mem_addr[2:2]
mem_cs_n[5:0]
mem_oe_n
mem_we_n[3:0]
mem_wait_n
mem_245_oe_n
mem_245_dt_r_n
edodram_ras_n[3:0]
edodram_cas_n[3:0]
edodram_oe_n
edodram_wait_n
edodram_245_oe_n
edodram_245_dt_r_n
sdram_addr[15:13]
RC32134
Logic
Symbol
dma_ready_n[1:0]
timer_tc_n[1:0]
uart_rx[1:0]
uart_tx[1:0]
reset_boot_mode
reset_pci_host_mode
Gnd
Vcc to IO
Vcc to core
pio[11:0]
DMA
Interface
sdram_245_oe_n
sdram_245_dt_r_n
sdram_addr_12
UART Timer
Interrupt
Interface
JTAG
Interface
Reset
Power/
Ground
sdram_addr[11:2]
sdram_ras_n
sdram_cas_n
sdram_we_n
sdram_clk
sdram_cke
sdram_cs[3:0]
sdram_bemask_n[3:0]
EDODRAM / SDRAM
Controller
edodram_we_n
pci_lock_n
pci_eeprom_mdi
pci_eeprom_mdo
pci_eeprom_cs
pci_eeprom_sk
jtag_tck
jtag_tms
jtag_tdi
jtag_tdo
jtag_trst_n
/Bus Interface
edodram_addr[15:2]
pci_cbe_n[3:0]
pci_ad[31:0]
pci_par
pci_frame_n
pci_trdy_n
pci_irdy_n
pci_stop_n
pci_idsel
pci_perr_n
pci_serr_n
pci_clk
pci_rst_n
pci_devsel_n
pci_req_n[2]
pci_req_n[1]
pci_req_n[0]
pci_gnt_n[2]
pci_gnt_n[1]
pci_gnt_n[0]
pci_inta_n
interrupt_n
Local Memory
mem_addr[22:2]
Memory & I/O Bus
Controllers
cpu_[31:0]
cpu_addr[3:2]
cpu_ale
cpu_cip_n
cpu_wr_n
cpu_be_n[3:0]
cpu_ack_n
cpu_last_n
cpu_buserr_n
cpu_masterclk
cpu_coldreset_n
cpu_reset_n
cpu_busreq_n
cpu_busgnt_n
cpu_int_n[3]
cpu_dt_r_n
PIO
Interface
PCI Interface
Local Memory / Bus Interface
Logic Diagram — RC32134
Gnd
Vcc IO
Vcc core
Note: The alternate signals are listed in “RC32134 Alternate Signal Functions” on page 22
13 of 25
April 9, 2001
IDT79RC32134
Clock Parameters — RC32134
(Tc = 0°C to +90°C Commercial, Tc = -40°C to +90°C Industrial, Vcc Core = +3.3V±5%)
Parameter
Symbol
RC32134
75MHz
Test Conditions
Min
Units
Max
cpu_masterclock HIGH
tMCHIGH
Transition ≤ 3ns
6
—
ns
cpu_masterclock LOW
tMCLOW
Transition ≤ 3ns
6
—
ns
cpu_masterclock period
tMCP
13.33
—
ns
cpu_masterclock Rise& Fall Time
tMCRise, tMCFall
—
3
ns
pci_clk Period
tPCP
30
—
ns
pci_clk Rise& Fall Time
tPCRise, tPCFall
—
3
ns
jtag_tck Rise& Fall Time
tJCRise, tJCFall
—
5
ns
jtag clock period
jtag_clk
100
—
ns
PCI 2.1
VCC
cpu_masterclk
(MClk)
cpu_coldreset_n
cpu_reset*(internal
signal)
modebit[9:0]
>= 150 ms
>= 10 ms
>= 64 MClk
cycles
Figure 2 Mode Configuration Interface Reset Sequence
There is no special requirement for how fast Vcc ramps up to 3.3V. However, all timing references are based on Vcc stabilized at 3.3V + 5%.
14 of 25
April 9, 2001
IDT79RC32134
AC Timing Characteristics — RC32134
(Tc = 0°C to +90°C Commercial, Tc = -40°C to +90°C Industrial, Vcc Core = +3.3V±5%)
Signal
75MHz
Reference
Edge
Symbol
Min
Max
Unit
User Manual
Timing Diagram
Reference
Local Memory/ Peripheral Bus
cpu_ad[31:0] (address phase), cpu_addr[3:2]
Tsu1
cpu_ale falling
3
—
ns
cpu_ad[31:0] (address phase), cpu_addr[3:2]
Thld1
cpu_ale falling
3
—
ns
cpu_ad[31:0] (data phase)
Tsu2
cpu_masterclk rising
5.5
—
ns
cpu_ad[31:0] (data phase)
Thld2
cpu_masterclk rising
0.7
—
ns
cpu_ale rising
Tsu3
cpu_masterclk falling
0
—
ns
cpu_ale falling (ale pulse width)
Tale high
cpu_ale rising
4
—
ns
cpu_busgnt_n, cpu_wr_n, cpu_be_n[3:0], cpu_last_n
Tsu4
cpu_masterclk rising
5
—
ns
cpu_busgnt_n, cpu_wr_n, cpu_be_n[3:0], cpu_reset_n, cpu_last_n Thld4
cpu_masterclk rising
0.7
—
ns
cpu_cip_n
Tsu5
cpu_masterclk rising
5
—
ns
cpu_cip_n
Thld5
cpu_masterclk rising
0.7
—
ns
cpu_ack_n, cpu_buserr_n, cpu_reset_n
Tdo1
cpu_masterclk rising
—
8
ns
cpu_busreq_n, cpu_int_n
Tdo2
cpu_masterclk rising
—
8
ns
cpu_dt_r_n
Tdo3
cpu_masterclk rising
—
8
ns
cpu_ad[31:0]
Tdo4
cpu_masterclk rising
—
8
ns
cpu_ad[31:0] output hold time
Tdoh1
cpu_masterclk rising
11
—
ns
cpu_ack_n, cpu_buserr_n, cpu_reset_n, cpu_busreq_n, cpu_int_n
Tdoh2
cpu_masterclk rising
0.5
—
ns
dma_ready_n[1:0], dma_done_n[1:0]
Tsu7
cpu_masterclk rising
3
—
ns
dma_ready_n[1:0], dma_done_n[1:0]
Thld9
cpu_masterclk rising
0.5
—
ns
mem_wait_n
Tsu6
cpu_masterclk rising
3
—
ns
mem_wait_n
Thld8
cpu_masterclk rising
0.5
—
ns
mem_addr[22:2]
Tdo5
cpu_masterclk rising
—
8
ns
mem_cs_n[5:0]
Tdo6
cpu_masterclk rising
—
8
ns
mem_oe_n, mem_we_[3:0], mem_245_dt_r_n, mem_245_oe_n
Tdo7
cpu_masterclk rising
—
8
ns
mem_addr[22:2]
mem_cs_n[5:0]
mem_oe_n, mem_we_[3:0], mem_245_dt_r_n, mem_245_oe_n
Tdoh3
cpu_masterclk rising
0.5
—
ns
Chapter 3,
Figure 3.6
Figure 3.7
Figure 3.8
Figure 3.9
Figure 5.4
Figure 8.8
Figure 8.9
DMA
Chapter 9,
Figures 9.6 & 9.7
Memory-I/O Controller
15 of 25
Chapter 3,
Figure 3.6
Figure 3.7
Figure 3.8
April 9, 2001
IDT79RC32134
Signal
75MHz
Reference
Edge
Symbol
Min
Max
Unit
User Manual
Timing Diagram
Reference
PCI
pci_ad[31:0], pci_cbe_n[3:0], pci_par, pci_frame_n, pci_trdy_n,
T_su
pci_irdy_n, pci_stop_n, pci_idse, pci_perr_n, pci_serr_n, pci_rst_n,
pci_devsel_n, pci_lock_n
pci_clk rising
7
—
ns
pci_gnt_n[0]
T_su(ptp)
10
—
ns
pci_req_n[2:0]
T_su(ptp)
12
—
ns
0
—
ns
pci_ad[31:0], pci_cbe_n[3:0], pci_par, pci_frame_n, pci_trdy_n,
T_h
pci_irdy_n, pci_stop_n, pci_idse, pci_perr_n, pci_serr_n, pci_rst_n,
pci_devsel_n, pci_req_n[2], pci_req_n[1], pci_req_n[0], pci_gnt_n[0],
pci_lock_n
pci_clk rising
pci_eeprom_mdi
Tsu
pci_clk rising,
10
pci_eeprom_sk falling
ns
pci_eeprom_mdi
Thld
pci_clk rising,
10
pci_eeprom_sk falling
ns
pci_eeprom_mdo, pci-eeprom_cs
Tp
pci_clk rising,
pci_eeprom_sk falling
10
ns
pci_eeprom_sk
Tp
pci_clk rising
12
ns
pci_ad[31:0], pci_cbe_n[3:0], pci_par, pci_frame_n, pci_trdy_n,
pci_irdy_n, pci_stop_n, pci_perr_n, pci_serr_n, pci_devsel_n,
pci_inta_n, pci_lock_n
T_val
pci_clk rising
2
11
ns
pci_req_n[0], pci_gnt_n[2:0]
T_val(ptp)
pci_clk rising
2
12
ns
sdram_245_dt_r_n, sdram_addr[15:2]
Tdo8
cpu_masterclk rising
—
8
ns
sdram_ras_n, sdram_cas_n, sdram_we_n, sdram_cs_n[3:0],
sdram_bemask_n[3:0] sdram_cke
Tdo9
cpu_masterclk rising
—
8
ns
sdram_addr_12
Tdo10
cpu_masterclk rising
—
8
ns
sdram_245_oe_n
Tdo11
cpu_masterclk rising
—
8
ns
cpu_masterclk rising
1
1
—
ns
Tdoh4
cpu_masterclk rising
11
—
ns
edodram_wait_n
Tsu7
cpu_masterclk rising
3
—
ns
edodram_wait_n
Thld8
cpu_masterclk rising
0.5
—
ns
edodram_addr[15:2], edodram_245_dt_r_n
Tdo12
cpu_masterclk rising
—
8
ns
edodram_ras_n[3:0], edodram_cas_n[3:0], edodram_we_n,
edodram_oe_n
Tdo13
cpu_masterclk rising
—
8
ns
edodram_245_oe_n
Tdo14
cpu_masterclk rising
—
8
ns
Note: Refer to PCI
Specification, Revision 2.1
for a detailed timing
diagram.
SDRAM Controller
sdram_245_dt_r_n, sdram_addr[15:2]
sdram_ras_n, sdram_cas_n, sdram_we_n, sdram_cs_n[3:0],
sdram_bemask_n[3:0] sdram_cke
sdram_addr_12
sdram_245_oe_n
Tdoh4
Chapter 4,
Figure 4.4
EDODDRAM Controller
16 of 25
Chapter 5,
Figure 5.3
April 9, 2001
IDT79RC32134
Signal
75MHz
Reference
Edge
Symbol
Min
Max
Unit
User Manual
Timing Diagram
Reference
Tdoh5
cpu_masterclk rising
11
—
ns
Chapter 5,
Figure 5.3
(Continued)
timer_tc_n[1:0], timer_gate_n[1:0]
Tsu8
cpu_masterclk rising
3
—
ns
timer_tc_n[1:0], timer_gate_n[1:0]
Thld10
cpu_masterclk rising
0.5
—
ns
Chapter 10,
Figures 10.6 and 10.7
timer_tc_n[1:0], timer_gate_n[1:0]
Tdo15
cpu_masterclk rising
—
8
ns
Tdoh6
cpu_masterclk rising
11
—
ns
PIO[11:0]
Tsu7
cpu_masterclk rising
3
—
ns
PIO[11:0]
Thld9
cpu_masterclk rising
0.5
—
ns
PIO[11], PIO[9:0]
Tdo16
cpu_masterclk rising
—
10
ns
PIO[10]
Tdo19
cpu_masterclk rising
—
12
ns
PIO[11], PIO[9:0]
Tdoh7
cpu_masterclk rising
11
—
ns
Tdoh7
cpu_masterclk rising
11
—
ns
uart_rx[1:0], uart_tx[1:0]
Tsu9
cpu_masterclk rising
10
ns
uart_rx[1:0], uart_tx[1:0]
Thld11
cpu_masterclk rising
10
ns
uart_rx[1:0], uart_tx[1:0]
Tdo16
cpu_masterclk rising
—
10
ns
Tdoh8
cpu_masterclk rising
11
—
ns
interrupt_n
Tdo2
cpu_masterclk rising
—
8
ns
interrupt_n
Tdoh2
cpu_masterclk-rising
11
—
ns
reset_boot_mode, reset_pci_host_mode
Tsu8
cpu_masterclk-rising
3
ns
reset_boot_mode, reset_pci_host_mode
Thld12
cpu_masterclk-rising
0.5
ns
jtag_tms, jtag_tdi, jtag_trst_n
Tsu
jtag_tck rising
10
ns
jtag_tms, jtag_tdi, jtag_trst_n
Thld
jtag_tck rising
10
ns
jtag_tdo
Tdo18
jtag_tck falling
—
edodram_addr[15:2], edodram_245_dt_r_n
edodram_ras_n[3:0], edodram_cas_n[3:0], edodram_we_n,
edodram_oe_n
edodram_245_oe_n
Timer
timer_tc_n[1:0], timer_gate_n[1:0]
PIO
PIO[10]
Chapter 9,
Figures 9.6 and 9.7
UARTs
uart_rx[1:0], uart_tx[1:0]
Chapter 11,
Figure 11.15
Interrupt Handling
Chapter 8,
Figures 8.8 and 8.9
Reset
Chapter 2,
Figure 2.6
JTAG Interface
10
Refer to Figure 2 below
ns
Note: Tsux = input setup time to RC32134
Thldx = input hold time to RC32134
Tdox = output propagation time from RC32134
Tdohx = output hold time from RC32134
17 of 25
April 9, 2001
IDT79RC32134
t TC K
JTAG _TC K
t5
t3
t1
t2
JTA G _TD I/
JTAG _TM S
T su
T hld
JTA G _TD O
T do
Notes to diagram:
JT AG _TRST
t1 = tTCKlow
t2 = tTCKHIGH
t3 = tTCKFALL
t4
t4 = TRST (reset pulse width)
t5 = tTCKRise
> = 25 ns
Figure 3 Standard JTAG timing
Output Loading for AC Testing (for non-PCI signals)
VREF
To Device
Under Test
–
+
+1.5V
CLD
Signal
All Signals
Cld
50 pF
Note: PCI pins have been correlated to PCI 2.1.
Recommended Operation Temperature and Supply Voltage
Grade
Temperature
Gnd
VccIO
VccCore
Commercial
0°C to +90°C (Case)
0V
3.3V±5%
3.3V±5%
Industrial
-40° + 90°C (Case)
0V
3.3V±5%
3.3V±5%
Capacitive Load Deration
Refer to the IDT document “RC32134 IBIS Model” under sub-category RC32134 Integrated Processor on the company’s web page for Processors
(http://www.idt.com/products/pages/Processors.html) .
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IDT79RC32134
DC Electrical Characteristics
Tc = 0°C to +90°C Commercial, Tc = -40°C to +90°C Industrial, Vcc Core = +3.3V±5%
RC32134
75MHz
Parameter
LOW Drive
Pads
HIGH Drive
Pads
PCI Drive
Pads
Pin Numbers
Conditions
Minimum
Maximum
VOL
—
0.4V
VOH
Vcc - 0.4V
—
VIL
—
0.8V
VIH
2.0V
Vcc + 2.0V
VOL
—
0.4V
VOH
Vcc - 0.4V
—
VIL
—
0.8V
VIH
2.0V
Vcc + 2.0V
VOL
—
0.4V
VOH
Vcc - 0.4V
—
VIL
—
0.8V
VIH
2.0V
5.5
CIN
—
10pF
All Except 41, 57
—
CIN
5pf
12pF
41
Per PCI 2.1
8pF
57
Per PCI 2.1
CIN
1, 2, 3, 4, 5, 8, 15, 18, 19, 20, 21, 22, 23, 24, 25,
28, 29, 30, 31, 104, 106, 118, 133, 137, 142, 161
|IOUT| = 10.8mA
|IOUT| = 7.8mA
—
9, 10, 11, 12, 13, 107, 108, 109, 112, 113, 114,
115, 116, 117, 119, 122, 123, 124, 125, 126, 129,
132, 134, 135, 138, 139, 143, 144, 146, 147, 149,
152, 154, 155, 159, 160, 165, 167, 168, 169, 170,
171, 174, 175, 176, 177, 178, 179, 180, 181, 184,
185, 186, 187, 188, 189, 190, 191, 194, 195, 196,
197, 198, 199, 200, 201, 204, 205, 206, 207, 208
|IOUT| = 19mA
35, 39, 42, 43, 45, 48, 49, 50, 51, 52, 53, 54, 55,
56, 60, 61, 62, 63, 64, 65, 66, 67, 70, 71, 72, 73,
74, 75, 77, 80, 81, 82, 83, 84, 85, 86, 87, 90, 91,
92, 93, 94, 95, 96, 97, 100, 101, 102, 103
|IOUT| = 25mA
|IOUT| = 15.6mA
—
|IOUT| = 19.5mA
—
COUT
—
10pF
All output pads
—
I/OLEAK
—
20uA
All pins
Input/Output Leakage
Power Consumption—RC32134
Parameter
RC32134
75MHz
Conditions
Typical lCC
Ptyp
360mA
1.2W
CL = 50pF
Ta= 25oC
Vcc core = 3.3V
Vcc IO = 3.3V
cpu_masterclk = 75MHz
pci_clk = 33MHz
Max lCC
Pmax
460mA
1.6W
CL = 50pF
Ta= 55oC
Vcc core = Vcc core Max
Vcc IO = 3.47V
cpu_masterclk = 75MHz
pci_clk = 33MHz
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IDT79RC32134
Absolute Maximum Ratings
Note: Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent damage to the device. This is a
stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of
this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability.
Symbol
Parameter
Min
Max
Unit
VCC
Supply Voltage
-0.3
4.0
V
Vi
Input Voltage
Gnd
5.5
V
Tstg
Storage Temperature
-40
125
degrees C
Ta
Ambient Temperature
Value
0
70
degrees C
Package Pin-out - 208-PQFP
The following table lists the pin numbers and signal names for the RC32134. To maximize pin usage, several pins have alternate functions, as
noted in the “Alt” column and described in “RC32134 Alternate Signal Functions” on page 22. Signal names ending with an _n are active when low.
Pin
Function
Alt
Pin
Function
Alt
Pin
Function
Alt
Pin
Function
Alt
1
mem_cs_n[5]
53
pci_ad[26]
105
cpu_wr_n
157
cpu_coldreset_n
2
mem_cs_n[4]
54
pci_ad[25]
106
cpu_reset_n
158
cpu_be_n[3]
3
mem_cs_n[3]
55
pci_ad[24]
107
cpu_ad[21]
159
cpu_ad[20]
4
mem_cs_n[2]
56
pci_cbe_n[3]
108
cpu_ad[9]
160
cpu_ad[11]
5
mem_cs_n[1]
57
pci_req_n[2] (Host mode)
109
cpu_ad[22]
161
cpu_busreq_n
6
Vcc I/O
58
Vcc I/O
110
Vcc I/O
162
Vcc I/O
7
Vss
59
Vss
111
Vss
163
Vss
8
mem_cs_n[0]
60
pci_ad[23]
112
cpu_ad[8]
164
cpu_addr[2]
9
mem_oe_n
61
pci_ad[22]
113
cpu_ad[23]
165
cpu_ad[10]
10
mem_we_n[3]
62
pci_ad[21]
114
cpu_ad[7]
166
cpu_addr[3]
11
mem_we_n[2]
63
pci_ad[20]
115
cpu_ad[24]
167
mem_addr[22]
1
12
mem_we_n[1]
64
pci_ad[19]
116
cpu_ad[6]
168
mem_addr[21]
1
13
mem_we_n[0]
65
pci_ad[18]
117
cpu_ad[25]
169
mem_addr[20]
1
14
mem_wait_n
66
pci_ad[17]
118
cpu_dt_r_n
170
mem_addr[19]
15
mem_245_oe_n
67
pci_ad[16]
119
cpu_ad[5]
171
mem_addr[18]
16
Vcc I/O
68
Vcc I/O
120
Vcc I/O
172
Vcc I/O
17
Vss
69
Vss
121
Vss
173
Vss
18
dma_ready_n[1]
2
70
pci_cbe_n[2]
122
cpu_ad[26]
174
mem_addr[17]
19
dma_ready_n[0]
2
71
pci_frame_n
123
cpu_ad[4]
175
mem_addr[16]
20
timer_tc_n[1]
2
72
pci_irdy_n
124
cpu_ad[27]
176
mem_addr[15]
2
21
timer_tc_n[0]
2
73
pci_trdy_n
125
cpu_ad[3]
177
mem_addr[14]
2
2
1
3
Table 3: RC32134 208-pin QFP Package Pin-Out (Page 1 of 2)
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IDT79RC32134
Pin
Function
Alt
Pin
Function
Alt
Pin
Function
Alt
Pin
Function
Alt
22
uart_rx[1]
1
74
pci_devsel_n
126
cpu_ad[28]
178
mem_addr[13]
2
23
uart_tx[1]
1
75
pci_stop_n
127
cpu_cip_n
179
sdram_bemask_n[3]
1
24
uart_rx[0]
1
76
pci_lock_n
128
cpu_last_n
180
sdram_bemask_n[2]
1
25
uart_tx[0]
1
77
pci_perr_n
129
cpu_ad[2]
181
sdram_cs_n[3]
1
26
Vcc Core
78
Vcc Core
130
Vcc Core
182
Vcc Core
27
Vss
79
Vss
131
Vss
183
Vss
28
pci_eeprom_mdo
1
80
pci_serr_n
132
cpu_ad[29]
184
sdram_cs_n[2]
29
pci_eeprom_mdi
1
81
pci_par
133
cpu_buserr_n
185
sdram_cke
30
pci_eeprom_sk
1
82
pci_cbe_n[1]
134
cpu_ad[1]
186
mem_addr[12]
1
31
sdram_addr_12
1
83
pci_ad[15]
135
cpu_ad[30]
187
mem_addr[11]
2
32
jtag_trst_n
84
pci_ad[14]
136
cpu_ale
188
mem_addr[10]
2
33
jtag_tck
85
pci_ad[13]
137
cpu_ack_n
189
mem_addr[9]
2
34
jtag_tms
86
pci_ad[12]
138
cpu_ad[0]
190
mem_addr[8]
2
35
jtag_tdo
87
pci_ad[11]
139
cpu_ad[31]
191
mem_addr[7]
2
36
Vcc I/O
88
Vcc I/O
140
Vcc I/O
192
Vcc I/O
37
Vss
89
Vss
141
Vss
193
Vss
38
jtag_tdi
90
pci_ad[10]
142
cpu_masterclk
194
mem_addr[6]
2
39
pci_gnt_n[2] (Host mode)
91
pci_ad[9]
143
cpu_ad[15]
195
mem_addr[5]
2
40
pci_rst_n
92
pci_ad[8]
144
cpu_ad[16]
196
mem_addr[4]
2
41
pci_clk
93
pci_cbe_n[0]
145
cpu_be_n[0]
197
mem_addr[3]
2
42
pci_gnt_n[1] (Host mode)
94
pci_ad[7]
146
cpu_ad[17]
198
mem_addr[2]
2
43
pci_gnt_n[0]
95
pci_ad[6]
147
cpu_ad[14]
199
sdram_ras_n
1
44
pci_req_n[1] (Host mode)
96
pci_ad[5]
148
cpu_be_n[1]
200
sdram_cs_n[1]
1
45
pci_req_n[0]
97
pci_ad[4]
149
cpu_ad[18]
201
sdram_cs_n[0]
1
46
Vcc I/O
98
Vcc I/O
150
Vcc I/O
202
Vcc I/O
47
Vss
99
Vss
151
Vss
203
Vss
48
pci_ad[31]
100
pci_ad[3]
152
cpu_ad[13]
204
sdram_bemask_n[1]
1
49
pci_ad[30]
101
pci_ad[2]
153
cpu_be_n[2]
205
sdram_bemask_n[0]
1
50
pci_ad[29]
102
pci_ad[1]
154
cpu_ad[19]
206
sdram_cas_n
51
pci_ad[28]
103
pci_ad[0]
155
cpu_ad[12]
207
sdram_we_n
1
52
pci_ad[27]
104
cpu_int_n[3]
156
cpu_busgnt_n
208
sdram_245_oe_n
2
1
1
1
1
1
1
Table 3: RC32134 208-pin QFP Package Pin-Out (Page 2 of 2)
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RC32134 Alternate Signal Functions
Pin
Alt #1
Alt #2
Alt #3
Pin
Alt #1
Alt #2
Alt
#3
14
sdram_wait_n
edodram_wait_n
NA
169
reset_pci_host_mode
NA
NA
18
dma_done_n[1]
pio[0]
NA
179
edodram_cas_n[3]
NA
NA
19
dma_done_n[0]
pio[1]
NA
180
edodram_cas_n[2]
NA
NA
20
timer_gate_n[1]
pio[2]
NA
181
edodram_ras_n[3]
NA
NA
21
timer_gate_n[0]
pio[3]
NA
184
edodram_ras_n[2]
NA
NA
22
pio[5]
NA
NA
186
edodram_addr[12]
NA
NA
23
pio[4]
NA
NA
187
sdram_addr[11]
edodram_addr[11]
NA
24
pio[7]
NA
NA
188
sdram_addr[10]
edodram_addr[10]
NA
25
pio[6]
NA
NA
189
sdram_addr[9]
edodram_addr[9]
NA
28
pio[11]
NA
NA
190
sdram_addr[8]
edodram_addr[8]
NA
29
pio[8]
NA
NA
191
sdram_addr[7]
edodram_addr[7]
NA
30
pio[10]
NA
NA
194
sdram_addr[6]
edodram_addr[6]
NA
31
pio[9]
NA
NA
195
sdram_addr[5]
edodram_addr[5]
NA
39
pci_inta_n Satellite
NA
NA
196
sdram_addr[4]
edodram_addr[4]
NA
42
NA
pci_eeprom_cs
(Satellite )
NA
197
sdram_addr[3]
edodram_addr[3]
NA
44
unused (Satellite)
NA
NA
198
sdram_addr[2]
edodram_addr[2]
NA
57
pci_idsel (Satellite)
NA
NA
199
edodram_oe_n
NA
NA
104
interrrupt_n
NA
NA
200
edodram_ras_n[1]
NA
NA
118
mem_245_dt_r_N
sdram_245_dt_r_n
edodram_245_dt_r_n
201
edodram_ras_n[0]
NA
NA
142
sdram_clk
NA
207
edodram_we_n
NA
NA
167
reset_boot_mode[1]
NA
208
edodram_245_oe_n
edodram_oe_n
NA
168
reset_boot_mode[0]
NA
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IDT79RC32134
Package Drawing - 208-pin PQFP
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IDT79RC32134
Package Drawing - page two
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IDT79RC32134
Ordering Information
IDT79RCXX
Product
Type
V
Operating
Voltage
DDD
PP
T
Device
Type
Package
Temp range/
Process
blank = Commercial Temperature (0°C to +90°C Case)
I = Industrial Temperature (-40°C to +90°C Case)
DS = 208-pin PQFP
134 = 32134 System Controller
V = 3.3V ±5%
IDT79RC32 = 32-bit family product
Valid Combinations
IDT79RC32V134 DS
208-pin PQFP package - Commercial Temperature
IDT79RC32V134 DSI
208-pin PQFP package - Industrial Temperature
CORPORATE HEADQUARTERS
2975 Stender Way
Santa Clara, CA 95054
for SALES:
800-345-7015 or 408-727-6116
fax: 408-330-1748
www.idt.com
for Tech Support:
email: [email protected]
phone: 408-492-8208
The IDT logo is a registered trademark of Integrated Device Technology, Inc.
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