Motorola MVME5101-0131 Single Board Computer

Motorola   MVME5101-0131  Single Board Computer

The MVME5100 is a high-performance VME single board computer featuring the

Motorola Computer Group (MCG) PowerPlus II architecture with a choice of PowerPC®

processors—either Motorola’s MPC7400 with AltiVec™ technology for algorithmic

intensive computations or the low-power MPC750.

As of the printing date of this manual, the MVME5100 is available in the configurations

shown below. All models of the MVME5100 are available with either VME SCANBE

front panel (-01x1) or IEEE 1101 compatible front panel (-01x3).

MVME5100-0131

MVME5100-0161

MVME5100-0133

MVME5100-0163

MVME5101-0131

MVME5101-0161

MVME5101-0133

MVME5101-0163

The MVME5100 is a state-of-the-art Single Board Computer. It

incorporates Motorola’s PowerPlus II architecture with a choice of

PowerPC processors—either Motorola’s MPC7400 with AltiVec™

technology for algorithmic intensive computations or the low-power

MPC750.

The MVME5100 incorporates a highly optimized PCI interface and

memory controller enabling up to 582MB memory read bandwidth and

640 MB burst write bandwidth.

The on-board Hawk ASIC provides the bridge function between the

processor’s bus and the PCI bus. It provides 32-bit addressing and 64-bit

data; however, 64-bit addressing (dual address cycle) is not supported. The

ASIC also supports various processor external bus frequencies up to

10MHz

Feature Specification

Microprocessors and

Bus Clock Frequency

•MPC7400 @400 MHz Internal Clock Frequency

•MPC750 @450 MHz Internal Clock Frequency

• Bus Clock Frequency up to 100 MHz

L2 Cache (Optional) • 1MB (MPC750) or 2MB (MPC7400) using burst-mode

SRAM modules.

Memory • EEPROM, on-board programmable

• 1MB via two 32-pin PLCC/CLCC sockets;

16MB Surface Mount

Main Memory

(SDRAM)

• PC100 ECC SDRAM with 100 MHz bus

• 32MB to 512MB on board, expandable to

1GB via RAM500 memory mezzanine

NVRAM • 32KB (4KB available for users)

Memory Controller • Hawk System Memory Controller (SMC)

PCI Host Bridge • Hawk PCI Host Bridge (PHB)

Interrupt Controller • Hawk Multi-Processor Interrupt Controller (MPIC)

Peripheral Support • Dual 16550-Compatible Asynchronous Serial Port’s

Routed to the Front Panel RJ45 Connnector (COM1) and

On-Board Header (COM2)

• Dual Ethernet Interfaces, one routed to the Front Panel

RJ45. one routed to the Front Panel RJ45 or optionally

routed to P2. RJ45 on MVME761

VMEbus • Tundra Universe Controller, 64-bit PCI

• Programmable Interrupter & Interrupt Handler

• Programmable DMA Controller With Link List Support

• Full System Controller Functions

PCI/PMC/Expansion • Two 32/64-bit PMC Slots with Front-Panel I/O Plus,

P2 Rear I/O (MVME2300 Routing)

• One PCI Expansion Connector (for the PMCSpan)

Miscellaneous • Combined RESET and ABORT Switch

• Status LEDs

Form Factor • 6U VME

Memory maps

The following sections describe the memory maps for the MVME5100.

Processor Memory Map

Following a reset, the memory map presented to the processor is identical

to the CHRP memory map described in the PowerPlus II Engineering

Specification listed in Appendix A, Related Documentation.

The MVME5100 is fully capable of supporting both the PREP and the

CHRP processor memory maps with ROM/FLASH size limited to

16MBytes and RAM size limited to 1GB.

PCI / VME Memory Map

Following a reset, the Hawk ASIC disables all PCI slave map decoders. As

stated above, the MVME5100 is fully capable of supporting both the PREP

and the CHRP PCI and VME memory maps.

System Bus

The following sections describe the processor system bus for the

MVME5100.

Processors

The MVME5100 has the BGA foot print that supports the MPC7400

processor. The maximum external processor bus speed is 100 MHz. Parity

checking is supported for the system address and data busses.

Processor Type Identification

The type of the processor can be determined by reading the Processor

Version Register (PVR). The PVR value for the MPC7400 processor is

0x000C0100h

Processor PLL Configuration

The processor internal clock frequency (core frequency) is a multiple of

the system bus frequency. The processor has four configuration pins,

PLL_CFG[0:3], for hardware strapping of the processor core frequency

between 2x and 8x the system bus frequency, in 0.5x steps.

The PLL configuration shall be dynamic at power-up and be dependent

upon the existence of a memory mezzanine attached to the host board.

L2 Cache

The MVME5100 incorporates an L2 cache using a 2-way, set-associative

tag memory located in the MPC7400 processor, with external direct

mapped synchronous SRAMs for data storage. The external SRAMs are

accessed through a dedicated L2 cache port on the processor.

L2 Cache SRAM Size

The L2 cache port will support SRAM configurations of 1MB or 2MB.

The L2 cache size is defined by reading the Vital Product Data (VPD)

SROM and programming the L2SIZ bits in the processor’s Cache Control

Register (L2CR).

Cache Speed

The MPC7400 cache port provides the clock for the synchronous SRAMs.

This clock is generated by dividing the processor core frequency.

Available core-to-cache dividers range from 1 to 4. in .5 steps.

The core-to-cache ratio is selected by reading the VPD SROM and

programming the L2CLK bits of the processor’s Cache Control Register.

Flash Memory

The MVME5100 Flash memory characteristics are fully compatible with

those specified in the Hawk’s specification for Flash Blocks

A and B

System Memory

MVME5100 system memory characteristics are fully compatible with

those of the Hawk ASIC for memory Blocks A, B, C, and E.

The on-board memory Blocks are Blocks A and B. The optional add-on

mezzanine memory Blocks are C (first mezzanine attached) and

E (second mezzanine attached).

Serial Presence Detect (SPD) Definitions

The MVME5100 SPD uses the SPD JEDEC standard definition. On board

SPD for SDRAM Bank A or both A and B of the Hawk shall be accessed

at Address $A8 . Only Bank A or Banks A and B will be populated. If both

banks A and B are populated, they will be the same speed and memory

size. Memory Mezzanine 1 SPD for SDRAM Bank C of the Hawk shall be

accessed at Address $AA. Memory Mezzanine 2 SPD for SDRAM Bank

E of the Hawk shall be accessed at address $AC.

Hawk ASIC

Hawk I2C interface and configuration information

The Hawk ASIC has an I2C (Inter-Integrated Circuit) two-wire serial

interface bus: Serial Clock Line (SCL) and Serial Data Line (SDA)

composed of two 256 x 8 Serial EEPROM’s.

This interface has master-only capability and is used to communicate the

configuration information to a slave I2C serial EEPROM. A seperate

EEPROM is used to maintain the configuration information related to the

board (Vital Product Data, User configuration Data, etc.) and a seperate

EEPROM is used for on-board Memory Subsystem Data (MSD).

If a optional memory mezzanine is used, that mezzanine shall contain a

seperate EEPROM with its own memory subsystem data. Each slave

device connected to the I2C bus is software addressable by a unique

address.

There can be seven slave devices connected to the I2C bus on the

MVME5100. The Vital Product Data (VPD) address shall be $A0. The

User configuration Data (UPD) address shall be $A2.

The on-board MSD address (Memory Bank A and B) shall be $A8. The

optional Memory Mezzanine 1 MSD addresses shall be $AA (Memory

Bank C) and $AC (Memory Bank E) for mezzanine 2.

The IPMC761 VPD address shall be $A4. A digital thermometer

(DS1621) I2C address shall be $96. Some configuration options in the

Hawk ASIC must be configured at power-up reset time before software

performs any accesses to it. Other configuration information is needed by

software to properly configure the Hawk’s control registers. This

information can be obtained from devices connected to the I2C bus.