AMCC 405GPR

Part Number 405GPr
Revision 2.04 – September 7, 2007
405GPr
Data Sheet
Power PC 405GPr Embedded Processor
Features
• PowerPC® 405 32-bit RISC processor core
operating up to 400MHz with 16KB I- and
D-caches
• Synchronous DRAM (SDRAM) interface operating
up to 133MHz
- 32-bit interface for non-ECC applications
- 40-bit interface serves 32 bits of data plus 8
check bits for ECC applications
- Synchronous or asynchronous PCI Bus
interface
- Internal or external PCI Bus Arbiter
• Ethernet 10/100Mbps (full-duplex) support with
media independent interface (MII)
• Programmable interrupt controller supports 13
external and 19 internal edge triggered or levelsensitive interrupts
• 4KB on-chip memory (OCM)
• Programmable timers
• External peripheral bus
• Two serial ports (16550 compatible UART)
- Flash ROM/Boot ROM interface
• One IIC interface
- Direct support for 8-, 16-, or 32-bit SRAM and
external peripherals
• General purpose I/O (GPIO) available
- Up to eight devices
- External Mastering supported
• DMA support for external peripherals, internal
UART and memory
• Supports JTAG for board level testing
• Internal processor local Bus (PLB) runs at SDRAM
interface frequency
• Supports PowerPC processor boot from PCI
memory
- Scatter-gather chaining supported
- Four channels
• Unique software-accessible 64-bit chip ID number
(ECID).
• PCI Revision 2.2 compliant interface (32-bit, up to
66MHz)
Description
Designed specifically to address embedded
applications, the PowerPC 405GPr (PPC405GPr)
provides a high-performance, low-power solution that
interfaces to a wide range of peripherals by
incorporating on-chip power management features
and lower power dissipation requirements.
This chip contains a high-performance RISC
processor core, SDRAM controller, PCI bus interface,
Ethernet interface, control for external ROM and
peripherals, DMA with scatter-gather support, serial
AMCC
ports, IIC interface, and general purpose I/O.
Technology: CMOS SA-27E, 0.18 μm
(0.11 μm Leff)
Package: 456-ball (35mm or 27mm) enhanced plastic
ball grid array (E-PBGA) in both leaded and lead-free
versions
Power (typical): 0.72W at 266MHz
1
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Contents
Ordering, PVR, and JTAG Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Address Map Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
On-Chip Memory (OCM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
PLB to PCI Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
SDRAM Memory Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
External Peripheral Bus Controller (EBC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Serial Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
IIC Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
General Purpose IO (GPIO) Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Universal Interrupt Controller (UIC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
10/100 Mbps Ethernet MAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
JTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Signal List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Spread Spectrum Clocking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Strapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
Tables
System Memory Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
DCR Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Signals Listed Alphabetically . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Signals Listed by Ball Assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Pin Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Signal Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Package Thermal Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Recommended DC Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Input Capacitance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Clocking Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Peripheral Interface Clock Timings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
I/O Specifications—Group 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
I/O Specifications—Group 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
PPC405GPr Legacy Mode Strapping Pin Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
PPC405GPr New Mode Strapping Pin Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
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AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Figures
PPC405GPr Embedded Controller Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
27mm, 456-Ball E-PBGA Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
35mm, 456-Ball E-PBGA Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
5V-Tolerant Input Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Input Setup and Hold Waveform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
Output Delay and Float Timing Waveform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
AMCC
3
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Ordering, PVR, and JTAG Information
Product Name
Order Part Number1
Processor Frequency
Package
Rev
Level
PVR Value
JTAG ID
PPC405GPr
PPC405GPr-3BB266
266MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB266
266MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3BB266Z
266MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB266Z
266MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB266
266MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB266
266MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB266Z
266MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB266Z
266MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr-3BB333
333MHz2
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB333
333MHz2
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3BB333Z
333MHz2
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB333Z
333MHz2
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB333
333MHz2
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB333
333MHz2
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB333Z
333MHz2
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB333Z
333MHz2
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3BB400
400MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB400
400MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3BB400Z
400MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3JB400Z
400MHz
35mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB400
400MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB400
400MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3DB400Z
400MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
PPC405GPr-3KB400Z
400MHz
27mm, 456 E-PBGA
B
0x50910951
0x24088049
PPC405GPr
Notes
1: Z at the end of the Order Part Number indicates a tape-and-reel shipping package. Otherwise, the chips are shipped in a tray.
2. If the 333MHz parts are operated at 266MHz or less, the operational temperature range is extended to 105°C
The part number contains a revision code. This refers to the die mask revision number and is included in the part
numbering scheme for identification purposes only.
The PVR (Processor Version Register) is software accessible and contains additional information about the
revision level of the part. Refer to the PowerPC 405GPr Embedded Processor User’s Manual for details on the
register content.
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AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Order Part Number Key
PPC405GPr-3BB266x
Shipping Package
Blank = Tray
Z = Tape and reel
Part Number
Grade 3 Reliability
Package and Operational Case Temperature
B: 35mm, 456 E-PBGA, -40°C to +85°C
D: 27mm, 456 E-PBGA, -40°C to +85°C
J: 35mm, 456 E-PBGA lead-free, -40°C to +85°C
K: 27mm, 456 E-PBGA lead-free, -40°C to +85°C
AMCC
Processor Speed
266MHz
333MHz
400MHz
Revision Level
5
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
PPC405GPr Embedded Controller Functional Block Diagram
Universal
Interrupt
Controller
Clock
Control
Reset
Power
Mgmt
OCM
SRAM
Timers
DOCM
MMU
IOCM
OCM
Control
PPC405
Processor Core
16KB
D-Cache
JTAG
Trace
DCU
ICU
DCRs
GPIO
DCR Bus
16KB
I-Cache
Arb
DMA
Controller
(4-Channel)
Arb
IIC
UART
UART
On-chip Peripheral Bus (OPB)
OPB
Bridge
MAL
Ethernet
Processor Local Bus (PLB)
Code
Decompression
(CodePack™)
SDRAM
Controller
13-bit addr
32-bit data
External
Bus
Controller
External
Bus Master
Controller
32-bit addr
32-bit data
PCI Bridge
66 MHz max (async)
33 MHz max (sync)
MII
The PPC405GPr is designed using the IBM® Microelectronics Blue LogicTM methodology in which major functional
blocks are integrated together to create an application-specific ASIC product. This approach provides a consistent
way to create complex ASICs using IBM CoreConnectTM Bus Architecture.
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AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Address Map Support
The PPC405GPr incorporates two simple and separate address maps. The first address map defines the possible
use of address regions that the processor can access. The second address map is for Device Configuration
Registers (DCRs). The DCRs are accessed by software running on the PPC405GPr processor through the use of
mtdcr and mfdcr instructions.
System Memory Address Map 4GB System Memory
Function
General Use
Boot-up
Subfunction
SDRAM, External Peripherals, and PCI
Memory
Note: Any of the address ranges listed at
right may be use for any of the above
functions.
Peripheral Bus Boot 1
PCI Boot
PCI
Internal Peripherals
2
Start Address
End Address
Size
0x00000000
0xE7FFFFFF
3712MB
0xE8010000
0xE87FFFFF
8MB
0xEC000000
0xEEBFFFFF
44MB
0xEEE00000
0xEF3FFFFF
6MB
0xEF500000
0xEF5FFFFF
1MB
0xF0000000
0xFFFFFFFF
256MB
0xFFE00000
0xFFFFFFFF
2MB
0xFFFE0000
0xFFFFFFFF
128KB
PCI I/O
0xE8000000
0xE800FFFF
64KB
PCI I/O
0xE8800000
0xEBFFFFFF
56MB
Configuration Registers
0xEEC00000
0xEEC00007
8B
Interrupt Acknowledge and Special Cycle
0xEED00000
0xEED00003
4B
Local Configuration Registers
0xEF400000
0xEF40003F
64B
UART0
0xEF600300
0xEF600307
8B
UART1
0xEF600400
0xEF600407
8B
IIC0
0xEF600500
0xEF60051F
32B
OPB Arbiter
0xEF600600
0xEF60063F
64B
GPIO Controller Registers
0xEF600700
0xEF60077F
128B
Ethernet Controller Registers
0xEF600800
0xEF6008FF
256B
Notes:
1. When peripheral bus boot is selected, peripheral bank 0 is automatically configured at reset to the address range listed above.
2. If PCI boot is selected, a PLB-to-PCI mapping is automatically configured at reset to the address range listed above.
3. After the boot process, software may reassign the boot memory regions for other uses.
4. All address ranges not listed above are reserved.
AMCC
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405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
DCR Address Map 4KB Device Configuration Registers
Function
Total DCR Address Space1
Start Address
End Address
Size
0x000
0x3FF
1KW (4KB)1
16W
By function:
Reserved
0x000
0x00F
Memory Controller Registers
0x010
0x011
2W
External Bus Controller Registers
0x012
0x013
2W
Decompression Controller Registers
0x014
0x015
2W
Reserved
0x016
0x017
2W
On-Chip Memory Controller Registers
0x018
0x01F
8W
Reserved
0x020
0x07F
96W
PLB Registers
0x080
0x08F
16W
Reserved
0x090
0x09F
16W
OPB Bridge Out Registers
0x0A0
0x0A7
8W
Electronic Chip ID (ECID)
0x0A8
0x0A9
2W
Reserved
0x0AA
0x0AF
6W
Clock, Control, Interrupt Routing, and Reset
0x0B0
0x0B7
8W
Power Management
0x0B8
0x0BF
8W
Interrupt Controller
0x0C0
0x0CF
16W
Reserved
0x0D0
0x0FF
48W
DMA Controller Registers
0x100
0x13F
64W
Reserved
0x140
0x17F
64W
Ethernet MAL Registers
0x180
0x1FF
128W
Reserved
0x200
0x3FF
512W
Notes:
1. DCR address space is addressable with up to 10 bits (1024 or 1K unique addresses). Each unique address represents a single 32-bit
(word) register, or 1 kiloword (KW) (which equals 4 KB).
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AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
On-Chip Memory (OCM)
The OCM feature comprises a memory controller and a one-port 4KB static RAM (SRAM) accessed by the
processor core.
Features include:
• Low-latency access to critical instructions and data
• Performance identical to cache hits without misses
• Contents change only under program control
PLB to PCI Interface
The PLB to PCI interface core provides a mechanism for connecting PCI devices to the local PowerPC processor
and local memory. This interface is compliant with version 2.2 of the PCI Specification.
Features include:
• Internal PCI bus arbiter for up to six external devices at PCI bus speeds up to 66MHz. Internal arbiter use is
optional and can be disabled for systems which employ an external arbiter.
• PCI bus frequency up to 66MHz
- Synchronous operation at 1/n fractions of PLB speed (n = 1 to 4) to 33MHz maximum
- Asynchronous operation from 1/8 PLB frequency to 66MHz maximum
• 32-bit PCI address/data bus
• Power Management:
- PCI Bus Power Management v1.1 compliant
• Supports 1:1, 2:1, 3:1, 4:1 clock ratios from PLB to PCI
• Buffering between PLB and PCI:
- PCI target 64-byte write post buffer
- PCI target 96-byte read prefetch buffer
- PLB slave 32-byte write post buffer
- PLB slave 64-byte read prefetch buffer
• Error tracking/status
• Supports PCI target side configuration
• Supports processor access to all PCI address spaces:
- Single-byte PCI I/O reads and writes
- PCI memory single-beat and prefetch-burst reads and single-beat writes
- Single-byte PCI configuration reads and writes (type 0 and type 1)
- PCI interrupt acknowledge
- PCI special cycle
AMCC
9
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
• Supports PCI target access to all PLB address spaces
• Supports PowerPC processor boot from PCI memory
SDRAM Memory Controller
The PPC405GPr Memory Controller core provides a low latency access path to SDRAM memory. A variety of
system memory configurations are supported. The memory controller supports up to four physical banks. Up to
256MB per bank are supported, up to a maximum of 1GB. Memory timings, address and bank sizes, and memory
addressing modes are programmable.
Features include:
• 11x8 to 13x11 addressing for SDRAM (2- and 4-bank)
• 32-bit memory interface support
• Programmable address compare for each bank of memory
• Industry standard 168-pin DIMMS are supported (some configurations)
• PC-133 support for 133 MHz memory
• 4MB to 256MB per bank
• Programmable address mapping and timing
• Auto refresh
• Page mode accesses with up to 4 open pages
• Power management (self-refresh)
• Error checking and correction (ECC) support
- Standard single-error correct, double-error detect coverage
- Aligned nibble error detect
- Address error logging
External Peripheral Bus Controller (EBC)
• Supports eight banks of ROM, EPROM, SRAM, Flash memory, or slave peripherals
• Up to 66MHz operation
• Burst and non-burst devices
• 8-, 16-, 32-bit byte-addressable data bus width support
• Latch data on Ready
• Programmable 2K clock time-out counter with disable for Ready
• Programmable access timing per device
- 0–255 wait states for non-bursting devices
- 0–31 burst wait states for first access and up to 7 wait states for subsequent accesses
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AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
- Programmable CSon, CSoff relative to address
- Programmable OEon, WEon, WEoff (0 to 3 clock cycles) relative to CS
• Programmable address mapping
• Peripheral Device pacing with external “Ready”
• External master interface
- Write posting from external master
- Read prefetching on PLB for external master reads
- Bursting capable from external master
- Allows external master access to all non-EBC PLB slaves
- External master can control EBC slaves for own access and control
DMA Controller
• Supports the following transfers:
- Memory-to-memory transfers
- Buffered peripheral to memory transfers
- Buffered memory to peripheral transfers
• Four channels
• Scatter/gather capability for programming multiple DMA operations
• 8-, 16-, 32-bit peripheral support (OPB and external)
• 32-bit addressing
• Address increment or decrement
• Internal 32-byte data buffering capability
• Supports internal and external peripherals
• Support for memory mapped peripherals
• Support for peripherals running on slower frequency buses
AMCC
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405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Serial Interface
• One 8-pin UART and one 4-pin UART interface provided
• Selectable internal or external serial clock to allow a wide range of baud rates
• Register compatibility with NS16550 register set
• Complete status reporting capability
• Transmitter and receiver are each buffered with 16-byte FIFOs when in FIFO mode
• Fully programmable serial-interface characteristics
• Supports DMA using internal DMA engine
IIC Bus Interface
• Compliant with Philips® Semiconductors I2C Specification, dated 1995
• Operation at 100kHz or 400kHz
• 8-bit data
• 10- or 7-bit address
• Slave transmitter and receiver
• Master transmitter and receiver
• Multiple bus masters
• Supports fixed VDD IIC interface
• Two independent 4 x 1 byte data buffers
• Fifteen memory-mapped, fully programmable configuration registers
• One programmable interrupt request signal
• Provides full management of all IIC bus protocol
• Programmable error recovery
General Purpose IO (GPIO) Controller
• Controller functions and GPIO registers are programmed and accessed via memory-mapped OPB bus master
accesses
• 23 of 24 GPIOs are pin-shared with other functions. DCRs control whether a particular pin that has GPIO
capabilities acts as a GPIO or is used for another purpose. The 23 GPIOs are multiplexed with:
- 7 of 8 chip selects
- All 13 external interrupts
- All nine instruction trace pins
• Each GPIO output is separately programmable to emulate an open-drain driver (i.e., drives to zero, threestated if output bit is 1)
12
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Universal Interrupt Controller (UIC)
The Universal Interrupt Controller (UIC) provides the control, status, and communications necessary between the
various sources of interrupts and the local PowerPC processor.
Features include:
• Supports 13 external and 19 internal interrupts
• Seven of the 13 interrupts are mapped to the same GPIOs as the PPC405GP.
• The other six interrupts can be mapped to any of the GPIOs.
• Edge triggered or level-sensitive
• Positive or negative active
• Non-critical or critical interrupt to processor core
• Programmable critical interrupt priority ordering
• Programmable critical interrupt vector for faster vector processing
10/100 Mbps Ethernet MAC
• Capable of handling full/half duplex 100Mbps and 10Mbps operation
• Uses the medium independent interface (MII) to the physical layer (PHY not included on chip)
JTAG
• IEEE 1149.1 test access port
• IBM RISCWatch debugger support
• JTAG Boundary Scan Description Language (BSDL)
AMCC
13
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
27mm, 456-Ball E-PBGA Package
Top View
Part Number
Logo View
Gold Gate Release
Corresponds to
A1 Ball Location
®
24 TYP
PPC405GPr
1YWWBZZZZZ CCCCCCC
Lot Number
Notes: 1. All dimensions are in mm.
2. This package is available in leaded or lead-free configurations.
0.20 C
A
0.20
C
27.0
0.25 C
25.0
Bottom View
0.35 C
AF
AD
AB
Y
V
T
27.0
P
M
K
H
F
D
1.0 TYP
AE
AC
AA
Mold
Compound
W
U
Thermal Balls
R
N
PCB
Substrate
L
J
G
E
C
B
A
B
1 3 5 7 9 11 13 15 17 19 21 23 25
2 4 6 8 10 12 14 16 18 20 22 24 26
0.60 ± 0.1 SOLDERBALL x 456
∅ 0.30 M C A B
∅ 0.10 M C
14
0.5±0.1
2.65 max
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
35mm, 456-Ball E-PBGA Package
Top View
Part Number
Logo View
Gold Gate Release
Corresponds to
A1 Ball Location
®
30.0 Typ
PPC405GPr
1YWWBZZZZZ CCCCCCC
Lot Number
Notes: 1. All dimensions are in mm.
2. This package is available in leaded or lead-free configurations.
0.20 C
A
0.20
C
35.0
AF
AD
AB
Y
V
T
35.0
P
M
K
H
F
D
0.25 C
31.75
Bottom View
0.35 C
1.27
AE
AC
AA
Mold
Compound
W
U
Thermal Balls
R
N
PCB
Substrate
L
J
G
E
C
B
A
B
1 3 5 7 9 11 13 15 17 19 21 23 25
2 4 6 8 10 12 14 16 18 20 22 24 26
0.75 ± 0.15 SOLDERBALL x 456
∅ 0.30 M C A B
∅ 0.15 M C
AMCC
0.6±0.1
2.65 max
15
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Pin Lists
The PPC405GPr embedded controller is available as a 456-ball E-PBGA leaded or lead-free package. The 456ball package is available in two sizes—35 millimeters and 27 millimeters. In this section there are two tables that
correlate the external signals to the physical package pin (ball) on which they appear.
The following table lists all the external signals in alphabetical order and shows the ball number on which the signal
appears. Multiplexed signals are shown with the default signal (following reset) not in brackets and the alternate
signal in brackets. Multiplexed signals appear alphabetically multiple times in the list—once for each signal name
on the ball. The page number listed gives the page in “Signal Functional Description” on page 30 where the signals
in the indicated interface group begin.
Signals Listed Alphabetically
Signal Name
(Sheet 1 of 9)
Ball
Interface Group
Page
AGND
E22
System
35
AVDD
D25
System
35
BA0
BA1
AB24
AC24
SDRAM
32
BankSel0
BankSel1
BankSel2
BankSel3
AD17
AF17
AE15
AC14
SDRAM
32
PCI
30
BE0[PCIC0]
BE1[PCIC1]
BE2[PCIC2]
BE3[PCIC3]
BusReq
D19
F24
K24
R26
External Master Peripheral
34
CAS
AB23
R3
SDRAM
32
ClkEn0
ClkEn1
AB25
AC25
SDRAM
32
DMAAck0
DMAAck1
DMAAck2
DMAAck3
D16
B15
B14
C12
External Slave Peripheral
32
DMAReq0
DMAReq1
DMAReq2
DMAReq3
C16
D14
C11
A7
External Slave Peripheral
32
DQM0
DQM1
DQM2
DQM3
AC12
AC10
AC6
AA3
SDRAM
32
DQMCB
AC15
SDRAM
32
ECC0
ECC1
ECC2
ECC3
ECC4
ECC5
ECC6
ECC7
AE14
AF15
AF14
AD13
AF13
AF12
AE13
AD12
SDRAM
32
EMCMDClk
H24
Ethernet
31
AD26
Ethernet
31
EMCTxD0
EMCTxD1
EMCTxD2
EMCTxD3
J26
L25
L24
P25
Ethernet
31
EMCTxEn
K23
Ethernet
31
EMCMDIO[PHYMDIO]
16
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 2 of 9)
Ball
Interface Group
Page
EMCTxErr
K25
Ethernet
31
EOT0/TC0
EOT1/TC1
EOT2/TC2
EOT3/TC3
F3
G2
V2
Y1
External Slave Peripheral
32
ExtAck
Y3
External Master Peripheral
34
ExtReq
Y4
External Master Peripheral
34
ExtReset
T3
External Master Peripheral
34
GND
AMCC
A1
A2
A6
A11
A16
A19
A21
A26
B2
B25
B26
C3
C24
D4
D23
E5
E9
E13
E14
E18
F1
Ground
F26
Note: L11-L16, M11-M16, N11-N16, P11-P16, R11-R16, and T11-T16 are also
H1
thermal balls.
J5
J22
L1
L11-L16
L26
M11-M16
N5
N11-N16
N22
P5
P11-P16
P22
R11-R16
T1
T11-T16
T26
V5
V22
W26
AA1
AA26
AB5
37
17
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signals Listed Alphabetically
Signal Name
GND
(Sheet 3 of 9)
Ball
AB9
AB13
AB14
AB18
AB22
AC4
AC23
AD3
AD24
AE1
AE2
AE25
AF1
AF6
AF8
AF11
AF16
AF21
AF25
AF26
Interface Group
Ground
Note: L11-L16, M11-M16, N11-N16, P11-P16, R11-R16, and T11-T16 are also
thermal balls.
Page
37
Gnt[PCIReq0]
C19
PCI
30
GPIO1[TS1E]
GPIO2[TS2E]
GPIO3[TS1O]
GPIO4[TS2O]
GPIO5[TS3]
GPIO6[TS4]
GPIO7[TS5]
GPIO8[TS6]
GPIO9[TrcClk]
D18
C20
A22
AF18
AC9
AE8
AF5
AC7
AB3
System
35
C4
C5
A4
B9
B10
A9
B11
System
35
[GPIO17]IRQ0
[GPIO18]IRQ1
[GPIO19]IRQ2
[GPIO20]IRQ3
[GPIO21]IRQ4
[GPIO22]IRQ5
[GPIO23]IRQ6
GPIO24
V25
V23
W24
W25
Y24
Y25
AA24
D20
System
35
Halt
AB26
[GPIO10]PerCS1
[GPIO11]PerCS2
[GPIO12]PerCS3
[GPIO13]PerCS4
[GPIO14]PerCS5
[GPIO15]PerCS6
[GPIO16]PerCS7
System
35
HoldAck
U2
External Master Peripheral
34
HoldPri
T2
External Master Peripheral
34
HoldReq
External Master Peripheral
34
IICSCL
AD6
Internal Peripheral
34
IICSDA
AE7
Internal Peripheral
34
IRQ0[GPIO17]
IRQ1[GPIO18]
IRQ2[GPIO19]
IRQ3[GPIO20]
IRQ4[GPIO21]
IRQ5[GPIO22]
IRQ6[GPIO23]
V25
V23
W24
W25
Y24
Y25
AA24
Interrupts
35
18
V1
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 4 of 9)
Ball
Interface Group
Page
MemAddr0
MemAddr1
MemAddr2
MemAddr3
MemAddr4
MemAddr5
MemAddr6
MemAddr7
MemAddr8
MemAddr9
MemAddr10
MemAddr11
MemAddr12
AE22
AC21
AE21
AD21
AF22
AE20
AC19
AE19
AD19
AC18
AF19
AD18
AC17
SDRAM
Note: During a CAS cycle MemAddr0 is the least significant bit (lsb) on this bus.
32
MemClkOut0
MemClkOut1
AC26
AA23
SDRAM
32
MemData0
MemData1
MemData2
MemData3
MemData4
MemData5
MemData6
MemData7
MemData8
MemData9
MemData10
MemData11
MemData12
MemData13
MemData14
MemData15
MemData16
MemData17
MemData18
MemData19
MemData20
MemData21
MemData22
MemData23
MemData24
MemData25
MemData26
MemData27
MemData28
MemData29
MemData30
MemData31
AC13
AE12
AD11
AC11
AF10
AE11
AD10
AF9
AD9
AE9
AD8
AF7
AC8
AD7
AE6
AE5
AE4
AD5
AD4
AC5
AD1
AB2
AA4
AA2
AB1
Y2
W4
W2
W3
V4
W1
V3
SDRAM
Note: MemData0 is the most significant bit (msb) on this bus.
32
AMCC
19
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 5 of 9)
Ball
Interface Group
Page
OVDD
B17
C13
E6
E7
E8
E19
E20
E21
F5
F22
G5
G22
H5
H22
K2
N24
P3
U25
W5
W22
Y5
Y22
AA5
AA22
AB6
AB7
AB8
AB19
AB20
AB21
AD14
AE10
PCIAD0
PCIAD1
PCIAD2
PCIAD3
PCIAD4
PCIAD5
PCIAD6
PCIAD7
PCIAD8
PCIAD9
PCIAD10
PCIAD11
PCIAD12
PCIAD13
PCIAD14
PCIAD15
PCIAD16
PCIAD17
PCIAD18
PCIAD19
PCIAD20
PCIAD21
PCIAD22
PCIAD23
PCIAD24
PCIAD25
PCIAD26
PCIAD27
PCIAD28
PCIAD29
PCIAD30
PCIAD31
A17
B16
C17
A18
D17
C18
B18
A20
B21
A23
D21
B22
B23
C22
C26
F25
K26
L23
M25
M23
N25
M26
N26
P24
R24
R23
P23
R25
T24
U26
T25
V26
PCI
Note: PCIAD31 is the most significant bit (msb) on this bus.
30
PCIC0[BE0]
PCIC1[BE1]
PCIC2[BE2]
PCIC3[BE3]
D19
F24
K24
R26
PCI
30
20
Output driver voltage
37
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 6 of 9)
Ball
Interface Group
Page
PCIClk
B20
PCI
30
PCIDevSel
H25
PCI
30
PCIFrame
J24
PCI
30
PCIGnt0[Req]
PCIGnt1
PCIGnt2
PCIGnt3
PCIGnt4
PCIGnt5
U23
T23
F23
H26
N23
M24
PCI
30
PCIIDSel
P26
PCI
30
PCIINT[PerWE]
C23
PCI
30
PCIIRDY
J23
PCI
30
PCIParity
E26
PCI
30
PCIPErr
G25
PCI
30
PCIReq0[Gnt]
PCIReq1
PCIReq2
PCIReq3
PCIReq4
PCIReq5
C19
C21
B19
A24
G23
J25
PCI
30
PCIReset
B24
PCI
30
PCISErr
G24
PCI
30
PCIStop
H23
PCI
30
PCITRDY
G26
PCI
30
PerAddr0
PerAddr1
PerAddr2
PerAddr3
PerAddr4
PerAddr5
PerAddr6
PerAddr7
PerAddr8
PerAddr9
PerAddr10
PerAddr11
PerAddr12
PerAddr13
PerAddr14
PerAddr15
PerAddr16
PerAddr17
PerAddr18
PerAddr19
PerAddr20
PerAddr21
PerAddr22
PerAddr23
PerAddr24
PerAddr25
PerAddr26
PerAddr27
PerAddr28
PerAddr29
PerAddr30
PerAddr31
D5
A3
B4
B5
D6
B6
C6
D7
A5
B7
C7
D8
B8
C8
D9
A8
C9
D10
C10
A10
D11
B12
D13
D12
B13
A12
A13
C14
A14
A15
C15
D15
External Slave Peripheral
32
PerBLast
F2
External Slave Peripheral
32
PerClk
E4
External Master Peripheral
34
AMCC
21
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 7 of 9)
Ball
Interface Group
Page
PerCS0
PerCS1[GPIO10]
PerCS2[GPIO11]
PerCS3[GPIO12]
PerCS4[GPIO13]
PerCS5[GPIO14]
PerCS6[GPIO15]
PerCS7[GPIO16]
B3
C4
C5
A4
B9
B10
A9
B11
External Slave Peripheral
32
PerData0
PerData1
PerData2
PerData3
PerData4
PerData5
PerData6
PerData7
PerData8
PerData9
PerData10
PerData11
PerData12
PerData13
PerData14
PerData15
PerData16
PerData17
PerData18
PerData19
PerData20
PerData21
PerData22
PerData23
PerData24
PerData25
PerData26
PerData27
PerData28
PerData29
PerData30
PerData31
U4
U3
U1
T4
R2
P4
R4
P2
R1
P1
N3
N1
M1
N2
M3
M4
N4
M2
L3
L4
K1
L2
K3
J1
K4
J3
J2
J4
H3
G1
H2
H4
External Slave Peripheral
32
PerErr
B1
External Master Peripheral
34
PerOE
C2
External Slave Peripheral
32
PerPar0
PerPar1
PerPar2
PerPar3
D3
G4
G3
E1
External Slave Peripheral
32
PerReady
E3
External Slave Peripheral
32
PerR/W
C1
External Slave Peripheral
32
PerWBE0
PerWBE1
PerWBE2
PerWBE3
D2
E2
F4
D1
External Slave Peripheral
32
External Slave Peripheral
32
AA25
Ethernet
31
PHYCrS
W23
Ethernet
31
PHYRxClk
AF20
Ethernet
31
PHYMDIO[EMCMDIO]
AD26
Ethernet
31
PHYRxD0
PHYRxD1
PHYRxD2
PHYRxD3
AE23
AF23
AC20
AD20
Ethernet
31
PHYRxDV
V24
Ethernet
31
[PerWE]PCIINT
PHYCol
22
C23
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 8 of 9)
Ball
Interface Group
Page
PHYRxErr
U24
Ethernet
31
PHYTxClk
E25
Ethernet
31
RAS
AF24
SDRAM
32
Reserved
C25
E23
E24
Y23
Y26
AF41
Other
Note: AF4 must be tied to OVDD or GND. All other reserved pins should be left
unconnected.
37
Req[PCIGnt0]
U23
PCI
30
SysClk
A25
System
35
SysErr
AD25
System
35
D22
System
35
SysReset
TCK
AD22
JTAG
35
TDI
AE24
JTAG
35
TDO
AD23
JTAG
35
TestEn
D26
System
35
TmrClk
D24
System
35
TMS
AC22
JTAG
35
TRST
AE26
JTAG
35
[TS1E]GPIO1
[TS2E]GPIO2
[TS1O]GPIO3
[TS2O]GPIO4
[TS3]GPIO5
[TS4]GPIO6
[TS5]GPIO7
[TS6]GPIO8
[TrcClk]GPIO9
D18
C20
A22
AF18
AC9
AE8
AF5
AC7
AB3
System
35
UART0_CTS
AB4
Internal Peripheral
34
UART0_DCD
AE18
Internal Peripheral
34
UART0_DSR
AE3
Internal Peripheral
34
UART0_DTR
AF2
Internal Peripheral
34
UART0_RI
AD15
Internal Peripheral
34
UART0_RTS
AD16
Internal Peripheral
34
UART0_Rx
AE16
Internal Peripheral
34
UART0_Tx
AF3
Internal Peripheral
34
UART1_CTS/UART1_DSR
AC3
Internal Peripheral
34
UART1_DSR/UART1_CTS
AC3
Internal Peripheral
34
UART1_DTR/UART1_RTS
AD2
Internal Peripheral
34
UART1_RTS/UART1_DTR
AD2
Internal Peripheral
34
UART1_Rx
AC1
Internal Peripheral
34
UART1_Tx
AC2
Internal Peripheral
34
UARTSerClk
AE17
Internal Peripheral
34
AMCC
23
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signals Listed Alphabetically
Signal Name
(Sheet 9 of 9)
Ball
Interface Group
Page
VDD
E10
E11
E12
E15
E16
E17
K5
K22
L5
L22
M5
M22
R5
R22
T5
T22
U5
U22
AB10
AB11
AB12
AB15
AB16
AB17
Logic voltage
37
WE
AC16
SDRAM
32
24
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed by Ball Assignment
(Sheet 1 of 3)
Ball
Signal Name
Ball
Signal Name
Ball
Signal Name
Ball
Signal Name
A1
GND
B14
DMAAck2
D1
PerWBE3
E14
GND
A2
GND
B15
DMAAck1
D2
PerWBE0
E15
VDD
A3
PerAddr1
B16
PCIAD1
D3
PerPar0
E16
VDD
A4
PerCS3[GPIO12]
B17
OVDD
D4
GND
E17
VDD
A5
PerAddr8
B18
PCIAD6
D5
PerAddr0
E18
GND
A6
GND
B19
PCIReq2
D6
PerAddr4
E19
OVDD
A7
DMAReq3
B20
PCIClk
D7
PerAddr7
E20
OVDD
A8
PerAddr15
B21
PCIAD8
D8
PerAddr11
E21
OVDD
A9
PerCS6[GPIO15]
B22
PCIAD11
D9
PerAddr14
E22
AGND
A10
PerAddr19
B23
PCIAD12
D10
PerAddr17
E23
Reserved
A11
GND
B24
PCIReset
D11
PerAddr20
E24
Reserved
A12
PerAddr25
B25
GND
D12
PerAddr23
E25
PHYTxClk
A13
PerAddr26
B26
GND
D13
PerAddr22
E26
PCIParity
A14
PerAddr28
C1
PerR/W
D14
DMAReq1
F1
GND
A15
PerAddr29
C2
PerOE
D15
PerAddr31
F2
PerBLast
A16
GND
C3
GND
D16
DMAAck0
F3
EOT0/TC0
A17
PCIAD0
C4
PerCS1[GPIO10]
D17
PCIAD4
F4
PerWBE2
A18
PCIAD3
C5
PerCS2[GPIO11]
D18
GPIO1[TS1E]
F5
OVDD
A19
GND
C6
PerAddr6
D19
PCIC0[BE0]
F22
OVDD
A20
PCIAD7
C7
PerAddr10
D20
GPIO24
F23
PCIGnt2
A21
GND
C8
PerAddr13
D21
PCIAD10
F24
PCIC1[BE1]
A22
GPIO3[TS1O]
C9
PerAddr16
D22
SysReset
F25
PCIAD15
A23
PCIAD9
C10
PerAddr18
D23
GND
F26
GND
A24
PCIReq3
C11
DMAReq2
D24
TmrClk
G1
PerData29
A25
SysClk
C12
DMAAck3
D25
AVDD
G2
EOT1/TC1
A26
GND
C13
OVDD
D26
TestEn
G3
PerPar2
B1
PerErr
C14
PerAddr27
E1
PerPar3
G4
PerPar1
B2
GND
C15
PerAddr30
E2
PerWBE1
G5
OVDD
B3
PerCS0
C16
DMAReq0
E3
PerReady
G22
OVDD
B4
PerAddr2
C17
PCIAD2
E4
PerClk
G23
PCIReq4
B5
PerAddr3
C18
PCIAD5
E5
GND
G24
PCISErr
B6
PerAddr5
C19
PCIReq0[Gnt]
E6
OVDD
G25
PCIPErr
B7
PerAddr9
C20
GPIO2[TS2E]
E7
OVDD
G26
PCITRDY
B8
PerAddr12
C21
PCIReq1
E8
OVDD
H1
GND
B9
PerCS4[GPIO13]
C22
PCIAD13
E9
GND
H2
PerData30
B10
PerCS5[GPIO14]
C23
PCIINT[PerWE]
E10
VDD
H3
PerData28
B11
PerCS7[GPIO16]
C24
GND
E11
VDD
H4
PerData31
H5
OVDD
B12
PerAddr21
C25
Reserved
E12
VDD
B13
PerAddr24
C26
PCIAD14
E13
GND
H22
OVDD
H23
PCIStop
M1
PerData12
P14
GND
U1
PerData2
H24
EMCMDClk
M2
PerData17
P15
GND
U2
HoldAck
H25
PCIDevSel
M3
PerData14
P16
GND
U3
PerData1
H26
PCIGnt3
M4
PerData15
P22
GND
U4
PerData0
AMCC
25
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed by Ball Assignment
26
(Sheet 2 of 3)
Ball
Signal Name
Ball
Signal Name
Ball
Signal Name
Ball
Signal Name
J1
PerData23
M5
VDD
P23
PCIAD26
U5
VDD
J2
PerData26
M11
GND
P24
PCIAD23
U22
VDD
J3
PerData25
M12
GND
P25
EMCTxD3
U23
PCIGnt0[Req]
J4
PerData27
M13
GND
P26
PCIIDSel
U24
PHYRxErr
J5
GND
M14
GND
R1
PerData8
U25
OVDD
J22
GND
M15
GND
R2
PerData4
U26
PCIAD29
J23
PCIIRDY
M16
GND
R3
BusReq
V1
HoldReq
J24
PCIFrame
M22
VDD
R4
PerData6
V2
EOT2/TC2
J25
PCIReq5
M23
PCIAD19
R5
VDD
V3
MemData31
J26
EMCTxD0
M24
PCIGnt5
R11
GND
V4
MemData29
K1
PerData20
M25
PCIAD18
R12
GND
V5
GND
K2
OVDD
M26
PCIAD21
R13
GND
V22
GND
IRQ1[GPIO18]
K3
PerData22
N1
PerData11
R14
GND
V23
K4
PerData24
N2
PerData13
R15
GND
V24
PHYRxDV
K5
VDD
N3
PerData10
R16
GND
V25
IRQ0[GPIO17]
K22
VDD
N4
PerData16
R22
VDD
V26
PCIAD31
K23
EMCTxEn
N5
GND
R23
PCIAD25
W1
MemData30
K24
PCIC2[BE2]
N11
GND
R24
PCIAD24
W2
MemData27
K25
EMCTxErr
N12
GND
R25
PCIAD27
W3
MemData28
K26
PCIAD16
N13
GND
R26
PCIC3[BE3]
W4
MemData26
L1
GND
N14
GND
T1
GND
W5
OVDD
L2
PerData21
N15
GND
T2
HoldPri
W22
OVDD
L3
PerData18
N16
GND
T3
ExtReset
W23
PHYCrS
L4
PerData19
N22
GND
T4
PerData3
W24
IRQ2[GPIO19]
L5
VDD
N23
PCIGnt4
T5
VDD
W25
IRQ3[GPIO20]
L11
GND
N24
OVDD
T11
GND
W26
GND
L12
GND
N25
PCIAD20
T12
GND
Y1
EOT3/TC3
L13
GND
N26
PCIAD22
T13
GND
Y2
MemData25
L14
GND
P1
PerData9
T14
GND
Y3
ExtAck
L15
GND
P2
PerData7
T15
GND
Y4
ExtReq
L16
GND
P3
OVDD
T16
GND
Y5
OVDD
L22
VDD
P4
PerData5
T22
VDD
Y22
OVDD
L23
PCIAD17
P5
GND
T23
PCIGnt1
Y23
Reserved
L24
EMCTxD2
P11
GND
T24
PCIAD28
Y24
IRQ4[GPIO21]
L25
EMCTxD1
P12
GND
T25
PCIAD30
Y25
IRQ5[GPIO22]
L26
GND
P13
GND
T26
GND
Y26
Reserved
AA1
GND
AB26
Halt
AD9
MemData8
AE18
UART0_DCD
AA2
MemData23
AC1
UART1_Rx
AD10
MemData6
AE19
MemAddr7
AA3
DQM3
AC2
UART1_Tx
AD11
MemData2
AE20
MemAddr5
AA4
MemData22
AC3
UART1_DSR/
UART1_CTS
AD12
ECC7
AE21
MemAddr2
AA5
OVDD
AC4
GND
AD13
ECC3
AE22
MemAddr0
AA22
OVDD
AC5
MemData19
AD14
OVDD
AE23
PHYRxD0
AA23
MemClkOut1
AC6
DQM2
AD15
UART0_RI
AE24
TDI
AA24
IRQ6[GPIO23]
AC7
GPIO8[TS6]
AD16
UART0_RTS
AE25
GND
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signals Listed by Ball Assignment
(Sheet 3 of 3)
Ball
Signal Name
Ball
Signal Name
AA25
PHYCol
AC8
MemData12
AA26
GND
AC9
GPIO5[TS3]
Ball
Signal Name
Ball
Signal Name
AD17
BankSel0
AE26
TRST
AD18
MemAddr11
AF1
GND
AB1
MemData24
AC10
DQM1
AD19
MemAddr8
AF2
UART0_DTR
AB2
MemData21
AC11
MemData3
AD20
PHYRxD3
AF3
UART0_Tx
AB3
GPIO9[TrcClk]
AC12
DQM0
AD21
MemAddr3
AF4
Reserved
AB4
UART0_CTS
AC13
MemData0
AD22
TCK
AF5
GPIO7[TS5]
AB5
GND
AC14
BankSel3
AD23
TDO
AF6
GND
AB6
OVDD
AC15
DQMCB
AD24
GND
AF7
MemData11
AB7
OVDD
AC16
WE
AD25
SysErr
AF8
GND
AB8
OVDD
AC17
MemAddr12
AD26
EMCMDIO
[PHYMDIO]
AF9
MemData7
AB9
GND
AC18
MemAddr9
AE1
GND
AF10
MemData4
AB10
VDD
AC19
MemAddr6
AE2
GND
AF11
GND
AB11
VDD
AC20
PHYRxD2
AE3
UART0_DSR
AF12
ECC5
AB12
VDD
AC21
MemAddr1
AE4
MemData16
AF13
ECC4
AB13
GND
AC22
TMS
AE5
MemData15
AF14
ECC2
AB14
GND
AC23
GND
AE6
MemData14
AF15
ECC1
AB15
VDD
AC24
BA1
AE7
IICSDA
AF16
GND
AB16
VDD
AC25
ClkEn1
AE8
GPIO6[TS4]
AF17
BankSel1
AB17
VDD
AC26
MemClkOut0
AE9
MemData9
AF18
GPIO4[TS2O]
AB18
GND
AD1
MemData20
AE10
OVDD
AF19
MemAddr10
AB19
OVDD
AD2
UART1_RTS/
UART1_DTR
AE11
MemData5
AF20
PHYRxClk
AB20
OVDD
AD3
GND
AE12
MemData1
AF21
GND
AB21
OVDD
AD4
MemData18
AE13
ECC6
AF22
MemAddr4
AB22
GND
AD5
MemData17
AE14
ECC0
AF23
PHYRxD1
AB23
CAS
AD6
IICSCL
AE15
BankSel2
AF24
RAS
AB24
BA0
AD7
MemData13
AE16
UART0_Rx
AF25
GND
AB25
ClkEn0
AD8
MemData10
AE17
UARTSerClk
AF26
GND
AMCC
27
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signal List
The following table provides a summary of the number of package pins associated with each functional interface
group.
Pin Summary
Group
No. of Pins
PCI
60
Ethernet
18
SDRAM
71
External peripheral
96
External master
9
Internal peripheral
15
Interrupts
7
JTAG
5
System
18
Total Signal Pins
299
OVDD
32
VDD
24
Gnd
59
Thermal (and Gnd)
36
Reserved
6
Total Pins
456
Multiplexed Pins
In the table “Signal Functional Description” on page 30, each external signal is listed along with a description of the
signal function. Some signals are multiplexed on the same pin (ball) so that the pin can be used for different
functions. Multiplexed signals are shown as a default signal with a secondary signal in square brackets (for
example, GPIO1[TS1E]). Active-low signals (for example, RAS) are marked with an overline.
It is expected that in any single application a particular pin will always be programmed to serve the same function.
The flexibility of multiplexing allows a single chip to offer a richer pin selection than would otherwise be possible.
In addition to multiplexing, many pins are also multi-purpose. For example, the EBC peripheral controller address
pins are used as outputs by the PPC405GPr to broadcast an address to external slave devices when the
PPC405GPr has control of the external bus. When, during the course of normal chip operation, an external master
gains ownership of the external bus, these same pins are used as inputs which are driven by the external master
and received by the EBC in the PPC405GPr. In this example, the pins are also bidirectional, serving as both inputs
and outputs.
Intialization Strapping
One group of pins is used as strapped inputs during system reset. These pins function as strapped inputs only
during reset and are used for other functions during normal operation (see “Strapping” on page 51). Note that the
use of these pins for strapping is not considered multiplexing since the strapping function is not programmable.
28
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Pull-Up and Pull-Down Resistors
Pull-up and pull-down resistors are used for strapping during reset and to retain unused or undriven inputs in an
appropriate state. The recommended pull-up value of 3kΩ to +3.3V (10kΩ to +5V can be used on 5V tolerant I/Os)
and pull-down value of 1kΩ to GND, applies only to individually terminated signals. To prevent possible damage to
the device, I/Os capable of becoming outputs must never be tied together and terminated through a common
resistor.
If your system-level test methodology permits, input-only signals can be connected together and terminated
through either a common resistor or directly to +3.3V or GND. When a resistor is used, its value must ensure that
the grouped I/Os reach a valid logic zero or logic one state when accounting for the total input current into the
PPC405GPr.
Unused I/Os
For some interfaces, it is possible to turn off input receivers for some or all of the signals by means of bit settings in
register CPC0_CR1. When this gating capability is applied to unused signals, it is not necessary to terminate them.
Refer to the PowerPC 405GPr Embedded Processor User’s Manual for details.
If receiver gating is not used, termination of some pins may be necessary when they are unused. Although the
PPC405GPr requires only the pull-up and pull-down terminations as specified in the “Signal Functional
Description” on page 30, good design practice is to terminate all unused inputs or to configure I/Os such that they
always drive. If unused, and receiver gating is not used, the peripheral, SDRAM, and PCI buses should be
configured and terminated as follows:
• Peripheral interface—PerAddr0:31, PerData0:31, and all of the control signals are driven by default. Terminate
PerReady high and PerError low.
• SDRAM—Program SDRAM0_CFG[EMDULR]=1 and SDRAM0_CFG[DCE]=1. This causes the PPC405GPr to
actively drive all of the SDRAM address, data, and control signals.
• PCI—The PCI pull-up requirements given in the Signal Functional Description apply only when the PCI
interface is being used. When the PCI bridge is unused, configure the PCI controller to park on the bus and
actively drive PCIAD31:0, PCIC3:0[BE3:0], and the remaining PCI control signals by doing the following:
- Strap the PPC405GPr to disable the internal PCI arbiter and to operate the PCI interface in synchronous
mode.
- Individually connect PCISErr, PCIPErr, PCITRDY, and PCIStop through 3kΩ resistors to +3.3V.
- Terminate PCIReq1:5 to +3.3V.
- Terminate PCIReq0[Gnt] to GND.
External Bus Control Signals
All peripheral bus control signals (PerCS0:7, PerR/W, PerWBE0:3, PerOE, PerWE, PerBLast, HoldAck, ExtAck)
are set to the high-impedance state when ExtReset=0. In addition, as detailed in the PowerPC 405GPr Embedded
Processor User’s Manual, the peripheral bus controller can be programmed via EBC0_CFG to float some of these
control signals between transactions and/or when an external master owns the peripheral bus. As a result, a pullup resistor should be added to those control signals where an undriven state may affect any devices receiving that
particular signal.
The following table lists all of the I/O signals provided by the PPC405GPr. Please refer to “Signals Listed
Alphabetically” on page 16 for the pin number to which each signal is assigned.
AMCC
29
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signal Functional Description
(Sheet 1 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Description
Notes
I/O
Type
PCI Address/Data Bus. Multiplexed address and data bus.
I/O
5V tolerant
3.3V PCI
PCI bus command and byte enables.
I/O
5V tolerant
3.3V PCI
PCIParity
PCI parity. Parity is even across PCIAD0:31 and PCIC0:3[BE0:3].
PCIParity is valid one cycle after either an address or data phase.
The PCI device that drove PCIAD0:31 is responsible for driving
PCIParity on the next PCI bus clock.
I/O
5V tolerant
3.3V PCI
PCIFrame
PCIFrame is driven by the current PCI bus master to indicate the
beginning and duration of a PCI access.
I/O
5V tolerant
3.3V PCI
2
PCIIRDY
PCIIRDY is driven by the current PCI bus master. Assertion of
PCIIRDY indicates that the PCI initiator is ready to transfer data.
I/O
5V tolerant
3.3V PCI
2
PCITRDY
The target of the current PCI transaction drives PCITRDY. Assertion
of PCITRDY indicates that the PCI target is ready to transfer data.
I/O
5V tolerant
3.3V PCI
2
PCIStop
The target of the current PCI transaction can assert PCIStop to
indicate to the requesting PCI master that it wants to end the current
transaction.
I/O
5V tolerant
3.3V PCI
2
PCIDevSel
PCIDevSel is driven by the target of the current PCI transaction. A
PCI target asserts PCIDevSel when it has decoded an address and
command encoding and claims the transaction.
I/O
5V tolerant
3.3V PCI
2
PCIIDSel
PCIIDSel is used during configuration cycles to select the PCI slave
interface for configuration.
I
5V tolerant
3.3V PCI
PCISErr
PCISErr is used for reporting address parity errors or catastrophic
failures detected by a PCI target.
I/O
5V tolerant
3.3V PCI
2
PCIPErr
PCIPErr is used for reporting data parity errors on PCI transactions.
PCIPErr is driven active by the device receiving PCIAD0:31,
PCIC0:3[BE0:3], and PCIParity, two PCI clocks following the data in
which bad parity is detected.
I/O
5V tolerant
3.3V PCI
2
PCIClk
PCIClk is used as the asynchronous PCI clock when in
asynchronous mode. It is unused when the PCI interface is operated
synchronously with the PLB bus.
I
5V tolerant
3.3V PCI
PCI specific reset.
O
5V tolerant
3.3V PCI
PCIINT[PerWE]
PCI interrupt. Open-drain output (two states; 0 or open circuit)
or
Peripheral write enable. Low when any of the four PerWBE0:3 write
byte enables are low.
O
5V tolerant
3.3V PCI
PCIReq0[Gnt]
Multipurpose signal, used as PCIReq0 when internal arbiter is used,
and as Gnt when external arbiter is used.
I
5V tolerant
3.3V PCI
Used as PCIReq1:5 input when internal arbiter is used.
I
5V tolerant
3.3V PCI
PCI Interface
PCIAD31:0
PCIC3:0[BE3:0]
PCIReset
PCIReq1:5
30
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signal Functional Description
(Sheet 2 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Notes
I/O
Type
Gnt0 when internal arbiter is used
or
Req when external arbiter is used.
O
5V tolerant
3.3V PCI
Used as PCIGnt1:5 output when internal arbiter is used.
O
5V tolerant
3.3V PCI
PHYRxD3:0
Received data. This is a nibble wide bus from the PHY. The data is
synchronous with the PHYRxClk.
I
5V tolerant
3.3V LVTTL
1
EMCTxD3:0
Transmit data. A nibble wide data bus towards the net. The data is
synchronous to the PHYTxClk.
O
5V tolerant
3.3V LVTTL
6
PHYRxErr
Receive Error. This signal comes from the PHY and is synchronous
to the PHYRxClk.
I
5V tolerant
3.3V LVTTL
1
PHYRxClk
Receiver Medium clock. This signal is generated by the PHY.
I
5V tolerant
3.3V LVTTL
1
PHYRxDV
Receive Data Valid. Data on the Data Bus is valid when this signal is
activated. Deassertion of this signal indicates end of the frame
reception.
I
5V tolerant
3.3V LVTTL
1
PHYCrS
Carrier Sense signal from the PHY. This is an asynchronous signal.
I
5V tolerant
3.3V LVTTL
1
EMCTxErr
Transmit Error. This signal is generated by the Ethernet controller, is
connected to the PHY and is synchronous with the PHYTxClk. It
informs the PHY that an error was detected.
O
5V tolerant
3.3V LVTTL
6
EMCTxEn
Transmit Enable. This signal is driven by the EMAC to the PHY. Data
is valid during the active state of this signal. Deassertion of this signal
indicates end of frame transmission. This signal is synchronous to
the PHYTxClk.
O
5V tolerant
3.3V LVTTL
6
PHYTxClk
This clock comes from the PHY and is the Medium Transmit clock.
I
5V tolerant
3.3V LVTTL
1
Collision signal from the PHY. This is an asynchronous signal.
I
5V tolerant
3.3V LVTTL
1
EMCMDClk
Management Data Clock. The MDClk is sourced to the PHY. This
clock has a period of 400ns, adjustable via EMAC0_STACR[OPBC].
Management information is transferred synchronously with respect to
this clock.
O
5V tolerant
3.3V LVTTL
EMCMDIO[PHYMDIO]
Management Data Input/Output is a bidirectional signal between the
Ethernet controller and the PHY. It is used to transfer control and
status information.
I/O
5V tolerant
3.3V LVTTL
PCIGnt0[Req]
PCIGnt1:5
Description
Ethernet Interface
PHYCol
AMCC
1
31
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signal Functional Description
(Sheet 3 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Description
I/O
Type
MemData0:31
Memory data bus.
Notes:
1. MemData0 is the most significant bit (msb).
2. MemData31 is the least significant bit (lsb).
I/O
3.3V LVTTL
MemAddr12:0
Memory address bus.
Notes:
1. MemAddr12 is the most significant bit (msb).
2. MemAddr0 is the least significant bit (lsb).
O
3.3V LVTTL
BA1:0
Bank Address supporting up to 4 internal banks.
O
3.3V LVTTL
Notes
SDRAM Interface
RAS
Row Address Strobe.
O
3.3V LVTTL
CAS
Column Address Strobe.
O
3.3V LVTTL
DQM0:3
DQM for byte lane: 0 (MemData0:7),
1 (MemData8:15),
2 (MemData16:23), and
3 (MemData24:31)
O
3.3V LVTTL
DQMCB
DQM for ECC check bits.
O
3.3V LVTTL
ECC0:7
ECC check bits 0:7.
I/O
3.3V LVTTL
Select up to four external SDRAM banks.
O
3.3V LVTTL
Write Enable.
O
3.3V LVTTL
SDRAM Clock Enable.
O
3.3V LVTTL
Two copies of an SDRAM clock allows, in some cases, glueless
SDRAM attach without requiring this signal to be repowered by a PLL
or zero-delay buffer.
O
3.3V LVTTL
BankSel0:3
WE
ClkEn0:1
MemClkOut0:1
External Slave Peripheral Interface
PerData0:31
Peripheral data bus used by PPC405GPr when not in external
master mode, otherwise used by external master.
Note: PerData0 is the most significant bit (msb) on this bus.
I/O
5V tolerant
3.3V LVTTL
1
PerAddr0:31
Peripheral address bus used by PPC405GPr when not in external
master mode, otherwise used by external master.
Note: PerAddr0 is the most significant bit (msb) on this bus.
I/O
5V tolerant
3.3V LVTTL
1
Peripheral byte parity signals.
I/O
5V tolerant
3.3V LVTTL
1
PerWBE0:3
As outputs, these pins can act as byte-enables which are valid for an
entire cycle or as write-byte-enables which are valid for each byte on
each data transfer, allowing partial word transactions. As outputs,
pins are used by either the pripheral controller or the DMA controller
depending upon the type of transfer involved. Used as inputs when
an external bus master owns the external interface.
I/O
5V tolerant
3.3V LVTTL
1, 7
[PerWE]PCIINT
Peripheral write enable. Low when any of the four PerWBE0:3 write
byte enables are low.
or
PCI interrupt. Open-drain output (two states; 0 or open circuit)
O
5V tolerant
3.3V PCI
PerPar0:3
32
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signal Functional Description
(Sheet 4 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
I/O
Type
Notes
O
5V tolerant
3.3V LVTTL
7
PerCS1:7[GPIO10:16]
Seven additional peripheral chip selects
or
General Purpose I/O. To access this function, software must toggle a
DCR bit.
O[I/O]
5V tolerant
3.3V LVTTL
1, 7
PerOE
Used by either the peripheral controller or the DMA controller
depending upon the type of transfer involved. When the PPC405GPr
is the bus master, it enables the selected device to drive the bus.
O
5V tolerant
3.3V LVTTL
7
PerR/W
Used by the PPC405GPr when not in external master mode, as
output by either the peripheral controller or DMA controller depending
upon the type of transfer involved. High indicates a read from
memory, low indicates a write to memory.
Otherwise it used by the external master as an input to indicate the
direction of data transfer.
I/O
5V tolerant
3.3V LVTTL
1
Signal Name
PerCS0
Peripheral chip select bank 0.
PerReady
Used by a peripheral slave to indicate it is ready to transfer data.
I
5V tolerant
3.3V LVTTL
1
PerBLast
Used by the PPC405GPr when not in external master mode,
otherwise used by external master. Indicates the last transfer of a
memory access.
I/O
5V tolerant
3.3V LVTTL
1, 7
DMAReq0:3
DMAReq0:3 are used by slave peripherals to indicate they are
prepared to transfer data.
I
5V tolerant
3.3V LVTTL
1
DMAAck0:3
DMAAck0:3 are used by the PPC405GPr to cause the DMA
peripheral to transfer data.
O
5V tolerant
3.3V LVTTL
6
End Of Transfer/Terminal Count.
I/O
5V tolerant
3.3V LVTTL
1
EOT0:3/TC0:3
AMCC
Description
33
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signal Functional Description
(Sheet 5 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Description
I/O
Type
Notes
External Master Peripheral Interface
PerClk
Peripheral clock to be used by an external master and by
synchronous peripheral slaves.
O
5V tolerant
3.3V LVTTL
ExtReset
Peripheral reset to be used by an external master and by
synchronous peripheral slaves.
O
5V tolerant
3.3V LVTTL
HoldReq
Hold Request, used by an external master to request ownership of
the peripheral bus.
I
5V tolerant
3.3V LVTTL
1, 5
HoldAck
Hold Acknowledge, used by the PPC405GPr to transfer ownership of
peripheral bus to an external master.
O
5V tolerant
3.3V LVTTL
6
ExtReq
ExtReq is used by an external master to indicate it is prepared to
transfer data.
I
5V tolerant
3.3V LVTTL
1
ExtAck
ExtAck is used by the PPC405GPr to indicate a data transfer cycle.
O
5V tolerant
3.3V LVTTL
6
HoldPri
Used by an external master to indicate the priority of a given external
master tenure.
I
5V tolerant
3.3V LVTTL
1
BusReq
Used when the PPC405GPr needs to regain control of peripheral
interface from an external master.
O
5V tolerant
3.3V LVTTL
PerErr
An input used to indicate to the PPC405GPr that an external slave
peripheral error occurred.
I
5V tolerant
3.3V LVTTL
1, 5
Serial Clock used to provide an alternate clock to the internally
generated serial clock. Used in cases where the allowable internally
generated baud rates are not satisfactory. This input can be
individually connected to either UART.
I
5V tolerant
3.3V LVTTL
1
UART0_Rx
UART0 Serial Data In.
I
5V tolerant
3.3V LVTTL
1
UART0_Tx
UART0 Serial Data Out.
O
5V tolerant
3.3V LVTTL
6
UART0_DCD
UART0 Data Carrier Detect.
I
5V tolerant
3.3V LVTTL
1
UART0_DSR
UART0 Data Set Ready.
I
5V tolerant
3.3V LVTTL
1
UART0_CTS
UART0 Clear To Send.
I
5V tolerant
3.3V LVTTL
1
UART0_DTR
UART0 Data Terminal Ready.
O
5V tolerant
3.3V LVTTL
6
UART0_RTS
UART0 Request To Send.
O
5V tolerant
3.3V LVTTL
6
UART0_RI
UART0 Ring Indicator.
I
5V tolerant
3.3V LVTTL
1
UART1_Rx
UART1 Serial Data In.
I
5V tolerant
3.3V LVTTL
1
Internal Peripheral Interface
UARTSerClk
34
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signal Functional Description
(Sheet 6 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
I/O
Type
Notes
UART1 Serial Data Out.
O
5V tolerant
3.3V LVTTL
6
UART1_DSR/
UART1_CTS
UART1 Data Set Ready
or
UART1 Clear To Send. To access this function, software must toggle
a DCR bit.
I
5V tolerant
3.3V LVTTL
1
UART1_RTS/
UART1_DTR
UART1 Request To Send
or
UART1 Data Terminal Ready. To access this function, software must
toggle a DCR bit.
O
5V tolerant
3.3V LVTTL
6
IICSCL
IIC Serial Clock.
I/O
5V tolerant
3.3V LVTTL
1, 2
IICSDA
IIC Serial Data.
I/O
5V tolerant
3.3V LVTTL
1, 2
I[I/O]
5V tolerant
3.3V LVTTL
1
Signal Name
UART1_Tx
Description
Interrupts Interface
IRQ0:6[GPIO17:23]
Interrupt requests
or
General Purpose I/O. To access this function, software must toggle a
DCR bit.
JTAG Interface
TDI
Test data in.
I
5V tolerant
3.3V LVTTL
1, 4
TMS
JTAG test mode select.
I
5V tolerant
3.3V LVTTL
1, 4
TDO
Test data out.
O
5V tolerant
3.3V LVTTL
TCK
JTAG test clock. The frequency of this input can range from DC to
25MHz.
I
5V tolerant
3.3V LVTTL
1, 4
TRST
JTAG reset. TRST must be low at power-on to initialize the JTAG
controller and for normal operation of the PPC405GPr.
I
5V tolerant
3.3V LVTTL
5
Main system clock input.
I
5V tolerant
3.3V LVTTL
I/O
5V tolerant
3.3V LVTTL
System Interface
SysClk
SysReset
AVDD
Clean voltage input for the PLL.
I
AGND
Clean Ground input for the PLL.
I
SysErr
Set to 1 when a Machine Check is generated.
O
5V tolerant
3.3V LVTTL
Halt from external debugger.
I
5V tolerant
3.3V LVTTL
Halt
AMCC
Main system reset. External logic can drive this bidirectional pin low
(minimum of 16 cycles) to initiate a system reset. A system reset can
also be initiated by software. Implemented as an open-drain output
(two states; 0 or open circuit).
1, 2
1, 2
35
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Signal Functional Description
(Sheet 7 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Description
I/O
Type
Notes
GPIO1[TS1E]
GPIO2[TS2E]
General Purpose I/O
or
Even Trace execution status. To access this function, software must
toggle a DCR bit.
I/O[O]
5V tolerant
3.3V LVTTL
1, 6
GPIO3[TS1O]
General Purpose I/O
or
Odd Trace execution status. To access this function, software must
toggle a DCR bit.
I/O[O]
5V tolerant
3.3V LVTTL
1, 6
GPIO4[TS2O]
General Purpose I/O
or
Odd Trace execution status. To access this function, software must
toggle a DCR bit.
I/O[O]
5V tolerant
3.3V LVTTL
1, 6
GPIO5:8[TS3:6]
General Purpose I/O
or
Trace status. To access this function, software must toggle a DCR
bit.
I/O[O]
5V tolerant
3.3V LVTTL
1, 6
GPIO9[TrcClk]
General Purpose I/O
or
Trace interface clock. A toggling signal that is always half of the CPU
core frequency. To access this function, software must toggle a DCR
bit.
Note: Initialization strapping must hold this pin low (0) during reset.
I/O[O]
5V tolerant
3.3V LVTTL
1, 6
GPIO24
General Purpose I/O.
Note: The pull-up initialization strapping resistor must be 1kΩ rather
than 3kΩ in order to overcome the internal pull-down resistor.
I/O
3.3V LVTTL
w/pull-down
1, 6
TestEn
Test Enable. Used only for manufacturing tests. Pull down for normal
operation.
I
1.8V CMOS
w/pull-down
TmrClk
An external clock input that can be used to clock the timers in the
CPU core.
I
5V tolerant
3.3V LVTTL
1
Trace Interface
[TS1E]GPIO1
[TS2E]GPIO2
Even Trace execution status. To access this function, software must
toggle a DCR bit
or
General Purpose I/O.
O[I/O]
5V tolerant
3.3V LVTTL
1, 6
[TS1O]GPIO3
Odd Trace execution status. To access this function, software must
toggle a DCR bit
or
General Purpose I/O.
O[I/O]
5V tolerant
3.3V LVTTL
1, 6
[TS2O]GPIO4
Odd Trace execution status. To access this function, software must
toggle a DCR bit
or
General Purpose I/O.
O[I/O]
5V tolerant
3.3V LVTTL
1, 6
Trace status. To access this function, software must toggle a DCR bit
or
O[I/O]
General Purpose I/O.
5V tolerant
3.3V LVTTL
1, 6
[TS3:6]GPIO5:8
36
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Signal Functional Description
(Sheet 8 of 8)
Multiplexed signals are shown in brackets following the first signal name assigned to each multiplexed ball.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 29 for recommended termination values.
4. If not used, must pull up.
5. If not used, must pull down.
6. Strapping input during reset; pull up or pull down as required.
7. Pull-up may be required. See “External Bus Control Signals” on page 29.
Signal Name
Description
I/O
Type
Notes
[TrcClk]GPIO9
Trace interface clock. A toggling signal that is always half of the CPU
core frequency. To access this function, software must toggle a DCR
bit
or
General Purpose I/O.
Note: Initialization strapping must hold this pin low (0) during reset.
O[I/O]
5V tolerant
3.3V LVTTL
1, 6
Ground pins
GND
Ground
Note: L11-L16, M11-M16, N11-N16, P11-P16, R11-R16, and
T11-T16 are also thermal balls.
OVDD pins
OVDD
Output driver voltage—3.3V.
VDD pins
VDD
Logic voltage—1.8V.
Other pins
Reserved
AMCC
Reserved—Except for AF4, do not connect signals, voltage, or
ground to these pins. AF4 must be tied to OVDD or GND.
37
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Absolute Maximum Ratings
The absolute maximum ratings below are stress ratings only. Operation at or beyond these maximum ratings can cause
permanent damage to the device
Characteristic
Symbol
Value
Unit
Supply Voltage (Internal Logic)
VDD
0 to +1.95
V
Supply Voltage (I/O Interface)
OVDD
0 to +3.6
V
PLL Supply Voltage
AVDD
0 to +1.95
V
Input Voltage (1.8V CMOS receivers)
VIN
-0.6 to VDD + 0.45
V
Input Voltage (3.3V LVTTL receivers)
VIN
-0.6 to OVDD + 0.6
V
Input Voltage (5.0V LVTTL receivers)
VIN
-0.6 to OVDD + 2.4
V
Storage Temperature Range
TSTG
-55 to +150
°C
Case temperature under bias
TC
-40 to +120
°C
Notes:
1. All specified voltages are with respect to GND.
2. Empirical data indicates that all chip voltages should begin to ramp-up within 1 ms of each other. There should never be voltage present
at the I/O pins before OVDD is within operating range.
Package Thermal Specifications
The PPC405GPr is designed to operate within a case temperature range of -40°C to +85°C3. Thermal resistance values for the
E-PBGA packages (leaded and lead-free) in a convection environment are as follows:
Airflow
ft/min (m/sec)
Symbol
Unit
Package—Thermal Resistance
0 (0)
100 (0.51)
200 (1.02)
35mm, 456-balls—Junction-to-Case
θJC
2
2
2
°C/W
35mm, 456-balls—Case-to-Ambient1
θCA
14
13
12
°C/W
27mm, 456-balls—Junction-to-Case
θJC
2
2
2
°C/W
27mm, 456-balls—Case-to-Ambient1
θCA
18
16
15
°C/W
Notes:
1. For a chip mounted on a JEDEC 2S2P card without a heat sink.
2. For a chip mounted on a card with at least one signal and two power planes, the following relationships exist:
a. Case temperature, TC, is measured at top center of case surface with device soldered to circuit board.
b. TA = TC – P×θ CA, where TA is ambient temperature and P is power consumption.
c. TCMax = TJMax – P×θJC, where TJMax is maximum junction temperature and P is power consumption.
3. 333MHz operated at 266MHz or less can operate at +105°C.
38
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Recommended DC Operating Conditions
Device operation beyond the conditions specified is not recommended. Extended operation beyond the recommended
conditions can affect device reliability.
Notes:
1. PCI drivers meet PCI specifications.
2. See “5V-Tolerant Input Current” on page 40.
3. 333MHz operated at 266MHz or less can operate at +105°C.
Parameter
Symbol
Minimum
Typical
Maximum
Unit
Logic Supply Voltage (266 &333MHz)
VDD
1.7
1.8
1.9
V
Logic Supply Voltage (400MHz)
VDD
1.8
1.85
1.9
V
I/O Supply Voltage
OVDD
3.0
3.3
3.6
V
PLL Supply Voltage
AVDD
1.7
1.8
1.9
V
Input Logic High (1.8V CMOS
receivers)
VIH
0.65VDD
VDD
V
Input Logic High (3.3V LVTTL
receivers)
VIH
2.0
OVDD
V
Input Logic High (5.0V LVTTL
receivers)
VIH
2.0
5.0
V
Input Logic Low (1.8V CMOS receivers)
VIL
0
0.65VDD
V
Input Logic Low (3.3/5.0V LVTTL
receivers)
VIL
0
0.8
V
Output Logic High
VOH
2.4
OVDD
V
Output Logic Low
VOL
0
0.4
V
3.3V I/O Input Current (no pull-up or
pull-down)
IIL1
±10
μA
Input Current (with internal pull-down)
IIL2
±10 (@ 0V)
200 (@ VDD)
μA
5V Tolerant I/O Input Current
IIL4
±10
-325
μA
Input Max Allowable Overshoot (1.8V
CMOS receivers)
VIMAO1.8
VDD + 0.6
V
Input Max Allowable Overshoot (3.3V
LVTTL receivers)
VIMAO3
OVDD + 0.6
V
Input Max Allowable Overshoot (5.0V
LVTTL receivers)
VIMAO5
5.5
V
Input Max Allowable Undershoot
VIMAU
Output Max Allowable Overshoot
VOMAO
Output Max Allowable Undershoot
VOMAU3
-0.6
TC
-40
Case Temperature
AMCC
-0.6
Notes
2
V
OVDD + 0.3
V
V
+85
°C
3
39
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
5V-Tolerant Input Current
50
0
Input Current (μA)
-50
-100
-150
-200
-250
-300
-350
0.0
1.0
2.0
3.0
4.0
5.0
Input Voltage (V)
Input Capacitance
Parameter
Symbol
Maximum
Unit
3.3V LVTTL I/O
CIN1
8.8
pF
5V tolerant LVTTL I/O
CIN2
8
pF
PCI I/O
CIN3
9.3
pF
Rx only pins
CIN4
4.5
pF
40
Notes
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
DC Electrical Characteristics
Parameter
Symbol
Typical
Maximum
Unit
Active Operating Current (VDD)–266MHz
IDD
300
610
mA
Active Operating Current (VDD)–333MHz
IDD
325
690
mA
Active Operating Current (VDD)–400MHz
IDD
355
770
mA
Active Operating Current (OVDD)
IODD
45
200
mA
PLL VDD Input current
IPLL
16
23
mA
Active Operating Power–266 MHz
PDD
0.72
1.92
W
Active Operating Power–333MHz
PDD
0.76
2.07
W
Active Operating Power–400MHz
PDD
0.82
2.23
W
Note:
1. The maximum current and power values listed above are not guaranteed to be the highest obtainable. These values are dependent on
many factors including the type of applications running, clock rates, use of internal functional capabilities, external interface usage, case
temperature, and the power supply voltages. Your specific application can produce significantly different results. VDD (logic) current and
power are primarily dependent on the applications running and the use of internal chip functions (DMA, PCI, Ethernet, and so on). OVDD
(I/O) current and power are primarily dependent on the capacitive loading, frequency, and utilization of the external buses. The following
information provides details about the conditions under which the listed values were obtained:
a. In general, the values were measured using a PPC405GPr Evaluation Board with four PCI devices, an external bus master on the
peripheral bus, and external wrap-back on the Ethernet port. For all CPU clock rates, PLB = 133.3MHz, OPB = PerClk = 66.6MHz,
PCI = SysClk = 33.3MHz.
b. Typical current and power are characterized at VDD = +1.8V, OVDD = +3.3V, and TC = +36 °C while running various applications
under the Linux operating system.
c. Maximum current and power are characterized at VDD = +1.9V, OVDD = +3.6V, and TC = +85 °C while running applications designed
to maximize CPU power consumption. An external PCI master heavily loads the PCI bus with transfers targeting SDRAM while the
internal DMA controller further increases SDRAM bus traffic.
2. AVDD should be derived from VDD using the following circuit:
AVDD
VDD
L1
+
C1
C2
C1 – 3.3 μF SMT tantalum
C3
AGND
GND
AMCC
L1 – 2.2 μH SMT inductor (equivalent to MuRata
LQH3C2R2M34) or SMT chip ferrite bead (equivalent
to MuRata BLM31A700S)
C2 – 0.1 μF SMT monolithic ceramic capacitor with X7R
dielectric or equivalent
C3 – 0.01 μF SMT monolithic ceramic capacitor with X7R
dielectric or equivalent
41
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Test Conditions
Clock timing and switching characteristics are specified in accordance with
operating conditions shown in the table “Recommended DC Operating
Conditions.” For all signals other than PCI signals, AC specifications are
characterized at OVDD = +3V and TC = +85°C with the 50pF test load
shown in the figure at right.
For PCI signals there are two different test load circuits, one for the rising
edge and one the falling edge as shown in the figures at right.
Output
Pin
50pF
All signals other
than PCI
Output
Pin
PCI Rising edge
Output
Pin
10pF
25Ω
25Ω
OVDD
PCI Falling edge
10pF
42
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Clocking Specifications
Symbol
Parameter
Min
Max
Units
266.66/333.33/400
MHz
CPU
PFC
Processor clock frequency
PTC
Processor clock period
3.75/3/2.5
ns
SysClk Input
SCFC
Clock input frequency
25
66.66
MHz
SCTC
Clock period
15
40
ns
SCTCS
Clock edge stability (phase jitter, cycle to cycle)
± 0.15
ns
SCTCH
Clock input high time
40% of nominal period
60% of nominal period
ns
SCTCL
Clock input low time
40% of nominal period
60% of nominal period
ns
133.33
MHz
Note: Input slew rate > 1V/ns between 0.8V and 2.0V
MemClkOut Output
MCOFC
Clock output frequency @ PFC = 266MHz
MCOTC
Clock period @ PFC = 266MHz
7.5
ns
MCOTCS
Clock edge stability (phase jitter, cycle to cycle)
± 0.2
ns
MCOTCH
Clock output high time
45% of nominal period
55% of nominal period
ns
MCOTCL
Clock output low time
45% of nominal period
55% of nominal period
ns
TrcClk Output
TCFC
Clock output frequency
PFC / 2
MHz
TCTC
Clock period
PTC x 2
ns
± 0.2
ns
TCTCS
Clock edge stability (phase jitter, cycle to cycle)
TCTCH
Clock output high time
45% of nominal period
55% of nominal period
ns
TCTCL
Clock output low time
45% of nominal period
55% of nominal period
ns
Other Clocks
VCOFC
VCO frequency
500
1000
MHz
VCOFC
VCO frequency @ PFC = 333MHz or 400MHz
500
1333
MHz
PLBFC
PLB frequency
133.33
MHz
OPBFC
OPB frequency
66.66
MHz
Clocking Waveform
2.0V
1.5V
0.8V
TCH
TCL
TC
AMCC
43
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Spread Spectrum Clocking
Care must be taken when using a spread spectrum clock generator (SSCG) with the PPC405GPr. This controller
uses a PLL for clock generation inside the chip. The accuracy with which the PLL follows the SSCG is referred to
as tracking skew. The PLL bandwidth and phase angle determine how much tracking skew there is between the
SSCG and the PLL for a given frequency deviation and modulation frequency. When using an SSCG with the
PPC405GPr the following conditions must be met:
• The frequency deviation must not violate the minimum clock cycle time. Therefore, when operating the
PPC405GPr with one or more internal clocks at their maximum supported frequency, the SSCG can only lower
the frequency.
• The maximum frequency deviation cannot exceed −3%, and the modulation frequency cannot exceed 40kHz.
In some cases, on-board PPC405GPr peripherals impose more stringent requirements (see Note 1).
• Use the peripheral bus clock (PerClk) for logic that is synchronous to the peripheral bus since this clock tracks
the modulation.
• Use the SDRAM MemClkOut since it also tracks the modulation.
Notes:
1. The serial port baud rates are synchronous to the modulated clock. The serial port has a tolerance of
approximately 1.5% on baud rate before framing errors begin to occur. The 1.5% tolerance assumes that the
connected device is running at precise baud rates. If an external serial clock is used the baud rate is unaffected
by the modulation.
2. Operation of the PPC405GPr PCI Bridge is unaffected by the use of a SSCG.
For PCI frequencies of 33.33 MHz and below the PCI controller supports synchronous mode operation. This is
accomplished by strapping the PPC405GPr for synchronous mode PCI and connecting the PCI bus clock to the
PPC405GPr SysClk input. For 33.33 MHz signalling, the PCI specification has no limitation on the amount of
frequency deviation or modulation that may be applied to the PCI clock. Therefore, the PPC405GPr SSCG
requirements stated above take precedence.
At PCI frequencies above 33.33 MHz, the PCI controller must be operated in asynchronous mode. When in
asynchronous mode, the PCI bus clock must be driven into the PPC405GPr PCIClk input. In this configuration
the PCI controller supports the 66.66 MHz PCI clock specification which specifies a maximum frequency
deviation of -1% at a modulation of between 30 kHz and 33 kHz.
3. Ethernet operation is unaffected.
4. IIC operation is unaffected.
Caution: It is up to the system designer to ensure that any SSCG used with the PPC405GPr meets the above
requirements and does not adversely affect other aspects of the system.
44
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Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Peripheral Interface Clock Timings
Parameter
Min
Max
Units
Note 1
66.66
MHz
PCIClk period (asynchronous mode)
15
Note 1
ns
PCI Clock frequency (synchronous mode)
25
33.33
MHz
PCI Clock period (synchronous mode - Note 2)
30
40
ns
PCIClk input frequency (asynchronous mode)
PCIClk input high time
40% of nominal period
60% of nominal period
ns
PCIClk input low time
40% of nominal period
60% of nominal period
ns
MHz
EMCMDClk output frequency
–
2.5
EMCMDClk period
400
–
ns
EMCMDClk output high time
160
–
ns
EMCMDClk output low time
160
–
ns
PHYTxClk input frequency
2.5
25
MHz
PHYTxClk period
40
400
ns
PHYTxClk input high time
35% of nominal period
–
ns
PHYTxClk input low time
35% of nominal period
–
ns
MHz
PHYRxClk input frequency
2.5
25
PHYRxClk period
40
400
ns
PHYRxClk input high time
35% of nominal period
–
ns
PHYRxClk input low time
35% of nominal period
–
ns
PerClk output frequency
–
66.66
MHz
PerClk period
15
–
ns
PerClk output high time
45% of nominal period
55% of nominal period
ns
PerClk output low time
45% of nominal period
55% of nominal period
ns
± 0.3
ns
–
1000/(2TOPB+2ns)
MHz
UARTSerClk period
2TOPB+2
–
ns
UARTSerClk input high time
TOPB+1
–
ns
UARTSerClk input low time
TOPB+1
–
ns
TmrClk input frequency
–
66.66
MHz
TmrClk period
15
–
ns
PerClk clock edge stability (phase jitter, cycle to cycle)
UARTSerClk input frequency (Note 3)
TmrClk input high time
40% of nominal period
60% of nominal period
ns
TmrClk input low time
40% of nominal period
60% of nominal period
ns
Note:
1. In asynchronous PCI mode the minimum PCIClk frequency is 1/8 the PLB Clock. Refer to the PowerPC 405GPr Embedded Processor
User’s Manual for more information.
2. In synchronous PCI mode the PCI clock is derived from SysClk and the PCIClk input pin is unused.
3. TOPB is the period in ns of the OPB clock. The maximum OPB clock frequency is 66.66MHz.
AMCC
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Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Input Setup and Hold Waveform
Clock
TIS min
TIH min
Inputs
Valid
Output Delay and Float Timing Waveform
Clock
Outputs
TOV max
TOV max
TOV max
TOH min
TOH min
TOH min
High (Drive)
Float (High-Z)
Valid
Valid
Low (Drive)
46
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Notes: 1. In all of the following I/O Specifications tables a timing values of “na” means “not applicable” and “dc”
means “don’t care.”
2. See “Test Conditions” on page 42 for output capacitive loading.
I/O Specifications—Group 1
(Sheet 1 of 3)
Notes:
1. PCI timings are for operation up to 66.66MHz. PCI output hold time requirement is 1ns for 66.66MHz and 2ns for 33.33MHz.
In synchronous mode, timing is relative to SysClk. In asynchronous mode, timing is relative to PCIClk.
2. Ethernet interface meets timing requirements as defined by IEEE 802.3 standard.
3. For PCI, I/O H is specified at 0.9OVDD and I/O L is specified at 0.1OVDD. For all other interfaces, I/O H is specified at 2.4 V
and I/O L is specified at 0.4 V.
Input (ns)
Signal
Output (ns)
Output Current (mA)
Setup Time
(TIS min)
Hold Time
(TIH min)
Valid Delay
(TOV max)
Hold Time
(TOH min)
I/O H
(min)
I/O L
(min)
Clock
Notes
PCIAD31:0
3
0
6
1
0.5
1.5
PCI Clock
1
PCIC3:0[BE3:0]
3
0
6
1
0.5
1.5
PCI Clock
PCIClk
dc
dc
na
na
na
na
PCIDevSel
3
0
6
1
0.5
1.5
PCI Clock
1
PCIFrame
3
0
6
1
0.5
1.5
PCI Clock
1
PCIGnt0[Req]
PCIGnt1:5
na
na
na
na
0.5
1.5
PCI Clock
1
PCI Interface
1
async
PCIIDSel
3
0
6
1
na
na
PCI Clock
1
PCIINT[PerWE]
na
na
dc
dc
0.5
1.5
PCI Clock
async
PCIIRDY
3
0
6
1
0.5
1.5
PCI Clock
1
PCIParity
3
0
6
1
0.5
1.5
PCI Clock
1
PCIPErr
3
0
6
1
0.5
1.5
PCI Clock
1
PCIReq0[Gnt]
PCIReq1:5
5
0
na
na
na
na
PCI Clock
1
PCIReset
na
na
na
na
0.5
1.5
PCI Clock
PCISErr
na
na
na
na
0.5
1.5
PCI Clock
PCIStop
3
0
6
1
0.5
1.5
PCI Clock
1
PCITRDY
3
0
6
1
0.5
1.5
PCI Clock
1
na
na
settable
2
10.3
7.1
0
1 OPB clock
period + 10ns
1 OPB clock
period
10.3
7.1
Ethernet Interface
EMCMDClk
EMCMDIO[PHYMDIO]
100
2, async
EMCMDClk
2
EMCTxD3:0
na
na
20
2
10.3
7.1
PHYTX
2
EMCTxEn
na
na
20
2
10.3
7.1
PHYTX
2
EMCTxErr
na
na
20
2
PHYTX
10.3
7.1
PHYCol
10.3
7.1
PHYCrS
10.3
7.1
2, async
na
na
2, async
PHYRxClk
2
2, async
PHYRxD3:0
4
1
na
na
10.3
7.1
PHYRX
2
PHYRxDV
4
1
na
na
10.3
7.1
PHYRX
2
PHYRxErr
4
1
na
na
10.3
7.1
PHYRX
na
na
PHYTxClk
AMCC
2
2, async
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Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
I/O Specifications—Group 1
(Sheet 2 of 3)
Notes:
1. PCI timings are for operation up to 66.66MHz. PCI output hold time requirement is 1ns for 66.66MHz and 2ns for 33.33MHz.
In synchronous mode, timing is relative to SysClk. In asynchronous mode, timing is relative to PCIClk.
2. Ethernet interface meets timing requirements as defined by IEEE 802.3 standard.
3. For PCI, I/O H is specified at 0.9OVDD and I/O L is specified at 0.1OVDD. For all other interfaces, I/O H is specified at 2.4 V
and I/O L is specified at 0.4 V.
Input (ns)
Signal
Setup Time
(TIS min)
Output (ns)
Hold Time
(TIH min)
Valid Delay
(TOV max)
Output Current (mA)
Hold Time
(TOH min)
I/O H
(min)
I/O L
(min)
Clock
Notes
Internal Peripheral Interface
IICSCL
na
na
na
na
15.3
10.2
IICSDA
na
na
na
na
15.3
10.2
UART0_CTS
na
na
10.3
7.1
UART0_DCD
na
na
10.3
7.1
UART0_DSR
na
na
10.3
7.1
UART0_DTR
UART0_RI
na
na
na
na
na
UART0_RTS
UART0_Rx
na
10.3
7.1
10.3
7.1
10.3
7.1
10.3
7.1
UART0_Tx
na
na
10.3
7.1
UART1_RTS/
UART1_DTR
na
na
10.3
7.1
na
na
UART1_DSR/
UART1_CTS
na
na
UART1_Rx
na
na
na
na
10.3
7.1
na
na
10.3
7.1
TCK
na
na
async
TDI
na
na
async
TDO
10.3
7.1
async
TMS
na
na
async
TRST
na
na
async
10.3
7.1
UART1_Tx
UARTSerClk
na
na
na
na
Interrupts Interface
IRQ0:6[GPIO17:23]
JTAG Interface
System Interface
GPIO1
GPIO2
GPIO3
GPIO4
GPIO5
GPIO6
GPIO7
GPIO8
GPIO9
GPIO24
Halt
na
na
na
na
SysClk
dc
dc
na
na
na
na
async
SysErr
na
na
10.3
7.1
SysReset
10
1
10.3
7.1
async
async
TestEn
dc
dc
na
na
na
na
async
TmrClk
dc
dc
na
na
na
na
async
48
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
I/O Specifications—Group 1
(Sheet 3 of 3)
Notes:
1. PCI timings are for operation up to 66.66MHz. PCI output hold time requirement is 1ns for 66.66MHz and 2ns for 33.33MHz.
In synchronous mode, timing is relative to SysClk. In asynchronous mode, timing is relative to PCIClk.
2. Ethernet interface meets timing requirements as defined by IEEE 802.3 standard.
3. For PCI, I/O H is specified at 0.9OVDD and I/O L is specified at 0.1OVDD. For all other interfaces, I/O H is specified at 2.4 V
and I/O L is specified at 0.4 V.
Input (ns)
Signal
Output (ns)
Output Current (mA)
Setup Time
(TIS min)
Hold Time
(TIH min)
Valid Delay
(TOV max)
Hold Time
(TOH min)
I/O H
(min)
I/O L
(min)
Clock
Notes
na
na
PTC/2+0.7
PTC/2-0.5
10.3
7.1
TrcClk
10pF load
on
clk/data
Trace
[TS1E]
[TS2E]
[TS1O]
[TS2O]
[TS3]
[TS4]
[TS5]
[TS6]
AMCC
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Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
I/O Specifications—Group 2
Notes:
1. The SDRAM command interface is configurable through SDRAM0_TR[LDF] to provide a 2 to 4 cycle delay before the
command is used by SDRAM.
2. SDRAM I/O timings are specified relative to a MemClkOut terminated into a lumped 10pF load.
3. SDRAM interface hold times are guaranteed at the PPC405GPr package pin. System designers must use the PPC405GPr
IBIS model (available from www.amcc.com) to ensure their clock distribution topology minimizes loading and reflections,
and that the relative delays on clock wiring do not exceed the delays on other SDRAM signal wiring.
4. PerClk timing is specified with a 10pF load at the package pin. The indicated timing is valid only if PerClk feedback is
selected. Refer to the PowerPC 405GPr Embedded Processor User’s Manual for more information.
5. Input timings are specified at 1.5V, assuming transition times between 1 and 2ns, when measured between the 10% and
90% points of the output voltage.
6. I/O H is specified at 2.4 V and I/O L is specified at 0.4 V.
Input (ns)
Signal
Output (ns)
Output Current (mA)
Setup Time
(TIS min)
Hold Time
(TIH min)
Valid Delay
(TOV max)
Hold Time
(TOH min)
I/O H
(minimum)
I/O L
(minimum)
Clock
Notes
BA1:0
na
na
4.5
1.6
15.3
10.2
MemClkOut
1, 2, 5
BankSel3:0
na
na
4.5
1.5
15.3
10.2
MemClkOut
2, 5
CAS
na
na
4.4
1.5
15.3
10.2
MemClkOut
1, 2, 5
SDRAM Interface
ClkEn0:1
na
na
3.9
1.4
23
19.3
MemClkOut
2, 5
DQM0:3
na
na
4.5
1.4
15.3
10.2
MemClkOut
2, 5
DQMCB
na
na
4.3
1.4
15.3
10.2
MemClkOut
2, 5
ECC0:7
1.4
0
4.5
1.5
15.3
10.2
MemClkOut
2, 5
MemAddr12:0
na
na
4.6
1.5
15.3
10.2
MemClkOut
1, 2, 5
MemData0:31
1.4
0
5.1
1.4
15.3
10.2
MemClkOut
2, 5
RAS
na
na
4.4
1.5
15.3
10.2
MemClkOut
1, 2, 5
WE
na
na
4.4
1.5
15.3
10.2
MemClkOut
1, 2, 5
External Slave Peripheral Interface
DMAAck0:3
na
na
6.1
2.2
10.3
7.1
PerClk
5
DMAReq0:3
3.2
0
na
na
na
na
PerClk
5
EOT0:3/TC0:3
dc
dc
6.4
2
10.3
7.1
PerClk
5
PerAddr0:31
2.2
0
7.1
2
15.3
10.2
PerClk
5
PerBLast
3.3
0
6.5
2.3
10.3
7.1
PerClk
5
PerCS0
PerCS1:7[GPIO10:16]
na
na
6.5
2.1
10.3
7.1
PerClk
5
PerData0:31
4.7
0.9
7.2
1.9
15.3
10.2
PerClk
5
PerOE
na
na
6.5
2.1
10.3
7.1
PerClk
5
PerPar0:3
2.3
0
7.2
2.1
15.3
10.2
PerClk
5
PerR/W
3.3
0
6.6
2.1
10.3
7.1
PerClk
5
PerReady
5.5
0
na
na
na
na
PerClk
5
PerWBE0:3
2.3
0
6.1
2.2
10.3
7.1
PerClk
5
5
External Master Peripheral Interface
BusReq
na
na
6.1
2.2
10.3
7.1
PerClk
ExtAck
na
na
5.9
2.1
10.3
7.1
PerClk
5
ExtReq
4.1
0
na
na
na
na
PerClk
5
ExtReset
na
na
6
1
15.3
10.2
PerClk
5
HoldAck
na
na
6.1
2
10.3
7.1
PerClk
5
5
HoldPri
2.1
0
na
na
na
na
PerClk
HoldReq
3.1
0
na
na
na
na
PerClk
5
PerClk
na
na
0.7
-0.5
15.3
10.2
SysClk
4, 5
PerErr
2.4
0
na
na
na
na
PerClk
5
50
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Strapping
When the SysReset input is driven low by an external device (system reset), the state of certain I/O pins is read to
enable default initial conditions prior to PPC405GPr start-up. The actual capture instant is the nearest SysClk edge
before the deassertion of reset. These pins must be strapped using external pull-up (logical 1) or pull-down
(logical 0) resistors to select the desired default conditions. The recommended pull-up is 3kΩ to +3.3V or 10kΩ to
+5V. The recommended pull-down is 1KΩ to GND. These pins are use for strap functions only during reset. They
are used for other signals during normal operation. The following tables list the strapping pins along with their
functions and strapping options. The signal names assigned to the pins for normal operation follow the pin
number.
The PPC405GPr can be used as a replacement for the PPC405GP. When the PPC405GPr is used for this
purpose, it should be strapped to operate in the PPC405GPr Legacy Mode. This option is selected by strapping
ball D20 (GPIO24) low (0). If Legacy Mode is selected, the “PPC405GPr Legacy Mode Strapping Pin Assignments”
table should be used to determine the strapping options. To operate the chip as a PPC405GPr, strap D20
(GPIO24) high (1) and use “PPC405GPr New Mode Strapping Pin Assignments” on page 53 to determine the
strapping options.
PPC405GPr Legacy Mode Strapping Pin Assignments
Function
PLL Tuning
(Sheet 1 of 2)
Option
1
for 6 ≤ M ≤ 7 use choice 3
Ball Strapping
AF3
UART0_Tx
AF2
UART0_DTR
AD16
UART0_RTS
for 7 < M ≤ 12 use choice 5
Choice 1; TUNE[9:0] = 1010111100
0
0
0
for 12 < M ≤ 32 use choice 6
Choice 2; TUNE[9:0] = 0100111000
0
0
1
Choice 3; TUNE[9:0] = 0100110110
0
1
0
Choice 4; TUNE[9:0] = 0100111100
0
1
1
Choice 5; TUNE[9:0] = 0100111000
1
0
0
Choice 6; TUNE[9:0] = 1000111100
1
0
1
Choice 7; TUNE[9:0] = 1000111110
1
1
0
1
1
1
D16
DMAAck0
B15
DMAAck1
Choice 8; TUNE[9:0] = 1011111110
PLL Forward Divider
2
PLL Feedback Divider
PLB Divider from CPU
AMCC
Bypass mode
0
0
Divide by 3
0
1
Divide by 4
1
0
Divide by 6
1
1
B14
DMAAck2
C12
DMAAck3
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
Divide by 4
1
1
P25
EMCTxD3
L24
EMCTxD2
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
Divide by 4
1
1
2
2
51
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
PPC405GPr Legacy Mode Strapping Pin Assignments
Function
Ball Strapping
L25
EMCTxD1
J26
EMCTxD0
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
OPB Divider from PLB 2
Divide by 4
1
1
D18
GPIO1[TS1E]
C20
GPIO2[TS2E]
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
PCI Divider from PLB 2, 3
Divide by 4
External Bus Divider from PLB
(Sheet 2 of 2)
Option
1
1
K25
EMCTxErr
K23
EMCTxEn
Divide by 2
0
0
Divide by 3
0
1
Divide by 4
1
0
Divide by 5
1
1
AC2
UART1_Tx
AD2
UART1_RTS/
UART1_DTR
2
ROM Width
8-bit ROM
0
0
16-bit ROM
0
1
32-bit ROM
1
0
Reserved
1
1
ROM Location
U2
HoldAck
PPC405GPr Peripheral Attach
PPC405GPr PCI Attach
PCI Asynchronous Mode Enable
0
1
Y3
ExtAck
Synchronous PCI Mode
0
Asynchronous Mode
1
AF18
GPIO4[TS2O]
PCI Arbiter Enable 3
Internal Arbiter Disabled
0
Internal Arbiter Enabled
1
Note:
1. The tune bits adjust parameters that control PLL jitter. The recommended values minimize jitter for the PLL implemented in the
PPC405GPr. These bits are shown for information only; and do not require modification except in special clocking circumstances such as
spread spectrum clocking. For details on the use of Spread Spectrum Clock Generators (SSCGs) with the PPC405GPr, visit the technical
documents area of the AMCC PowerPC web site.
2. Not all combinations of dividers produce valid operating configurations. Frequencies must be within the limits specified in “Clocking
Specifications” on page 43. Further requirements are detailed in the Clocking chapter of the PowerPC 405GPr Embedded Processor
User’s Manual.
3. Additional consideration must be given to pins that normally function as Trace signals. Improved design margin can be gained by using
three-state buffers instead of strapping resistors, and minimizing trace lengths and stubs.
52
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
PPC405GPr New Mode Strapping Pin Assignments
Function
PLL Tuning
See the PowerPC 405GPr
Embedded Processor User’s
Manual for details.
AF2
UART0_DTR
AD16
UART0_RTS
Choice 1; TUNE[9:0] = 1010111100
0
0
0
Choice 2; TUNE[9:0] = 0100111000
0
0
1
Choice 3; TUNE[9:0] = 0100110110
0
1
0
Choice 4; TUNE[9:0] = 0100111100
0
1
1
Choice 5; TUNE[9:0] = 0100111000
1
0
0
Choice 6; TUNE[9:0] = 1000111100
1
0
1
Choice 7; TUNE[9:0] = 1000111110
1
1
0
Choice 8; TUNE[9:0] = 1011111110
AMCC
Ball Strapping
AF3
UART0_Tx
1
1
1
D16
DMAAck0
B15
DMAAck1
AC9
GPIO5[TS3]
Divide by 8
0
0
0
Divide by 7
0
0
1
Divide by 6
0
1
0
Divide by 5
0
1
1
Divide by 4
1
0
0
Divide by 3
1
0
1
Divide by 2
1
1
0
Divide by 1
1
1
1
P25
EMCTxD3
L24
EMCTxD2
AE8
GPIO6[TS4]
Divide by 8
0
0
0
Divide by 7
0
0
1
Divide by 6
0
1
0
Divide by 5
0
1
1
Divide by 4
1
0
0
Divide by 3
1
0
1
Divide by 2
1
1
0
Divide by 1
1
1
1
PLL Forward Divider A 2
PLL Forward Divider B
(Sheet 1 of 3)
Option
2
53
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
PPC405GPr New Mode Strapping Pin Assignments
Function
OPB Divider from PLB
C12
DMAAck3
AF5
GPIO7[TS5]
AC7
GPIO8[TS6]
Divide by 16
0
0
0
0
Divide by 1
0
0
0
1
Divide by 2
0
0
1
0
Divide by 3
0
0
1
1
Divide by 4
0
1
0
0
Divide by 5
0
1
0
1
Divide by 6
0
1
1
0
Divide by 7
0
1
1
1
Divide by 8
1
0
0
0
Divide by 9
1
0
0
1
Divide by 10
1
0
1
0
Divide by 11
1
0
1
1
Divide by 12
1
1
0
0
Divide by 13
1
1
0
1
Divide by 14
1
1
1
0
Divide by 15
1
1
1
1
L25
EMCTxD1
J26
EMCTxD0
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
Divide by 4
1
1
D18
GPIO1[TS1E]
C20
GPIO2[TS2E]
Divide by 1
0
0
Divide by 2
0
1
Divide by 3
1
0
Divide by 4
1
1
K25
EMCTxErr
K23
EMCTxEn
Divide by 2
0
0
Divide by 3
0
1
Divide by 4
1
0
Divide by 5
1
1
AC2
UART1_Tx
AD2
UART1_RTS/
UART1_DTR
2
2, 3
External Bus Divider from
PLB 2
ROM Width
8-bit ROM
0
0
16-bit ROM
0
1
32-bit ROM
1
0
1
1
Reserved
ROM Location
54
Ball Strapping
B14
DMAAck2
PLL Feedback Divider 2, 3
PCI Divider from PLB
(Sheet 2 of 3)
Option
U2
HoldAck
PPC405GPr Peripheral Attach
0
PPC405GPr PCI Attach
1
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
PPC405GPr New Mode Strapping Pin Assignments
Function
Ball Strapping
PCI Asynchronous Mode
Enable
Y3
ExtAck
Synchronous PCI Mode
Asynchronous Mode
External Bus Synchronous
Mode Enable 3
0
1
A22
GPIO3[TS1O]
Asynchronous Mode
0
Synchronous Mode
1
AF18
GPIO4[TS2O]
PCI Arbiter Enable 3
Internal Arbiter Disabled
Internal Arbiter Enabled
New Mode Enable
In Legacy mode the
PPC405GPr functions like the
PPC405GP.
If not strapped, the PPC405GPr
defaults to Legacy mode.
Flip Circuit Disable
(must be strapped low (0)
during initilization).
(Sheet 3 of 3)
Option
0
1
D20
GPIO24
Legacy (PPC405GP) mode
0
mode4
1
New (PPC405GPr)
AB3
GPIO9[TrcClk]
Normal operation
0
Note:
1. The tune bits adjust parameters that control PLL jitter. The recommended values minimize jitter for the PLL implemented in the
PPC405GPr. These bits are shown for information only; and do not require modification except in special clocking circumstances such as
spread spectrum clocking. For details on the use of Spread Spectrum Clock Generators (SSCGs) with the PPC405GPr, visit the technical
documents area of the AMCC PowerPC web site.
2. Not all combinations of dividers produce valid operating configurations. Frequencies must be within the limits specified in “Clocking
Specifications” on page 43. Further requirements are detailed in the Clocking chapter of the PowerPC 405GPr Embedded Processor
User’s Manual.
3. Additional consideration must be given to pins that normally function as Trace signals. Improved design margin can be gained by using
three-state buffers instead of strapping resistors, and minimizing trace lengths and stubs.
4. The pull-up initialization strapping resistor must be 1kΩ rather than 3kΩ in order to overcome the internal pull-down resistor.
Revision Log
Date
AMCC
Contents of Modification
03/13/2003
400MHz part numbers and new power/current numbers
08/28/2003
Add new VDD values for 400MHz parts.
11/22/2004
Correct package drawings and add lead-free part numbers.
Add +105°C temperature specification.
Add 1 ms. voltage ramp-up restriction.
12/02/2004
Update to AMCC format.
01/06/2005
Correct typographical error in 27mm package drawing.
08/29/2005
Add dashes back into PNs.
03/13/2007
Revise package drawings to add logo view.
Update AMCC address and copyright date on last page.
09/07/2007
Change TestEn signal from active low to active high.
Correct AMCC telephone numbers.
55
405GPr – Power PC 405GPr Embedded Processor
Revision 2.04 – September 7, 2007
Data Sheet
Printed in the United States of America, Friday, September 07, 2007
The following are trademarks of AMCC in the United States, or other countries, or both:
AMCC
Other company, product, and service names may be trademarks or service marks of others.
The information contained in this document is subject to change or withdrawal at any time without notice
and is being provided on an "AS IS" basis without warranty or indemnity of any kind, whether express or
implied, including without limitation, the implied warranties of non-infringement, merchantability, or fitness
for a particular purpose. Any products, services, or programs discussed in this document are sold or
licensed under AMCC's standard terms and conditions, copies of which may be obtained from your local
AMCC representative. Nothing in this document shall operate as an express or implied license or indemnity
under the intellectual property rights of AMCC or third parties.
Without limiting the generality of the foregoing, any performance data contained in this document was
determined in a specific or controlled environment and not submitted to any formal AMCC test. Therefore,
the results obtained in other operating environments may vary significantly. Under no circumstances will
AMCC be liable for any damages whatsoever arising out of or resulting from any use of the document or the
information contained herein.
56
AMCC
Revision 2.04 – September 7, 2007
405GPr – Power PC 405GPr Embedded Processor
Data Sheet
Applied Micro Circuits Corporation
215 Moffett Park Drive, Sunnyvale, CA 94089
Phone: (408) 542-8600 — (800) 840-6055 — Fax: (408) 542-8601
http://www.amcc.com
AMCC reserves the right to make changes to its products, its datasheets, or related documentation, without notice and warrants its products solely pursuant to its terms and conditions of sale, only to substantially comply with the latest available
datasheet. Please consult AMCC’s Term and Conditions of Sale for its warranties and other terms, conditions and limitations.
AMCC may discontinue any semiconductor product or service without notice, and advises its customers to obtain the latest
version of relevant information to verify, before placing orders, that the information is current. AMCC does not assume any liability arising out of the application or use of any product or circuit described herein, neither does it convey any license under
its patent rights nor the rights of others. AMCC reserves the right to ship devices of higher grade in place of those of lower
grade.
AMCC SEMICONDUCTOR PRODUCTS ARE NOT DESIGNED, INTENDED, AUTHORIZED, OR WARRANTED TO BE
SUITABLE FOR USE IN LIFE-SUPPORT APPLICATIONS, DEVICES OR SYSTEMS OR OTHER CRITICAL
APPLICATIONS.
AMCC is a registered Trademark of Applied Micro Circuits Corporation. Copyright © 2007 Applied Micro Circuits Corporation.
AMCC
57