3/19/03
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
1
Features
IBM PowerPC405 32-bit RISC processor core
operating up to 266MHz with 16KB D- and I-
caches
PC-133 synchronous DRAM (SDRAM) interface
- 32-bit interface for non-ECC applications
4KB on-chip memory (OCM)
External peripheral bus
- Flash ROM/Boot ROM interface
- Direct support for 8- or 16-bit SRAM and
external peripherals
- Up to five devices
DMA support for memory and UARTs.
- Scatter-gather chaining supported
- Four channels
PCI Revision 2.2 compliant interface (32-bit, up
to 66MHz)
- Asynchronous PCI Bus interface
- Internal or external PCI Bus Arbiter
Two Ethernet 10/100Mbps (full-duplex) ports
with media independent interface (MII)
Programmable interrupt controller supports
seven external and 19 internal edge triggered or
level-sensitive interrupts
Programmable timers
Software accessible event counters
Two serial ports (16750 compatible UART)
One IIC interface
General purpose I/O (GPIO) available
Supports JTAG for board level testing
Internal processor local Bus (PLB) runs at
SDRAM interface frequency
Supports PowerPC processor boot from PCI
memory
Description
Designed specifically to address embedded
applications, the PowerPC 405EP (PPC405EP)
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 ports, IIC interface, and general
purpose I/O.
Technology: IBM CMOS SA-27E, 0.18 µm
(0.11 µm Leff)
Package: 31mm, 385-ball, enhanced plastic ball
grid array (E-PBGA)
Power (typical): 1.2W at 200MHz
While the information contained herein is believed to be accurate, such information is preliminary, and should not be
relied upon for accuracy or completeness, and no representations or warranties of accuracy or completeness are made.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
23/19/03
Contents
Ordering, PVR, and JTAG Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Address Map Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
On-Chip Memory (OCM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
PLB to PCI Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
SDRAM Memory Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
External Peripheral Bus Controller (EBC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Serial Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
IIC Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
General Purpose IO (GPIO) Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Universal Interrupt Controller (UIC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
10/100 Mbps Ethernet MAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
JTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Signal List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Spread Spectrum Clocking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
Tables
System Memory Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
DCR Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Signals Listed Alphabetically . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Signals Listed by Ball Assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Pin Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Signal Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Package Thermal Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Recommended DC Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Input Capacitance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Clocking Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Peripheral Interface Clock Timings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
I/O Specifications—Group 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
I/O Specifications—Group 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
Strapping Pin Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 3
Figures
PPC405EP Embedded Controller Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
31mm, 385-Ball E-PBGA Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5V-Tolerant Input Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Input Setup and Hold Timing Waveform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
Output Delay and Float Timing Waveform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
43/19/03
Ordering, PVR, and JTAG Information
This section provides the part number nomenclature. For availability, contact your local IBM sales office.
The part number contains a part modifier. Included in the modifier is a revision code. This refers to the die
mask revision number and is specified in the part numbering scheme for identification purposes only.
The PVR (Processor Version Register) and the JTAG ID register are software accessible (read-only) and
contain information that uniquely identifies the part. Refer to the PowerPC 405EP Embedded Processor
User’s Manual for details on accessing these registers.
Order Part Number Key
Product Name Order Part Number1Processor
Frequency Package Rev
Level PVR Value JTAG ID
PPC405EP IBM25PPC405EP-3GB133C 133MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
PPC405EP IBM25PPC405EP-3GB133CZ 133MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
PPC405EP IBM25PPC405EP-3GB200C 200MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
PPC405EP IBM25PPC405EP-3GB200CZ 200MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
PPC405EP IBM25PPC405EP-3GB266C 266MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
PPC405EP IBM25PPC405EP-3GB266CZ 266MHz 31mm, 385 E-PBGA B 0x51210950 0x20267049
Note 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.
IBM Part Number
IBM25PPC405EP-3GB266Cx
Package
Processor Speed
Grade 3 Reliability
Operational Case Temperature
Shipping Package
Blank = Tray
Z = Tape and reel
(-40°C to +85°C)
Range
266 = 266MHz
31mm, 385 E-PBGA
200 = 200MHz
Revision Level
133 = 133MHz
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 5
PPC405EP Embedded Controller Functional Block Diagram
The PPC405EP 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.
PPC405
Processor Core
DOCM
IOCM
DCU ICU
OCM
Control
OCM
SRAM
DCR Bus
16KB On-chip Peripheral Bus (OPB)
GPIO IIC GPT UART
MAL Ethernet
DMA
Bridge
Processor Local Bus (PLB)
SDRAM PCI Bridge
External
Bus
Controller
Controller
Clock
Control
Reset
Power
Mgmt
JTAG Trace
Timers
MMU
MII
Controller OPB
Interrupt
Controller
Arb
29-bit addr
16-bit data
13-bit addr
32-bit data
Universal
I-Cache
D-Cache
(4-Channel)
66 MHz max (async)
DCRs
16KB
Arb
x2
x2
Event
Counters
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
63/19/03
Address Map Support
The PPC405EP incorporates two address maps. The first address map defines the possible use of
addressable memory regions that the processor can access. The second address map defines Device
Configuration Register (DCR) addresses (numbers). The DCRs are accessed by software running on the
PPC405EP processor through the use of mtdcr and mfdcr instructions.
System Memory Address Map 4GB System Memory
Function Subfunction Start Address End Address Size
General Use
SDRAM, External Peripherals, and PCI
Memory
Note: Any of the address ranges listed at
right may be use for any of the above
functions.
0x00000000 0xE7FFFFFF 3712MB
0xE8010000 0xE87FFFFF 8MB
0xEC000000 0xEEBFFFFF 44MB
0xEEE00000 0xEF3FFFFF 6MB
0xEF500000 0xEF5FFFFF 1MB
0xEF900000 0xFFFFFFFF 263MB
Boot-up Peripheral Bus Boot 10xFFE00000 0xFFFFFFFF 2MB
PCI Boot 20xFFFE0000 0xFFFFFFFF 128KB
PCI
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
Internal Peripherals
UART0 0xEF600300 0xEF600307 8B
UART1 0xEF600400 0xEF600407 8B
IIC0 0xEF600500 0xEF60051F 32B
OPB Arbiter 0xEF600600 0xEF60063F 64B
GPIO Controller Registers 0xEF600700 0xEF60077F 128B
Ethernet 0 Controller Registers 0xEF600800 0xEF6008FF 256B
Ethernet 1 Controller Registers 0xEF600900 0xEF6009FF 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.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 7
DCR Address Map 4KB Device Configuration Registers
Function Start Address End Address Size
Total DCR Address Space10x000 0x3FF 1KW (4KB)1
By function:
Reserved 0x000 0x00F 16W
Memory Controller Registers 0x010 0x011 2W
External Bus Controller Registers 0x012 0x013 2W
Reserved 0x014 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
Reserved 0x0A8 0x0AF 6W
Clock, Control, 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
Event Counters 0x200 0x203 4W
Reserved 0x204 0x3FF 508W
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).
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
83/19/03
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
- 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
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 9
- PCI special cycle
Supports PCI target access to all PLB address spaces
Supports PowerPC processor boot from PCI memory
SDRAM Memory Controller
The PPC405EP 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 two 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 banks)
32-bit memory interface support
Programmable address compare for each bank of memory
Industry standard 168-pin DIMMS are supported (some configurations)
Up to 133MHz memory with PC-133 support
- 266MHz and 133MHz processors support 133MHz memory
- 200MHz processors support 100 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)
External Peripheral Bus Controller (EBC)
Supports five banks of ROM, EPROM, SRAM, Flash memory, or slave peripherals
Up to 66MHz operation
Burst and non-burst devices
8- and 16-bit byte-addressable data bus width support
Latch data on Ready, synchronous or asynchronous
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
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
10 3/19/03
- 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
DMA Controller
Supports memory-to-memory transfers
Four channels
Scatter/gather capability for programming multiple DMA operations
32-bit addressing
Address increment or decrement
Internal 32-byte data buffering capability
Serial Interface
One 8-pin UART and one 2-pin (Tx and Rx only) UART interface provided
Internal serial clock to allows a wide range of baud rates
Register compatibility with NS16750 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 Phillips® 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
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 11
Two independent 4 x 1 byte data buffers
Twelve 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
All 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.
Each GPIO output is separately programmable to emulate an open-drain driver (i.e., drives to zero, three-
stated if output bit is 1)
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 seven external and 19 internal interrupts
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
Two ports 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)
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
12 3/19/03
31mm, 385-Ball E-PBGA Package
A
s
1.27 TYP
0.65 ± 0.05 SOLDERBALL x 385
31.0±0.2
27.98
31.0
B
A
C
0.20
0.30
0.15 sCAB
ss
15.5 TYP
Gold Gate Release
Corresponds to
0.20
C
C
2.49 REF
0.6±0.1
PCB
Substrate
Mold
Compound
BC
DE
FG
HJ
KL
M
AA
N
PR
TU
VW
Y
AB AC
Thermal Balls
A1 Ball Location
1357911131517
19
246810
12 14 16 18 21 23
20 22
Top View
Bottom View
0.25
0.35 C
C
Note:
All dimensions are in mm.
2.65 max
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 13
Pin Lists
The PPC405EP embedded controller is available in a 31 millimeter, 385-ball E-PBGA package.
The following table lists all the external signals in alphabetical order and shows the ball (pin) 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 33 where the signals in the indicated interface group begin.
Signals Listed Alphabetically (Part 1 of 12)
Signal Name Ball Interface Group Page
AGND AB21 System 37
AVDD AC20
BA0 Y15 SDRAM 35
BA1 AC16
BankSel0 AB13 SDRAM 35
BankSel1 AC13
CAS Y14 SDRAM 35
ClkEn0 AB14 SDRAM 35
ClkEn1 AC14
DQM0 AC10
SDRAM 35
DQM1 AA7
DQM2 W04
DQM3 U02
EMCMDClk Y06 Ethernet 34
EMCMDIO AA5 Ethernet 34
EMC0Tx0D0 U03
Ethernet 34
EMC0Tx0D1 N03
EMC0Tx0D2 L01
EMC0Tx0D3 P03
EMC0Tx0En W01 Ethernet 34
EMC0Tx0Err V03 Ethernet 34
EMC0Tx1D0 B15
Ethernet 34
EMC0Tx1D1 C14
EMC0Tx1D2 A15
EMC0Tx1D3 D14
EMC0Tx1En A16 Ethernet 34
EMC0Tx1Err C15 Ethernet 34
ExtReset A03 External Slave Peripheral 35
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
14 3/19/03
GND A01
Ground
Note: K10-K14, L10-L14, M10-M14, N10-N14, and P10-P14 are also thermal
balls.
38
GND A02
GND A07
GND A12
GND A17
GND A22
GND A23
GND B01
GND B02
GND B22
GND B23
GND C03
GND C21
GND D04
GND D20
GND E05
GND E09
GND E12
GND E15
GND E19
GND G01
GND G23
GND J05
GND J19
GND K10-K14
GND L10-L14
Signals Listed Alphabetically (Part 2 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 15
GND M01
Power
Note: K10-K14, L10-L14, M10-M14, N10-N14, and P10-P14 are also thermal
balls.
38
GND M05
GND M10-M14
GND M19
GND M20
GND M23
GND N10-N14
GND P10-P14
GND R05
GND R19
GND U01
GND U23
GND W05
GND W09
GND W12
GND W15
GND W19
GND Y04
GND Y20
GND AA03
GND AA21
GND AB01
GND AB02
GND AB22
GND AB23
GND AC01
GND AC02
GND AC07
GND AC12
GND AC17
GND AC22
GND AC23
Signals Listed Alphabetically (Part 3 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
16 3/19/03
GPIO00[PerBLast]A09
System 37
GPIO01[TS1E] AA23
GPIO02[TS2E] Y22
GPIO03[TS1O] Y23
GPIO04[TS2O] W21
GPIO05[TS3] U20
GPIO06[TS4] V23
GPIO07[TS5] U21
GPIO08[TS6] U22
GPIO09[TrcClk] T21
GPIO10[PerCS1]C02
GPIO11[PerCS2]E03
GPIO12[PerCS3]D03
GPIO13[PerCS4]D05
GPIO14[PerAddr03] B04
GPIO15[PerAddr04] A04
GPIO16[PerAddr05] A05
GPIO17[IRQ0] W22
GPIO18[IRQ1] W23
GPIO19[IRQ2] V21
GPIO20[IRQ3] V22
GPIO21[IRQ4] T22
GPIO22[IRQ5] R20
GPIO23[IRQ6] T23
GPIO24[UART0_DCD]M04
GPIO25[UART0_DSR]K01
GPIO26[UART0_RI] L04
GPIO27[UART0_DTR]J01
GPIO28[UART1_Rx] J02
GPIO29[UART1_Tx] J03
GPIO30[RejectPkt0] W20
GPIO31[RejectPkt1] Y21
Halt C22 System 37
IICSCL AB4 Internal Peripheral 36
IICSDA Y01
[IRQ0]GPIO17 W22
Interrupts 36
[IRQ1]GPIO18 W23
[IRQ2]GPIO19 V21
[IRQ3]GPIO20 V22
[IRQ4]GPIO21 T22
[IRQ5]GPIO22 R20
[IRQ6]GPIO23 T23
Signals Listed Alphabetically (Part 4 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 17
MemAddr00 AB15
SDRAM
Note: During a CAS cycle MemAddr00 is the least significant bit (lsb) on this bus. 35
MemAddr01 AB16
MemAddr02 AB17
MemAddr03 AA17
MemAddr04 AC18
MemAddr05 AA18
MemAddr06 AC19
MemAddr07 AB19
MemAddr08 Y18
MemAddr09 AA19
MemAddr10 Y19
MemAddr11 AA20
MemAddr12 AC21
MemClkOut0 AA14 SDRAM 35
MemClkOut1 Y13
Signals Listed Alphabetically (Part 5 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
18 3/19/03
MemData00 AB12
SDRAM
Note: MemData00 is the most significant bit (msb) on this bus. 35
MemData01 AA12
MemData02 AC11
MemData03 AA11
MemData04 Y11
MemData05 AA10
MemData06 AC9
MemData07 AB9
MemData08 AC8
MemData09 Y09
MemData10 AA8
MemData11 AB7
MemData12 AB6
MemData13 Y07
MemData14 AA6
MemData15 AC5
MemData16 AB5
MemData17 AC4
MemData18 Y05
MemData19 AA4
MemData20 AB3
MemData21 Y03
MemData22 W03
MemData23 V04
MemData24 W02
MemData25 U04
MemData26 V02
MemData27 T04
MemData28 T02
MemData29 R04
MemData30 R03
MemData31 R02
OVDD B11
Power 38
OVDD B09
OVDD B19
OVDD C17
OVDD D13
OVDD E06
OVDD E07
OVDD E08
Signals Listed Alphabetically (Part 6 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 19
OVDD E16
Power 38
OVDD E17
OVDD E18
OVDD E21
OVDD F05
OVDD F19
OVDD F23
OVDD G05
OVDD G19
OVDD H05
OVDD H19
OVDD H22
OVDD K04
OVDD K20
OVDD K23
OVDD M22
OVDD N01
OVDD P20
OVDD P23
OVDD T05
OVDD T19
OVDD T20
OVDD U05
OVDD U19
OVDD V01
OVDD V05
OVDD V19
OVDD W06
OVDD W07
OVDD W08
OVDD W16
OVDD W17
OVDD W18
OVDD Y12
OVDD AC06
Signals Listed Alphabetically (Part 7 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
20 3/19/03
PCIAD00 B16
PCI
Note: PCIAD31 is the most significant bit (msb) on this bus. 33
PCIAD01 C16
PCIAD02 B17
PCIAD03 D16
PCIAD04 B18
PCIAD05 D17
PCIAD06 C18
PCIAD07 A19
PCIAD08 D18
PCIAD09 C19
PCIAD10 A20
PCIAD11 B20
PCIAD12 C20
PCIAD13 C23
PCIAD14 D21
PCIAD15 D22
PCIAD16 J22
PCIAD17 J23
PCIAD18 K21
PCIAD19 K22
PCIAD20 L21
PCIAD21 L22
PCIAD22 L23
PCIAD23 M21
PCIAD24 N23
PCIAD25 N22
PCIAD26 N21
PCIAD27 P22
PCIAD28 P21
PCIAD29 R23
PCIAD30 R22
PCIAD31 R21
PCIC0/BE0 A18
PCI 33
PCIC1/BE1 D19
PCIC2/BE2 L20
PCIC3/BE3 N20
PCIClk B21 PCI 33
PCIDevSel H21 PCI 33
PCIFrame F22 PCI 33
PCIGnt0/Req D23 PCI 33
PCIGnt1 E23 PCI 33
PCIGnt2 F21
PCIIDSel A21 PCI 33
Signals Listed Alphabetically (Part 8 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 21
PCIINT[PerWE]D15PCI 33
PCIIRDY H20 PCI 33
PCIParity J21 PCI 33
PCIPErr H23 PCI 33
PCIReq0/Gnt E20
PCI 33PCIReq1 F20
PCIReq2 E22
PCIReset G20 PCI 33
PCISErr J20 PCI 33
PCIStop G22 PCI 33
PCITRDY G21 PCI 33
[PerAddr03]GPIO14 B04
External Slave Peripheral
Note: PerAddr3 is the most significant bit (msb) on this bus. 35
[PerAddr04]GPIO15 A04
[PerAddr05]GPIO16 A05
PerAddr06 D07
PerAddr07 B06
PerAddr08 A06
PerAddr09 D08
PerAddr10 C07
PerAddr11 B07
PerAddr12 C08
PerAddr13 B08
PerAddr14 D09
PerAddr15 A08
PerAddr16 C09
PerAddr17 D10
PerAddr18 C10
PerAddr19 B10
PerAddr20 D11
PerAddr21 A10
PerAddr22 C11
PerAddr23 A11
PerAddr24 D12
PerAddr25 B12
PerAddr26 C12
PerAddr27 A13
PerAddr28 B13
PerAddr29 C13
PerAddr30 A14
PerAddr31 B14
[PerBLast]GPIO00 A09 External Slave Peripheral 35
PerClk C04 External Slave Peripheral 35
Signals Listed Alphabetically (Part 9 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
22 3/19/03
PerCS0 E04
External Slave Peripheral 35
[PerCS1]GPIO10 C02
[PerCS2]GPIO11 E03
[PerCS3]GPIO12 D03
[PerCS4]GPIO13 D05
PerData00 P02
External Slave Peripheral
Note: PerData00 is the most significant bit (msb) on this bus. 35
PerData01 N04
PerData02 P01
PerData03 M02
PerData04 M03
PerData05 L02
PerData06 L03
PerData07 K02
PerData08 K03
PerData09 H01
PerData10 J04
PerData11 G02
PerData12 G04
PerData13 H04
PerData14 F01
PerData15 D01
PerOE F04 External Slave Peripheral 35
PerReady B03 External Slave Peripheral 35
PerR/W D02 External Slave Peripheral 35
PerWBE0 F03 External Slave Peripheral 35
PerWBE1 E01
[PerWE]PCIINT D15 External Slave Peripheral 35
PHY0Col0 AB8 Ethernet 34
PHY0Col1 C05
PHY0CrS0 AA9 Ethernet 34
PHY0CrS1 B05
PHY0Rx0Clk AB10 Ethernet 34
PHY0Rx0D0 Y16
Ethernet 34
PHY0Rx0D1 AA22
PHY0Rx0D2 AA16
PHY0Rx0D3 AA13
PHY0Rx0DV Y10 Ethernet 34
PHY0Rx0Err AB11 Ethernet 34
PHY0Rx1Clk E02 Ethernet 34
PHY0Rx1D0 R01
Ethernet 34
PHY0Rx1D1 H03
PHY0Rx1D2 G03
PHY0Rx1D3 F02
Signals Listed Alphabetically (Part 10 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 23
PHY0Rx1DV D06 Ethernet 34
PHY0Rx1Err C01 Ethernet 34
PHY0Tx0Clk Y08 Ethernet 34
PHY0Tx1Clk C06
SysClk AB18 System 37
RAS AA15 SDRAM 35
[RejectPkt0]GPIO30 W20 System 37
[RejectPkt1]GPIO31 Y21 System 37
Reserved Other 38
SysErr Y17 System 37
SysReset AB20 System 37
TCK Y02 JTAG 37
TDI AA1 JTAG 37
TDO AA2 JTAG 37
TestEn V20 System 37
TMS AC3 JTAG 37
TRST H02 JTAG 37
[TS1E]GPIO01 AA23
Trace 38
[TS2E]GPIO02 Y22
[TS1O]GPIO03 Y23
[TS2O]GPIO04 W21
[TS3]GPIO05 U20
[TS4]GPIO06 V23
[TS5]GPIO07 U21
[TS6]GPIO08 U22
[TrcClk]GPIO09 T21 Trace 38
UART0_CTS T03
Internal Peripheral 36
[UART0_DCD]GPIO24 M04
[UART0_DSR]GPIO25 K01
[UART0_DTR]GPIO27 J01
[UART0_RI]GPIO26 L04
UART0_RTS N02
UART0_Rx T01
UART0_Tx P04
[UART1_Rx]GPIO28 J02 Internal Peripheral 36
[UART1_Tx]GPIO29 J03
Signals Listed Alphabetically (Part 11 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
24 3/19/03
VDD E10
Power 38
VDD E11
VDD E13
VDD E14
VDD K05
VDD K19
VDD L05
VDD L19
VDD N05
VDD N19
VDD P05
VDD P19
VDD W10
VDD W11
VDD W13
VDD W14
WE AC15 SDRAM 35
Signals Listed Alphabetically (Part 12 of 12)
Signal Name Ball Interface Group Page
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 25
Signals Listed by Ball Assignment (Part 1 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
A01 GND B01 GND C01 PHY0Rx1Err D01 PerData15
A02 GND B02 GND C02 GPIO10[PerCS1] D02 PerR/W
A03 ExtReset B03 PerReady C03 GND D03 GPIO12[PerCS3]
A04 GPIO15[PerAddr04] B04 GPIO14[PerAddr03] C04 PerClk D04 GND
A05 GPIO16[PerAddr05] B05 PHY0CrS1 C05 PHY0Col1 D05 GPIO13[PerCS4]
A06 PerAddr08 B06 PerAddr07 C06 PHY0Tx1Clk D06 PHY0Rx1DV
A07 GND B07 PerAddr11 C07 PerAddr10 D07 PerAddr06
A08 PerAddr15 B08 PerAddr13 C08 PerAddr12 D08 PerAddr09
A09 GPIO00[PerBLast] B09
OVDD C09 PerAddr16 D09 PerAddr14
A10 PerAddr21 B10 PerAddr19 C10 PerAddr18 D10 PerAddr17
A11 PerAddr23 B11 OVDD C11 PerAddr22 D11 PerAddr20
A12 GND B12 PerAddr25 C12 PerAddr26 D12 PerAddr24
A13 PerAddr27 B13 PerAddr28 C13 PerAddr29 D13 OVDD
A14 PerAddr30 B14 PerAddr31 C14 EMC0Tx1D1 D14 EMC0Tx1D3
A15 EMC0Tx1D2 B15 EMC0Tx1D0 C15 EMC0Tx1Err D15 PCIINT[PerWE]
A16 EMC0Tx1En B16 PCIAD00 C16 PCIAD01 D16 PCIAD03
A17 GND B17 PCIAD02 C17 OVDD D17 PCIAD05
A18 PCIC0/BE0 B18 PCIAD04 C18 PCIAD06 D18 PCIAD08
A19 PCIAD07 B19 OVDD C19 PCIAD09 D19 PCIC1/BE1
A20 PCIAD10 B20 PCIAD11 C20 PCIAD12 D20 GND
A21 PCIIDSel B21 PCIClk C21 GND D21 PCIAD14
A22 GND B22 GND C22 Halt D22 PCIAD15
A23 GND B23 GND C23 PCIAD13 D23 PCIGnt0/Req
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
26 3/19/03
E01 PerWBE1 F01 PerData14 G01 GND H01 PerData09
E02 PHY0Rx1Clk F02 PHY0Rx1D3 G02 PerData11 H02 TRST
E03 GPIO11[PerCS2] F03 PerWBE0 G03 PHY0Rx1D2 H03 PHY0Rx1D1
E04 PerCS0 F04 PerOE G04 PerData12 H04 PerData13
E05 GND F05 OVDD G05 OVDD H05 OVDD
E06 OVDD F06 No ball G06 No ball H06 No ball
E07 OVDD F07 No ball G07 No ball H07 No ball
E08 OVDD F08 No ball G08 No ball H08 No ball
E09 GND F09 No ball G09 No ball H09 No ball
E10 VDD F10 No ball G10 No ball H10 No ball
E11 VDD F11 No ball G11 No ball H11 No ball
E12 GND F12 No ball G12 No ball H12 No ball
E13 VDD F13 No ball G13 No ball H13 No ball
E14 VDD F14 No ball G14 No ball H14 No ball
E15 GND F15 No ball G15 No ball H15 No ball
E16 OVDD F16 No ball G16 No ball H16 No ball
E17 OVDD F17 No ball G17 No ball H17 No ball
E18 OVDD F18 No ball G18 No ball H18 No ball
E19 GND F19 OVDD G19 OVDD H19 OVDD
E20 PCIReq0/Gnt F20 PCIReq1 G20 PCIReset H20 PCIIRDY
E21 OVDD F21 PCIGnt2 G21 PCITRDY H21 PCIDevSel
E22 PCIReq2 F22 PCIFrame G22 PCIStop H22 OVDD
E23 PCIGnt1 F23 OVDD G23 GND H23 PCIPErr
Signals Listed by Ball Assignment (Part 2 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 27
J01 GPIO27[UART0_DTR] K01 GPIO25[UART0_DSR] L01 EMC0Tx0D2 M01 GND
J02 GPIO28[UART1_Rx] K02 PerData07 L02 PerData05 M02 PerData03
J03 GPIO29[UART1_Tx] K03 PerData08 L03 PerData06 M03 PerData04
J04 PerData10 K04 OVDD L04 GPIO26[UART0_RI] M04 GPIO24[UART0_DCD]
J05 GND K05 VDD L05 VDD M05 GND
J06 No ball K06 No ball L06 No ball M06 No ball
J07 No ball K07 No ball L07 No ball M07 No ball
J08 No ball K08 No ball L08 No ball M08 No ball
J09 No ball K09 No ball L09 No ball M09 No ball
J10 No ball K10 GND L10 GND M10 GND
J11 No ball K11 GND L11 GND M11 GND
J12 No ball K12 GND L12 GND M12 GND
J13 No ball K13 GND L13 GND M13 GND
J14 No ball K14 GND L14 GND M14 GND
J15 No ball K15 No ball L15 No ball M15 No ball
J16 No ball K16 No ball L16 No ball M16 No ball
J17 No ball K17 No ball L17 No ball M17 No ball
J18 No ball K18 No ball L18 No ball M18 No ball
J19 GND K19 VDD L19 VDD M19 GND
J20 PCISErr K20 OVDD L20 PCIC2/BE2 M20GND
J21 PCIParity K21 PCIAD18 L21 PCIAD20 M21 PCIAD23
J22 PCIAD16 K22 PCIAD19 L22 PCIAD21 M22 OVDD
J23 PCIAD17 K23 OVDD L23 PCIAD22 M23 GND
Signals Listed by Ball Assignment (Part 3 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
28 3/19/03
N01 OVDD P01 PerData02 R01 PHY0Rx1D0 T01 UART0_Rx
N02 UART0_RTS P02 PerData00 R02 MemData31 T02 MemData28
N03 EMC0Tx0D1 P03 EMC0Tx0D3 R03 MemData30 T03 UART0_CTS
N04 PerData01 P04 UART0_Tx R04 MemData29 T04 MemData27
N05 VDD P05 VDD R05 GND T05 OVDD
N06 No ball P06 No ball R06 No ball T06 No ball
N07 No ball P07 No ball R07 No ball T07 No ball
N08 No ball P08 No ball R08 No ball T08 No ball
N09 No ball P09 No ball R09 No ball T09 No ball
N10 GND P10 GND R10 No ball T10 No ball
N11 GND P11 GND R11 No ball T11 No ball
N12 GND P12 GND R12 No ball T12 No ball
N13 GND P13 GND R13 No ball T13 No ball
N14 GND P14 GND R14 No ball T14 No ball
N15 No ball P15 No ball R15 No ball T15 No ball
N16 No ball P16 No ball R16 No ball T16 No ball
N17 No ball P17 No ball R17 No ball T17 No ball
N18 No ball P18 No ball R18 No ball T18 No ball
N19 VDD P19 VDD R19 GND T19 OVDD
N20 PCIC3/BE3 P20 OVDD R20 GPIO22[IRQ5] T20 OVDD
N21 PCIAD26 P21 PCIAD28 R21 PCIAD31 T21 GPIO09[TrcClk]
N22 PCIAD25 P22 PCIAD27 R22 PCIAD30 T22 GPIO21[IRQ4]
N23 PCIAD24 P23 OVDD R23 PCIAD29 T23 GPIO23[IRQ6]
Signals Listed by Ball Assignment (Part 4 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 29
U01 GND V01 OVDD W01 EMC0Tx0En Y01 IICSDA
U02 DQM3 V02 MemData26 W02 MemData24 Y02 TCK
U03 EMC0Tx0D0 V03 EMC0Tx0Err W03 MemData22 Y03 MemData21
U04 MemData25 V04 MemData23 W04 DQM2 Y04 GND
U05 OVDD V05 OVDD W05 GND Y05 MemData18
U06 No ball V06 No ball W06 OVDD Y06 EMC0MDClk
U07 No ball V07 No ball W07 OVDD Y07 MemData13
U08 No ball V08 No ball W08 OVDD Y08 PHY0Tx0Clk
U09 No ball V09 No ball W09 GND Y09 MemData09
U10 No ball V10 No ball W10 VDD Y10 PHY0Rx0DV
U11 No ball V11 No ball W11 VDD Y11 MemData04
U12 No ball V12 No ball W12 GND Y12 OVDD
U13 No ball V13 No ball W13 VDD Y13 MemClkOut1
U14 No ball V14 No ball W14 VDD Y14 CAS
U15 No ball V15 No ball W15 GND Y15 BA0
U16 No ball V16 No ball W16 OVDD Y16 PHY0Rx0D0
U17 No ball V17 No ball W17 OVDD Y17 SysErr
U18 No ball V18 No ball W18 OVDD Y18 MemAddr08
U19 OVDD V19 OVDD W19 GND Y19 MemAddr10
U20 GPIO05[TS3] V20 TestEn W20 GPIO30[RejectPkt0] Y20 GND
U21 GPIO07[TS5] V21 GPIO19[IRQ2] W21 GPIO04[TS2O] Y21 GPIO31[RejectPkt1]
U22 GPIO08[TS6] V22 GPIO20[IRQ3] W22 GPIO17[IRQ0] Y22 GPIO02[TS2E]
U23 GND V23 GPIO06[TS4] W23 GPIO18[IRQ1] Y23 GPIO03[TS1O]
Signals Listed by Ball Assignment (Part 5 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
30 3/19/03
AA01 TDI AB01 GND AC01 GND
AA02 TDO AB02 GND AC02 GND
AA03 GND AB03 MemData20 AC03 TMS
AA04 MemData19 AB04 IICSCL AC04 MemData17
AA05 EMC0MDIO AB05 MemData16 AC05 MemData15
AA06 MemData14 AB06 MemData12 AC06 OVDD
AA07 DQM1 AB07 MemData11 AC07 GND
AA08 MemData10 AB08 PHY0Col0 AC08 MemData08
AA09 PHY0CrS0 AB09 MemData07 AC09 MemData06
AA10 MemData05 AB10 PHY0Rx0Clk AC10 DQM0
AA11 MemData03 AB11 PHY0Rx0Err AC11 MemData02
AA12 MemData01 AB12 MemData00 AC12 GND
AA13 PHY0Rx0D3 AB13 BankSel0 AC13 BankSel1
AA14 MemClkOut0 AB14 ClkEn0 AC14 ClkEn1
AA15 RAS AB15 MemAddr00 AC15 WE
AA16 PHY0Rx0D2 AB16 MemAddr01 AC16 BA1
AA17 MemAddr03 AB17 MemAddr02 AC17 GND
AA18 MemAddr05 AB18 SysClk AC18 MemAddr04
AA19 MemAddr09 AB19 MemAddr07 AC19 MemAddr06
AA20 MemAddr11 AB20 SysReset AC20 AVDD
AA21 GND AB21 AGND AC21 MemAddr12
AA22 PHY0Rx0D1 AB22 GND AC22 GND
AA23 GPIO01[TS1E] AB23 GND AC23 GND
Signals Listed by Ball Assignment (Part 6 of 6)
Ball Signal Name Ball Signal Name Ball Signal Name Ball Signal Name
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 31
Signal List
The following table provides a summary of the number of package pins associated with each functional
interface group.
In the table “Signal Functional Description” on page 33, each external signal is listed along with a short
description of the signal function. Active-low signals (for example, RAS) are marked with an overline. Please
see “Signals Listed Alphabetically” on page 13 for the pin (ball) number to which each signal is assigned.
Multiplexed Pins
Some signals are multiplexed on the same package pin (ball) so that the pin can be used for different
functions. In most cases, the signal names shown in this table are not accompanied by signal names that
may be multiplexed on the same pin. If you need to know what, if any, signals are multiplexed with a particular
signal, look up the name in “Signals Listed Alphabetically” on page 13. 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, in the PCI interface
PCIC3:0/BE3:0 serves as both Command and Byte Enable signals. In this example, the pins are also
bidirectional, serving as both inputs and outputs.
Initialization 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 “Initialization” on page 50).
Note that the use of these pins for strapping is not considered multiplexing since the strapping function is not
programmable.
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 3k to +3.3V (10k to +5V can be used on 5V
tolerant I/Os) and pull-down value of 1k 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.
Pin Summary
Group No. of Pins
Non multiplexed 215
Multiplexed 33
Total Signal Pins 248
OVDD 43
VDD 16
Gnd 53
Thermal (and Gnd) 25
Reserved 0
Total Pins 385
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
32 3/19/03
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 PPC405EP.
Unused I/Os
Strapping of some pins may be necessary when they are unused. Although the PPC405EP requires only the
pull-up and pull-down terminations as specified in the “Signal Functional Description” on page 33, good
design practice is to terminate all unused inputs or to configure I/Os such that they always drive. If unused,
the peripheral, SDRAM, and PCI buses should be configured and terminated as follows:
Peripheral interface—PerAddr03:31, PerData00:15, and all of the control signals are driven by default.
Terminate PerReady high.
SDRAM—Program SDRAM0_CFG[EMDULR]=1 and SDRAM0_CFG[DCE]=1. This causes the
PPC405EP 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 PCIAD31:00, PCIC3:0/BE3:0, and the remaining PCI control signals by doing the
following:
- Strap the PPC405EP to disable the internal PCI arbiter.
- Individually connect PCISErr, PCIPErr, PCITRDY, and PCIStop through 3.3k resistors to +3.3V.
- Terminate PCIReq1:2 to +3.3V.
- Terminate PCIReq0/Gnt to GND.
For selected interfaces, it is possible to turn off input receivers for some or all of the signals on that interface.
Control for this receiver gating is in register CPC0_CR1. When this gating capability is applied to unused
signals, it is not necessary to strap them. Refer to the PowerPC 405EP Embedded Processor User’s Manual
for details.
External Bus Control Signals
All peripheral bus control signals (PerCS0:4, PerR/W, PerWBE0:1, PerOE, PerWE, PerBLast) are set to the
high-impedance state when ExtReset=0. In addition, as detailed in the PowerPC 405EP Embedded
Processor User’s Manual, the peripheral bus controller can be programmed via EBC0_CFG to float some of
these control signals between transactions. As a result, a pull-up 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 PPC405EP. Please refer to “Signals Listed
Alphabetically” on page 13 for the pin number to which each signal is assigned.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 33
Signal Functional Description (Part 1 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
PCI Interface
PCIAD31:00 PCI Address/Data Bus. Multiplexed address and data bus. I/O 5V tolerant
3.3V PCI
PCIC3:0/BE3:0 PCI bus command and byte enables. I/O 5V tolerant
3.3V PCI
PCIClk PCIClk is used as the asynchronous PCI clock when in asynch
mode. I5V 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
PCIParity
PCI parity. Parity is even across PCIAD00:31 and
PCIC3:0/BE3:0. PCIParity is valid one cycle after either an
address or data phase. The PCI device that drove PCIAD00:31 is
responsible for driving PCIParity on the next PCI bus clock.
I/O 5V tolerant
3.3V PCI
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. I5V tolerant
3.3V PCI
PCIINT
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.
O5V 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
PCIAD00:31, PCIC3:0/BE3:0, and PCIParity, two PCI clocks
following the data in which bad parity is detected.
I/O 5V tolerant
3.3V PCI 2
PCIReset PCI specific reset. 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. I5V tolerant
3.3V PCI
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
34 3/19/03
PCIReq1:2 PCIReq input when internal arbiter is used. I 5V tolerant
3.3V PCI
PCIGnt0/Req
Gnt0 when internal arbiter is used
or
Req when external arbiter is used.
O5V tolerant
3.3V PCI
PCIGnt1:2 PCIGnt output when internal arbiter is used. O 5V tolerant
3.3V PCI
Ethernet Interface
PHY0Rx0:1D3:0 Received data. This is a nibble wide bus from the PHY. The data
is synchronous with the PHY0RxClk. I5V tolerant
3.3V LVTTL 1
EMC0Tx0:1D3:0 Transmit data. A nibble wide data bus towards the net. The data
is synchronous to the PHY0TxClk. O5V tolerant
3.3V LVTTL
PHY0Rx0:1Err Receive Error. This signal comes from the PHY and is
synchronous to the PHY0RxClk. I5V tolerant
3.3V LVTTL 1
PHY0Rx0:1Clk Receive Medium clock. This signal is generated by the PHY. I 5V tolerant
3.3V LVTTL 1
PHY0Rx0:1DV 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
PHY0CrS0:1 Carrier Sense signal from the PHY. This is an asynchronous
signal. I5V tolerant
3.3V LVTTL 1
EMC0Tx0:1Err 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. O5V tolerant
3.3V LVTTL
EMC0Tx0:1En
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 PHY0TxClk.
O5V tolerant
3.3V LVTTL
PHY0Tx0:1Clk This clock comes from the PHY and is the Medium Transmit
clock. I 5V tolerant
3.3V LVTTL 1
PHY0Col0:1 Collision signal from the PHY. This is an asynchronous signal. I 5V tolerant
3.3V LVTTL 1
EMC0MDClk Management Data Clock. The MDClk is sourced to the PHY.
Management information is transferred synchronously with
respect to this clock. O5V tolerant
3.3V LVTTL
EMC0MDIO 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 1
Signal Functional Description (Part 2 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 35
SDRAM Interface
MemData00:31
Memory data bus.
Notes:
1. MemData00 is the most significant bit (msb).
2. MemData31 is the least significant bit (lsb).
I/O 3.3V LVTTL
MemAddr12:00
Memory address bus.
Notes:
1. MemAddr12 is the most significant bit (msb).
2. MemAddr00 is the least significant bit (lsb).
O3.3V LVTTL
BA1:0 Bank Address supporting up to 4 internal banks. O 3.3V LVTTL
RAS Row Address Strobe. O 3.3V LVTTL
CAS Column Address Strobe. O 3.3V LVTTL
DQM0:3
DQM for byte lane: 0 (MemData00:7),
1 (MemData08:15),
2 (MemData16:23), and
3 (MemData24:31)
O3.3V LVTTL
BankSel0:1 Select up to two external SDRAM banks. O 3.3V LVTTL
WE Write Enable. O 3.3V LVTTL
ClkEn0:1 SDRAM Clock Enable. O 3.3V LVTTL
MemClkOut0:1 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. O3.3V LVTTL
External Slave Peripheral Interface
PerData00:15 Peripheral data bus.
Note: PerData00 is the most significant bit (msb) on this bus. I/O 5V tolerant
3.3V LVTTL 1
PerAddr03:05
PerAddr06:31
Peripheral address bus.
Note: PerAddr03 is the most significant bit (msb) on this bus. I/O 5V tolerant
3.3V LVTTL 1
PerWBE0:1 These pins 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. O5V tolerant
3.3V LVTTL 7
[PerWE]
Peripheral write enable. Low when either of the two PerWBE0:1
write byte enables are low.
To access this function, software must toggle a DCR bit.
O5V tolerant
3.3V LVTTL
PerCS0 Peripheral chip select bank 0. O 5V tolerant
3.3V LVTTL 7
[PerCS1:4]Four additional peripheral chip selects
To access this function, software must toggle a DCR bit. O5V tolerant
3.3V LVTTL 1, 7
Signal Functional Description (Part 3 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
36 3/19/03
PerOE Peripheral output enable. O 5V tolerant
3.3V LVTTL 7
PerR/W Peripheral read/write. High indicates a read from memory, low
indicates a write to memory. O5V tolerant
3.3V LVTTL
PerReady Ready to transfer data. I 5V tolerant
3.3V LVTTL 1
[PerBLast]Used to indicates the last transfer of a memory access.
To access this function, software must toggle a DCR bit. I/O 5V tolerant
3.3V LVTTL 1, 7
PerClk Peripheral clock to be used by peripheral slaves. O 5V tolerant
3.3V LVTTL
ExtReset Peripheral reset to be used by peripheral slaves. O 5V tolerant
3.3V LVTTL
Internal Peripheral Interface
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.
To access this function, software must toggle a DCR bit. I5V tolerant
3.3V LVTTL 1
[UART0_DSR]UART0 Data Set Ready.
To access this function, software must toggle a DCR bit. I5V tolerant
3.3V LVTTL 1
UART0_CTS UART0 Clear To Send. I 5V tolerant
3.3V LVTTL 1
[UART0_DTR]UART0 Data Terminal Ready.
To access this function, software must toggle a DCR bit. O5V tolerant
3.3V LVTTL
UART0_RTS UART0 Request To Send. O 5V tolerant
3.3V LVTTL 6
[UART0_RI]UART0 Ring Indicator.
To access this function, software must toggle a DCR bit. I5V tolerant
3.3V LVTTL 1
[UART1_Rx] UART1 Serial Data In.
To access this function, software must toggle a DCR bit. I5V tolerant
3.3V LVTTL 1
[UART1_Tx] UART1 Serial Data Out.
To access this function, software must toggle a DCR bit. O5V tolerant
3.3V LVTTL
IICSCL IIC Serial Clock. I/O 3.3V IIC 1, 2
IICSDA IIC Serial Data. I/O 3.3V IIC 1, 2
Interrupts Interface
[IRQ0:6] Interrupt requests
To access this function, software must toggle a DCR bit. I5V tolerant
3.3V LVTTL 1
Signal Functional Description (Part 4 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 37
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. I5V 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 PPC405EP. I5V tolerant
3.3V LVTTL 5
System Interface
SysReset
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).
I/O 5V tolerant
3.3V LVTTL 1, 2
SysErr Set to 1 when a Machine Check is generated. O 5V tolerant
3.3V LVTTL 6
Halt Halt from external debugger. I 5V tolerant
3.3V LVTTL 1, 2
GPIO00:31 General Purpose I/O. All of the GPIO signals are multiplexed with
other signals. I/O 5V tolerant
3.3V LVTTL 1
TestEn Test Enable. Used only for manufacturing tests. Pull down for
normal operation. I1.8V CMOS
w/pull-down
SysClk Main system clock input. I 3.3V LVTTL
[RejectPkt0:1] External request to reject a packet. I 5V tolerant
3.3V LVTTL
AVDD Clean voltage input for the PLL. I
AGND Clean Ground input for the PLL. I
Signal Functional Description (Part 5 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
38 3/19/03
Trace Interface
[TS1E]
[TS2E] Even Trace execution status. To access this function, software
must toggle a DCR bit O5V tolerant
3.3V LVTTL 1
[TS1O]
[TS2O] Odd Trace execution status. To access this function, software
must toggle a DCR bit O5V tolerant
3.3V LVTTL 1
[TS3:6] Trace status. To access this function, software must toggle a
DCR bit O5V tolerant
3.3V LVTTL 1
[TrcClk]
Trace interface clock. Operates at half 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.
O5V tolerant
3.3V LVTTL 1
Power
GND
Ground
Note: K10-K14, L10-L14, M10-M14, N10-N14, and P10-P14 are
also thermal balls.
na na na
OVDD Output driver voltage—3.3V. na na na
VDD Logic voltage—1.8V. na na na
Other pins
Reserved Reserved pins. Do not make voltage, ground, or signal
connections to these pins. na na na
Signal Functional Description (Part 6 of 6)
Secondary multiplexed signals are shown in brackets.
Notes:
1. Receiver input has hysteresis.
2. Must pull up. See “Pull-Up and Pull-Down Resistors” on page 31 for recommended termination values.
3. Must pull down. See “Pull-Up and Pull-Down Resistors” on page 31 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 32.
Signal Name Description I/O Type Notes
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 39
Note:
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×θCA, 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.
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. None of the performance specification contained in this document are guaranteed
when operating at these maximum ratings.
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 to +1.95 V
Input Voltage (3.3V LVTTL receivers) VIN 0 to +3.6 V
Input Voltage (5.0V LVTTL receivers) VIN 0 to +5.5 V
Storage Temperature Range TSTG -55 to +150 °C
Case temperature under bias TC-40 to +120 °C
Note: All specified voltages are with respect to GND.
Package Thermal Specifications
The PPC405EP is designed to operate within a case temperature range of -40°C to +85°C. Thermal resistance values for
the E-PBGA packages in a convection environment are as follows:
Package—Thermal Resistance Symbol
Airflow
ft/min (m/sec) Unit
0 (0) 100 (0.51) 200 (1.02)
31mm, 385-balls—Junction-to-Case θJC 222°C/W
31mm, 385-balls—Case-to-Ambient1θCA 17.8 16.8 16.1 °C/W
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
40 3/19/03
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.
Parameter Symbol Minimum Typical Maximum Unit Notes
Logic Supply Voltage VDD +1.65 +1.8 +1.95 V
I/O Supply Voltage OVDD +3.0 +3.3 +3.6 V
PLL Supply Voltage AVDD +1.65 +1.8 +1.95 V
Input Logic High (1.8V CMOS receivers) VIH 0.65VDD VDD V
Input Logic High (3.3V PCI receivers) VIH 0.5OVDD OVDD+0.5 V
Input Logic High
(3.3V LVTTL, 5V tolerant receivers) VIH +2.0 +5.5 V
Input Logic Low (1.8V CMOS receivers) VIL 00.65VDD V
Input Logic Low (3.3V PCI receivers) VIL -0.5 0.35OVDD V
Input Logic Low
(3.3V LVTTL, 5V tolerant receivers) VIL 0+0.8V
Output Logic High (3.3V PCI receivers) VOH 0.9OVDD OVDD V
Output Logic High
(3.3V LVTTL, 5V tolerant receivers) VOH +2.4 OVDD V
Output Logic Low (3.3V PCI receivers) VOL -0.5 0.35OVDD V
Output Logic Low
(3.3V LVTTL, 5V tolerant receivers) VOL 0+0.4V
Input Leakage Current (no pull-up or pull-
down) IIL1 00
µA
Input Leakage Current (with internal pull-
down) IIL2 0 200 µA
5V Tolerant I/O Input Current 1IIL4 ±10 -325 µA
Input Max Allowable Overshoot
(1.8V CMOS receivers) VIMAO1.8 VDD + 0.6 V
Input Max Allowable Overshoot
(3.3V LVTTL, 5V tolerant receivers) VIMAO +5.5 V
Input Max Allowable Undershoot (3.3V
LVTTL, 5V tolerant receivers) VIMAU -0.6 V
Output Max Allowable Overshoot (3.3V
LVTTL, 5V tolerant receivers) VOMAO +5.5 V
Output Max Allowable Undershoot (3.3V
LVTTL, 5V tolerant receivers) VOMAU -0.6 V
Case Temperature TC-40 +85 °C
Note:
1. See “5V-Tolerant Input Current” on page 41
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 41
5V-Tolerant Input Current
Input Capacitance
Parameter Symbol Maximum Unit Notes
3.3V LVTTL I/O CIN1 12 pF
5V tolerant, 3.3V LVTTL I/O CIN2 12 pF
PCI I/O CIN3 12 pF
Rx only pins CIN4 9pF
IIC pads CIN5 6.7 pF
-350
-300
-250
-200
-150
-100
-50
0
50
1.0 2.0 3.0 4.0 5.00.0
Input Current (
µ
A)
Input Voltage (V)
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
42 3/19/03
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.
DC Electrical Characteristics
Parameter Symbol Minimum Typical Maximum Unit
Active Operating Current (VDD)I
DD 440 520 606 mA
Active Operating Current (OVDD)I
ODD 59 70 81 mA
Active Operating Current (AVDD)I
ADD 14 17 19 mA
Total Power PT1.2 1.4 W
Note:
1. AVDD should be derived from VDD using the following circuit:
VDD
C1 C2 C3
AVDD
L1
L1 – 2.2µH SMT inductor (equivalent to MuRata
LQH3C2R2M34) or SMT chip ferrite bead (equivalent
to MuRata BLM31A700S)
C1 – 3.3 µF SMT tantalum
C2 – 0.1µF SMT monolithic ceramic capacitor with X7R
dielectric or equivalent
C3 – 0.01µF SMT monolithic ceramic capacitor with X7R
dielectric or equivalent
+
AGND
GND
Output
Pin 50pF
All signals other
than PCI
Output
Pin 10pF 25
Output
Pin
10pF
25OVDD
PCI Rising edge
PCI Falling edge
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 43
Clocking Waveform
Clocking Specifications
Symbol Parameter Min Max Units
CPU
PFCProcessor clock frequency 133.33 or 200 or 266.66 MHz
PTCProcessor clock period 7.5 or 5 or 3.75 ns
SysClk Input
FCFrequency 25 100 MHz
TCPeriod 10 40 ns
TCS Edge stability (phase jitter, cycle to cycle) ±0.15 ns
TCH Input high time 40% of nominal period 60% of nominal period ns
TCL Input low time 40% of nominal period 60% of nominal period ns
Note: Input slew rate > 2V/ns
MemClkOut Output
FCFrequency 133 MHz
TCPeriod 7.50 ns
TCS Edge stability (phase jitter, cycle to cycle) ±0.2 ns
TCH Output high time 45% of nominal period 55% of nominal period ns
TCL Output low time 45% of nominal period 55% of nominal period ns
TrcClk Output
FCClock output frequency PFC / 2 MHz
TCClock period PTC x 2 ns
TCS Clock edge stability (phase jitter, cycle to cycle) ± 0.2 ns
TCH Clock output high time 45% of nominal period 55% of nominal period ns
TCL Clock output low time 45% of nominal period 55% of nominal period ns
Other Clocks
VCOFCVCO frequency @ PFC = 133 or 200 or 266MHz 500 1000 MHz
PLBFCPLB frequency @ PFC = 133 or 266MHz 133.33 MHz
PLBFCPLB frequency @ PFC = 200MHz 100 MHz
OPBFCOPB frequency @ PFC = 133 or 266MHz 66.66 MHz
OPBFCOPB frequency @ PFC = 200MHz 50 MHz
TCL
TCH
TC
2.0V
1.5V
0.8V
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
44 3/19/03
Spread Spectrum Clocking
Care must be taken when using a spread spectrum clock generator (SSCG) with the PPC405EP. 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 PPC405EP the following conditions must be met:
The frequency deviation must not violate the minimum clock cycle time. Therefore, when operating the
PPC405EP 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 PPC405EP 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 PPC405EP PCI Bridge is unaffected by the use of an SSCG.
The PCI controller must be operated in asynchronous mode. When in asynchronous mode, the PCI bus
clock must be driven into the PPC405EP 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 PPC405EP meets the above
requirements and does not adversely affect other aspects of the system.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 45
Peripheral Interface Clock Timings
Parameter Min Max Units
PCIClk input frequency (asynchronous mode) Note 1 66.66 MHz
PCIClk period (asynchronous mode) 15 Note 1 ns
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
EMC0MDClk output frequency 2.5 MHz
EMC0MDClk period 400 ns
EMC0MDClk output high time 160 ns
EMC0MDClk output low time 160 ns
PHY0Tx0:1Clk input frequency 2.5 25 MHz
PHY0Tx0:1Clk period 40 400 ns
PHY0Tx0:1Clk input high time 35% of nominal period ns
PHY0Tx0:1Clk input low time 35% of nominal period ns
PHY0Rx0:1Clk input frequency 2.5 25 MHz
PHY0Rx0:1Clk period 40 400 ns
PHY0Rx0:1Clk input high time 35% of nominal period ns
PHY0Rx0:1Clk 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
PerClk clock edge stability (phase jitter, cycle to cycle) ± 0.3 ns
Note:
1. In asynchronous PCI mode the minimum PCIClk frequency is 1/8 the PLB Clock. Refer to the PowerPC 405EP Embedded Proces-
sor User’s Manual for more information.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
46 3/19/03
Input Setup and Hold Timing Waveform
Output Delay and Float Timing Waveform
System Clock
TIS TIH
MIN MIN
Inputs Valid
1.5V
1.5V
Valid
TOV TOH
MIN
Outputs
System Clock
Outputs
TOF
MIN
MAX
MAX
1.5V
1.5V
1.5V
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 47
Notes: 1. In the following I/O Specifications tables a timing value 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 (Part 1 of 2)
Notes:
1. PCI timings are for asynchronous operation up to 66.66MHz. PCI output hold time requirement is 1ns for 66.66MHz
and 2ns for 33.33MHz.
2. Ethernet interface meets timing requirements as defined by IEEE 802.3 standard. Timing shown is with EMAC noise
filter selected. See the CPC0_EPCTL register PowerPC 405EP Embedded Processor User’s Manual.
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.
Signal
Input (ns) Output (ns) Output Current (mA)
Clock Notes
Setup Time
(TIS min) Hold Time
(TIH min) Valid Delay
(TOV max) Hold Time
(TOH min) I/O H
(min) I/O L
(min)
PCI Interface
PCIAD31:00 3 0 6 1 0.5 1.5 PCIClk 1
PCIC3:0/BE3:0 3 0 6 1 0.5 1.5 PCIClk 1
PCIClk na na na na na na async
PCIDevSel 3 0 6 1 0.5 1.5 PCIClk 1
PCIFrame 3 0 6 1 0.5 1.5 PCIClk 1
PCIGnt0/Req
PCIGnt1:2 na na 6 1 0.5 1.5 PCIClk 1
PCIIDSel 3 0 na na na na PCIClk 1
PCIINT[PerWE] na na na na 0.5 1.5 PCIClk 1
PCIIRDY 3 0 6 1 0.5 1.5 PCIClk 1
PCIParity 3 0 6 1 0.5 1.5 PCIClk 1
PCIPErr 3 0 6 1 0.5 1.5 PCIClk 1
PCIReq0/Gnt
PCIReq1:2 5 0 na na na na PCIClk 1
PCIReset na na na na 0.5 1.5 PCIClk 1
PCISErr na na na na 0.5 1.5 PCIClk 1
PCIStop 3 0 6 1 0.5 1.5 PCIClk 1
PCITRDY 3 0 6 1 0.5 1.5 PCIClk 1
Ethernet Interface
EMC0MDClk na na settable 2 10.3 7.1 async 2
EMC0MDIO 100 0 1 OPB clock
period + 10ns 1 OPB clock
period 10.3 7.1 EMC0MDClk 2
EMC0Tx0:1D3:0 na na 14 5 10.3 7.1 PHY0TxClk 2
EMC0Tx0:1En na na 14 5 10.3 7.1 PHY0TxClk 2
EMC0Tx0:1Err na na 14 5 10.3 7.1 PHY0TxClk 2
PHY0Col0:1 2 3 na na na na PHY0RxClk 2
PHY0CrS0:1 2 3 na na na na PHY0RxClk 2
PHY0Rx0:1Clk na na na na na na async 2
PHY0Rx0:1D3:0 2 4 na na na na PHY0RxClk 2
PHY0Rx0:1DV 2 4 na na na na PHY0RxClk 2
PHY0Rx0:1Err 2 4 na na na na PHY0RxClk 2
PHY0Tx0:1Clk na na na na na na async 2
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
48 3/19/03
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 na na na na
UART0_RTS na na na na 10.3 7.1
UART0_Rx na na na na na na
UART0_Tx na na na na 10.3 7.1
UART1_Rx na na na na na na
UART1_Tx na na na na 10.3 7.1
Interrupts Interface
[IRQ0:6] 10.3 7.1
JTAG Interface
TCK nanananananaasync
TDI na na na na na na async
TDO na na na na 10.3 7.1 async
TMS nanananananaasync
TRST na na na na na na async
System Interface
GPIO00:31 na na na na 10.3 7.1
Halt na na na na na na async
SysErr na na na na 10.3 7.1 async
SysReset na na na na 10.3 7.1 async
TestEn na na na na na na async
[RejectPkt0:1] 3 1 na na na na async
SysClk na na na na na na
I/O Specifications—Group 1 (Part 2 of 2)
Notes:
1. PCI timings are for asynchronous operation up to 66.66MHz. PCI output hold time requirement is 1ns for 66.66MHz
and 2ns for 33.33MHz.
2. Ethernet interface meets timing requirements as defined by IEEE 802.3 standard. Timing shown is with EMAC noise
filter selected. See the CPC0_EPCTL register PowerPC 405EP Embedded Processor User’s Manual.
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.
Signal
Input (ns) Output (ns) Output Current (mA)
Clock Notes
Setup Time
(TIS min) Hold Time
(TIH min) Valid Delay
(TOV max) Hold Time
(TOH min) I/O H
(min) I/O L
(min)
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 49
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 PPC405EP package pin. System designers must use the
PPC405EP IBIS model (available from www.chips.ibm.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 rising edge at package pin with a 10pF load trails the internal PLB clock by approximately 0.8ns.
5. I/O H is specified at 2.4 V and I/O L is specified at 0.4 V.
Signal
Input (ns) Output (ns) Output Current (mA)
Clock Notes
Setup Time
(TIS min) Hold Time
(TIH min) Valid Delay
(TOV max) Hold Time
(TOH min) I/O H
(minimum) I/O L
(minimum)
SDRAM Interface
BA1:0 na na 4.7 2 15.3 10.2 MemClkOut 1, 2
BankSel3:0 na na 4.5 1.7 15.3 10.2 MemClkOut 1, 2
CAS na na 4.8 2 15.3 10.2 MemClkOut 1, 2
ClkEn0:1 na na 4.1 1.6 28.7 19.3 MemClkOut 1, 2
DQM0:3 na na 4.7 1.9 15.3 10.2 MemClkOut 1, 2
MemAddr12:00 na na 4.8 2.1 15.3 10.2 MemClkOut 1, 2
MemData00:31 1.6 1 4 1.2 15.3 10.2 MemClkOut 1, 2
RAS na na 5 2.1 15.3 10.2 MemClkOut 1, 2
WE na na 4.9 2 15.3 10.2 MemClkOut 1, 2
External Slave Peripheral Interface
PerAddr06:31 na na 3.8 1.6 15.3 10.2 PerClk
[PerBLast] 418 0128PerClk
PerCS0
[PerCS1:4]na na 4.1 1.5 10.3 7.1 PerClk
PerData00:31 5 1 6.4 1.5 15.3 10.2 PerClk
PerOE na na 4.1 1.5 10.3 7.1 PerClk
PerR/W na na 4.1 1.6 10.3 7.1 PerClk
PerReady 6.5 1 na na na na PerClk
PerWBE0:3 na na 4.1 1.6 10.3 7.1 PerClk
ExtReset na na na na 15.3 10.2 PerClk
PerClk na na 0.4 -0.2 15.3 10.2 PLB Clk 4
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
50 3/19/03
Initialization
The following describes the method by which initial chip settings are established when a system reset occurs.
Strapping
When the SysReset input is driven low (system reset), the state of certain I/O pins is read to enable default
initial conditions prior to PPC405EP start-up. The actual capture instant is the nearest system clock 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 3k to +3.3V or
10k to +5V. The recommended pull-down is 1K to GND. These pins are use for strap functions only
during reset. They are used for other signals during normal operation. The following table lists the strapping
pins along with their functions and strapping options. The signal names assigned to the pins for normal
operation appear below the pin number.
EEPROM
During reset, configuration values other than the internal default values can be read from a serial EEPROM
connected to the IIC port. The association of bits in the EEPROM with the configuration values and their
default values are covered in detail in the PowerPC 405EP Embedded Processor User’s Manual.
Caution: If P04 is strapped to 1, and the EEPROM is not connected or is defective, the PPC405EP remains
in the reset state and will not boot.
Revision Log
Strapping Pin Assignments
Function Option Ball Strapping
IIC EEPROM controller
If the controller is enabled, 32 bytes of configuration
data are read from the EEPROM.
P04
UART0_Tx
Disable 0
Enable 1
EEPROM address (P04 = 1)
or
Boot ROM width (P04 = 0)
N02
UART0_RTS Y17
SysErr
When P04 = 1, these pins set the high-order two bits of
the EEPROM base address. High order EEPROM base address bits Address bit Address bit
When P04 = 0, these pins indicated the width of the
boot ROM.
8 bits 0 0
16 bits 0 1
reserved 1 0
reserved 1 1
Date Contents of Modification
01/30/2003 Add revision log.
03/18/2003 Update revision level of chip.
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
3/19/03 51
Inside of back cover
Preliminary
PowerPC 405EP Embedded Processor Data Sheet
(c) Copyright International Business Machines Corporation 1999, 2003
All Rights Reserved
Printed in the United States of America, 3/19/03
The following are trademarks of International Business Machines Corporation in
the United States, or other countries, or both:
Other company, product, and service names may be trademarks or service marks
of others.
Preliminary Edition (3/19/03)
This document contains information on a new product under development by IBM.
IBM reserves the right to change or discontinue this product without notice.
This document is a preliminary edition of the PowerPC 405EP data sheet. Make
sure you are using the correct edition for the level of the product.
While the information contained herein is believed to be accurate, such
information is preliminary, and should not be relied upon for accuracy or
completeness, and no representations or warranties of accuracy or completeness
are made.
All information contained in this document is subject to change without notice. The
products described in this document are NOT intended for use in implantation, life
support, or other hazardous uses where malfunction could result in death, bodily
injury, or catastrophic property damage. The information contained in this
document does not affect or change IBM product specifications or warranties.
Nothing in this document shall operate as an express or implied license or
indemnity under the intellectual property rights of IBM or third parties. All
information contained in this document was obtained in specific environments,
and is presented as an illustration. The results obtained in other operating
environments may vary.
THE INFORMATION CONTAINED IN THIS DOCUMENT IS PROVIDED ON AN
“AS IS” BASIS. In no event will IBM be liable for damages arising directly or
indirectly from any use of the information contained in this document.
IBM Microelectronics Division
1580 Route 52
Hopewell Junction, NY 12533-6351
The IBM home page is www. ibm.com.
The IBM Microelectronics Division home page is www.chips.ibm.com.
SA14-2704-02
Blue Logic IBM PowerPC
CoreConnect IBM Logo