Features
• PC603e™ Microprocessor (Embedded PowerPC™ Core) at 133 - 300 MHz
•
•
•
•
•
•
•
– 280 MIPS at 200 MHz (Dhrystone 2.1)
– 520 MIPS at 300 MHz (Dhrystone 2.1)
– High-performance, Superscalar Microprocessor
– Disable CPU Mode
– Improved Low-power Core
– 16-Kbyte Data and 16-Kbyte Instruction Cache, Four-way Set Associative
– Memory Management Unit (MMU)
– Floating Point Unit (FPU)
– Common On-chip Processor (COP)
Two Bus Architectures: One 64-bit PowerPC and One 32-bit PCI or Local Bus
System Integration Unit (SIU)
– Memory Controller, Including Two Dedicated SDRAM Machines
– PCI up to 66 MHz
– Hardware Bus Monitor and Software Watchdog Timer
– IEEE 1149.1 JTAG Test Access Port
High-performance Communications Processor Module (CPM)
– CPM Frequency Up to 200 MHz
– PowerPC and CPM May Run at Different Frequencies
– Parallel I/O Registers
– On-board 32 KBytes of Dual-port RAM
– Two Multi-channel Controllers (MCCs) Each Supporting 128 Full-duplex, 64-Kbps,
HDLC Lines
– Virtual DMA Functionality
– 3 FCCs Supporting:
Up to 155 Mbps ATM SAR, Maximum of Two (AAL0, AAL1, AAL2, AAL5)
10/100 Mbps Ethernet, Up to Three (IEEE 802.3X with Flow Control)
45 Mbps HDLC/Transparent (Up to Three)
Two UTOPIA Level-2 Master/Slave Ports, Both with Multi-PHY Support. One Can
Support 8/16 bit Data
Three MII Interfaces
Eight TDM Interfaces (T1/E1), Two TDM Ports Can Be Glueless to T3/E3
Power Consumption: 2.5W at 300 MHz
PowerPC™based
Communications
Processor
PC8265A
PowerQUICC II™
Preliminary
Specification
Alpha Site
Description
The PC8265A PowerQUICC II™ is a versatile communications processor that integrates on one chip, a high-performance PowerPC (PC603e) RISC microprocessor, a
highly flexible system integration unit, and many communications peripheral controllers that can be used in a variety of applications, particularly in communications and
networking systems.
The core is an embedded variant of the PC603e microprocessor, specifically referred
to later in this document as the EC603e, with 16 Kbytes of instruction cache and
16 Kbytes of data cache and floating-point unit (FPU). The system interface unit (SIU)
consists of a flexible memory controller that interfaces to almost any user-defined
memory system, a 60x-to-PCI bus bridge and many other peripherals, making this
device a complete system on a chip.
The communications processor module (CPM) includes all the peripherals found in
the PC860, with the addition of three high-performance communication channels that
support new emerging protocols (for example, 155-Mbps ATM and Fast Ethernet).
Equipped with dedicated hardware, the PC8265A can handle up to 256 full-duplex,
time-division, multiplexed logical channels.
5336A–HIREL–08/03
1
Screening Quality
Packaging
This product is manufactured in full compliance with:
•
Upscreening based upon Atmel standards
•
Military temperature range (TC = -55°C, TC = +125°C)
•
480-ball Tape Ball Grid Array package (TBGA 37.5 x 37.5 mm)
PC8265A Architecture
General Overview
Figure 1. PC8265A Block Diagram
16 Kbytes
I-Cache
I-MMU
System Interface Unit
(SIU)
G2 Core
16 Kbytes
D-Cache
Bus Interface Unit
PCI Bus
60x-to-PCI
Bridge
60x-to-Local
Bridge
D-MMU
Communication Processor Module (CPM)
32 bits, up to 66 MHz
or
Local Bus
Memory Controller
Timers
Serial
DMAs
32 Kbytes
Dual-Port RAM
Interrupt
Controller
60x Bus
32 bits, up to 83 MHz
Clock Counter
Parallel I/O
MCC1
MCC2
4 Virtual
IDMAs
32-bit RISC Microcontroller
and Program ROM
Baud Rate
Generators
FCC1
FCC2
FCC3
SCC1
SCC2
SCC3
SCC4
System Functions
SMC1
SMC2
SPI
I2C
Time Slot Assigner
Serial Interface
3 MII
Ports
8 TDM Ports
Features
2 UTOPIA
Ports
Non-Multiplexed
I/O
The major features of the PC8265A family are as follows:
•
Dual-issue integer core
A core version of the EC603e microprocessor
System core microprocessor supporting frequencies of 150 – 300 MHz
Separate 16-Kbyte data and instruction caches:
–
Four-way set associative
–
Physically addressed
–
LRU replacement algorithm
PowerPC architecture-compliant memory management unit (MMU)
Common on-chip processor (COP) test interface
2
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
High-performance (6.6 - 7.65 SPEC95 benchmark at 300 MHz; 1.68 MIPs/MHz
without inlining and 1.90 Dhrystones MIPS/MHz with inlining)
Supports bus snooping for data cache coherency
Floating-point unit (FPU)
•
Separate power supply for internal logic and for I/O
•
Separate PLLs for G2 core and for the CPM
G2 core and CPM can run at different frequencies for power/performance
optimization
Internal core/bus clock multiplier that provides 1.5:1, 2:1, 2.5:1, 3:1, 3.5:1, 4:1, 5:1,
6:1 ratios
Internal CPM/bus clock multiplier that provides 2:1, 2.5:1, 3:1, 3.5:1, 4:1, 5:1, 6:1
ratios
•
64-bit data and 32-bit address 60x bus
Bus supports multiple master designs
Supports single- and four-beat burst transfers
64-, 32-, 16-, and 8-bit port sizes controlled by on-chip memory controller
Supports data parity or ECC and address parity
•
32-bit data and 18-bit address local bus
Single-master bus, supports external slaves
Eight-beat burst transfers
32-, 16-, and 8-bit port sizes controlled by on-chip memory controller
•
60x-to-PCI bridge
Programmable host bridge and agent
32-bit data bus, 66 MHz, 3.3V
Synchronous and asynchronous 60x and PCI clock modes
All internal address space available to external PCI host
DMA for memory block transfers
PCI-to-60x address remapping
•
System interface unit (SIU)
Clock synthesizer
Reset controller
Real-time clock (RTC) register
Periodic interrupt timer
Hardware bus monitor and software watchdog timer
IEEE 1149.1 JTAG test access port
•
Twelve-bank memory controller
Glueless interface to SRAM, page mode SDRAM, DRAM, EPROM, Flash and other
user-definable peripherals
Byte write enables and selectable parity generation
32-bit address decoder with programmable bank size
Three user programmable machines, general-purpose chip-select machine, and
page-mode pipeline SDRAM machine
Byte selects of 64 bus width (60x) and byte selects for 32 bus width (local)
Dedicated interface logic for SDRAM
3
5336A–HIREL–08/03
•
CPU core can be disabled and the device can be used in slave mode to an external
core
•
Communications processor module (CPM)
Embedded 32-bit communications processor (CP) uses a RISC architecture for flexible support of communications protocols
Interfaces to G2 core through an on-chip 32-Kbyte dual-port RAM and DMA
controller
Serial DMA channels for receive and transmit on all serial channels
Parallel I/O registers with open-drain and interrupt capability
Virtual DMA functionality executing memory-to-memory and memory-to-I/O
transfers
Three fast communications controllers supporting the following protocols:
–
10/100-Mbit Ethernet/IEEE 802.3 CDMA/CS interface through a media
independent interface (MII)
–
ATM – Full-duplex SAR protocols at 155 Mbps, through UTOPIA interface,
AAL5, AAL1, AAL0 protocols, TM 4.0 CBR, VBR, UBR, ABR traffic types, up
to 16 K external connections
–
Transparent
–
HDLC – Up to T3 rates (clear channel)
Two multichannel controllers (MCCs)
–
Each MCC handles 128 serial, full-duplex, 64-Kbps data channels. Each
MCC can be split into four subgroups of 32 channels each
–
Almost any combination of subgroups can be multiplexed to single or
multiple TDM interfaces up to four TDM interfaces per MCC
Four serial communications controllers (SCCs) identical to those on the PC860,
supporting the digital portions of the following protocols:
–
Ethernet/IEEE 802.3 CDMA/CS
–
HDLC/SDLC and HDLC bus
–
Universal asynchronous receiver transmitter (UART)
–
Synchronous UART
–
Binary synchronous (BISYNC) communications
–
Transparent
Two serial management controllers (SMCs), identical to those of the PC860
–
Provides management for BRI devices as general circuit interface (GCI)
controllers in time-division-multiplexed (TDM) channels
–
Transparent
–
UART (low-speed operation)
One serial peripheral interface identical to the PC860 SPI
One inter-integrated circuit (I2C) controller (identical to the PC860 I2 C controller)
–
Microwire compatible
–
Multiple-master, single-master, and slave modes
Up to eight TDM interfaces
4
–
Supports two groups of four TDM channels for a total of eight TDMs
–
2,048 bytes of SI RAM
–
Bit or byte resolution
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
–
Independent transmit and receive routing, frame synchronization
–
Supports T1, CEPT, T1/E1, T3/E3, pulse code modulation highway, ISDN
basic rate, ISDN primary rate, Motorola interchip digital link (IDL), general
circuit interface (GCI), and user-defined TDM serial interfaces
Eight independent baud rate generators and 20 input clock pins for supplying clocks
to FCCs, SCCs, SMCs, and serial channels
Four independent 16-bit timers that can be interconnected as two 32-bit timers
•
CPM
32-Kbyte dual-port RAM
Additional MCC host commands
•
CPM multiplexing
FCC2 can also be connected to the TC layer
•
PCI bridge
PCI Specification Revision 2.2 compliant and supports frequencies up to 66 MHz
On-chip arbitration
Support for PCI to 60x memory and 60x memory to PCI streaming
PCI Host Bridge or Peripheral capabilities
Includes 4 DMA channels for the following transfers:
–
PCI-to-60x to 60x-to-PCI
–
60x-to-PCI to PCI-to-60x
–
PCI-to-60x to PCI-to-60x
–
60x-to-PCI to 60x-to-PCI
Includes all of the configuration registers (which are automatically loaded from the
EPROM and used to configure the PC8265A) required by the PCI standard as well
as message and doorbell registers
Supports the I2O standard
Hot-Swap friendly (supports the Hot Swap Specification as defined by PICMG 2.1
R1.0 August 3, 1998)
Support for 66 MHz, 3.3V specification
60x-PCI bus core logic which uses a buffer pool to allocate buffers for each port
Makes use of the local bus signals, so there is no need for additional pins
5
5336A–HIREL–08/03
Pinout
This section provides the pin assignments and pinout list for the PC8265A.
Pin Assignments
Figure 2 shows the pinout of the PC8265A’s 480 TBGA package as viewed from the top
surface.
Figure 2. Pinout of the 480 TBGA Package as Viewed from the Top Surface
1
2
3
4 5 6
7
8
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
1
2
3
4 5 6
7
8
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29
Not to Scale
6
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Figure 3 shows the side profile of the TBGA package to indicate the direction of the top
surface view.
Figure 3. Side View of the TBGA Package
View
Copper Heat Spreader
(Oxidized for Insulation)
Die
Attach
Polymide Tape
Etched
Cavity
Pressure Sensitive
Adhesive
Die
Soldermask
Glob-Top Filled Area
Glob-Top Dam
1.27 mm Pitch
Copper Traces
Table 1 shows the pinout list of the PC8265A. Table 2 on page 31 defines conventions
and acronyms used in Table 1.
Table 1. Pinout List
Pin Name
Ball
BR
W5
BG
F4
ABB
IRQ2
E2
TS
E3
A0
G1
A1
H5
A2
H2
A3
H1
A4
J5
A5
J4
A6
J3
A7
J2
A8
J1
A9
K4
A10
K3
A11
K2
A12
K1
A13
L5
A14
L4
A15
L3
A16
L2
7
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
8
Pin Name
Ball
A17
L1
A18
M5
A19
N5
A20
N4
A21
N3
A22
N2
A23
N1
A24
P4
A25
P3
A26
P2
A27
P1
A28
R1
A29
R3
A30
R5
A31
R4
TT0
F1
TT1
G4
TT2
G3
TT3
G2
TT4
F2
TBST
D3
TSIZ0
C1
TSIZ1
E4
TSIZ2
D2
TSIZ3
F5
AACK
F3
ARTRY
E1
DBG
V1
DBB
IRQ3
V2
D0
B20
D1
A18
D2
A16
D3
A13
D4
E12
D5
D9
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
D6
A6
D7
B5
D8
A20
D9
E17
D10
B15
D11
B13
D12
A11
D13
E9
D14
B7
D15
B4
D16
D19
D17
D17
D18
D15
D19
C13
D20
B11
D21
A8
D22
A5
D23
C5
D24
C19
D25
C17
D26
C15
D27
D13
D28
C11
D29
B8
D30
A4
D31
E6
D32
E18
D33
B17
D34
A15
D35
A12
D36
D11
D37
C8
D38
E7
D39
A3
D40
D18
D41
A17
9
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
10
Pin Name
Ball
D42
A14
D43
B12
D44
A10
D45
D8
D46
B6
D47
C4
D48
C18
D49
E16
D50
B14
D51
C12
D52
B10
D53
A7
D54
C6
D55
D5
D56
B18
D57
B16
D58
E14
D59
D12
D60
C10
D61
E8
D62
D6
D63
C2
DP0
RSRV
EXT_BR2
B22
IRQ1
DP1
EXT_BG2
A22
IRQ2
DP2
TLBISYNC
EXT_DBG2
E21
IRQ3
DP3
CKSTP_OUT
EXT_BR3
D21
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
IRQ4
DP4
CORE_SRESET
EXT_BG3
C21
IRQ5
DP5
TBEN
EXT_DBG3
B21
IRQ6
DP6
CSE0
A21
IRQ7
DP7
CSE1
E20
PSDVAL
V3
TA
C22
TEA
V5
GBL
IRQ1
W1
CI
BADDR29
IRQ2
U2
WT
BADDR30
IRQ3
U3
L2_HIT
IRQ4
Y4
CPU_BG
BADDR31
IRQ5
U4
CPU_DBG
R2
CPU_BR
Y3
CS0
F25
CS1
C29
CS2
E27
CS3
E28
CS4
F26
CS5
F27
CS6
F28
CS7
G25
11
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
12
Pin Name
Ball
CS8
D29
CS9
E29
CS10
BCTL1
F29
CS11
AP0
G28
BADDR27
T5
BADDR28
U1
ALE
T2
BCTL0
A27
PWE0
PSDDQM0
PBS0
C25
PWE1
PSDDQM1
PBS1
E24
PWE2
PSDDQM2
PBS2
D24
PWE3
PSDDQM3
PBS3
C24
PWE4
PSDDQM4
PBS4
B26
PWE5
PSDDQM5
PBS5
A26
PWE6
PSDDQM6
PBS6
B25
PWE7
PSDDQM7
PBS7
A25
PSDA10
PGPL0
E23
PSDWE
PGPL1
B24
POE
PSDRAS
PGPL2
A24
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PSDCAS
PGPL3
B23
PGTA
PUPMWAIT
PGPL4
PPBS
A23
PSDAMUX
PGPL5
D22
LWE0
LSDDQM0
LBS0
PCI_CFG0
H28
LWE1
LSDDQM1
LBS1
PCI_CFG1
H27
LWE2
LSDDQM2
LBS2
PCI_CFG2
H26
LWE3
LSDDQM3
LBS3
PCI_CFG3
G29
LSDA10
LGPL0
PCI_MODCKH0
D27
LSDWE
LGPL1
PCI_MODCKH1
C28
LOE
LSDRAS
LGPL2
PCI_MODCKH2
E26
LSDCAS
LGPL3
PCI_MODCKH3
D25
LGTA
LUPMWAIT
LGPL4
LPBS
C26
13
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
14
Pin Name
Ball
LGPL5
LSDAMUX
PCI_MODCK
B27
LWR
D28
L_A14
PAR
N27
L_A15
FRAME
SMI
T29
L_A16
TRDY
R27
L_A17
IRDY
CKSTP_OUT
R26
L_A18
STOP
R29
L_A19
DEVSEL
R28
L_A20
IDSEL
W29
L_A21
PERR
P28
L_A22
SERR
N26
L_A23
REQ0
AA27
L_A24
REQ1
HSEJSW
P29
L_A25
GNT0
AA26
L_A26
GNT1
HSLED
N25
L_A27
GNT2
HSENUM
AA25
L_A28
RST
CORE_SRESET
AB29
L_A29
INTA
AB28
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
L_A30
REQ2
P25
L_A31
DLLOUT
AB27
LCL_D0
AD0
H29
LCL_D1
AD1
J29
LCL_D2
AD2
J28
LCL_D3
AD3
J27
LCL_D4
AD4
J26
LCL_D5
AD5
J25
LCL_D6
AD6
K25
LCL_D7
AD7
L29
LCL_D8
AD8
L27
LCL_D9
AD9
L26
LCL_D10
AD10
L25
LCL_D11
AD11
M29
LCL_D12
AD12
M28
LCL_D13
AD13
M27
LCL_D14
AD14
M26
LCL_D15
AD15
N29
LCL_D16
AD16
T25
LCL_D17
AD17
U27
15
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
16
Pin Name
Ball
LCL_D18
AD18
U26
LCL_D19
AD19
U25
LCL_D20
AD20
V29
LCL_D21
AD21
V28
LCL_D22
AD22
V27
LCL_D23
AD23
V26
LCL_D24
AD24
W27
LCL_D25
AD25
W26
LCL_D26
AD26
W25
LCL_D27
AD27
Y29
LCL_D28
AD28
Y28
LCL_D29
AD29
Y25
LCL_D30
AD30
AA29
LCL_D31
AD31
AA28
LCL_DP0
C0
BE0
L28
LCL_DP1
C1
BE1
N28
LCL_DP2
C2
BE2
T28
LCL_DP3
C3
BE3
W28
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
IRQ0
NMI_OUT
T1
IRQ7
INT_OUT
APE
D1
TRST
AH3
TCK
AG5
TMS
AJ3
TDI
AE6
TDO
AF5
TRIS
AB4
PORESET
AG6
HRESET
AH5
SRESET
AF6
QREQ
AA3
RSTCONF
AJ4
MODCK1
AP1
TC0
BNKSEL0
W2
MODCK2
AP2
TC1
BNKSEL1
W3
MODCK3
AP3
TC2
BNKSEL2
W4
XFC
AB2
CLKIN1
AH4
PA0
RESTART1
DREQ3
FCC2_UTM_TXADDR2
AC29
PA1
REJECT1
FCC2_UTM_TXADDR1
DONE3
AC25
17
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
18
Pin Name
Ball
PA2
CLK20
FCC2_UTM_TXADDR0
DACK3
AE28
PA3
CLK19
FCC2_UTM_RXADDR0
DACK4
L1RXD1A2
AG29
PA4
REJECT2
FCC2_UTM_RXADDR1
DONE4
AG28
PA5
RESTART2
DREQ4
FCC2_UTM_RXADDR2
AG26
PA6
L1RSYNCA1
AE24
PA7
SMSYN2
L1TSYNCA1
L1GNTA1
AH25
PA8
SMRXD2
L1RXD0A1
L1RXDA1
AF23
PA9
SMTXD2
L1TXD0A1
AH23
PA10
FCC1_UT8_RXD0
FCC1_UT16_RXD8
MSNUM5
AE22
PA11
FCC1_UT8_RXD1
FCC1_UT16_RXD9
MSNUM4
AH22
PA12
FCC1_UT8_RXD2
FCC1_UT16_RXD10
MSNUM3
AJ21
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PA13
FCC1_UT8_RXD3
FCC1_UT16_RXD11
MSNUM2
AH20
PA14
FCC1_UT8_RXD4
FCC1_UT16_RXD12
FCC1_RXD3
AG19
PA15
FCC1_UT8_RXD5
FCC1_UT16_RXD13
FCC1_RXD2
AF18
PA16
FCC1_UT8_RXD6
FCC1_UT16_RXD14
FCC1_RXD1
AF17
PA17
FCC1_UT8_RXD7
FCC1_UT16_RXD15
FCC1_RXD0
FCC1_RXD
AE16
PA18
FCC1_UT8_TXD7
FCC1_UT16_TXD15
FCC1_TXD0
FCC1_TXD
AJ16
PA19
FCC1_UT8_TXD6
FCC1_UT16_TXD14
FCC1_TXD1
AG15
PA20
FCC1_UT8_TXD5
FCC1_UT16_TXD13
FCC1_TXD2
AJ13
PA21
FCC1_UT8_TXD4
FCC1_UT16_TXD12
FCC1_TXD3
AE13
PA22
FCC1_UT8_TXD3
FCC1_UT16_TXD11
AF12
PA23
FCC1_UT8_TXD2
FCC1_UT16_TXD10
AG11
19
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
20
Pin Name
Ball
PA24
FCC1_UT8_TXD1
FCC1_UT16_TXD9
MSNUM1
AH9
PA25
FCC1_UT8_TXD0
FCC1_UT16_TXD8
MSNUM0
AJ8
PA26
FCC1_UTM_RXCLAV
FCC1_UTS_RXCLAV
FCC1_MII_RX_ER
AH7
PA27
FCC1_UT_RXSOC
FCC1_MII_RX_DV
AF7
PA28
FCC1_UTM_RXENB
FCC1_UTS_RXENB
FCC1_MII_TX_EN
AD5
PA29
FCC1_UT_TXSOC
FCC1_MII_TX_ER
AF1
PA30
FCC1_UTM_TXCLAV
FCC1_UTS_TXCLAV
FCC1_MII_CRS
FCC1_RTS
AD3
PA31
FCC1_UTM_TXENB
FCC1_UTS_TXENB
FCC1_MII_COL
AB5
PB4
FCC3_TXD3
FCC2_UT8_RXD0
L1RSYNCA2
FCC3_RTS
AD28
PB5
FCC3_TXD2
FCC2_UT8_RXD1
L1TSYNCA2
L1GNTA2
AD26
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PB6
FCC3_TXD1
FCC2_UT8_RXD2
L1RXDA2
L1RXD0A2
AD25
PB7
FCC3_TXD0
FCC3_TXD
FCC2_UT8_RXD3
L1TXDA2
L1TXD0A2
AE26
PB8
FCC2_UT8_TXD3
FCC3_RXD0
FCC3_RXD
TXD3
L1RSYNCD1
AH27
PB9
FCC2_UT8_TXD2
FCC3_RXD1
L1TXD2A2
L1TSYNCD1
L1GNTD1
AG24
PB10
FCC2_UT8_TXD1
FCC3_RXD2
L1RXDD1
AH24
PB11
FCC3_RXD3
FCC2_UT8_TXD0
L1TXDD1
AJ24
PB12
FCC3_MII_CRS
L1CLKOB1
L1RSYNCC1
TXD2
AG22
PB13
FCC3_MII_COL
L1RQB1
L1TSYNCC1
L1GNTC1
L1TXD1A2
AH21
21
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
22
Pin Name
Ball
PB14
FCC3_MII_TX_EN
RXD3
L1RXDC1
AG20
PB15
FCC3_MII_TX_ER
RXD2
L1TXDC1
AF19
PB16
FCC3_MII_RX_ER
L1CLKOA1
CLK18
AJ18
PB17
FCC3_MII_RX_DV
L1RQA1
CLK17
AJ17
PB18
FCC2_UT8_RXD4
FCC2_RXD3
L1CLKOD2
L1RXD2A2
AE14
PB19
FCC2_UT8_RXD5
FCC2_RXD2
L1RQD2
L1RXD3A2
AF13
PB20
FCC2_UT8_RXD6
FCC2_RXD1
L1RSYNCD2
L1TXD1A1
AG12
PB21
FCC2_UT8_RXD7
FCC2_RXD0
FCC2_RXD
L1TSYNCD2
L1GNTD2
L1TXD2A1
AH11
PB22
FCC2_UT8_TXD7
FCC2_TXD0
FCC2_TXD
L1RXD1A1
L1RXDD2
AH16
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PB23
FCC2_UT8_TXD6
FCC2_TXD1
L1RXD2A1
L1TXDD2
AE15
PB24
FCC2_UT8_TXD5
FCC2_TXD2
L1RXD3A1
L1RSYNCC2
AJ9
PB25
FCC2_UT8_TXD4
FCC2_TXD3
L1TSYNCC2
L1GNTC2
L1TXD3A1
AE9
PB26
FCC2_MII_CRS
FCC2_UT8_TXD1
L1RXDC2
AJ7
PB27
FCC2_MII_COL
FCC2_UT8_TXD0
L1TXDC2
AH6
PB28
FCC2_MII_RX_ER
FCC2_RTS
L1TSYNCB2
L1GNTB2
TXD1
AE3
PB29
FCC2_UTM_RXCLAV
FCC2_UTS_RXCLAV
L1RSYNCB2
FCC2_MII_TX_EN
AE2
PB30
FCC2_MII_RX_DV
FCC2_UT_TXSOC
L1RXDB2
AC5
PB31
FCC2_MII_TX_ER
FCC2_UT_RXSOC
L1TXDB2
AC4
23
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
24
Pin Name
Ball
PC0
DREQ1
BRGO7
SMSYN2
L1CLKOA2
AB26
PC1
DREQ2
BRGO6
L1RQA2
AD29
PC2
FCC3_CD
FCC2_UT8_TXD3
DONE2
AE29
PC3
FCC3_CTS
FCC2_UT8_TXD2
DACK2
CTS4
AE27
PC4
FCC2_UTM_RXENB
FCC2_UTS_RXENB
SI2_L1ST4
FCC2_CD
AF27
PC5
FCC2_UTM_TXCLAV
FCC2_UTS_TXCLAV
SI2_L1ST3
FCC2_CTS
AF24
PC6
FCC1_CD
L1CLKOC1
FCC1_UTM_RXADDR2
FCC1_UTS_RXADDR2
FCC1_UTM_RXCLAV1
AJ26
PC7
FCC1_CTS
L1RQC1
FCC1_UTM_TXADDR2
FCC1_UTS_TXADDR2
FCC1_UTM_TXCLAV1
AJ25
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PC8
CD4
RENA4
FCC1_UT16_TXD0
SI2_L1ST2
CTS3
AF22
PC9
CTS4
CLSN4
FCC1_UT16_TXD1
SI2_L1ST1
L1TSYNCA2
L1GNTA2
AE21
PC10
CD3
RENA3
FCC1_UT16_TXD2
SI1_L1ST4
FCC2_UT8_RXD3
AF20
PC11
CTS3
CLSN3
L1CLKOD1
L1TXD3A2
FCC2_UT8_RXD2
AE19
PC12
CD2
RENA2
SI1_L1ST3
FCC1_UTM_RXADDR1
FCC1_UTS_RXADDR1
AE18
PC13
CTS2
CLSN2
L1RQD1
FCC1_UTM_TXADDR1
FCC1_UTS_TXADDR1
AH18
PC14
CD1
RENA1
FCC1_UTM_RXADDR0
FCC1_UTS_RXADDR0
AH17
25
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
26
Pin Name
Ball
PC15
CTS1
CLSN1
SMTXD2
FCC1_UTM_TXADDR0
FCC1_UTS_TXADDR0
AG16
PC16
CLK16
TIN4
AF15
PC17
CLK15
TIN3
BRGO8
AJ15
PC18
CLK14
TGATE2
AH14
PC19
CLK13
BRGO7
AG13
PC20
CLK12
TGATE1
AH12
PC21
CLK11
BRGO6
AJ11
PC22
CLK10
DONE1
AG10
PC23
CLK9
BRGO5
DACK1
AE10
PC24
FCC2_UT8_TXD3
CLK8
TOUT4
AF9
PC25
FCC2_UT8_TXD2
CLK7
BRGO4
AE8
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PC26
CLK6
TOUT3
TMCLK
AJ6
PC27
FCC3_TXD
FCC3_TXD0
CLK5
BRGO3
AG2
PC28
CLK4
TIN1
TOUT2
CTS2
CLSN2
AF3
PC29
CLK3
TIN2
BRGO2
CTS1
CLSN1
AF2
PC30
FCC2_UT8_TXD3
CLK2
TOUT1
AE1
PC31
CLK1
BRGO1
AD1
PD4
BRGO8
L1TSYNCD1
L1GNTD1
FCC3_RTS
SMRXD2
AC28
PD5
FCC1_UT16_TXD3
DONE1
AD27
PD6
FCC1_UT16_TXD4
DACK1
AF29
27
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
28
Pin Name
Ball
PD7
SMSYN1
FCC1_UTM_TXADDR3
FCC1_UTS_TXADDR3
FCC1_TXCLAV2
AF28
PD8
SMRXD1
FCC2_UT_TXPRTY
BRGO5
AG25
PD9
SMTXD1
FCC2_UT_RXPRTY
BRGO3
AH26
PD10
L1CLKOB2
FCC2_UT8_RXD1
L1RSYNCB1
BRGO4
AJ27
PD11
L1RQB2
FCC2_UT8_RXD0
L1TSYNCB1
L1GNTB1
AJ23
PD12
SI1_L1ST2
L1RXDB1
AG23
PD13
SI1_L1ST1
L1TXDB1
AJ22
PD14
FCC1_UT16_RXD0
L1CLKOC2
I2CSCL
AE20
PD15
FCC1_UT16_RXD1
L1RQC2
I2CSDA
AJ20
PD16
FCC1_UT_TXPRTY
L1TSYNCC1
L1GNTC1
SPIMISO
AG18
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Pin Name
Ball
PD17
FCC1_UT_RXPRTY
BRGO2
SPIMOSI
AG17
PD18
FCC1_UTM_RXADDR4
FCC1_UTS_RXADDR4
FCC1_UTM_RXCLAV3
SPICLK
AF16
PD19
FCC1_UTM_TXADDR4
FCC1_UTS_TXADDR4
FCC1_UTM_TXCLAV3
SPISEL
BRGO1
AH15
PD20
RTS4
TENA4
FCC1_UT16_RXD2
L1RSYNCA2
AJ14
PD21
TXD4
FCC1_UT16_RXD3
L1RXD0A2
L1RXDA2
AH13
PD22
RXD4
FCC1_UT16_TXD5
L1TXD0A2
L1TXDA2
AJ12
PD23
RTS3
TENA3
FCC1_UT16_RXD4
L1RSYNCD1
AE12
PD24
TXD3
FCC1_UT16_RXD5
L1RXDD1
AF10
PD25
RXD3
FCC1_UT16_TXD6
L1TXDD1
AG9
29
5336A–HIREL–08/03
Table 1. Pinout List (Continued)
Pin Name
Ball
PD26
RTS2
TENA2
FCC1_UT16_RXD6
L1RSYNCC1
AH8
PD27
TXD2
FCC1_UT16_RXD7
L1RXDC1
AG7
PD28
RXD2
FCC1_UT16_TXD7
L1TXDC1
AE4
PD29
RTS1
TENA1
FCC1_UTM_RXADDR3
FCC1_UTS_RXADDR3
FCC1_UTM_RXCLAV2
AG1
PD30
FCC2_UTM_TXENB
FCC2_UTS_TXENB
TXD1
AD4
PD31
RXD1
AD2
SYN
AB3
SYN1
B9
GNDSYN
AB1
CLKIN2(1)
AE11
(2)
SPARE4
(3)
PCI_MODE
AF25
SPARE6(2)
V4
THERMAL0(4)
AA1
(4)
AG4
THERMAL1
30
U5
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 1. Pinout List (Continued)
Notes:
Pin Name
Ball
I/O Power
AG21, AG14, AG8, AJ1, AJ2, AH1, AH2,
AG3, AF4, AE5, AC27, Y27, T27, P27, K26,
G27, AE25, AF26, AG27, AH28, AH29, AJ28,
AJ29, C7, C14, C16, C20, C23, E10, A28,
A29, B28, B29, C27, D26, E25, H3, M4, T3,
AA4, A1, A2, B1, B2, C3, D4, E5
Core Power
U28, U29, K28, K29, A9, A19, B19, M1, M2,
Y1, Y2, AC1, AC2, AH19, AJ19, AH10, AJ10,
AJ5
Ground
AA5, AF21, AF14, AF8, AE7, AF11, AE17,
AE23, AC26, AB25, Y26, V25, T26, R25,
P26, M25, K27, H25, G26, D7, D10, D14,
D16, D20, D23, C9, E11, E13, E15, E19, E22,
B3, G5, H4, K5, M3, P5, T4, Y5, AA2, AC3
1. This pin should be used as CLKIN2
2. Must be pulled down or left floating
3. This pin should be asserted if the PCI function is desired or pulled up or left floating if
PCI is not desired
4. For information on how to use this pin, refer to MPC8260 PowerQUICC II Thermal
Resistor Guide available at www.motorola.com/semiconductors
Symbols used in Table 1 are described in Table 2.
Table 2. Symbol Legend
Symbol
Meaning
OVERBAR
Signals with overbars, such as TA, are active low
UTM
Indicates that a signal is part of the UTOPIA master interface
UTS
Indicates that a signal is part of the UTOPIA slave interface
UT8
Indicates that a signal is part of the 8-bit UTOPIA interface
UT16
Indicates that a signal is part of the 16-bit UTOPIA interface
MII
Indicates that a signal is part of the media independent interface
31
5336A–HIREL–08/03
Electrical and Thermal
Characteristics
This section provides AC and DC electrical specifications and thermal characteristics for
the PC8265A.
DC Electrical Characteristics
This section describes the DC electrical characteristics for the PC8265A. Table 3 shows
the maximum electrical ratings.
Table 3. Absolute Maximum Ratings(1)
Rating
Symbol
Value
Unit
VDD
-0.3 – +2.5
V
PLL supply voltage(2)
SYN
-0.3 – +2.5
V
I/O supply voltage(3)
Core supply voltage
(2)
VDDH
-0.3 – +4.0
V
(4)
VIN
GND(-0.3) – +3.6
V
Storage temperature range
TSTG
-55 – +150
°C
Input voltage
Notes:
1. Absolute maximum ratings are stress ratings only; functional operation (see Table 4)
at the maximums is not guaranteed. Stress beyond those listed may affect device
reliability or cause permanent damage.
2. Caution: VDD/SYN must not exceed VDDH by more than 0.4V at any time, including
during power-on reset.
3. Caution: VDDH can exceed VDD/SYN by 3.3V during power on reset by no more than
100 ms. VDDH should not exceed VDD/SYN by more than 2.5V during normal
operation.
4. Caution: VIN must not exceed VDDH by more than 2.5V at any time, including during
power-on reset.
Table 4 lists recommended operational voltage conditions.
Table 4. Recommended Operating Conditions(1)
Rating
Symbol
Unit
VDD
1.7 – 1.9(2)
1.7 – 2.1(3)
1.9 – 2.2(4)
V
PLL supply voltage
SYN
(2)
(3)
(4)
V
CPU minimum frequency
Fmin
I/O supply voltage
VDDH
3.135 – 3.465
V
Input voltage
VIN
GND (-0.3) – 3.465
V
Tcase
TC
-55 – +125
°C
Core supply voltage
32
Value
1.7 – 1.9
150
1.7 – 2.1
1.9 – 2.2
190
190
MHz
Notes:
1. Caution: These are the recommended and tested operating conditions. Proper device
operation outside of these conditions is not guaranteed
2. CPU frequency less than or equal to 200 MHz
3. CPU frequency greater than 200 MHz but less than or equal 233 MHz
4. CPU frequency greater than 233 MHz
Note:
VDDH and VDD must track each other and both must vary in the same direction – in the
positive direction (+5% and +0.1 VDC) or in the negative direction (-5% and -0.1 VDC).
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
This device contains circuitry protection against damage due to high static voltage or
electrical fields; however, it is advised that normal precautions be taken to avoid application of any voltages higher than maximum-rated voltages. Reliability of operation is
enhanced if unused inputs are tied to an appropriate logic voltage level (either GND or
VCC).
Table 5 shows DC Electrical Characteristics
Table 5. DC Electrical Characteristics
Characteristic
Symbol
Min
Max
Unit
Input high voltage, all inputs except CLKIN
VIH
2.0
3.465
V
Input low voltage
VIL
GND
0.8
V
CLKIN input high voltage
VIHC
2.4
3.465
V
CLKIN input low voltage
VILC
GND
0.4
V
Input leakage current, VIN = VDDH
IIN
–
10
µA
Hi-Z (off state) leakage current, VIN = VDDH
IOZ
–
10
µA
Signal low input current, VIL = 0.8V
IL
–
1
µA
Signal high input current, VIH = 2.0V
IH
–
1
µA
Output high voltage, IOH = -2 mA
except XFC, UTOPIA mode, and open drain pins
In UTOPIA mode: IOH = -8.0 mA
PA[0-31]
PB[4-31]
PC[0-31]
PD[4-31]
VOH
2.4
–
V
In UTOPIA mode: IOL = 8.0 mA
PA[0-31]
PB[4-31]
PC[0-31]
PD[4-31]
VOL
–
0.5
V
IOL = 7.0 mA
BR
BG
ABB/IRQ2
TS
A[0-31]
TT[0-4]
TBST
TSIZE[0–3]
AACK
ARTRY
DBG
VOL
–
0.4
V
33
5336A–HIREL–08/03
Table 5. DC Electrical Characteristics (Continued)
Characteristic
Symbol
Min
Max
Unit
VOL
–
0.4
V
DBB/IRQ3
D[0-63]
DP(0)/RSRV/EXT_BR2
DP(1)/IRQ1/EXT_BG2
DP(2)/TLBISYNC/IRQ2/EXT_DBG2
DP(3)/IRQ3/EXT_BR3/CKSTP_OUT
DP(4)/IRQ4/EXT_BG3/CORE_SREST
DP(5)/TBEN/IRQ5/EXT_DBG3
DP(6)/CSE(0)/IRQ6
DP(7)/CSE(1)/IRQ7
PSDVAL
TA
TEA
GBL/IRQ1
CI/BADDR29/IRQ2
WT/BADDR30/IRQ3
L2_HIT/IRQ4
CPU_BG/BADDR31/IRQ5
CPU_DBG
CPU_BR
IRQ0/NMI_OUT
IRQ7/INT_OUT/APE
PORESET
HRESET
SRESET
RSTCONF
QREQ
IOL = 5.3 mA
CS[0-9]
CS(10)/BCTL1
CS(11)/AP(0)
BADDR[27–28]
ALE
BCTL0
PWE(0:7)/PSDDQM(0:7)/PBS(0:7)
PSDA10/PGPL0
PSDWE/PGPL1
POE/PSDRAS/PGPL2
PSDCAS/PGPL3
PGTA/PUPMWAIT/PGPL4/PPBS
PSDAMUX/PGPL5
LWE[0–3]LSDDQM[0–3]/LBS[0–3]/PCI_CFG[0–3(1)
LSDA10/LGPL0/PCI_MODCKH0(1)
LSDWE/LGPL1/PCI_MODCKH1(1)
34
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 5. DC Electrical Characteristics (Continued)
Characteristic
Symbol
Min
Max
Unit
LOE/LSDRAS/LGPL2/PCI_MODCKH2(1)
LSDCAS/LGPL3/PCI_MODCKH3(1)
LGTA/LUPMWAIT/LGPL4/LPBS
LSDAMUX/LGPL5/PCI_MODCK(1)
LWR
MODCK1/AP(1)/TC(0)/BNKSEL(0)
MODCK2/AP(2)/TC(1)/BNKSEL(1)
MODCK3/AP(3)/TC(2)/BNKSEL(2)
IOL = 3.2 mA
L_A14/PAR(1)
L_A15/FRAME(1)/SMI
L_A16/TRDY(1)
L_A17/IRDY(1)/CKSTP_OUT
L_A18/STOP(1)
L_A19/DEVSEL(1)
L_A20/IDSEL(1)
L_A21/PERR(1)
L_A22/SERR(1)
L_A23/REQ0(1)
L_A24/REQ1(1)/HSEJSW(1)
L_A25/GNT0(1)
L_A26/GNT1(1)/HSLED(1)
L_A27/GNT2(1)/HSENUM(1)
L_A28/RST(1)/CORE_SRESET
L_A29/INTA(1)
L_A30/REQ2(1)
L_A31
LCL_D(0-31)/AD(0-31)(1)
LCL_DP(0-3)/C/BE(0-3)(1)
PA[0–31]
PB[4–31]
PC[0–31]
PD[4–31]
TDO
Note:
1. The leakage current is measured for nominal VDDH and VDD or both VDDH and VDD
must vary in the same direction; that is, VDDH and VDD either both vary in the positive
direction (+5% and +0.1 VDC) or both vary in the negative direction
(-5% and -0.1 VDC)
35
5336A–HIREL–08/03
Thermal Characteristics
Table 6 describes thermal characteristics.
Table 6. Thermal Characteristics for the 480 TBGA Package
Characteristics
Symbol
Junction to ambient
Unit
Air Flow
°C/W
NC(2)
ΘJA
13.07
ΘJA
9.55(1)
°C/W
1 m/s
ΘJA
10.48(3)
°C/W
NC
(1)
ΘJA
7.78
°C/W
1 m/s
Junction to board
ΘJB
6
°C/W
–
Junction to case(5)
ΘJC
2
°C/W
–
(4)
Notes:
Power Considerations
Value
(3)
1.
2.
3.
4.
Assumes a single layer board with no thermal vias
Natural convection
Assumes a four layer board
Thermal resistance between the die and the printed circuit board per JEDEC
JESD51-8. Board temperature is measured on the top surface of the board near the
package
5. Thermal resistance between the die and the case top surface as measured by the
cold plate method (MIL SPEC-883 Method 1012.1)
The average chip-junction temperature, TJ, in °C can be obtained from the following:
TJ = TA + (PD x ΘJA)
(1)
where
TA = ambient temperature °C
ΘJA = package thermal resistance, junction to ambient, °C/W
PD = PINT + PI/O
PINT = IDD x VDD Watts (chip internal power)
PI/O = power dissipation on input and output pins (determined by user)
For most applications PI/O < 0.3 x PINT. If PI/O is neglected, an approximate relationship
between PD and TJ is as follows:
PD = K/(TJ + 273°C)
(2)
Solving equations (1) and (2) for K gives:
K = PD x (TA + 273°C) + ΘJA x PD2
(3)
where K is a constant pertaining to the particular part. K can be determined from equation (3) by measuring P D (at equilibrium) for a known T A. Using this value of K, the
values of PD and TJ can be obtained by solving equations (1) and (2) iteratively for any
value of TA.
36
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Layout Practices
Each pin should be provided with a low-impedance path to the board’s power supply.
Each ground pin should likewise be provided with a low-impedance path to ground. The
power supply pins drive distinct groups of logic on the chip. The power supply should be
bypassed to ground using at least four 0.1 µF by-pass capacitors located as close as
possible to the four sides of the package. The capacitor leads and associated printed
circuit traces connecting to the chip and ground should be kept to less than half an inch
per capacitor lead. A four-layer board is recommended, employing two inner layers as
GND planes.
All output pins on the PC8265A have fast rise and fall times. Printed circuit (PC) trace
interconnection length should be minimized in order to minimize overdamped conditions
and reflections caused by these fast output switching times. This recommendation particularly applies to the address and data buses.
Maximum PC trace lengths of six inches are recommended. Capacitance calculations
should consider all device loads as well as parasitic capacitances due to the PC traces.
Attention to proper PCB layout and bypassing becomes especially critical in systems
with higher capacitive loads because these loads create higher transient currents in the
GND circuits. Pull up all unused inputs or signals that will be inputs during reset. Special
care should be taken to minimize the noise levels on the PLL supply pins.
Table 7 provides preliminary, estimated power dissipation for various configurations.
Note that suitable thermal management is required for conditions above PD = 3W (when
the ambient temperature is 70°C or greater) to ensure the junction temperature does not
exceed the maximum specified value. Also note that the I/O power should be included
when determining whether to use a heat sink.
Table 7. Estimated Power Dissipation for Various Configurations(1)
PINT(W)(2)
Vddl 1.8 Volts
Vddl 2.0 Volts
Bus (MHz)
CPM
Multiplier
Core CPU
Multiplier
CPM (MHz)
CPU (MHz)
Nominal
Maximum
Nominal
Maximum
66.66
2
3
133
200
1.2
2
1.8
2.3
66.66
2.5
3
166
200
1.3
2.1
1.9
2.3
66.66
3
4
200
266
–
–
2.3
2.9
66.66
3
4.5
200
300
–
–
2.4
3.1
83.33
2
3
166
250
–
–
2.2
2.8
83.33
2
3
166
250
–
–
2.2
2.8
83.33
2.5
3.5
208
291
–
–
2.4
3.1
Notes:
1. Test temperature = room temperature (25°C)
2. PINT = IDD x VDD Watts (chip internal power)
37
5336A–HIREL–08/03
AC Electrical
Characteristics
The following sections include illustrations and tables of clock diagrams, signals, and
CPM outputs and inputs for the 66 MHz PC8265A device. Note that AC timings are
based on a 50-pf load. Typical output buffer impedances are shown in Table 8.
Table 8. Output Buffer Impedances(1)
Note:
Output Buffers
Typical Impedance (Ω)
60x bus
40
Local bus
40
Memory Controller
40
Parallel I/O
46
PCI
25
1. These are typical values at 65°C. The impedance may vary by ±25% with process
and temperature.
Table 9 lists CPM output characteristics.
Table 9. AC Characteristics for CPM Outputs(1)
Max Delay (ns)
Spec_num Max/Min
66 MHz
83 MHz
66 MHz
83 MHz
sp36a/sp37a
FCC outputs – internal clock (NMSI)
6
5.5
1
1
sp36b/sp37b
FCC outputs – external clock (NMSI)
14
12
2
1
sp38a/sp39a
SCC/SMC/SPI/I2C outputs – internal clock (NMSI)
19
16
1
0.5
sp38b/sp39b
Ex_SCC/SMC/SPI/I2C outputs – external clock (NMSI)
19
16
2
1
TIMER/IDMA outputs
14
11
1
0.5
PIO outputs
14
11
0.5
0.5
sp42/sp43
sp42a/sp43a
Note:
Characteristic
Min Delay (ns)
1. Output specifications are measured from the 50% level of the rising edge of CLKIN to the 50% level of the signal. Timings
are measured at the pin.
Table 10 lists CPM input characteristics.
Table 10. AC Characteristics for CPM Inputs(1)
Setup (ns)
Spec_num
Characteristic
sp16a/sp17a
Hold (ns)
66 MHz
83 MHz
66 MHz
83 MHz
FCC inputs – internal clock (NMSI)
10
8
0
0
sp16b/sp17b
FCC inputs – external clock (NMSI)
3
2.5
3
2
sp20/sp21
TDM inputs/SI
15
12
12
10
sp18a/sp19a
SCC/SMC/SPI/I2C inputs – internal clock (NMSI)
20
16
0
0
sp18b/sp19b
SCC/SMC/SPI/I2C inputs – external clock (NMSI)
5
4
5
4
sp22/sp23
PIO/TIMER/IDMA inputs
10
8
3
3
Note:
1. Input specifications are measured from the 50% level of the signal to the 50% level of the rising edge of CLKIN. Timings are
measured at the pin.
Note that although the specifications generally reference the rising edge of the clock, the following AC timing diagrams also
apply when the falling edge is the active edge.
38
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Figure 4 shows the FCC external clock.
Figure 4. FCC External Clock Diagram
Serial ClKin
sp17b
sp16b
FCC input signals
sp36b/sp37b
FCC output signals
when GFMR[TCI] = 0
sp36b/sp37b
FCC output signals
when GFMR[TCI] = 1
Figure 5 shows the FCC internal clock.
Figure 5. FCC Internal Clock Diagram
BRG_OUT
sp17a
sp16a
FCC input signals
sp36a/sp37a
FCC output signals
when GFMR.TCI = 0
sp36a/sp37a
FCC output signals
when GFMR.TCI = 1
39
5336A–HIREL–08/03
Figure 6 shows the SCC/SMC/SPI/I2C external clock.
Figure 6. SCC/SMC/SPI/I2C External Clock Diagram
Serial CLKin
sp19b
SCC/SMC/SPI/I2C input signals
(See note.)
sp18b
sp38b/sp39b
SCC/SMC/SPI/I2C output signals
(See note.)
Note:
The clock edge is selectable on SCC and SPI.
Figure 7 shows the SCC/SMC/SPI/I2C internal clock.
Figure 7. SCC/SMC/SPI/I2C Internal Clock Diagram
BRG_OUT
sp19a
sp18a
SCC/SMC/SPI/I2C input signals
(See note.)
sp38a/sp39a
SCC/SMC/SPI/I2C output signals
(See note.)
Note:
The clock edge is selectable on SCC and SPI
Figure 8 shows TDM input and output signals.
Figure 8. TDM Signals Diagram
Serial CLKin
sp20
sp21
TDM input signals
sp40/sp41
TDM output signals
There are four possible TDM timing conditions:
1. Input sampled on the rising edge and output driven on the rising edge (shown)
2. Input sampled on the rising edge and output driven on the falling edge
3. Input sampled on the falling edge and output driven on the falling edge
4. Input sampled on the falling edge and output driven on the rising edge
40
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Figure 9 shows PIO, timer, and DMA signals.
Figure 9. PIO, Timer, and DMA Signal Diagram
CLKin
sp23
sp22
PIO/TIMER/IDMA input signals
sp42/sp43
TIMER/IDMA output signals
sp42a/sp43a
PIO output signals
Table 11 lists SIU input characteristics.
Table 11. AC Characteristics for SIU Inputs(1)
Setup (ns)
Spec_num
Characteristic
sp11/sp10
Hold (ns)
66 MHz
83 MHz
66 MHz
83 MHz
AACK/ARTRY/TA/TS/TEA/DBG/BG/BR
6
5
1
1
sp12/sp10
Data bus in normal mode
5
4
1
1
sp13/sp10
Data bus in ECC and PARITY modes
8
6
1
1
sp14/sp10
DP pins
7
6
1
1
sp15/sp10
All other pins
5
4
1
1
Note:
1. Input specifications are measured from the 50% level of the signal to the 50% level of the rising edge of CLKIN. Timings are
measured at the pin.
41
5336A–HIREL–08/03
Table 12 lists SIU output characteristics.
Table 12. AC Characteristics for SIU Outputs(1)
Setup (ns)
Spec_num Max/Min
Note:
42
Characteristic
Hold (ns)
66 MHz
83 MHz
66 MHz
83 MHz
sp31/sp30
PSDVAL/TEA/TA
7
6
0.5
0.5
sp32/sp30
ADD/ADD_atr./BADDR/CI/GBL/WT
8
6.5
0.5
0.5
sp33a/sp30
Data bus
6.5
6.5
0.5
0.5
sp33b/sp30
DP
8
7
0.5
0.5
sp34/sp30
Memory controller signals/ALE
6
5
0.5
0.5
sp35/sp30
All other signals
6
5.5
0.5
0.5
1. Output specifications are measured from the 50% level of the rising edge of CLKIN to the 50% level of the signal. Timings
are measured at the pin.
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Figure 10 shows the interaction of several bus signals.
Figure 10. Bus Signals
CLKin
sp10
sp11
AACK/ARTRY/TA/TS/TEA/
DBG/BG/BR input signals
sp10
sp12
DATA bus normal mode
input signal
sp10
SP15
All other input signals
SP31
sp30
PSDVAL/TEA/TA output signals
SP32
ADD/ADD_atr/BADDR/CI/
GBL/WT output signals
sp30
SP33a
sp30
DATA bus output signals
SP35
sp30
All other output signals
Note:
Activating data pipelining (setting BR x [DR] in the memory controller) improves the AC timing. When data pipelining is activated, sp12 can be used for data bus setup even when ECC or PARITY are used. Also, sp33a can be used as the AC
specification for DP signals.
43
5336A–HIREL–08/03
Figure 11 shows signal behavior for all parity modes (including ECC, RMW parity, and standard parity).
Figure 11. Parity Mode Diagram
CLKin
sp10
sp13
DATA bus, ECC, and PARITY mode input signals
sp10
sp14
DP mode input signal
sp33b/sp10
DP mode output signal
Figure 12 shows signal behavior in MEMC mode.
Figure 12. MEMC Mode Diagram
CLKin
V_CLK
sp34/sp30
Memory controller signals
Note:
Generally, all PC8265A bus and system output signals are driven from the rising edge of
the input clock (CLKin). Memory controller signals, however, trigger on four points within
a CLKin cycle. Each cycle is divided by four internal ticks: T1, T2, T3, and T4. T1 always
occurs at the rising edge, and T3 at the falling edge, of CLKin. However, the spacing of
T2 and T4 depends on the PLL clock ratio selected, as shown in Table 13.
Table 13. Tick Spacing for Memory Controller Signals
Tick Spacing (T1 Occurs at the Rising Edge of CLKin)
PLL Clock Ratio
44
T2
T3
T4
1:2, 1:3, 1:4, 1:5, 1:6
1/4 CLKin
1/2 CLKin
3/4 CLKin
1:2.5
3/10 CLKin
1/2 CLKin
8/10 CLKin
1:3.5
4/14 CLKin
1/2 CLKin
11/14 CLKin
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Figure 13 is a graphical representation of Table 13.
Figure 13. Internal Tick Spacing for Memory Controller Signals
CLKin
for 1:2, 1:3, 1:4, 1:5, 1:6
T1
T2
T3
T4
CLKin
for 1:2.5
T1
T2
T3
T4
for 1:3.5
CLKin
T1
Note:
T2
T3
T4
The UPM machine outputs change on the internal tick determined by the memory controller programming; the AC specifications are relative to the internal tick. Note that
SDRAM and GPCM machine outputs change on CLKin’s rising edge.
45
5336A–HIREL–08/03
Clock Configuration
Modes
To configure the main PLL multiplication factor and the core, the CPM, and 60x bus frequencies, the MODCK[1:3] pins are sampled while HRESET is asserted. Table 14
shows the eight basic configuration modes. Another 49 modes are available by using
the configuration pin (RSTCONF) and driving four pins on the data bus.
Local Bus Mode
Table 14 describes default clock modes for the PC8265A.
Table 14. Clock Default Modes
MODCK[1–3]
Input Clock
Frequency
(MH)z
CPM
Multiplication
Factor
CPM Frequency
(MHz)
Core
Multiplication
Factor
Core Frequency
(MHz)
000
33
3
100
4
133
001
33
3
100
5
166
010
33
4
133
4
133
011
33
4
133
5
166
100
66
2
133
2.5
166
101
66
2
133
3
200
110
66
2.5
166
2.5
166
111
66
2.5
166
3
200
Table 15 describes all possible clock configurations when using the hard reset configuration sequence.
Note that the clock configuration changes only after POR is asserted. Note also that basic modes are shown in boldface
type.
Table 15. Clock Configuration Modes(1)
MODCK_H–MODCK[1–3]
Input Clock
Frequency(2)(3)
(MHz)
CPM
Multiplication
Factor(2)
CPM
Frequency(2)
(MHz)
Core
Multiplication
Factor(2)
Core
Frequency(2)
(MHz)
0001_000
33
2
66
4
133
0001_001
33
2
66
5
166
0001_010
33
2
66
6
200
0001_011
33
2
66
7
233
0001_100
33
2
66
8
266
0001_101
33
3
100
4
133
0001_110
33
3
100
5
166
0001_111
33
3
100
6
200
0010_000
33
3
100
7
233
0010_001
33
3
100
8
266
0010_010
33
4
133
4
133
0010_011
33
4
133
5
166
46
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 15. Clock Configuration Modes(1) (Continued)
MODCK_H–MODCK[1–3]
Input Clock
Frequency(2)(3)
(MHz)
CPM
Multiplication
Factor(2)
CPM
Frequency(2)
(MHz)
Core
Multiplication
Factor(2)
Core
Frequency(2)
(MHz)
0010_100
33
4
133
6
200
0010_101
33
4
133
7
233
0010_110
33
4
133
8
266
0010_111
33
5
166
4
133
0011_000
33
5
166
5
166
0011_001
33
5
166
6
200
0011_010
33
5
166
7
233
0011_011
33
5
166
8
266
0011_100
33
6
200
4
133
0011_101
33
6
200
5
166
0011_110
33
6
200
6
200
0011_111
33
6
200
7
233
0100_000
33
6
200
8
266
0100_001
0100_010
0100_011
Reserved
0100_100
0100_101
0100_110
0100_111
0101_000
0101_001
Reserved
0101_010
0101_011
0101_100
0101_101
66
2
133
2
133
0101_110
66
2
133
2.5
166
0101_111
66
2
133
3
200
0110_000
66
2
133
3.5
233
0110_001
66
2
133
4
266
0110_010
66
2
133
4.5
300
47
5336A–HIREL–08/03
Table 15. Clock Configuration Modes(1) (Continued)
MODCK_H–MODCK[1–3]
Input Clock
Frequency(2)(3)
(MHz)
CPM
Multiplication
Factor(2)
CPM
Frequency(2)
(MHz)
Core
Multiplication
Factor(2)
Core
Frequency(2)
(MHz)
0110_011
66
2.5
166
2
133
0110_100
66
2.5
166
2.5
166
0110_101
66
2.5
166
3
200
0110_110
66
2.5
166
3.5
233
0110_111
66
2.5
166
4
266
0111_000
66
2.5
166
4.5
300
0111_001
66
3
200
2
133
0111_010
66
3
200
2.5
166
0111_011
66
3
200
3
200
0111_100
66
3
200
3.5
233
0111_101
66
3
200
4
266
0111_110
66
3
200
4.5
300
0111_111
66
3.5
233
2
133
1000_000
66
3.5
233
2.5
166
1000_001
66
3.5
233
3
200
1000_010
66
3.5
233
3.5
233
1000_011
66
3.5
233
4
266
1000_100
66
3.5
233
4.5
300
Notes:
1. Because of speed dependencies, not all of the possible configurations in Table 15 are applicable.
2. The user should choose the input clock frequency and the multiplication factors such that the frequency of the CPU is equal
to or greater than150 MHz and the CPM ranges between 66 – 233 MHz.
3. Input clock frequency is given only for the purpose of reference. MODCK_H–MODCK_L should be set so that the resulting
configuration does not exceed the frequency rating of the user’s part.
Example. If a part is rated at 266 MHz CPU, 200 MHz CPM, and 66 MHz bus, any of the following are possible (note
that the three input clock frequencies are only three of many possible input clock frequencies):
1. 66 MHz input clock and MODCK_H–MODCK_L[0111–101] (with a core multiplication factor of 4 and a CPM
multiplication factor of 3). The resulting configuration equals the part’s maximum possible frequencies of 266
MHz CPU, 200 MHz CPM, and 66 MHz bus.
2. 50 MHz input clock and MODCK_H–MODCK_L[0111–101] to achieve a configuration of 200 MHz CPU, 150
MHz CPM, and 50 MHz bus.
3. 40 MHz input clock and MODCK_H–MODCK_L[0010–011] to achieve a configuration of 200 MHz CPU, 160
MHz CPM, and 40 MHz bus.
Note that with each example, any one of several values for MODCK_H–MODCK_L could possibly be used as long as
the resulting configuration does not exceed the part’s rating.
48
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
PCI Mode
This section pertains to the PC8265A and the PC8266A only.
In PCI mode only, MODCK_HI[0:3] and PCI_MODCK come from the following external
pins:
•
PCI_MODCK = LGPL5
•
MODCK_HI[0:3] = {LGPL0,LGPL1,LGPL2,LGPL3}
Note:
The minimum Tval = 2 when PCI_MODCK = 1 and minimum Tval = 1 when
PCI_MODCK = 0; therefore, board designers should use clock configurations that fit this
condition to achieve PCI-compliant AC timing.
Table 16. Clock Default Configurations in PCI Host Mode (MODCK_HI = 0000)
MODCK[1–
3](1)
Input Clock
Frequency
CPM
Multiplication
CPM
Frequency
Core
Multiplication
Core
Frequency
PCI Division
Factor(2)
PCI
Frequency(2)
000
66 MHz
2
133 MHz
2.5
166 MHz
2/4
66/33 MHz
001
66 MHz
2
133 MHz
3
200 MHz
2/4
66/33 MHz
010
66 MHz
2.5
166 MHz
3
200 MHz
3/6
55/28 MHz
011
66 MHz
2.5
166 MHz
3.5
233 MHz
3/6
55/28 MHz
100
66 MHz
2.5
166 MHz
4
266 MHz
3/6
55/28 MHz
101
66 MHz
3
200 MHz
3
200 MHz
3/6
66/33 MHz
110
66 MHz
3
200 MHz
3.5
233 MHz
3/6
66/33 MHz
111
66 MHz
3
200 MHz
4
266 MHz
3/6
66/33 MHz
Notes:
1. Assumes MODCK_HI = 0000.
2. The frequency depends on the value of PCI_MODCK. If PCI_MODCK is high (logic ‘1’), the PCI frequency is divided by 2
(33 instead of 66 MHz, etc.)
Table 17 describes all possible clock configurations when using the PC8265A or the PC8266A’s internal PCI bridge in host
mode.
Table 17. Clock Configuration Modes in PCI Host Mode
MODCK_H –
MODCK[1–3]
Input Clock
Frequency(1)
(Bus)
CPM
Multiplication
Factor
CPM
Frequency
Core
Multiplication
Factor
Core
Frequency
PCI Division
Factor(2)
PCI
Frequency(2)
0001_000
33 MHz
3
100 MHz
5
166 MHz
3/6
33/16 MHz
0001_001
33 MHz
3
100 MHz
6
200 MHz
3/6
33/16 MHz
0001_010
33 MHz
3
100 MHz
7
233 MHz
3/6
33/16 MHz
0001_011
33 MHz
3
100 MHz
8
266 MHz
3/6
33/16 MHz
0010_000
33 MHz
4
133 MHz
5
166 MHz
4/8
33/16 MHz
0010_001
33 MHz
4
133 MHz
6
200 MHz
4/8
33/16 MHz
0010_010
33 MHz
4
133 MHz
7
233 MHz
4/8
33/16 MHz
0010_011
33 MHz
4
133 MHz
8
266 MHz
4/8
33/16 MHz
0011_000(3)
33 MHz
5
166 MHz
5
166 MHz
5
33 MHz
(3)
33 MHz
5
166 MHz
6
200 MHz
5
33 MHz
0011_001
49
5336A–HIREL–08/03
Table 17. Clock Configuration Modes in PCI Host Mode (Continued)
MODCK_H –
MODCK[1–3]
Input Clock
Frequency(1)
(Bus)
CPM
Multiplication
Factor
CPM
Frequency
Core
Multiplication
Factor
Core
Frequency
PCI Division
Factor(2)
PCI
Frequency(2)
0011_010(3)
33 MHz
5
166 MHz
7
233 MHz
5
33 MHz
0011_011(3)
33 MHz
5
166 MHz
8
266 MHz
5
33 MHz
0100_0003
33 MHz
6
200 MHz
5
166 MHz
6
33 MHz
3
33 MHz
6
200 MHz
6
200 MHz
6
33 MHz
0100_0103
33 MHz
6
200 MHz
7
233 MHz
6
33 MHz
0100_0113
33 MHz
6
200 MHz
8
266 MHz
6
33 MHz
0101_000
66 MHz
2
133 MHz
2.5
166 MHz
2/4
66/33 MHz
0101_001
66 MHz
2
133 MHz
3
200 MHz
2/4
66/33 MHz
0101_010
66 MHz
2
133 MHz
3.5
233 MHz
2/4
66/33 MHz
0101_011
66 MHz
2
133 MHz
4
266 MHz
2/4
66/33 MHz
0101_100
66 MHz
2
133 MHz
4.5
300 MHz
2/4
66/33 MHz
0110_000
66 MHz
2.5
166 MHz
2.5
166 MHz
3/6
55/28 MHz
0110_001
66 MHz
2.5
166 MHz
3
200 MHz
3/6
55/28 MHz
0110_010
66 MHz
2.5
166 MHz
3.5
233 MHz
3/6
55/28 MHz
0110_011
66 MHz
2.5
166 MHz
4
266 MHz
3/6
55/28 MHz
0110_100
66 MHz
2.5
166 MHz
4.5
300 MHz
3/6
55/28 MHz
0111_000
66 MHz
3
200 MHz
2.5
166 MHz
3/6
66/33 MHz
0111_001
66 MHz
3
200 MHz
3
200 MHz
3/6
66/33 MHz
0111_010
66 MHz
3
200 MHz
3.5
233 MHz
3/6
66/33 MHz
0111_011
66 MHz
3
200 MHz
4
266 MHz
3/6
66/33 MHz
0111_100
66 MHz
3
200 MHz
4.5
300 MHz
3/6
66/33 MHz
1000_000
66 MHz
3
200 MHz
2.5
166 MHz
4/8
50/25 MHz
1000_001
66 MHz
3
200 MHz
3
200 MHz
4/8
50/25 MHz
1000_010
66 MHz
3
200 MHz
3.5
233 MHz
4/8
50/25 MHz
1000_011
66 MHz
3
200 MHz
4
266 MHz
4/8
50/25 MHz
1000_100
66 MHz
3
200 MHz
4.5
300 MHz
4/8
50/25 MHz
1001_000
66 MHz
3.5
233 MHz
2.5
166 MHz
4/8
58/29 MHz
1001_001
66 MHz
3.5
233 MHz
3
200 MHz
4/8
58/29 MHz
1001_010
66 MHz
3.5
233 MHz
3.5
233 MHz
4/8
58/29 MHz
0100_001
50
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 17. Clock Configuration Modes in PCI Host Mode (Continued)
MODCK_H –
MODCK[1–3]
Input Clock
Frequency(1)
(Bus)
CPM
Multiplication
Factor
CPM
Frequency
Core
Multiplication
Factor
Core
Frequency
PCI Division
Factor(2)
PCI
Frequency(2)
1001_011
66 MHz
3.5
233 MHz
4
266 MHz
4/8
58/29 MHz
1001_100
66 MHz
3.5
233 MHz
4.5
300 MHz
4/8
58/29 MHz
1010_000
100 MHz
2
200 MHz
2
200 MHz
3/6
66/33 MHz
1010_001
100 MHz
2
200 MHz
2.5
250 MHz
3/6
66/33 MHz
1010_010
100 MHz
2
200 MHz
3
300 MHz
3/6
66/33 MHz
1010_011
100 MHz
2
200 MHz
3.5
350 MHz
3/6
66/33 MHz
1010_100
100 MHz
2
200 MHz
4
400 MHz
3/6
66/33 MHz
1011_000
100 MHz
2.5
250 MHz
2
200 MHz
4/8
62/31 MHz
1011_001
100 MHz
2.5
250 MHz
2.5
250 MHz
4/8
62/31MHz
1011_010
100 MHz
2.5
250 MHz
3
300 MHz
4/8
62/31 MHz
1011_011
100 MHz
2.5
250 MHz
3.5
350 MHz
4/8
62/31 MHz
1011_100
100 MHz
2.5
250 MHz
4
400 MHz
4/8
62/31 MHz
Notes:
1. Input clock frequency is given only for the purpose of reference. User should set MODCK_H–MODCK_L so that the resulting configuration does not exceed the frequency rating of the user’s part.
Example. If a part is rated at 266 MHz CPU, 200 MHz CPM, and 66 MHz bus, any of the following are possible (note
that the three input clock frequencies are only three of many possible input clock frequencies):
1. 66 MHz input clock, MODCK_H–MODCK_L[0111–011] (with a core multiplication factor of 4 and a CPM multiplication factor of 3), and PCI_MODCK = 0 (see note 2 below). The resulting configuration equals the part’s
maximum possible frequencies of 266 MHz CPU, 200 MHz CPM, 66 MHz 60x bus, and a PCI frequency of 66
MHz.
2. 50 MHz input clock, MODCK_H–MODCK_L[0111–011], and PCI_MODCK = 0 (see note 2below) to achieve a
configuration of 200 MHz CPU, 150 MHz CPM, 50 MHz 60x bus, and a PCI frequency of 50 MHz.
3. 40 MHz input clock, MODCK_H–MODCK_L[0010–000], and PCI_MODCK = 0 (see note 2 below) to achieve a
configuration of 200 MHz CPU, 160 MHz CPM, 40 MHz 60x bus, and a PCI frequency of 40 MHz.
Note that with each of the examples, any one of several values for MODCK_H–MODCK_L could possibly be used as
long as the resulting configuration does not exceed the part’s rating.
2. The frequency depends on the value of PCI_MODCK. If PCI_MODCK is high (logic “1“), the PCI frequency is divided by 2
(33 instead of 66 MHz, etc.).
3. In this mode, PCI_MODCK must be “0”
51
5336A–HIREL–08/03
.
Table 18. Clock Default Configurations in PCI Agent Mode (MODCK_HI = 0000)(1)
MODCK[1–3](2)
Input Clock
Frequency
(PCI)(3)
CPM
Multiplication
Factor(3)
CPM
Frequency
Core
Multiplication
Factor
Core(4)
Frequency
Bus
Division
Factor
60x Bus(5)
Frequency
000
66/33 MHz
2/4
133 MHz
2.5
166 MHz
2
66 MHz
001
66/33 MHz
2/4
133 MHz
3
200 MHz
2
66 MHz
010
66/33 MHz
3/6
200 MHz
3
200 MHz
3
66 MHz
011
66/33 MHz
3/6
200 MHz
4
266 MHz
3
66 MHz
100
66/33 MHz
3/6
200 MHz
3
240 MHz
2.5
80 MHz
101
66/33 MHz
3/6
200 MHz
3.5
280 MHz
2.5
80 MHz
110
66/33 MHz
4/8
266 MHz
3.5
300 MHz
3
88 MHz
111
66/33 MHz
4/8
266 MHz
3
300 MHz
2.5
100 MHz
Notes:
1. The user should verify that all buses and functions run frequencies that are within the supported ranges
2. Assumes MODCK_HI = 0000
3. The frequency depends on the value of PCI_MODCK. If PCI_MODCK is high (logic ‘1’), the PCI frequency is divided by 2
(33 instead of 66 MHz, etc.) and the CPM multiplication factor is multiplied by 2
4. Core frequency = (60x bus frequency)(core multiplication factor)
5. Bus frequency = CPM frequency/bus division factor
Table 19 describes all possible clock configurations when using the PC8265A or the PC8266A’s internal PCI bridge in
agent mode.
Table 19. Clock Configuration Modes in PCI Agent Mode(1)
MODCK_H –
MODCK[1–3]
Input Clock
Frequency
(PCI)(2)(3)
CPM
Multiplication
Factor(2)
CPM
Frequency
Core
Multiplication
Factor
Core(4)
Frequency
Bus
Division
Factor
60x Bus(5)
Frequency
0001_001
66/33 MHz
2/4
133 MHz
5
166 MHz
4
33 MHz
0001_010
66/33 MHz
2/4
133 MHz
6
200 MHz
4
33 MHz
0001_011
66/33 MHz
2/4
133 MHz
7
233 MHz
4
33 MHz
0001_100
66/33 MHz
2/4
133 MHz
8
266 MHz
4
33 MHz
0010_001
50/25 MHz
3/6
150 MHz
3
180 MHz
2.5
60 MHz
0010_010
50/25 MHz
3/6
150 MHz
3.5
210 MHz
2.5
60 MHz
0010_011
50/25 MHz
3/6
150 MHz
4
240 MHz
2.5
60 MHz
0010_100
50/25 MHz
3/6
150 MHz
4.5
270 MHz
2.5
60 MHz
0011_000
66/33 MHz
2/4
133 MHz
2.5
110MHz
3
44 MHz
0011_001
66/33 MHz
2/4
133 MHz
3
132 MHz
3
44 MHz
0011_010
66/33 MHz
2/4
133 MHz
3.5
154 MHz
3
44 MHz
0011_011
66/33 MHz
2/4
133 MHz
4
176 MHz
3
44 MHz
0011_100
66/33 MHz
2/4
133 MHz
4.5
198 MHz
3
44 MHz
52
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Table 19. Clock Configuration Modes in PCI Agent Mode(1) (Continued)
Bus
Division
Factor
60x Bus
Frequency(
166 MHz
3
66 MHz
3
200 MHz
3
66 MHz
200 MHz
3.5
233 MHz
3
66 MHz
3/6
200 MHz
4
266 MHz
3
66 MHz
66/33 MHz
3/6
200 MHz
4.5
300 MHz
3
66 MHz
0101_0006
33 MHz
5
166 MHz
2.5
166 MHz
2.5
66 MHz
0101_0016
33 MHz
5
166 MHz
3
200 MHz
2.5
66 MHz
0101_0106
33 MHz
5
166 MHz
3.5
233 MHz
2.5
66 MHz
6
33 MHz
5
166 MHz
4
266 MHz
2.5
66 MHz
6
0101_100
33 MHz
5
166 MHz
4.5
300 MHz
2.5
66 MHz
0110_000
50/25 MHz
4/8
200 MHz
2.5
166 MHz
3
66 MHz
0110_001
50/25 MHz
4/8
200 MHz
3
200 MHz
3
66 MHz
0110_010
50/25 MHz
4/8
200 MHz
3.5
233 MHz
3
66 MHz
0110_011
50/25 MHz
4/8
200 MHz
4
266 MHz
3
66 MHz
0110_100
50/25 MHz
4/8
200 MHz
4.5
300 MHz
3
66 MHz
0111_000
66/33 MHz
3/6
200 MHz
2
200 MHz
2
100 MHz
0111_001
66/33 MHz
3/6
200 MHz
2.5
250 MHz
2
100 MHz
0111_010
66/33 MHz
3/6
200 MHz
3
300 MHz
2
100 MHz
0111_011
66/33 MHz
3/6
200 MHz
3.5
350 MHz
2
100 MHz
1000_000
66/33 MHz
3/6
200 MHz
2
160 MHz
2.5
80 MHz
1000_001
66/33 MHz
3/6
200 MHz
2.5
200 MHz
2.5
80 MHz
1000_010
66/33 MHz
3/6
200 MHz
3
240 MHz
2.5
80 MHz
1000_011
66/33 MHz
3/6
200 MHz
3.5
280 MHz
2.5
80 MHz
1000_100
66/33 MHz
3/6
200 MHz
4
320 MHz
2.5
80 MHz
1000_101
66/33 MHz
3/6
200 MHz
4.5
360 MHz
2.5
80 MHz
1001_000
66/33 MHz
4/8
266 MHz
2.5
166 MHz
4
66 MHz
1001_001
66/33 MHz
4/8
266 MHz
3
200 MHz
4
66 MHz
1001_010
66/33 MHz
4/8
266 MHz
3.5
233 MHz
4
66 MHz
1001_011
66/33 MHz
4/8
266 MHz
4
266 MHz
4
66 MHz
1001_100
66/33 MHz
4/8
266 MHz
4.5
300 MHz
4
66 MHz
MODCK_H –
MODCK[1–3]
Input Clock
Frequency
(PCI)(2)(3)
CPM
Multiplication
Factor(2)
CPM
Frequency
Core
Multiplication
Factor
Core
Frequency(
0100_000
66/33 MHz
3/6
200 MHz
2.5
0100_001
66/33 MHz
3/6
200 MHz
0100_010
66/33 MHz
3/6
0100_011
66/33 MHz
0100_100
0101_011
4)
5)
53
5336A–HIREL–08/03
Table 19. Clock Configuration Modes in PCI Agent Mode(1) (Continued)
Bus
Division
Factor
60x Bus
Frequency(
222 MHz
3
88 MHz
3
266 MHz
3
88 MHz
266 MHz
3.5
300 MHz
3
88 MHz
4/8
266 MHz
4
350 MHz
3
88 MHz
66/33 MHz
4/8
266 MHz
4.5
400 MHz
3
88 MHz
1011_000
66/33 MHz
4/8
266 MHz
2
212MHz
2.5
106 MHz
1011_001
66/33 MHz
4/8
266 MHz
2.5
265 MHz
2.5
106 MHz
1011_010
66/33 MHz
4/8
266 MHz
3
318 MHz
2.5
106 MHz
1011_011
66/33 MHz
4/8
266 MHz
3.5
371 MHz
2.5
106 MHz
1011_100
66/33 MHz
4/8
266 MHz
4
424 MHz
2.5
106 MHz
MODCK_H –
MODCK[1–3]
Input Clock
Frequency
(PCI)(2)(3)
CPM
Multiplication
Factor(2)
CPM
Frequency
Core
Multiplication
Factor
Core
Frequency(
1010_000
66/33 MHz
4/8
266 MHz
2.5
1010_001
66/33 MHz
4/8
266 MHz
1010_010
66/33 MHz
4/8
1010_011
66/33 MHz
1010_100
Notes:
4)
5)
1. The user should verify that all buses and functions run frequencies that are within the supported ranges.
2. The frequency depends on the value of PCI_MODCK. If PCI_MODCK is high (logic ‘1’), the PCI frequency is divided by 2
(33 instead of 66 MHz, etc.) and the CPM multiplication factor is multiplied by 2.
3. Input clock frequency is given only for the purpose of reference. MODCK_H–MODCK_L should be set so that the resulting
configuration does not exceed the frequency rating of the user’s part.
Example. If a part is rated at 266 MHz CPU, 200 MHz CPM, and 66 MHz bus, any of the following are possible
(note that the three input clock frequencies are only three of many possible input clock frequencies):
1. 50 MHz input clock, MODCK_H–MODCK_L[0110–011] (with a core multiplication factor of 4, a CPM multiplication factor of 4, and a bus division factor of 3), and PCI_MODCK = 0 (see note 2 above). The PCI frequency is
50 MHz and the resulting configuration equals the part’s maximum possible frequencies of 266 MHz CPU,
200 MHz CPM, and 66 MHz 60x bus.
2. 66 MHz input clock, MODCK_H–MODCK_L[0100–001], and PCI_MODCK = 1 (see note 2 above) to achieve a
PCI frequency of 33 MHz and a configuration of 200MHz CPU, 200 MHz CPM, and 66 MHz 60x bus.
3. 40 MHz input clock, MODCK_H–MODCK_L[1001–011], and PCI_MODCK = 0 (see note 2 above) to achieve a
PCI frequency of 40 MHz and a configuration of 160 MHz CPU, 160 MHz CPM, and 40 MHz 60x bus.
Note that with each of the examples, any one of several values for MODCK_H–MODCK_L could possibly be used
as long as the resulting configuration does not exceed the part’s rating.
4. Core frequency = (60x bus frequency) (core multiplication factor)
5. Bus frequency = CPM frequency/bus division factor
6. In this mode, PCI_MODCK must be “1”.
54
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Package Description
The following sections provide the package parameters and mechanical dimensions for
the PC8265A.
Package Parameters
Package parameters are provided in Table 20. The package type is a 37.5 x 37.5 mm,
480-lead TBGA.
Table 20. Package Parameters
Parameter
Value
Package Outline
37.5 x 37.5 mm
Interconnects
480 (29 x 29 ball array)
Pitch
1.27 mm
Nominal unmounted package height
1.55 mm
55
5336A–HIREL–08/03
Status
Table 21. Datasheet Status
Datasheet Status
Validity
Objective Specification
This datasheet contains target and goal specification for
discussion with customer and application validation.
Valid before design phase
Target Specification
This datasheet contains target or goal specifications for
product development.
Valid during the design phase
Preliminary Specification ∝ Site
This datasheet contains preliminary data. Additional data
may be published later. This could include simulation
results.
Valid before the characterization
phase
Preliminary Specification β Site
This datasheet also contains characterization results.
Valid before the industrialization
phase.
Product Specification
This datasheet contains final product specifications.
Valid for production purposes
Limiting Values
Limiting values given are in accordance with the Absolute Maximum Rating System
(IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or
at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device
reliability.
Application Information
Where application information is given, it is advisory and does not form part of the
specification.
Life Support Applications
These products are not designed for use in life support appliances, devices, or systems
where malfunction of these products can reasonably be expected to result in personal
injury. Atmel customers using or selling these products for use in such applications do
so at their own risk and agree to fully indemnify Atmel for any damages resulting from
such improper use or sale.
56
PC8265A PowerQUICC II
5336A–HIREL–08/03
PC8265A PowerQUICC II
Mechanical Dimensions
Figure 14 provides the mechanical dimensions and bottom surface nomenclature of the
480 TBGA package.
Figure 14. Mechanical Dimensions and Bottom Surface Nomenclature
B
A
D
0.15 A
480X
0.15 A
A1
SEATING
PLANE
E
A3
Notes:
1. Dimensions and Tolerancing per
ASME Y14.5M-1994
2. Dimensions in millimeters
4X
TOP VIEW
(D1)
C
0.2
3. Dimension b is measured at the
maximum solder ball diameter,
parallel to primary data A
A
28X e
AJ
AH
AG
AF
AE
AD
AC
AB
AA
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
4. Primary data A and the seating
plane are defined by the spherical
crowns of the solder balls
Millimeters
28X e
Dim
Min
(E1)
1 2 3 4 5 6 7 8 9 101112 1314 1516 171819202122232425262728 29
BOTTOM VIEW
3
480X b
3M A B C
15 M A
A2
Max
A
1.45
1.65
A1
0.60
0.70
A2
0.85
0.95
A3
0.25
_
b
0.65
0.85
D
37.50 BSC
D1
35.56 REF
e
1.27 BSC
E
37.50 BSC
E1
35.56 REF
A1
A
57
5336A–HIREL–08/03
Ordering Information
PC (X)
Prefix
8265A
M
TP
U
MHB
B
(1)
Revision Level
Prototype
Type
Temperature Range: Tj
M: -55, +125°C
V: -40, +110°C
CPU/CPM/Bus Speed (MHz)
M = 266 MHz
H = 166 MHz
B = 66 MHz
Package
TP: TBGA
Screening Level
U: Upscreening
(2)
(1) Atmel
(2) For availability of the different versions, contact your sales office.
58
PC8265A PowerQUICC II
5336A–HIREL–08/03
Atmel Corporation
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Disclaimer: Atmel Corporation makes no warranty for the use of its products, other than those expressly contained in the Company’s standard
warranty which is detailed in Atmel’s Terms and Conditions located on the Company’s web site. The Company assumes no responsibility for any
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Printed on recycled paper.
5336A–HIREL–08/03
0M