ETC TSXPC750AVGS12LH

Features
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12.4 SPECint95, 8.4 SPECfp95 at 266 MHz (TSPC750A) with 1 MB L2 at 133 MHz
11.5 SPECint95, 6.9 SPECfp95 at 266 MHz (TSPC740A)
488 MIPS at 266 MHz
Selectable Bus Clock (11 CPU Bus Dividers up to 8x)
PD Typical 4.2 W at 200 MHz, Full Operating Conditions
Nap, Doze and Sleep Modes for Power Savings
Superscalar (3 Instructions per Clock Cycle)
4-GByte Direct Addressing Range
64-bit Data and 32-bit Address Bus Interface
32 KB Instruction and Data Cache
Six Independent Execution Units and Two Register Files
Write-back and Write-through Operations
fint max = 266 MHz
fbus max = 83.3 MHz
Compatible CMOS Input / TTL Output
Description
The TSPC750A and TSPC740A microprocessor (after named 750A/740A) are lowpower implementations of the PowerPC Reduced Instruction Set Computer (RISC)
architecture.
The 750A/740A microprocessors’ designs are superscalar, capable of issuing three
instructions per clock cycle into six independent execution units.
The 740A/750A microprocessors use a 2.6/3.3V CMOS process technology and
maintain full interface compatibility with TTL devices.
PowerPC
750A/740A RISC
Microprocessor
Family PID8t750A/740A
Specification
TSPC750A/740A
The 750A/740A provide four software controllable power-saving modes and a thermal
assist unit management.
The 750A/740A microprocessors have separate 32K byte, physically-addressed
instruction and data caches and differ only in that the 750A features a dedicated L2
cache interface with L2 on-chip tags.
Both are software and bus-compatible with the PowerPC 603™ and PowerPC 604™
families, and are fully JTAG compliant.
The TSPC740A microprocessor is pin compatible with the TSPC603e family.
G suffix
CBGA255 and CBGA360
Ceramic Ball Grid Array
GS suffix
CI-CBGA255 and CI-CBGA360
Ceramic Ball Grid Array
with Solder Column Interposer (SCI)
Rev. 2128A–HIREL–01/02
1
Screening
This product is manufactured in full compliance with:
•
CBGA upscreenings based upon ATMEL-Grenoble standards
•
Full military temperature range (Tc = -55°C,+125°C)
Industrial temperature range (Tc = -40°C, +110°C)
•
CI-CGA versions of TSPC740A and TSPC750A (planned)
Simplified Block
Diagram
The TSPC750A is targeted for low power systems and supports the following power
management features — doze, nap, sleep, and dynamic power management. The
TSPC750A consists of a processor core and an internal L2 Tag combined with a dedicated L2 cache interface and a 60x bus.
Figure 1. TSPC750A Block Diagram
Instruction Fetch
Branch Unit
Completion
Control Unit
32K ICache
System Unit
BHT/BTIC
Dispatch
GPRs
FXU1
FXU2
Rename
Buffers
32K DCache
2
FPRs
LSU
L2 Tags
Rename
Buffers
L2 Cache
BIU
FPU
60x BIU
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
General Parameters
The general parameters of the 750A/740A are the following:
Technology
0.29 mm CMOS, five-layer metal
Die Size
7.56 mm x 8.79 mm (67 mm2)
Transistor Count
6.35 million
Logic Design
Fully-static
Packages L2
740A: Surface mount 255 ceramic ball grid array (CBGA) and column interposer ceramic grid
array CI-CGA without L2interface
750A: Surface mount 360 ceramic ball grid array (CBGA) and column interposer ceramic grid
array CI-CGA with L2 interface
Core Power Supply
2.6V ± 100 mV
I/O Power Supply
3.3V ± 5% VDC
Features
Except L2 cache interface that is not supported by the PowerPC version, the major features implemented in the PowerPC 750A architecture are as follows:
Level 2 (L2) Cache Interface
(not implemented on
TSPC740A)
•
Internal L2 cache controller and 4K-entry tags; external data SRAMs
•
256K, 512K, and 1-Mbyte 2-way set associative L2 cache support
•
Copy-back or write-through data cache (on a page basis, or for all L2)
•
64-byte (256K/512K) and 128-byte (1-Mbyte) sectored line size
•
Supports flow-through (reg-buf) synchronous burst SRAMs, pipelined (reg-reg)
synchronous burst SRAMs, and pipelined (reg-reg) late-write synchronous burst
SRAMs
•
Core-to-L2 frequency divisors of ÷1, ÷1.5, ÷2, ÷2.5, and ÷3 supported
•
Four instructions fetched per clock
•
One branch processed per cycle (plus resolving 2 speculations)
•
Up to 1 speculative stream in execution, 1 additional speculative stream in fetch
•
512-entry branch history table (BHT) for dynamic prediction
•
64-entry, 4-way set associative branch target instruction cache (BTIC) to minimize
branch delay slots
•
Full hardware detection of dependencies (resolved in the execution units)
•
Dispatch two instructions to six independent units (system, branch, load/store, fixedpoint unit 1, fixed-point unit 2, or floating-point)
•
Serialization control (predispatch, postdispatch, execution serialization)
•
One cycle load or store cache access (byte, half-word, word, double-word)
•
Effective address generation
Branch Processing Unit
Dispatch Unit
Load/Store Unit
•
Hits under misses (one outstanding miss)
•
Single-cycle misaligned access within double word boundary
•
Alignment, zero padding, sign extend for integer register file
•
Floating-point internal format conversion (alignment, normalization)
•
Sequencing for load/store multiples and string operations
•
Store gathering
•
Cache and TLB instructions
3
2128A–HIREL–01/02
Fixed-point Units
Bus Interface
Decode
Floating-point Unit
System Unit
Cache Structure
Memory Management Unit
4
•
Big- and little-endian byte addressing supported
•
Misaligned little-endian support in hardware
•
Fixed-point unit 1 (FXU1)-multiply, divide, shift, rotate, arithmetic, logical
•
Fixed-point unit 2 (FXU2)-shift, rotate, arithmetic, logical
•
Single-cycle arithmetic, shift, rotate, logical
•
Multiply and divide support (multi-cycle)
•
Early out multiply
•
Compatible with 60x processor interface
•
32-bit address bus
•
64-bit data bus
•
Bus-to-core frequency multipliers of 3x, 3.5x, 4x, 4.5x, 5x, 5.5x, 6x, 6.5x, 7x, 7.5x,
8x supported
•
Register file access
•
Forwarding control
•
Partial instruction decode
•
Support for IEEE-754 standard single- and double-precision floating-point arithmetic
•
3 cycle latency, 1 cycle throughput, single-precision multiply-add
•
3 cycle latency, 1 cycle throughput, double-precision add
•
4 cycle latency, 2 cycle throughput, double-precision multiply-add
•
Hardware support for divide
•
Hardware support for denormalized numbers
•
Time deterministic non-IEEE mode
•
Executes CR logical instructions and miscellaneous system instructions
•
Special register transfer instructions
•
32K, 32-byte line, 8-way set associative instruction cache
•
32K, 32-byte line, 8-way set associative data cache
•
Single-cycle cache access
•
Pseudo-LRU replacement
•
Copy-back or write-through data cache (on a page per page basis)
•
Supports all PowerPC memory coherency modes
•
Non-blocking instruction and data cache (one outstanding miss under hits)
•
No snooping of instruction cache
•
128 entry, 2-way set associative instruction TLB
•
128 entry, 2-way set associative data TLB
•
Hardware reload for TLBs
•
4 instruction BATs and 4 data BATs
•
Virtual memory support for up to 4 hexabytes (252) of virtual memory
•
Real memory support for up to 4 gigabytes (232) of physical memory
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Testability
•
LSSD scan design
•
JTAG interface
•
Low-power 2.6/3.3V design
•
Three static power saving modes: doze, nap, and sleep
•
Automatic dynamic power reduction when internal functional units are idle
Integrated Thermal
Management Assist Unit
•
On-chip thermal sensor and control logic
•
Thermal Management Interrupt for software regulation of junction temperature.
Reliability and Serviceability
•
Parity checking on 60x and L2 cache buses
Integrated Power
Management
Pin Assignments
TSPC740A Package
The pinout of the TSPC740A, 255 CBGA and CI-CGA packages as viewed from the top
surface.
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2128A–HIREL–01/02
Figure 2. Pinout of TSPC740A, CBGA and CI-CGA Packages as Viewed from the Top Surface
1 2 3 4 5 6 7 8
9 1 0 11 1 2 1 3 1 4 1516
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
Not to Scale
View
Substrate
Encapsulant
Die
CBGA255
Not to scale
View
Substrate Assembly
Encapsulant
Die
CI-CGA255
TSPC750A Package
6
The pinout of the TSPC750A, 360 CBGA and CI-CGA packages as viewed from the top
surface.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Figure 3. Pinout of TSPC750A, CBGA and CI-BGA Packages as Viewed from the Top Surface
Pin A1 index
1 2 3 4 5 6 7 8 9 10 11 1213 14 15 16 1718 19
TSXP750AVGU 12LH
GND
VDD
0VDD
L20VDD
0VDD
VDD
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
L20VDD
GND
S23670W002
Not to Scale
View
Substrate Assembly
Encapsulant
Not to scale
Die
CBGA360
Die
CI- CGA360
View
Substrate Assembly
Encapsulant
Pinout Listings
Table 1. Pinout Listing for the TSPC740A, 255 CBGA and CI-CGA Packages
Signal Name
Pin Number
Active
I/O
A[0-31]
C16, E4, D13, F2, D14, G1, D15, E2, D16, D4, E13, G2, E15, H1, E16, H2,
F13, J1, F14, J2, F15, H3, F16, F4, G13, K1, G15, K2, H16, M1, J15, P1
High
I/O
AACK
L2
Low
Input
ABB
K4
Low
I/O
AP[0-3]
C1, B4, B3, B2
High
I/O
ARTRY
J4
Low
I/O
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2128A–HIREL–01/02
Table 1. Pinout Listing for the TSPC740A, 255 CBGA and CI-CGA Packages (Continued)
Signal Name
Pin Number
Active
I/O
AVDD
A10
-
-
BG
L1
Low
Input
BR
B6
Low
Output
CI
E1
Low
Output
CKSTP_IN
D8
Low
Input
CKSTP_OUT
A6
Low
Output
CLK_OUT
D7
-
Output
DBB
J14
Low
I/O
DBG
N1
Low
Input
DBDIS
H15
Low
Input
DBWO
G4
Low
Input
DH[0-31]
P14, T16, R15, T15, R13, R12, P11, N11, R11, T12, T11, R10, P9, N9,
T10, R9, T9, P8, N8, R8, T8, N7, R7, T7, P6, N6, R6, T6, R5, N5, T5, T4
High
I/O
DL[0-31]
K13, K15, K16, L16, L15, L13, L14, M16, M15, M13, N16, N15, N13, N14,
P16, P15, R16, R14, T14, N10, P13, N12, T13, P3, N3, N4, R3, T1, T2,
P4, T3, R4
High
I/O
DP[0-7]
M2, L3, N2, L4, R1, P2, M4, R2
High
I/O
DRTRY
G16
Low
Input
GBL
F1
Low
I/O
GND
C5, C12, E3, E6, E8, E9, E11, E14, F5, F7, F10, F12, G6, G8, G9, G11,
H5, H7, H10, H12, J5, J7, J10, J12, K6, K8, K9, K11, L5, L7, L10, L12, M3,
M6, M8, M9, M11, M14, P5, P12
-
-
HRESET
A7
Low
Input
INT
B15
Low
Input
L1_TSTCLK(1)
D11
High
Input
L2_TSTCLK(1)
D12
High
Input
LSSD_MODE
B10
Low
Input
MCP
C13
Low
Input
NC (No-Connect)
B7, B8, C3, C6, C8, D5, D6, H4, J16, A4, A5, A2, A3, B1, B5
-
-
OVDD
C7, E5, E7, E10, E12, G3, G5, G12, G14, K3, K5, K12, K14, M5, M7, M10,
M12, P7, P10
-
-
PLL_CFG[0-3]
A8, B9, A9, D9
High
Input
QACK
D3
Low
Input
QREQ
J3
Low
Output
RSRV
D1
Low
Output
SMI
A16
Low
Input
SRESET
B14
Low
Input
SYSCLK
C9
-
Input
(1)
8
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Table 1. Pinout Listing for the TSPC740A, 255 CBGA and CI-CGA Packages (Continued)
Signal Name
Pin Number
Active
I/O
TA
H14
Low
Input
TBEN
C2
High
Input
TBST
A14
Low
I/O
TCK
C11
High
Input
TDI
A11
High
Input
TDO
A12
High
Output
TEA
H13
Low
Input
TLBISYNC
C4
Low
Input
TMS
B11
High
Input
TRST
C10
Low
Input
TS
J13
Low
I/O
TSIZ[0-2]
A13, D10, B12
High
Output
TT[0-4]
B13, A15, B16, C14, C15
High
I/O
WT
D2
Low
Output
VDD 2
F6, F8, F9, F11, G7, G10, H6, H8, H9, H11, J6, J8, J9, J11, K7, K10, L6,
L8, L9, L11
-
-
High
Output
VOLTDET 3
Notes:
F3
1. These are test signals for factory use only and must be pulled up to OVDD for normal machine operation.
2. OVDD inputs supply power to the I/O drivers and VDD inputs supply power to the processor core.
3. Internally tied to GND in the TSPC740A CBGA package to indicate to the power supply that a low-voltage processor is
present. This signal is not a power supply input.
Table 2. Pinout Listing for the TSPC750A, 360 CBGA and CI-CGA Packages
Signal Name
Pin Number
Active
I/O
A[0-31]
A13, D2, H11, C1, B13, F2, C13, E5, D13, G7, F12, G3, G6, H2, E2, L3,
G5, L4, G4, J4, H7, E1, G2, F3, J7, M3, H3, J2, J6, K3, K2, L2
High
I/O
AACK
N3
Low
Input
ABB
L7
Low
I/O
AP[0-3]
C4, C5, C6, C7
High
I/O
ARTRY
L6
Low
I/O
AVDD
A8
-
-
BG
H1
Low
Input
BR
E7
Low
Output
CKSTP_OUT
D7
High
Output
CI
C2
Low
Output
CKSTP_IN
B8
High
Input
CLKOUT
E3
-
Output
DBB
K5
Low
I/O
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2128A–HIREL–01/02
Table 2. Pinout Listing for the TSPC750A, 360 CBGA and CI-CGA Packages (Continued)
Signal Name
Pin Number
Active
I/O
DBDIS
G1
Low
Input
DBG
K1
Low
Input
DBWO
D1
Low
Input
DH[0-31]
W12, W11, V11, T9, W10, U9, U10, M11, M9, P8, W7, P9, W9, R10, W6,
V7, V6, U8, V9, T7, U7, R7, U6, W5, U5, W4, P7, V5, V4, W3, U4, R5
High
I/O
DL[0-31]
M6, P3, N4, N5, R3, M7, T2, N6, U2, N7, P11, V13, U12, P12, T13, W13,
U13, V10, W8, T11, U11, V12, V8, T1, P1, V1, U1, N1, R2, V3, U3, W2
High
I/O
DP[0-7]
L1, P2, M2, V2, M1, N2, T3, R1
High
I/O
DRTRY
H6
Low
Input
GBL
B1
Low
I/O
GND
D10, D14, D16, D4, D6, E12, E8, F4, F6, F10, F14, F16, G9, G11, H5, H8,
H10, H12, H15, J9, J11, K4, K6, K8, K10, K12, K14, K16, L9, L11, M5, M8,
M10, M12, M15, N9, N11, P4, P6, P10, P14, P16, R8, R12, T4, T6, T10,
T14, T16
-
-
HRESET
B6
Low
Input
INT
C11
Low
Input
L1_TSTCLK(1)
F8
High
Input
L2ADDR[0-16]
L17, L18, L19, M19, K18, K17, K15, J19, J18, J17, J16, H18, H17, J14,
J13, H19, G18
High
Output
L2AVDD
L13
-
-
L2CE
P17
Low
Output
L2CLKOUTA
N15
Low
Output
L2CLKOUTB
L16
Low
Output
L2DATA[0-63]
U14, R13, W14, W15, V15, U15, W16, V16, W17, V17, U17, W18, V18,
U18, V19, U19, T18, T17, R19, R18, R17, R15, P19, P18, P13, N14, N13,
N19, N17, M17, M13, M18, H13, G19, G16, G15, G14, G13, F19, F18,
F13, E19, E18, E17, E15, D19, D18, D17, C18, C17, B19, B18, B17, A18,
A17, A16, B16, C16, A14, A15, C15, B14, C14, E13
High
I/O
L2DP[0-7]
V14, U16, T19, N18, H14, F17, C19, B15
High
I/O
L2OVDD
D15, E14, E16, H16, J15, L15, M16, P15, R14, R16, T15, F15
-
-
L2SYNC_IN
L14
High
Input
M14
High
Output
F7
High
Input
N16
Low
Output
G17
High
Output
LSSD_MODE
F9
Low
Input
MCP
B11
Low
Input
-
-
-
-
L2SYNC_OUT
L2_TSTCLK
(1)
L2WE
L2ZZ
(1)
(4)
(4)
NC (No-Connect)
B3, B4, B5, A19, W19, W1, K9, K11
OVDD
D5, D8, D12, E4, E6, E9, E11, F5, H4, J5, L5, M4, P5, R4, R6, R9, R11,
T5, T8, T12
10
, K19
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Table 2. Pinout Listing for the TSPC750A, 360 CBGA and CI-CGA Packages (Continued)
Signal Name
Pin Number
Active
I/O
PLL_CFG[0-3]
A4, A5, A6, A7
High
Input
QACK
B2
Low
Input
QREQ
J3
Low
Output
RSRV
D3
Low
Output
SMI
A12
Low
Input
SRESET
E10
Low
Input
SYSCLK
H9
-
Input
TA
F1
Low
Input
TBEN
A2
High
Input
TBST
A11
Low
I/O
TCK
B10
High
Input
TDI
B7
High
Input
TDO
D9
High
Output
TEA
J1
Low
Input
TLBISYNC
A3
Low
Input
TMS
C8
High
Input
TRST
A10
Low
Input
TS
K7
Low
I/O
TSIZ[0-2]
A9, B9, C9
High
Output
TT[0-4]
C10, D11, B12, C12, F11
High
I/O
WT
C3
Low
Output
VDD (2)
G8, G10, G12, J8, J10, J12, L8, L10, L12, N8, N10, N12
-
-
VOLTDET (3)
K13
High
Output
Notes:
1. These are test signals for factory use only and must be pulled up to OVDD for normal machine operation.
2. OVDD inputs supply power to the I/O drivers and VDD inputs supply power to the processor core.
3. Internally tied to L2OVDD in the TSPC750A packages ATMEL-Grenoble to indicate the power present at the L2 cache interface. This signal is not a power supply input. Caution: this is different from the TSPC740A packages.
4. These pins are reserved for potential future use as additional L2 address pins.
11
2128A–HIREL–01/02
Signal Description
Figure 4. TSPC750A Microprocessor Signal Groups
L2VDD
L2AVDD
BR
ADDRESS
ARBITRATION
ADDRESS
START
BG
ABB
TS
A[0-31]
ADDRESS
BUS
AP[0-3]
TT[0-4]
TBST
TS1Z[0-2]
GBL
TRANSFER
ATTRIBUTE
WT
CI
1
17
1
1
64
8
1
1
32
1
2
4
1
AACK
DATA
ARBITRATION
DATA
TRANSFER
L2DP 0±7
L2WE
L2CLK±OUT A±B
L2SYNC_OUT
1
1
INT
SMI
3
1
1
1
1
1
MCP
SRESET
HRESET
RSRV
TBEN
TLBISYNC
QREQ
1
1
DBG
1
1
4
1
SYSCLK,
PLL_CFG 0±3
5
3
JTAG:COP
Factory Test
DBB
D 0±63
DP 0±7
1
1
64
8
1
TA
DRTRY
1
TEA
1
INTERRUPTS
RESET
CKSTP_IN
CKSTP_OUT
1
1
DBWO
L2 CACHE
CLOCK/CONTROL
L2SYNC_IN
5
1
1
1
TSPC750A
L2 CACHE
ADDRESS/
DATA
L2CE
ARTRY
DBDIS
DATA
TERMINATION
L2DATA 0±63
L2ZZ
1
1
1
ADDRESS
TERMINATION
L2ADDR 16±0
1
1
Not supported in the TSPC740A
PROCESSOR
STATUS
CONTROL
QACK
CLK_OUT
CLOCK
CONTROL
TEST INTERFACE
1
VDD VDD(I:O) AVDD
12
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Scope
This drawing describes the specific requirements for the microprocessor TSPC750A, in
compliance with ATMEL-Grenoble standard screening.
Applicable
Documents
1. MIL-STD-883: Test methods and procedures for electronics.
2. MIL-PRF-38535 appendix A: General specifications for microcircuits.
Requirements
General
The microcircuits are in accordance with the applicable documents and as specified
herein.
Design and Construction
Terminal Connections
Depending on the package, the terminal connections shall be is shown in Table 1, Table
2 and Figure 4.
Absolute Maximum
Rating
Table 3. Absolute Maximum Ratings
Characteristic
Symbol
Value
Unit
Core Supply Voltage
VDD
-0.3 to 2.75 (4)
V
PLL Supply Voltage
AVDD
-0.3 to 2.75 (4)
V
L2 DLL Supply Voltage
L2AVDD
-0.3 to 2.75 (4)
V
60x Bus Supply Voltage
OVDD
-0.3 to 3.6 (3.5)
V
L2 Bus Supply Voltage
L2OVDD
-0.3 to 3.6 (3.5)
V
VIN
-0.3 to 3.6 (2)
V
TSTG
-55 to 150
°C
Input Voltage
Storage Temperature Range
Notes:
1. Functional and tested operating conditions are given in Table 4. Absolute maximum ratings are stress ratings only, and functional operation at the maximums is not guaranteed. Stresses beyond those listed may affect device reliability or cause
permanent damage to the device.
2. Caution: VIN must not exceed OVDD by more than 0.3V at any time including during power-on reset.
3. Caution: OVDD must not exceed VDD/AVDD by more than 1.2V at any time including during power-on reset.
4. Caution: VDD/AVDD must not exceed OVDD by more than 0.4V at any time including during power-on reset.
5. Caution: VIN may overshoot/undershoot to a voltage and for a maximum duration as shown in Figure 5.
13
2128A–HIREL–01/02
Figure 5 shows the allowable undershoot and overshoot voltage on the TSPC750A and
TSPC 740A.
Figure 5. Overshoot/Undershoot Voltage
4V
(L2) OVDD + 5%
(L2) OVDD
VIH
VIL
Gnd
Gnd ± 0.3V
Gnd ± 1.0V
Not to exceed 10%
of tSYSCLK
Recommended
Operating Conditions
Table 4. Recommended Operating Conditions
Characteristic
Symbol
Value
Unit
Core Supply Voltage
VDD
2.5 to 2.7
V
PLL Supply Voltage
AVDD
2.5 to 2.7
V
L2 DLL Supply Voltage
L2AVDD
2.5 to 2.7
V
60x Bus Supply Voltage
OVDD
3.135 to 3.465
V
L2 Bus Supply Voltage
L2OVDD
3.135 to 3.465
V
VIN
GND to OVDD
V
Tj
-55 to +125
°C
Input Voltage
Junction Temperature
Note:
14
1. These are the recommended and tested operating conditions. Proper device operation outside of these conditions is not
guaranteed.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Thermal Characteristics
Table 5. Package Thermal Characteristics
Characteristic
Symbol
Value
Rating
CBGA and CI-CGA packages thermal resistance, junction-to-case thermal resistance
(typical)
θJC
0.03
°C/W
CBGA package thermal resistance, die junction-to-lead thermal resistance (typical)
θJB
3.8
°C/W
CI-CGA package thermal resistance, die junction-to-lead thermal resistance (typical)
θJB
4
°C/W
The board designer can choose between several types of heat sinks to place on the
TSPC750A. There are several commercially-available heat sinks for the TSPC750A
provided by the following vendors:
For the exposed-die packaging technology, shown in Table 5, the intrinsic conduction
thermal resistance paths are as follows:
•
The die junction-to-case (or top-of-die for exposed silicon) thermal resistance
•
The die junction-to-ball thermal resistance
Figure 6 depicts the primary heat transfer path for a package with an attached heat sink
mounted to a printed-circuit board.
Heat generated on the active side of the chip is conducted through the silicon, then
through the heat sink attach material (or thermal interface material), and finally to the
heat sink where it is removed by forced-air convection.
Since the silicon thermal resistance is quite small, for a first-order analysis, the temperature drop in the silicon may be neglected. Thus, the heat sink attach material and the
heat sink conduction/convective thermal resistances are the dominant terms.
Figure 6. C4 Package with Heat Sink Mounted to a Printed-Circuit Board
Radiation
External Resistance
Convection
Heat Sink
Thermal Interface Material
Die/Package
Die Junction
Package/Leads
Internal Resistance
Printed ± Circuit Board
External Resistance
Radiation
Convection
(Note the internal versus external package resistance)
Thermal Management
Assistance
The TSPC750A incorporates a thermal management assist unit (TAU) composed of a
thermal sensor, digital-to-analog converter, comparator, control logic, and dedicated
special-purpose registers (SPRs). Specifications for the thermal sensor portion of the
TAU are found in Table 6. More information on the use of this feature is given in the
MPC750A RISC Microprocessor User’s manual.
15
2128A–HIREL–01/02
Table 6. Thermal Sensor Specifications
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, 0 ≤ Tj < +125°C
Num
Characteristic
Min
Max
Unit
Notes
1
Temperature Range
0
127
°C
1
2
Comparator Settling Time
20
-
µs
2
3
Resolution
4
-
°C
3
Notes:
1. The temperature is the junction temperature of the die. The thermal assist unit’s raw output does not indicate an absolute
temperature, but it must be interpreted by software to derive the absolute junction temperature. For information about the
use and calibration of the TAU, see the Motorola application note AN1800/D “programming the thermal Assist Unit in the
MPC750A Microprocessor. This specification reflects the temperature span supported by design.
2. The comparator settling time value must be converted into the number of CPU clocks that need to be written into the
THRM3 SPR.
3. Guaranteed by design and characterization.
Thermal Management
Information
This section provides thermal management information for the ceramic ball grid array
(CBGA) package for air-cooled applications. Proper thermal control design is primarily
dependent upon the system-level design the heat sink, airflow and thermal interface
material. To reduce the die-junction temperature, heat sinks may be attached to the
package by several methods-adhesive, spring clip to holes in the printed circuit board or
package, and mounting clip and screw assembly; see Figure 7. This spring force should
not exceed 5.5 pounds of force.
Figure 7. Package Exploded Cross-Sectional View with Several Heat Sink Options
Heat Sink
CBGA Package
Heat Sink
Clip
Adhesive
or
Thermal Interface Material
Printed ± Circuit Board
Option
Ultimately, the final selection of an appropriate heat sink depends on many factors, such
as thermal performance at a given air velocity, spatial volume, mass, attachment
method, assembly, and cost.
16
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Adhesives and Thermal
Interface Materials
Figure 8. Thermal Performance of Select Thermal Interface Material
Silicone Sheet (0.006 inch)
Bare Joint
Floroether Oil Sheet (0.007 inch)
Graphite/Oil Sheet (0.005 inch)
Synthetic Grease
SpecificThermal Resistance (Kin2/W)
2
1.5
1
0.5
0
0
10
20
30
40
50
60
70
80
Contact Pressure (psi)
A thermal interface material is recommended at the package lid-to-heat sink interface to
minimize the thermal contact resistance. For those applications where the heat sink is
attached by spring clip mechanism, Figure 8 shows the thermal performance of three
thin-sheet thermal-interface materials (silicone, graphite/oil, floroether oil), a bare joint,
and a joint with thermal grease as a function of contact pressure. As shown, the performance of these thermal interface materials improves with increasing contact pressure.
The use of thermal grease significantly reduces the interface thermal resistance. That is,
the bare joint results in a thermal resistance approximately 7 times greater than the thermal grease joint.
Heat sinks are attached to the package by means of a spring clip to holes in the printedcircuit board (see Figure 7). This spring force should not exceed 5.5 pounds of force.
Therefore, the synthetic grease offers the best thermal performance, considering the
low interface pressure.
The board designer can choose between several types of thermal interface. Heat sink
adhesive materials should be selected based upon high conductivity, yet adequate
mechanical strength to meet equipment shock/vibration requirements.
17
2128A–HIREL–01/02
Heat Sink Selection Example
For preliminary heat sink sizing, the die-junction temperature can be expressed as
follows:
Tj = Ta + Tr + (θjc + θint + θsa) * Pd
Where:
Tj is the die-junction temperature
Ta is the inlet cabinet ambient temperature
Tr is the air temperature rise within the computer cabinet
θjc is the junction-to-case thermal resistance
θint is the adhesive or interface material thermal resistance
θsa is the heat sink base-to-ambient thermal resistance
Pd is the power dissipated by the device
During operation the die-junction temperatures (Tj) should be maintained less than the
value specified in Table 4. The temperature of the air cooling the component greatly
depends upon the ambient inlet air temperature and the air temperature rise within the
electronic cabinet. An electronic cabinet inlet-air temperature (Ta) may range from 30 to
40°C. The air temperature rise within a cabinet (Tr) may be in the range of 5 to 10°C.
The thermal resistance of the thermal interface material (θint) is typically about 1°C/W.
Assuming a Ta of 30°C, a Tr of 5°C, a CBGA package θjc = 2.2, and a power consumption (Pd) of 4.5 watts, the following expression for Tj is obtained:
Die-junction temperature: Tj = 30°C + 5°C + (2.2°C/W + 1.0°C/W + θsa) * 4.5 W
For a Thermalloy heat sink #2328B, the heat sink-to-ambient thermal resistance (θsa)
versus airflow velocity is shown in Figure 9.
Figure 9. Thermalloy #2328B Heat Sink-to-Ambient Thermal Resistance Versus Airflow Velocity
8
Thermalloy #2328B Pin±fin Heat Sink
HeatSink Thermal Resistance (°C/W)
7
(25 x 28 x 15 mm)
6
5
4
3
2
1
0.5
18
1
1.5
2
2.5
Approach AirVelocity(m/s)
3
3.5
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Assuming an air velocity of 0.5 m/s, we have an effective Rsa of 7°C/W, thus
Tj = 30°C + 5°C + (2.2°C/W +1.0°C/W + 7°C/W) * 4.5 W,
resulting in a die-junction temperature of approximately 81°C which is well within the
maximum operating temperature of the component.
Other heat sinks offered by Chip Coolers, IERC, Thermalloy, Wakefield Engineering,
and Aavid Engineering offer different heat sink-to-ambient thermal resistances, and may
or may not need air flow.
Though the die junction-to-ambient and the heat sink-to-ambient thermal resistances
are a common figure-of-merit used for comparing the thermal performance of various
microelectronic packaging technologies, one should exercise caution when only using
this metric in determining thermal management because no single parameter can adequately describe three-dimensional heat flow. The final die-junction operating
temperature, is not only a function of the component-level thermal resistance, but the
system-level design and its operating conditions. In addition to the component’s power
consumption, a number of factors affect the final operating die-junction temperature-airflow, board population (local heat flux of adjacent components), heat sink efficiency,
heat sink attach, heat sink placement, next-level interconnect technology, system air
temperature rise, altitude, etc.
Due to the complexity and the many variations of system-level boundary conditions for
today’s microelectronic equipment, the combined effects of the heat transfer mechanisms (radiation, convection and conduction) may vary widely. For these reasons, we
recommend using conjugate heat transfer models for the board, as well as, system-level
designs. To expedite system-level thermal analysis, several “compact” thermal-package
models are available within FLOTHERM®. These are available upon request.
Power Consideration
Power Management
The TSPC750A provides four power modes, selectable by setting the appropriate control bits in the MSR and HIDO registers. The four power modes are as follows:
•
Full-power: This is the default power state of the TSPC750A. The TSPC750A is fully
powered and the internal functional units are operating at the full processor clock
speed. If the dynamic power management mode is enabled, functional units that are
idle will automatically enter a low-power state without affecting performance,
software execution, or external hardware.
•
Doze: All the functional units of the TSPC750A are disabled except for the time
base/decrementer registers and the bus snooping logic. When the processor is in
doze mode, an external asynchronous interrupt, a system management interrupt, a
decrementer exception, a hard or soft reset, or machine check brings the
TSPC750A into the full-power state. The TSPC750A in doze mode maintains the
PLL in a fully powered state and locked to the system external clock input
(SYSCLK) so a transition to the full-power state takes only a few processor clock
cycles.
•
Nap: The nap mode further reduces power consumption by disabling bus snooping,
leaving only the time base register and the PLL in a powered state. The TSPC750A
returns to the full-power state upon receipt of an external asynchronous interrupt, a
system management interrupt, a decrementer exception, a hard or soft reset, or a
machine check input (MCP). A return to full-power state from a nap state takes only
a few processor clock cycles. When the processor is in nap mode, if QACK is
negated, the processor is put in doze mode to support snooping.
19
2128A–HIREL–01/02
•
Sleep: Sleep mode minimizes power consumption by disabling all internal functional
units, after which external system logic may disable the PPL and SUSCLK.
Returning the TSPC750A to the full-power state requires the enabling of the PPL
and SYSCLK, followed by the assertion of an external asynchronous interrupt, a
system management interrupt, a hard or soft reset, or a machine check input (MCP)
signal after the time required to relock the PPL.
Power Dissipation
Table 7. Power Consumption
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
Processor (CPU) Frequency
200 MHz
233 MHz
266 MHz
Unit
Notes
Typical
4.2
5.0
5.7
W
1, 3, 4
Maximum
6.0
7.0
7.9
W
1, 2, 4
1.6
1.8
2.1
W
1, 2
250
250
250
mW
1, 2
300
300
300
mW
1, 2
Typical
30
50
50
mW
1, 3
Maximum
60
100
100
mW
1, 2
Full-On Mode
Doze Mode
Maximum
Nap Mode
Maximum
Sleep Mode
Maximum
Sleep Mode—PLL and DLL Disabled
Notes:
1. These values apply for all valid 60x bus and L2 bus ratios. The values do not include I/O Supply Power (OVDD and L2OVDD)
or PLL/DLL supply power (AVDD and L2AVDD). OVDD and L2OVDD power is system dependent, but is typically <10% of VDD
power. Worst case power consumption for AVDD = 15 mw and L2AVDD = 15 mW.
2. Maximum power is measured at VDD = 2.7V
3. Typical power is an average value measured at VDD = AVDD = L2AVDD = 2.6V, OVDD = L2OVDD = 3.3V in a system executing
typical applications and benchmark sequences.
4. Full-On mode is measured using worst-case instruction sequence.
Electrical
Characteristics
Static Characteristics
Table 8. DC Electrical Specifications
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
Characteristic
Symbol
Min
Max
Unit
Notes
Input High Voltage (all inputs except SYSCLK)
VIH
2
3.465
V
1,2
Input Low Voltage (all inputs except SYSCLK)
VIL
GND
0.8
V
CVIH
2.4
3.465
V
SYSCLK Input High Voltage
20
1
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Table 8. DC Electrical Specifications
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
Characteristic
Symbol
Min
Max
Unit
CVIL
GND
0.4
V
Input Leakage Current, VIN = OVDD
Iin
-
30
µA
1, 2
Hi-Z (off-state) Leakage Current, VIN = OVDD
ITSI
-
30
µA
1, 2,4
Output High Voltage, IOH = -6 mA
VOH
2.4
-
V
Output Low Voltage, IOL = 6 mA
VOL
-
0.4
V
Capacitance, VIN = 0V, f = 1 MHz
Cin
-
5.0
pF
SYSCLK Input Low Voltage
Notes:
1.
2.
3.
4.
Notes
2, 3
For 60x bus signals, the reference is OVDD while L2OVDD is the reference for the L2 bus signals.
Excludes test signals (LSSD_MODE, L1_TSTCLK, L2_TSTCLK) and IEEE 1149.1 boundary scan (JTAG) signals.
Capacitance is periodically sampled rather than 100% tested.
The leakage is measured for nominal OVDD and VDD, or both OVDD and VDD must vary in the same direction (for example,
both OVDD and VDD vary by either +5% or -5%).
Dynamic Characteristics
After fabrication, parts are sorted by maximum processor core frequency as shown in
“Clock AC Specifications” and tested for conformance to the AC specifications for that
frequency. These specifications are for 200, 233, and 266 MHz processor core frequencies. The processor core frequency is determined by the bus (SYSCLK) frequency and
the settings of the PLL_CFG[0-3] signals. Parts are sold by maximum processor core
frequency.
Clock AC Specifications
Table 9 provides the clock AC timing specifications as defined in Figure 9.
Table 9. Clock AC Timing Specifications
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
200 MHz
Num
233 MHz
266 MHz
Characteristic
Min
Max
Min
Max
Min
Max
Unit
Processor Frequency
150
200
150
233
150
266
MHz
VCO Frequency
300
400
300
466
300
533
MHz
SYSCLK Frequency
25
83.3
25
83.3
25
83.3
MHz
1
SYSCLK Cycle Time
12
40
12
40
12
40
ns
2, 3
SYSCLK Rise and Fall Time
-
2
-
2
-
2
ns
2
4
SYSCLK Duty Cycle Measured at 1.4V
40
60
40
60
40
60
%
3
SYSCLK Jitter
-
±150
-
±150
-
±150
ps
4
Internal PLL Relock Time
-
100
-
100
-
100
µs
5
Notes:
Notes
1
1. Caution: The SYSCLK frequency and PLL_CFG[0-3] settings must be chosen such that the resulting SYSCLK (bus) frequency, CPU (core) frequency, and PLL (VCO) frequency do not exceed their respective maximum or minimum operating
frequencies. Refer to the PLL_CFG[0-3] signal description in “PLL Configuration,” for valid PLL_CFG[0-3] settings
2. Rise and fall times for the SYSCLK input are measured from 0.4 to 2.4V.
3. Timing is guaranteed by design and characterization.
4. The total input jitter (short term and long term combined) must be under ±150 ps.
5. Relock timing is guaranteed by design and characterization. PLL-relock time is the maximum amount of time required for
PLL lock after a stable VDD and SYSCLK are reached during the power-on reset sequence. This specification also applies
when the PLL has been disabled and subsequently re-enabled during sleep mode. Also note that HRESET must be held
asserted for a minimum of 255 bus clocks after the PLL-relock time during the power-on reset sequence.
21
2128A–HIREL–01/02
Figure 10 provides the SYSCLK input timing diagram.
Figure 10. SYSCLK Input Timing Diagram
1
2
4
3
4
CVIH
SYSCLK
VM
VM
VM
CVIL
VM = Midpoint Voltage (1.4V)
60x Bus Input AC
Specifications
Table 10 provides the 60x bus input AC timing specifications for the TSPC750A as
defined in Figure 11 and Figure 12. Input timing specifications for the L2 bus are provided in L2 Bus Input AC Specifications.
Table 10. 60x Bus Input AC Timing Specifications(1)
VDD =AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
200, 233, 266 MHz
Num
Characteristic
Min
Max
Unit
Notes
10a
Address/Data/Transfer Attribute Inputs Valid to SYSCLK (Input
Setup)
2.5
-
ns
2
10b
All Other Inputs Valid to SYSCLK (Input Setup)
3.0
-
ns
3
10c
Mode select input setup to HRESET (DRTRY, TLBISYNC)
8
-
tsysclk
4, 5, 6, 7
11a
SYSCLK to Address/Data/Transfer Attribute Inputs Invalid
(Input Hold)
1.0
-
ns
2
11b
SYSCLK to All Other Inputs Invalid (Input Hold)
1.0
-
ns
3
11c
HRESET to mode select input hold (DRTRY, TLBISYNC)
0
-
ns
4, 6, 7
Notes:
22
1. All input specifications are measured from the TTL level (0.8 to 2.0V) of the signal in question to the 1.4V of the rising edge
of the input SYSCLK. Input and output timings are measured at the pin.
2. Address/Data/Transfer Attribute inputs are composed of the following — A[0-31], AP[0-3], TT[0-4], TBST, TSIZ[0-2], GBL,
DH[0-31], DL[0-31], DP[0-7].
3. All other signal inputs are composed of the following-TS, ABB, DBB, ARTRY, BG, AACK, DBG, DBWO, TA, DRTRY, TEA,
DBDIS, HRESET, SRESET, INT, SMI, MCP, TBEN, QACK, TLBISYNC.
4. The setup and hold time is with respect to the rising edge of HRESET (see Figure 12).
5. tsysclk is the period of the external clock (SYSCLK) in nanoseconds (ns). The numbers given in the table must be multiplied
by the period of SYSCLK to compute the actual time duration (in nanoseconds) of the parameter in question.
6. Guaranteed by design and characterization.
7. This specification is for configuration mode select only. Also note that the HRESET must be held asserted for a minimum of
255 bus clocks after the PLL re-lock time during the power-on reset sequence.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Figure 11 provides the input timing diagram for the TSPC750A.
Figure 11. Input Timing Diagram
SYSCLK
VM
10a
10b
11a
11b
ALL INPUTS
VM = Midpoint
Voltage (1.4V)
Figure 12 provides the mode select input timing diagram for the TSPC750A.
Figure 12. Mode Select Input Timing Diagram
VIH
HRESET
10c
11c
MODE PINS
VIH = 2.0V
60x Bus Output AC
Specifications
Table 11 provides the 60x bus output AC timing specifications for the TSPC750A as
defined in Figure 13. Output timing specifications for the L2 bus are provided in L2 Bus
Output AC Specifications.
Table 11. 60x Bus Output AC Timing Specifications (1)
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C, CL = 50 pF(2)
200, 233, 266 MHz
Num
Characteristic
Min
Max
Unit
Notes
12
SYSCLK to Output Driven (Output Enable Time)
0.5
-
ns
13
SYSCLK to Output Valid (TS, ABB, ARTRY, DBB)
-
6.5
ns
5
14
SYSCLK to all other Outputs Valid (all except TS, ABB, ARTRY,
DBB)
-
6.5
ns
5
15
SYSCLK to Output Invalid (Output Hold)
1.0
-
ns
3
16
SYSCLK to Output High Impedance (all except ABB, ARTRY, DBB)
-
6.0
ns
8
17
SYSCLK to ABB, DBB High Impedance after precharge
-
1.0
tsysclk
4, 6, 8
18
SYSCLK to ARTRY High Impedance before precharge
-
5.5
ns
8
23
2128A–HIREL–01/02
Table 11. 60x Bus Output AC Timing Specifications (Continued)(1)
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C, CL = 50 pF(2)
200, 233, 266 MHz
Num
Characteristic
19
20
21
Notes:
Min
Max
Unit
Notes
SYSCLK to ARTRY Precharge Enable
0.2*tsysclk
+1.0
-
ns
3, 4, 7
Maximum Delay to ARTRY Precharge
-
1
tsysclk
4, 7
SYSCLK to ARTRY High Impedance After Precharge
-
2
tsysclk
4, 7, 8
1. All output specifications are measured from the 1.4V of the rising edge of SYSCLK to TTL level (0.8 V or 2.0 V) of the signal
in question. Both input and output timing are measured at the pin.
2. All maximum timing specifications assume CL = 50 pF.
3. This minimum parameter assumes CL = 0 pF.
4. tsysclk is the period of the external bus clock (SYSCLK) in nanoseconds (ns). The numbers given in the table must be multiplied by the period of SYSCLK to compute the actual time duration of the parameter in question.
5. Output signal transitions from GND to 2.0V or OVDD to 0.8V.
6. Nominal precharge width for ABB and DBB is 0.5 tsysclk.
7. Nominal precharge width for ARTRY is 1.0 tsysclk.
8. Guaranteed by design and characterization.
Figure 13. Output Timing Diagram
VM
VM
VM
SYSCLK
14
15
16
12
ALL OUTPUTS
(Except TS, ABB,
ARTRY, DBB)
15
13
16
13
TS
17
ABB, DBB
21
20
19
18
ARTRY
VM = Midpoint Voltage (1.4V)
24
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
L2 Clock AC Specifications
Table 12. L2CLK Output AC Timing Specifications
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC,-55 ≤ Tj < 125°C
Num
Characteristic
Min
Max
Unit
Notes
L2CLK Frequency
80
133
MHz
1, 5
22
L2CLK Cycle Time
7.5
12.5
ns
23
L2CLK Duty Cycle
50
L2CLK Jitter
Internal DLL-relock Time
Notes:
640
%
2
±150
ps
3
-
L2CLK
4
1. L2CLK outputs are L2CLK_OUTA, L2CLK_OUTB and L2SYNC_OUT pins. The L2 cache interface supports higher frequencies when appropriate load conditions have been considered. The L2 I/O drivers have been designed to support a 133 MHz
L2 bus loaded with 4 off-the-shelf pipelined synchronous burst SRAMs. Running the L2 bus beyond 133 MHz requires tightly
coupled customized SRAMs or a multi-chip module (MCM) implementation. The L2CLK frequency to core frequency settings must be chosen such that the resulting L2CLK frequency and core frequency do not exceed their respective maximum
or minimum operating frequencies. L2CLK_OUTA and L2CLK_OUTB must have equal loading.
2. The nominal duty cycle of the L2CLK is 50% measured at midpoint voltage.
3. The total input jitter (short term and long term combined) must be under ±150 ps.
4. The DLL re-lock time is specified in terms of L2CLKs. The number in the table must be multiplied by the period of L2CLK to
compute the actual time duration in nanoseconds. Re-lock timing is guaranteed by design and characterization.
5. The L2CR[L2SL] bit should be set for L2CLK frequencies less than 110 MHz.
25
2128A–HIREL–01/02
The L2CLK_OUT timing diagram is shown in Figure 14.
Figure 14. L2CLK_OUT Output Timing Diagram
22
L2 Single±Ended Clock Mode
23
VM
VM
VM
VM
VM
VM
VM
VM
VM
L2CLK_OUTA
L2CLK_OUTB
L2SYNC_OUT
VM = Midpoint Voltage (L2OVdd/2)
22
L2 Differential Clock Mode
L2OVdd
23
L2CLK_OUTB
VM
VM
VM
VM
VM
VM
L2CLK_OUTA
GND
L2SYNC_OUT
VM = Midpoint Voltage (L2OVdd/2)
Table 13 shows the L2 bus input timing diagrams for the TSPC750A.
Figure 15. L2 Bus Input Timing Diagrams
29
L2SYNC_IN
30
VM
24
25
ALL INPUTS
VM = Midpoint Voltage (1.4V)
26
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
L2 Bus Input AC
Specifications
The L2 bus input interface AC timing specifications are found in Table 13.
Table 13. L2 Bus Input Interface AC Timing Specifications, see note (1)
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C
Processor Frequency
200-266 MHz
Num
Characteristic
29, 30
L2SYNC_IN rise and fall time
24
25
Notes:
Min
Max
Unit
Notes
-
1.0
ns
2
Data and parity input setup to L2SYNC_IN
2.0
-
ns
L2SYNC_IN to data and parity input hold
0.5
_
ns
1. All input specifications are measured from the TTL level (0.8V or 2.0V) of the signal in question to the midpoint voltage of the
rising edge of the input L2SYNC_IN. Input timings are measured at the pins (see Figure 15).
2. Rise and fall times for the L2SYNC_IN input are measured from 0.4 to 2.4V.
L2 Bus Output AC
Specifications
Table 14 provides the L2 bus output interface AC timing specifications for the
TSPC750A as defined in Figure 16.
Table 14. L2 Bus Output Interface AC Timing Specifications see note (1)
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C, CL = 20 pF
see note (3)
L2CR[14-15] is equivalent to:
00
(2)
01
10
11
Min
Max
Min
Max
Min
Max
Min
Max
Unit
L2SYNC_IN to output valid
-
5.0
-
5.5
-
5.7
-
6
ns
27
L2SYNC_IN to output hold
0.5
-
1.0
-
1,2
-
1,5
-
ns
28
L2SYNC_IN to high impedance
-
4.0
-
4.5
-
4.7
-
5
ns
Num
Characteristic
26
Notes:
Notes
4
1. All outputs are measured from the midpoint voltage of the rising edge of L2SYNC_IN to the TTL level (0.8V or 2.0V) of the
signal in question. The output timings are measured at the pins.
2. The outputs are valid for both single-ended and differential L2CLK modes. For flow-THRU and pipelined reg-reg synchronous burst RAMs, L2CR[14-15] = 00 is recommended. For pipelined delay-write synchronous burst SRAMs, L2CR[14-15] =
01 is recommended.
3. All maximum timing specifications assume CL = 20 pF.
4. This measurement assumes CL = 5 pF.
5. Reserved for future use.
27
2128A–HIREL–01/02
Figure 16 shows the L2 bus output timing diagrams for the TSPC750A.
Figure 16. L2 Bus Output Timing Diagrams
VM
VM
L2SYNC_IN
26
27
ALL OUTPUTS
28
L2DATA BUS
VM = Midpoint Voltage(1.4V)
IEEE 1149.1 AC Timing
Specifications
Table 15 provides the IEEE 1149.1 (JTAG) AC timing specifications as defined in Figure
17, Figure 18, Figure 19, and Figure 20.
Table 15. JTAG AC Timing Specifications (Independent of SYSCLK)
VDD = AVDD = L2AVDD = 2.6 VDC ± 100 mV, OVDD = L2OVDD = 3.3 ± 5% VDC, GND = 0 VDC, -55 ≤ Tj < 125°C, CL = 50 pF
Num
Min
Max
Unit
TCK Frequency Of Operation
0
33.3
MHz
1
TCK Cycle Time
30
-
ns
2
TCK Clock Pulse Width Measured at 1.4V
15
-
ns
3
TCK Rise and Fall Times
0
2
ns
4
Specification Obsolete, Intentionally Omitted
5
TRST Assert Time
25
-
ns
1
6
Boundary-scan Input Data Setup Time
4
-
ns
2
7
Boundary-scan Input Data Hold Time
15
-
ns
2
8
TCK to Output Data Valid
4
20
ns
3
9
TCK to Output High Impedance
3
19
ns
3, 4
10
TMS, TDI Data Setup Time
0
-
ns
11
TMS, TDI Data Hold Time
12
-
ns
12
TCK to TDO Data Valid
4
12
ns
13
TCK to TDO High Impedance
3
9
ns
Notes:
28
Characteristic
1.
2.
3.
4.
Notes
4
TRST is an asynchronous level sensitive signal. The setup time is for test purposes only.
Non-JTAG signal input timing with respect to TCK.
Non-JTAG signal output timing with respect to TCK.
Guaranteed by design and characterization.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Figure 17 provides the JTAG clock input timing diagram.
Figure 17. JTAG Clock Input Timing Diagram
1
2
VM
TCK
3
2
VM
VM
3
VM = Midpoint Voltage
Figure 18 provides the TRST timing diagram.
Figure 18. TRST Timing Diagram
TRST
5
Figure 19 provides the boundary-scan timing diagram.
Figure 19. Boundary-Scan Timing Diagram
TCK
6
DATA INPUTS
7
INPUT DATA VALID
8
DATA OUTPUTS
OUTPUT DATA VALID
9
DATA OUTPUTS
8
DATA OUTPUTS
OUTPUT DATA VALID
29
2128A–HIREL–01/02
Figure 20 provides the test access port timing diagram.
Figure 20. Test Access Port Timing Diagram
TCK
10
TDI, TMS
11
INPUT DATA VALID
12
TDO
OUTPUT DATA VALID
13
TDO
12
TDO
OUTPUT DATA VALID
Preparation for
Delivery
Packaging
Microcircuits are prepared for delivery in accordance with MIL-PRF-38535.
Certificate of Compliance ATMEL-Grenoble offers a certificate of compliances with each shipment of parts, affirming the products are in compliance either with MIL-PRF-883 and guaranteeing the
parameters not tested at temperature extremes for the entire temperature range.
Handling
MOS devices must be handled with certain precautions to avoid damage due to accumulation of static charge. Input protection devices have been designed in the chip to
minimize the effect of static buildup. However, the following handling practices are
recommended:
a) Devices should be handled on benches with conductive and grounded surfaces.
b) Ground test equipment, tools and operator.
c) Do not handle devices by the leads.
d) Store devices in conductive foam or carriers.
e) Avoid use of plastic, rubber, or silk in MOS areas.
f) Maintain relative humidity above 50 percent if practical.
g) For CI-CGA packages, use specific tray to take care of the highest height of the
package compared with the regular CBGA.
30
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Clock Relationships
Choice
The TSPC750A’s PLL is configured by the PLL_CFG[0-3] signals. For a given SYSCLK
(bus) frequency, the PLL configuration signals set the internal CPU and VCO frequency
of operation. The PLL configuration for the TSPC750A is shown in Table 16 for nominal
frequencies. Table 17 provides sample core-to-L2 frequencies.
Table 16. TSPC750A Microprocessor PLL Configuration
Sample Bus-to-Core Frequency in MHz (VCO Frequency in MHz)
PLL_CFG
[0-3]
Bus-toCore
Multiplier
Core-to
VCO
Multiplier
Bus 50
MHz
Bus
66.6
MHz
Bus 75
MHz
Bus
83.3
MHz
1000
3x
2x
150
(300)
200
(400)
225
(450)
250
(500)
1110
3.5x
2x
175
(350)
233
(466)
262
(525)
1010
4x
2x
160
(320)
200
(400)
266
(533)
0111
4.5x
2x
150
(300)
180
(360)
225
(450)
1011
5x
2x
166
(333)
200
(400)
250
(500)
1001
5.5x
2x
183
(366)
220
(440)
1101
6x
2x
150
(300)
200
(400)
240
(480)
0101
6.5x
2x
162
(325)
216
(433)
260
(520)
0010
7x
2x
175
(350)
233
(466)
0001
7.5x
2x
187
(375)
250
(500)
1100
8x
2x
200
(400)
266
(533)
Bus 25
MHz
Bus
33.3
MHz
Bus 40
MHz
0011
PLL off/bypass
PLL off, SYSCLK clocks core circuitry directly, 1x bus-to-core implied
1111
PLL off
PLL off, no core clocking occurs
Notes:
Bus
100
MHz
1. PLL_CFG[0—3] settings not listed are reserved.
2. The sample bus-to-core frequencies shown are for reference only. Some PLL configurations may select bus, core, or VCO
frequencies which are not useful, not supported, or not tested for by the TSPC750A; see “Clock AC Specifications,” for valid
SYSCLK and VCO frequencies.
3. In PLL-bypass mode, the SYSCLK input signal clocks the internal processor directly, the PLL is disabled, and the bus mode
is set for 1:1 mode operation. This mode is intended for factory use only.
Note: The AC timing specifications given in this document do not apply in PLL-bypass mode.
4. In clock-off mode, no clocking occurs inside the TSPC750A regardless of the SYSCLK input.
31
2128A–HIREL–01/02
Table 17. Sample Core-to-L2 Frequencies
Core Frequency in MHz
÷1
÷1.5
÷2
÷2.5
÷3
200
200
133.3
100
80
-
208.3
208
138.6
104
83.3
-
210
210
140
105
84
-
220
220
146.6
110
88
-
225
225
150
112.5
90
-
233.3
233.3
155.5
116.6
93.3
-
240
240
160
120
96
80
266
266
177.3
133
106.4
88.6
Note:
1. The core and L2 frequencies are for reference only. Some configurations may select core or L2 frequencies which are not
useful, not supported, or not tested for by the TSPC750A; see “L2 Clock AC Specifications,” for valid L2CLK frequencies.
The L2CR[L2SL] bit should be set for L2CLK frequencies less than 110 MHz.
System Design
Information
PLL Power Supply
Filtering
The AVDD and L2AVDD power signals are provided on the TSPC750A to provide power
to the clock generation phase-locked loop and L2 cache delay-locked loop respectively.
To ensure stability of the internal clock, the power supplied to the AV DD input signal
should be filtered using a circuit similar to the one shown in Figure 21. The circuit should
be placed as close as possible to the AVDD pin to ensure it filters out as much noise as
possible. An identical but separate circuit should be placed as close as possible to the
L2AVDD pin.
Figure 21. PLL Power Supply Filter Circuit
10 Ω
VDD
AVDD (or L2AVDD)
10 µF
0.1 µF
GND
Decoupling
Recommendations
32
Due to the TSPC750A’s dynamic power management feature, large address and data
buses, and high operating frequencies, the TSPC750A can generate transient power
surges and high frequency noise in its power supply, especially while driving large
capacitive loads. This noise must be prevented from reaching other components in the
TSPC750A system, and the TSPC750A itself requires a clean, tightly regulated source
of power. Therefore, it is recommended that the system designer place at least one
decoupling capacitor at each VDD and OVDD pin (and L2OVDD for the 360 CBGA) of the
TSPC750A. It is also recommended that these decoupling capacitors receive their
power from separate VDD, OVDD, and GND power planes in the PCB, utilizing short
traces to minimize inductance.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
These capacitors should vary in value from 220 pF to 10 µF to provide both high- and
low-frequency filtering, and should be placed as close as possible to their associated
V DD or OV DD pins. Suggested values for the V DD pins-220 pF (ceramic), 0.01 µF
(ceramic), and 0.1 µF (ceramic). Suggested values for the OV DD pins — 0.01 µF
(ceramic), 0.1 µF (ceramic), and 10 µF (tantalum). Only SMT (surface mount technology) capacitors should be used to minimize lead inductance.
In addition, it is recommended that there be several bulk storage capacitors distributed
around the PCB, feeding the VDD and OVDD planes, to enable quick recharging of the
smaller chip capacitors. These bulk capacitors should have a low ESR (equivalent
series resistance) rating to ensure the quick response time necessary. They should also
be connected to the power and ground planes through two vias to minimize inductance.
Suggested bulk capacitors-100 µF (AVX TPS tantalum) or 330 µF (AVX TPS tantalum).
Connection
Recommendations
To ensure reliable operation, it is highly recommended to connect unused inputs to an
appropriate signal level. Unused active low inputs should be tied to VDD. Unused active
high inputs should be connected to GND. All NC (no-connect) signals must remain
unconnected.
Power and ground connections must be made to all external VDD, OVDD, and GND pins
of the TSPC750A.
External clock routing should ensure that the rising-edge of the L2 clock is coincident at
the CLK input of all SRAMs and at the L2SYNC_IN input of the TSPC750A. The
L2CLKOUTA network could be used only, or the L2CLKOUTB network could also be
used depending on the loading, frequency, and number of SRAMs.
Output Buffer DC
Impedance
The TSPC750A 60x and L2 I/O drivers were characterized over process, voltage, and
temperature. To measure Z0, an external resistor is connected to the chip pad, either to
OV DD or OGND. Then, the value of such resistor is varied until the pad voltage is
OVDD/2; see Figure 22.
The output impedance is actually the average of two components, the resistances of the
pull-up and pull-down devices. When Data is held low, SW1 is closed (SW2 is open),
and RN is trimmed until Pad = OVDD/2. RN then becomes the resistance of the pull-down
devices. When Data is held high, SW2 is closed (SW1 is open), and RP is trimmed until
Pad = OVDD/2. RP then becomes the resistance of the pull-up devices. With a properly
designed driver RP and RN are close to each other in value. Then Z0 = (RP + RN)/2.
33
2128A–HIREL–01/02
Figure 22. Driver Impedance Measurement
OVDD
RN
SW1
Pad
Data
SW2
RP
OGND
Table 18 summarizes the signal impedance results. The driver impedance values were
derived by simulation at 65°C. As the process varies, the output impedance will be
reduced by several ohms.
Table 18. Impedance Characteristics
VDD = 2.6V, OVDD = 3.3V, Tj = 65°C
Pull-up Resistor
Requirements
Process
60x
L2
Symbol
Unit
TYP
43
38
Z0
Ohms
The TSPC750A requires high-resistive (weak: 10KΩ) pull-up resistors on several control
signals of the bus interface to maintain the control signals in the negated state after they
have been actively negated and released by the TSPC750A or other bus masters.
These signals are TS, ABB, DBB, and ARTRY.
In addition, the TSPC750A has one open-drain style output that requires a pull-up resistors (weak or stronger: 4.7KΩ - 10KΩ) if it is used by the system. This signal is
CKSTP_OUT.
During inactive periods on the bus, the address and transfer attributes on the bus are
not driven by any master and may float in the high-impedance state for relatively long
periods of time. Since the TSPC750A must continually monitor these signals for snooping, this float condition may cause excessive power draw by the input receivers on the
TSPC750A or by other receivers in the system. It is recommended that these signals be
pulled up through weak (10KΩ) pull-up resistors or restored in some manner by the system. The snooped address and transfer attribute inputs are A[0-31], AP[0-3], TT[0-4],
TBST, and GBL.
34
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
The data bus input receivers are normally turned off when no read operation is in
progress and do not require pull-up resistors on the data bus. Other data bus receivers
in the system, however, may require pull-ups, or that those signals be otherwise driven
by the system during inactive periods. The data bus signals are DH[0-31], DL[0-31],
DP[0-7].
If address or data parity is not used by the system, and the respective parity checking is
disabled through HID0, the input receivers for those pins are disabled, and those pins
do not require pull-up resistors and should be left unconnected by the system. If all parity generation is disabled through HID0, then all parity checking should also be disabled
through HID0, and all parity pins may be left unconnected by the system.
No pull-up resistors are normally required for the L2 interface.
Definitions
Datasheet status
Validity
Objective specification
This datasheet contains target and goal specification for
discussion with customer and application validation.
Before design phase.
Target specification
This datasheet contains target or goal specification for
product development.
Valid during the design phase.
Preliminary specification ∝ site
This datasheet contains preliminary data. Additional data
may be published later; could include simulation result.
Valid before characterization
phase.
Preliminary specification β site
This datasheet contains also characterization results.
Valid before the
industrialization phase.
Product specification
This datasheet contains final product specification.
Valid for production purpose.
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-Grenoble customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify ATMEL-Grenoble for any
damages resulting from such improper use or sale.
35
2128A–HIREL–01/02
Package Mechanical
Data
Parameters for the
TSPC740A
The package parameters are as provided in the following list. The package types are 21
x 21 mm, 255-lead CBGA and CI-CGA.
Package outline — 21 x 21 mm
Interconnects — 255 (16 x 16 ball array - 1)
Pitch — 1.27 mm (50 mil)
Minimum module height — 2.45 mm (CBGA), 3,45 mm (CI-CGA)
Maximum module height — 3.00 mm (CBGA), 4.00 mm (CI-CGA
Ball or column diameter — 0.89 mm (35 mil)
Mechanical Dimensions of the
TSPC740A CBGA Package
36
Figure 23 provides the mechanical dimensions and bottom surface nomenclature of the
TSPC740A, 255 CBGA package.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Figure 23. Mechanical Dimensions and Bottom Surface Nomenclature of TSPC740A (CBGA)
2X
0.2
A1 CORNER
A
E
T
T
B
NOTES:
A. DIMENSIONING AND TOLERANCING
PER ASME Y14.5M, 1994.
B. DIMENSIONS IN MILLIMETERS.
C. TOP SIDE A1 CORNER INDEX IS A
METALIZED FEATURE WITH VARIOUS
SHAPES. BOTTOM SIDE A1 CORNER IS
DESIGNATED WITH A BALL MISSING
FROM THE ARRAY.
P
2X
0.2
F
N
MILLIMETERS
M
1 2 3 4 5 6 7 8 9 10 11 12 13 14 1516
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
K
A1
DIM
MIN
A
21.000 BSC
A1
0.9
B
21.000 BSC
C
2.45
D
0.820 0.930 0.032
MAX
1.10
MIN
MAX
0.827 BSC
0.035
0.043
0.827 BSC
3.000 0.096
0.118
H
C
G
H
K
G
INCHES
1.270 BSC
0.050 BSC
0.790 0.990 0.031
0.635 BSC
0.037
0.039
0.025 BSC
K
M
255X
0.074
2.00
D
0.3
T
0.15
T
E
F
N
8.3
8.5
0.327
0.335
P
9.0
9.2
0.354
0.362
37
2128A–HIREL–01/02
Mechanical Dimensions of the
TSPC740A CI-CGA Package
Figure 24 provides the mechanical dimensions and bottom surface nomenclature of
TSPC740A, 255 CI-CGA package.
Figure 24. Mechanical Dimensions and Bottom Surface Nomenclature of TSPC740A (CI-CGA)
38
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Parameters for the
TSPC750A
The package parameters are as provided in the following list. The package type is 25 x
25 mm, 360-lead CBGA and CI-CGA.
Package outline — 25 x 25 mm
Interconnects — 360 (19 x 19 ball array - 1)
Pitch — 1.27 mm (50 mil)
Minimum module height — 2.65 mm (CBGA), 3,65 mm (CI-CGA)
Maximum module height — 3.20 mm (CBGA), 4,20 mm (CI-CGA)
Ball or column diameter — 0.89 mm (35 mil)
39
2128A–HIREL–01/02
Mechanical Dimensions of the
TSPC750A CBGA Package
Figure 25 provides the mechanical dimensions and bottom surface nomenclature of the
TSPC750A, 360 CBGA package.
Figure 25. Mechanical Dimensions and Bottom Surface Nomenclature of the TSPC750A
2X
0.2
A
A1 CORNER
E
T
E3
0.2
T
P2
B
P
NOTES:
A. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
B. DIMENSIONS IN MILLIMETERS.
C. TOP SIDE A1 CORNER INDEX IS A
METALIZED FEATURE WITH VARIOUS
SHAPES. BOTTOM SIDE A1 CORNER IS
DESIGNATED WITH A BALL MISSING
FROM THE ARRAY.
D. TOP SIDE CAPACITOR ASSEMBLY AREAS
ARE CONNECTED TO POWER PLANES
BUT NOT USED
MILLIMETERS
2X
0.2
N
F
MIN
A
25.000 BSC
A1
1.1
MAX
1.3
MIN
MAX
0.984 BSC
0.043
0.052
M
N2
D3
B
1 2 3 4 5 6 7 8 910 11 12 13 14 15 16 171819
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
K
25.000 BSC
C
2.65
3.2
D
0.820 0.930
G
1.270 BSC
H
0.790 0.990
K
0.635 BSC
0.984 BSC
0.104 0.126
0.032
0.037
0.050 BSC
A1
H
0.031
0.039
C
M
0.025 BSC
0.079
2.00
N
8.3
8.5
0.327 0.335
P
9.0
9.2
0.354 0.362
D3
2.75
0.108
E3
3
0.118
K
G
360X
40
DIM
INCHES
D
N2
0.3
T
0.15
T
E
F
P2
12,5
0.492
14.3
0.563
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
Mechanical Dimensions of the
TSPC750A CI-CGA Package
Figure 26 provides the mechanical dimensions and bottom surface nomenclature of
TSPC750A, 360 CI-CGA package
Figure 26. Mechanical Dimensions and Bottom Surface Nomenclature of TSPC750A (CI-CGA)
41
2128A–HIREL–01/02
Ordering Information
TS (X) PC750A M
G
U/T 8
L
x
Revision Level(1)
E: Rev. 2.2 obsolete
H: Rev 3.1
Prefix
Prototype
Bus divider
(to be confirmed)
L: Any valid PLL configuration
Type
Temperature Range: TC
M: -55, +125°C
V: -40 C, +110°C
Max internal processor speed
8: 200 MHz
10: 233 MHz
12: 266 MHz
Package
G: CBGA
GS: CI_CGA
Screening Level(1)
_: Standard
B/Q: MIL-STD-883, Class Q
B/T: According to MIL-STD-883
U: Upscreening
U/T: Upscreening + burn-in
Note:
42
1. For availability of different versions, contact your Atmel sales office.
TSPC750A/740A
2128A–HIREL–01/02
TSPC750A/740A
43
2128A–HIREL–01/02
Atmel Headquarters
Atmel Operations
Corporate Headquarters
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San Jose, CA 95131
TEL 1(408) 441-0311
FAX 1(408) 487-2600
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2325 Orchard Parkway
San Jose, CA 95131
TEL 1(408) 436-4270
FAX 1(408) 436-4314
Microcontrollers
Atmel Corporate
2325 Orchard Parkway
San Jose, CA 95131
TEL 1(408) 436-4270
FAX 1(408) 436-4314
Atmel Nantes
La Chantrerie
BP 70602
44306 Nantes Cedex 3, France
TEL (33) 2-40-18-18-18
FAX (33) 2-40-18-19-60
Asia
Atmel Asia, Ltd.
Room 1219
Chinachem Golden Plaza
77 Mody Road Tsimhatsui
East Kowloon
Hong Kong
TEL (852) 2721-9778
FAX (852) 2722-1369
ASIC/ASSP/Smart Cards
Japan
Atmel Japan K.K.
9F, Tonetsu Shinkawa Bldg.
1-24-8 Shinkawa
Chuo-ku, Tokyo 104-0033
Japan
TEL (81) 3-3523-3551
FAX (81) 3-3523-7581
Atmel Rousset
Zone Industrielle
13106 Rousset Cedex, France
TEL (33) 4-42-53-60-00
FAX (33) 4-42-53-60-01
RF/Automotive
Atmel Heilbronn
Theresienstrasse 2
Postfach 3535
74025 Heilbronn, Germany
TEL (49) 71-31-67-0
FAX (49) 71-31-67-2340
Atmel Colorado Springs
1150 East Cheyenne Mtn. Blvd.
Colorado Springs, CO 80906
TEL 1(719) 576-3300
FAX 1(719) 540-1759
Biometrics/Imaging/Hi-Rel MPU/
High Speed Converters/RF Datacom
Atmel Grenoble
Avenue de Rochepleine
BP 123
38521 Saint-Egreve Cedex, France
TEL (33) 4-76-58-30-00
FAX (33) 4-76-58-34-80
Atmel Colorado Springs
1150 East Cheyenne Mtn. Blvd.
Colorado Springs, CO 80906
TEL 1(719) 576-3300
FAX 1(719) 540-1759
Atmel Smart Card ICs
Scottish Enterprise Technology Park
Maxwell Building
East Kilbride G75 0QR, Scotland
TEL (44) 1355-803-000
FAX (44) 1355-242-743
e-mail
[email protected]
Web Site
http://www.atmel.com
© Atmel Corporation 2002.
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 errors
which may appear in this document, reserves the right to change devices or specifications detailed herein at any time without notice, and does
not make any commitment to update the information contained herein. No licenses to patents or other intellectual property of Atmel are granted
by the Company in connection with the sale of Atmel products, expressly or by implication. Atmel’s products are not authorized for use as critical
components in life support devices or systems.
ATMEL ® is the registered trademarks of Atmel.
PowerPC ® is the registered trademark of IBM Company.
Other terms and product names may be the trademarks of others.
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