ETC IBM25PPC750L

PowerPC 740 and PowerPC 750
Microprocessor Datasheet
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Version 2.0
09/6/2002
IBM Microelectronics Division
Notices
Before using this information and the product it supports, be sure to read the general information on the
back cover of this book.
Trademarks
The following are trademarks of International Business Machines Corporation in the United States, or
other countries, or both:
IBM
IBM Logo
PowerPC
AIX
PowerPC 750
PowerPC 740
Other company, product, and service names may be trademarks or service marks of others.
This document contains information on a new product under development by IBM. IBM reserves the
right to change or discontinue this product without notice.
© International Business Machines Corporation 2001, 2002.
All rights reserved.
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Table of Contents
Preface ..................................................................................................................................................... 5
New Features for dd3.x ............................................................................................................................ 5
Overview................................................................................................................................................... 6
Features ................................................................................................................................................... 7
General Parameters ................................................................................................................................. 9
Electrical and Thermal Characteristics ................................................................................................... 10
DC Electrical Characteristics .............................................................................................................. 10
AC Electrical Characteristics .................................................................................................................. 14
Clock AC Specifications ...................................................................................................................... 14
Spread Spectrum Clock Generator (SSCG) ....................................................................................... 15
60x Bus Input AC Specifications ......................................................................................................... 16
60x Bus Output AC Specifications ...................................................................................................... 18
L2 Clock AC Specifications ................................................................................................................. 20
L2 Bus Input AC Specifications ........................................................................................................... 22
L2 Bus Output AC Specifications ........................................................................................................ 23
IEEE 1149.1 AC Timing Specifications .................................................................................................. 25
PowerPC 740 Microprocessor Pin Assignments .................................................................................... 27
PowerPC 740 Package .......................................................................................................................... 30
Mechanical Dimensions of the PowerPC 740 255 CBGA Package .................................................... 31
PowerPC 750 Microprocessor Pin Assignments .................................................................................... 32
PowerPC 750 Package .......................................................................................................................... 35
Mechanical Dimensions of the PowerPC 750 360 CBGA Package .................................................... 36
System Design Information .................................................................................................................... 38
PLL Power Supply Filtering ................................................................................................................. 41
Decoupling Recommendations ........................................................................................................... 41
Connection Recommendations ........................................................................................................... 41
Output Buffer DC Impedance .............................................................................................................. 42
Pull-up Resistor Requirements ........................................................................................................... 43
Thermal Management Information ...................................................................................................... 45
Internal Package Conduction Resistance ........................................................................................... 46
Heat Sink Selection Example .............................................................................................................. 48
Ordering Information............................................................................................................................... 51
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Preface
The PowerPC 740 and PowerPC 750 are members of the PowerPC family of reduced instruction set
computer (RISC) microprocessors. The PPC740L and PPC750L microprocessors are the PID-8p implementations of the PowerPC 740 and PowerPC 750 in IBM CMOS 7S 0.20 µm copper technology. They are
referred to in the body of this document as “740“ and “750.”
Information in this document does not apply to implementations of the PowerPC 740 and PowerPC 750 in
other technologies, such as the PID-8t.
The information in this document is also specific to revision level dd3.2 of the (PID-8p) PPC740L and
PPC750L, and does not apply to previous revisions.
This document is generally written in terms of the 750. Unless otherwise noted, information that applies to the
750 also applies to the 740. Exceptions are detailed.
The 740 uses the same die as the 750, but the 740 does not bring the L2 cache interface out to external
package pins.
New Features for dd3.x
• Selectable I/O voltages on 60X bus and L2 bus. See ”Recommended Operating Conditions,” on page 11.
Older revs must leave these pins “no connect” or “tied high” for 3.3v I/Os. AC timings are the same for all
I/O voltages modes unless otherwise noted.
• 60X bus:core frequency ratios now also support the 10x ratio. See ”PLL Configuration,” on page 40.
• Extra output hold on the 60x bus by L2_TSTCLK pin tied low is no longer available. The L2_TSTCLK pin
must now be tied to OVDD for normal operation. See ”60X Bus Output AC Timing Specifications for the
7501,” on page 18.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Overview
The 750 is targeted for high performance, low power systems and supports the following power management
features: doze, nap, sleep, and dynamic power management. The 750 consists of a processor core and an
internal L2 Tag combined with a dedicated L2 cache interface and a 60x bus. The L2 cache is not available
with the 740.
Figure 1 shows a block diagram of the 750.
Figure 1. 750 Block Diagram
Control Unit
Completion
Instruction Fetch
Branch Unit
32K ICache
System
Unit
BHT /
BTIC
Dispatch
GPRs
FXU1
FXU2
FPRs
LSU
32K DCache
FPU
Rename
Rename
Buffers
Buffers
L2 Tags
L2 Cache
BIU
9/6/2002
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60X
BIU
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Features
This section summarizes features of the implementation of the PowerPC 750 architecture. For details, see
the PowerPC 740 and PowerPC750 User’s Manual.
• Branch processing unit
- 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) for eliminating branch delay
slots.
• Dispatch unit
- Full hardware detection of dependencies (resolved in the execution units).
- Dispatch two instructions to six independent units (system, branch, load/store, fixed-point unit 1,
fixed-point unit 2, or floating-point).
- Serialization control (predispatch, postdispatch, execution, serialization).
• Decode
- Register file access.
- Forwarding control.
- Partial instruction decode.
• Load/store unit
- One cycle load or store cache access (byte, half word, word, double word).
- Effective address generation.
- 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.
- Big and little-endian byte addressing supported.
- Misaligned little-endian support in hardware.
• Fixed-point units
- 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.
• Floating-point unit
- Support for IEEE-754 standard single- and double-precision floating-point arithmetic.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
-
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.
• System unit
- Executes CR logical instructions and miscellaneous system instructions.
- Special register transfer instructions.
• Cache structure
- 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.
• Memory management unit
- 128 entry, 2-way set associative instruction TLB.
- 128 entry, 2-way set associative data TLB.
- Hardware reload for TLB's.
- 4 instruction BAT's and 4 data BATs.
- Virtual memory support for up to 4 exabytes (252) virtual memory.
- Real memory support for up to 4 gigabytes (232) of physical memory.
• Level 2 (L2) cache interface (Not available on the 740)
- 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 (l-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 with optional parity checking.
- Supports Core-to-L2 frequency divisors of ÷1, ÷1.5, ÷2, ÷2.5, and ÷3. The 750 supports the L2 frequency range specified in Section “L2 Clock AC Specifications,” on page 20. For higher L2 frequencies, please contact [email protected].
• Bus interface
- Compatible with 60x processor interface.
- 32-bit address bus with optional parity checking.
- 64-bit data bus (can be operated in 32-bit data bus mode) with optional parity checking.
- Bus-to-core frequency multipliers from 2x to 10x. See the ”PLL Configuration,” on page 40.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
• Integrated power management
- Low-power 2.0/3.3V 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 Interrupts for software regulation of junction temperature.
• Testability
- JTAG interface.
General Parameters
The following list provides a summary of the general parameters of the 750.
Technology
0.20µm CMOS (general lithography), six-layer copper metallization
0.12 ± 0.04µm Leff
Die Size
5.14mm x 7.78mm (40mm2)
Transistor count
6.35 million
Logic design
Fully-static
Package
740: Surface mount 21x21mm, 255-lead ceramic ball grid array (CBGA)
750: Surface mount 25x25mm, 360-lead ceramic ball grid array (CBGA)
PPC 740/PPC 750 core
power supply
2V Nominal (see Application Conditions)
I/O power supply
3.3V 2.5V, or 1.8V (Nominal Selectable)
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Electrical and Thermal Characteristics
DC Electrical Characteristics
The 750 60x bus power supply can be either 3.3V, 2.5V, or 1.8V nominal; likewise, the L2 power supply can
be either 3.3V, 2.5V, or 1.8V nominal. See the pinout listing for more information
Absolute Maximum Ratings See Notes
Characteristic
Symbol
Value
Unit
Core supply voltage
VDD
- 0.3 to 2.2
V
PLL supply voltage
AVDD
- 0.3 to 2.2
V
L2 DLL supply voltage
L2AVDD
- 0.3 to 2.2
V
60x bus supply voltage
OVDD(3.3V)
- 0.3 to 3.6
V
OVDD(2.5V)
- 0.3 to 2.8
OVDD(1.8V)
- 0.3 to 2.1
L2OVDD
- 0.3 to 3.6
V
VIN(3.3V)
- 0.3 to 3.6
V
VIN(2.5V)
- 0.3 to 2.8
VIN(1.8V)
- 0.3 to 2.1
TSTG
- 55 to 150
L2 bus supply voltage
Input voltage
Storage temperature range
°C
Note:
1. Functional and tested operating conditions are given in Table ”Recommended Operating Conditions,” below. 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. This is a DC specification only. VIN overshoot transients up to OVDD+1V, and undershoots down to GND-1V (both measured with the 740 in the circuit) are allowed for up to 5ns.
3. Caution: OVDD must not exceed VDD/AVDD by more than 2.0V at any time during normal operation. On power up and power down, OVDD is allowed to
exceed VDD/AVDD by up to 3.3V for up to 20 ms, or by up to 2.5V for 40 ms. Excursions beyond 40 ms or 3.3V are not allowed.
4. Caution: VDD/AVDD must not exceed OVDD by more than 0.4V during normal operation. On power up and power down, VDD/AVDD is allowed to exceed
OVDD by up to1.0V for up to 20 ms, or by up to 0.7V for 40 ms. Excursions beyond 40 ms or 1.0V are not allowed.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Recommended Operating Conditions
Characteristic
Symbol
Value
Unit
Notes
Core supply voltage
VDD
See Note 2
V
1, 2
PLL supply voltage
AVDD
VDD
V
1
L2DLL supply voltage
L2AVDD
VDD
V
1
60x bus supply voltage, pin W1 tied high
OVDD(3.3V)
3.135 to 3.465
V
1
60x bus supply voltage pin W1 tied to HRESET
OVDD(2.5V)
2.375 to 2.625
V
1
60x bus supply voltage, pin W1 tied to GND
OVDD(1.8V)
1.71 to 1.89
V
1
L2 bus supply voltage, pin A19 tied high
L2OVDD(3.3V)
3.135 to 3.465
V
1
L2 bus supply voltage, pin A19 tied to HRESET
L2OVDD(2.5V)
2.375 to 2.625
V
1
L2 bus supply voltage, pin A19 tied to GND
L2OVDD(1.8V)
1.71 to 1.89
V
1
VIN(60X)
GND to OVDD
V
1
VIN(L2)
GND to L2OVDD
V
1
TJ
-40 to 105
°C
1, 2
Input voltage (Under AC conditions, inputs must go rail-torail for maximum AC timing performance.)
Die-junction temperature
Note:
1. These are recommended and tested operating conditions. Proper device operation outside of these conditions is not guaranteed.
2. VDD and TJ are specified by the Application Conditions designator in the part number. See the Part Number Key on page 51 for more information.
Package Thermal Characteristics1
Characteristic
Symbol
740
750
Unit
Thermal resistance, junction-to-case (top surface
of die) typical
θJC
0.03
0.03
°C/W
Thermal resistance, junction-to-balls, typical
θJB
3.8 - 7.12
3.8 - 7.62
°C/W
50 FPM
16.0
15.1
°C/W
100 FPM
15.4
16.4
°C/W
150 FPM
14.9
14.2
°C/W
200 FPM
14.4
13.7
°C/W
21 x 21
25 x 25
mm2
5.12 x 7.78
5.12 x 7.78
mm2
Thermal resistance, junction-to-ambient, at airflow, no heat sink, typical
Package Size
Die Size
Note:
1. Refer to Section “Thermal Management Information,” on page 45 for more information about thermal management.
2. 3.8°C/W is the theoretical θJB mounted to infinite heat sink. The larger number applies to a module mounted on a 1.8 mm thick, 2P card using 1 oz copper power/gnd planes, with an effective area for heat transfer of 75mm x 75mm.
The 750 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). See the PowerPC
740 and PowerPC 750 User’s Manual for more information on the use of this feature. Specifications for the
thermal sensor portion of the TAU are found in the table below.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Thermal Sensor Specifications
See System Design Section.
DC Electrical Specifications
See ”Recommended Operating Conditions,” on page 11, for operating conditions.
Characteristic
Symbol
Min
Max
Unit
Notes
Input high voltage (all inputs except SYSCLK)
VIH(3.3V)
2.0
3.465
V
1, 2
VIH(2.5V)
1.75
2.625
VIH()1.8V
1.4
1.89
VIL(3.3V)
GND
0.8
VIL(2.5V)
GND
0.7
VIL()1.8V
GND
0.5
CVIH(3.3V)
2.0
3.465
CVIH(2.5V)
2.0
2.625
CVIH(1.8V)
1.5
1.89
CVIL
–
Input leakage current, VIN = OVDD
IIN
Hi-Z (off state) leakage current, Vin = OVDD
Input low voltage (all inputs except SYSCLK)
V
V
1, 4
0.4
V
4
–
20
µA
1, 2
ITSI
–
20
µA
1, 2
Output high voltage, IOH = –6mA
VOH(3.3V)
2.4
–
V
Output high voltage, IOH = –6mA
VOH((2.5V))
1.9
–
V
Output high voltage, IOH = –3mA
VOH(1.8V)
1.4
–
V
Output low voltage, IOL = 6mA
VOL
–
0.4
V
Capacitance, VIN =0 V, f = 1MHz
CIN
–
5.0
pF
SYSCLK input high voltage
SYSCLK input low voltage
2,3
Note:
1. For 60x bus signals, the reference is OVDD, while L2OVDD is the reference for the L2 bus signals.
2. JTAG port signal levels are controlled by the BVSEL pin and are the same as those shown for the 60x bus. LSSD_MODE, L1_TSTCLK, and L2TSTCLK
receiver voltage levels are those shown for OVDD = 1.8V nominal, regardless of BVSEL. JTAG, LSSD_MODE, L1_TSTCLK, and L2TSTCLK values in
this table are guaranteed by design and characterization, and are not tested.
3. Capacitance values are guaranteed by design and characterization, and are not tested.
4. SYSCLK input high and low voltage: I/O timings are measured using a “rail to rail” SYSCLK; I/O timing may be less favorable if SYSCLK does not travel
from GND to OVDD.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Power Consumption for 740 and 750
See Table “Recommended Operating Conditions,” on page 11, for operating conditions
Actual Processor CPU Frequency
Unit
Notes
300
333
350
366
375
400
433
466
500A
500C
533D
Typical
3.7
4.0
4.1
4.3
4.4
4.5
5.0
5.5
6.0
6.3
6.75
W
1, 3, 4
Maximum
4.5
5.0
5.2
5.5
5.7
6.0
6.3
6.8
7.5
7.8
8.25
W
1, 2, 4
1.7
1.7
1.7
1.8
1.8
1.9
2.1
2.2
2.5
3.3
3.3
W
1, 2, 4
250
250
250
250
250
250
250
250
250
800
800
mW
1, 4
n/s
n/s
n/s
n/s
n/s
n/s
n/s
n/s
350
500
500
mW
1, 4
Full-On Mode
Doze Mode
Maximum
Nap Mode
Maximum
Sleep Mode
Maximum
Note:
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 less than 10% of VDD power. Worst case power consumption for
AVDD = 15mW and L2AVDD = 15mW.
2. Maximum power is shown for a system executing worst case benchmark sequences at:
• VDD = AVDD = L2AVDD = 2.1V (300 through 466, 500A, 500C)
• VDD = AVDD = L2AVDD = 2.15V (533D)
• OVDD = L2OVDD = 3.3V
• Tj = 65°C
Maximum power at 85°C can be derived by adding 0.1 W to the maximum power shown at 65°C. Maximum power at 105°C can be derived by
adding 0.3 W to the maximum power shown at 65°C.
3. Typical power is an average value shown for a system executing typical applications and benchmark sequences at:
• VDD = AVDD = L2AVDD = 2.0V (300 through 400)
• VDD = AVDD = L2AVDD = 2.05V (433 through 466, 500A, 500C)
• VDD = AVDD = L2AVDD = 2.1V (533D)
• OVDD = L2OVDD = 3.3V
• Tj = 45°C.
4. Guaranteed by design and characterization, and is not tested.
5. 500A column describes operation of the 500A part at 500MHz.
500C column describes operation of the 500C part at 500MHz.
533D column describes operation of the 533D part at 533MHz.
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
AC Electrical Characteristics
This section provides the AC electrical characteristics for the 750. After fabrication, parts are sorted by maximum processor core frequency as shown in the Section “Clock AC Specifications,” on page 14, and tested for
conformance to the AC specifications for that frequency. Parts are sold by maximum processor core frequency, subject to the specified application conditions. See ”Ordering Information,” on page 51. Unless otherwise noted, all timings apply for all I/O supply voltages.
Clock AC Specifications
The following table provides the clock AC timing specifications as defined in Figure 2.
Clock AC Timing Specifications
See ”Recommended Operating Conditions,” on page 11, for operating conditions.
Num
1
2, 3
4
Characteristic
Fmax ≥ 400MHz
Fmax = 300-375MHz
Unit
Notes
Min
Max
Min
Max
Processor frequency
250
As specified by
part number
250
As specified by
part number
MHz
6
SYSCLK frequency
25
100
31
100
MHz
1
SYSCLK cycle time
10
40
10
32
ns
SYSCLK rise and fall time
–
1.0
–
1.0
ns
2, 3
SYSCLK duty cycle measured
at Vm
40
60
40
60
%
3
SYSCLK jitter, cycle-to-cycle
–
±150
–
±150
ps
4, 3
Internal PLL relock time
–
100
–
100
µs
5
Note:
1. Caution: The SYSCLK frequency and the PLL_CFG[0:3] settings must be chosen such that the resulting SYSCLK (bus) frequency, and CPU (core)
frequency do not exceed their respective maximum or minimum operating frequencies. Refer to the PLL_CFG[0:3] signal description in Section “PLL
Configuration,” on page 40 for valid PLL_CFG[0:3] settings. Bus operation above 100 MHz is possible, but requires careful timing analysis. Contact
IBM for details.
2. Rise and fall times for the SYSCLK input are measured from 0.5 to 1.5V.
3. Timing is guaranteed by design and characterization, and is not tested.
4. Short term jitter must be under ±150ps.
5. Relock timing is guaranteed by design and characterization, and is not tested. 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.
6. Under certain conditions, operation at core frequencies below those stated is possible. Contact IBM for details.
Figure 2. SYSCLK Input Timing Diagram
1
2
4
3
4
CVIH
VM
SYSCLK
CVIL
Vm = OVDD/2
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PowerPC 740 and PowerPC 750 Microprocessor
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Spread Spectrum Clock Generator (SSCG)
When designing with an SSCG, there are a number of issues that must be taken into account.
An SSCG creates a controlled amount of long-term jitter. In order for a receiving PLL in the 750 to function
correctly with an SSCG, it must be able to accurately track the jitter.
The accuracy with which the 750 PLL can track the SSCG is referred to as tracking skew. When performing
system timing analysis, the tracking skew must be added to or subtracted from the I/O timing specifications,
because the skew appears as a static phase error between the internal PLL and the SSCG.
To minimize the impact on I/O timing, the following SSCG configuration is recommended:
• Down-spread mode ≤ 0.5% of the maximum frequency
• Modulation frequency of 30kHz
• Linear sweep modulation or a modulation profile (Hershey Kiss 1) as shown in Figure 3.
With this configuration, the tracking skew is less than 100 ps.
Figure 3. Linear Sweep Modulation Profile
0%
Down spread
frequency
-1%
0µs
33.3µs
Time
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CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
60x Bus Input AC Specifications
The following table provides the 60X bus input AC timing specifications for the 750 as defined in Figure 4 and
Figure 5. Input timing specifications for the L2 bus are provided in “L2 Bus Input AC Specifications,” on page
22.
60X Bus Input Timing Specifications1
See ”Recommended Operating Conditions,” on page 11, for operating conditions.
Num
Characteristic
All Frequencies
Minimum
Maximum
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)
2.5
—
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)
0.6
—
ns
2
11b
SYSCLK to All Other Inputs Invalid (Input Hold)
0.6
—
ns
3
11c
HRESET to mode select input hold
0
—
ns
4, 6, 7
(DRTRY, TLBISYNC)
Note:
1. Input specifications are measured from the Vm of the signal in question to the Vm of the rising edge of the input SYSCLK. Input and output timings are
measured at the pin (see Figure 4).
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, TBEN, QACK, TLBISYNC.
4. The setup and hold time is with respect to the rising edge of HRESET (see Figure 5).
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 ns) of the parameter in question.
6. These values are guaranteed by design, and are not tested.
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.
9/6/2002
Version 2.0
Page 16
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 4. Input Timing Diagram
VM
SYSCLK
10a 10b
11a 11b
ALL INPUTS
VM
VM
Vm = 1.4 V for OVDD = 3.3 V., else Vm = OVDD/2
Figure 5. Mode Select Input Timing Diagram
VIH
HRESET
10c
11c
MODE PINS
VIH = 2.0V
Page 17
Version 2.0
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PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
60x Bus Output AC Specifications
The following table provides the 60x bus output AC timing specifications for the 750 as defined in Figure 6.
Output timing specification for the L2 bus are provided in the “L2 Bus Output AC Specifications,” on page 23.
60X Bus Output AC Timing Specifications for the 7501
See ”Recommended Operating Conditions,” on page 11 for operating conditions, CL = 50pF2
Num
Characteristic
All Frequencies
Minimum
Unit
Notes
ns
8
Maximum
12
SYSCLK to Output Driven (Output Enable Time)
0.5
13
SYSCLK to Output Valid (TS, ABB, ARTRY, DBB, and TBST)
–
4.5
ns
5
14
SYSCLK to all other Output Valid (all except TS, ABB, ARTRY,
DBB, and TBST)
–
5.0
ns
5
15
SYSCLK to Output Invalid (Output Hold)
ns
3, 8, 9
16
SYSCLK to Output High Impedance (all signals except ABB,
ARTRY, and DBB)
–
6.0
ns
8
17
SYSCLK to ABB and DBB high impedance after precharge
–
1.0
tSYSCLK
4, 6, 8
18
SYSCLK to ARTRY high impedance before precharge
–
5.5
ns
8
19
SYSCLK to ARTRY precharge enable
ns
3, 4, 7
20
Maximum delay to ARTRY precharge
1
tSYSCLK
4, 7
21
SYSCLK to ARTRY high impedance after precharge
2
tSYSCLK
4, 7, 8
1.0
0.2×tSYSCLK + 1.0
Note:
1. All output specifications are measured from Vm of the rising edge of SYSCLK to Vm of the signal in question. Both input and output timings are measured at the pin.
2. All maximum timing specifications assume CL = 50pF.
3. This minimum parameter assumes CL = 0pF.
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. This footnote has been deleted.
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, and not tested.
9. Connecting L2_TSTCLK to GND no longer provides additional Output Hold. For new designs, L2_TSTCLK should be pulled up to OVDD, but it can be
left connected to GND in Legacy systems.
9/6/2002
Version 2.0
Page 18
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 6. Output Timing Diagram
SYSCLK
VM
VM
VM
14
15
All Outputs
(Except TS,
ABB, DBB,
ARTRY)
16
12
VM
VM
13
15
13
TS
16
VM
17
ABB, DBB
21
20
19
ARTRY
18
Vm = 1.4 V for OVDD = 3.3 V., else Vm = OVDD/2
Page 19
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
L2 Clock AC Specifications
The following table provides the L2CLK output AC timing specifications for the 750 as defined in Figure 7.
L2CLK Output AC Timing Specifications
See ”Recommended Operating Conditions,” on page 11, for operating conditions.
Num
Characteristic
Min
Max
Unit
Notes
L2CLK frequency
80
267
MHz
1, 5
22
L2CLK cycle time
3.75
12.5
ns
23
L2CLK duty cycle
50
Internal DLL-relock time
L2CLK jitter
L2CLK skew
%
2
640
—
L2CLK
4
±
±150
ps
3, 6
0
ps
7
Note:
1. L2CLK outputs are L2CLKOUTA, L2CLKOUTB and L2SYNC_OUT pins. The internal design supports higher L2CLK frequencies. Consult IBM PowerPC Application Engineering ([email protected]) before operating the L2 SRAMs above core frequency/2. 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. L2CLKOUTA and L2CLKOUTB must have equal loading.
2. The nominal duty cycle of the L2CLK is 50% measured at midpoint voltage.
3. The major component of L2CLK jitter is passed through from SYSCLK. While SYSCLK jitter is less then ±150 ps, L2CLK jitter is also less than ±150 ps.
SYSCLK jitter in excess of ±150 ps causes L2CLK jitter to exceed ±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, and is not tested.
5. The L2CR [L2SL] bit should be set for L2CLK frequencies less than 110MHz.
6. Guaranteed by design and characterization, not tested.
7. Skew between the L2 output clocks is included in the other timing specs.
9/6/2002
Version 2.0
Page 20
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 7. L2CLK_OUT Output Timing Diagram
L2 SIngle-Ended Clock Mode
22
23
VM
VM
VM
VM
VM
VM
VM
VM
VM
L2CLK_OUTA
L2CLK_OUTB
L2SYNC_OUT
Vm = 1.4 V for L2OVDD = 3.3 V., else Vm = L2OVDD/2
L2 Differential Clock Mode
22
L2OVDD
23
L2CLK_OUTB
VM
VM
VM
VM
VM
VM
L2CLK_OUTA
GND
L2SYNC_OUT
Vm = 1.4 V for L2OVDD = 3.3 V., else Vm = L2OVDD/2
Page 21
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
L2 Bus Input AC Specifications
Some specifications are shown in the following table as a Function of Maximum Core Frequency (Fmax).
These specifications refer to the effective Fmax of the part after derating for application conditions. For example, a nominal 450 MHz part running at application conditions that derate its Fmax to 400 MHz will meet or
exceed the specifications shown for Fmax = 400 MHz.
L2 Bus Input Interface AC Timing Specifications
See ”Recommended Operating Conditions,” on page 11, for operating conditions.
Num
Characteristic
Min
Max
Unit
Notes
L2SYNC_IN rise and fall time
—
1.0
ns
2, 3
24
Data and parity input setup to L2SYNC_IN, Fmax up
through 375 MHz.
1.5
—
ns
1
24
Data and parity input setup to L2SYNC_IN, Fmax = 400
MHz.
1.4
—
ns
1
24
Data and parity input setup to L2SYNC_IN, Fmax = 433 and
450 MHz.
1.1
—
ns
1
24
Data and parity input setup to L2SYNC_IN, Fmax = 466 and
above.
1.0
—
ns
1
25
L2SYNC_IN to data and parity input hold
0.5
—
ns
1
29,30
Note:
1. All input specifications are measured from the Vm of the signal in question to the Vm of the rising edge of the input L2SYNC_IN. Input timings are
measured at the pins (see Figure 8).
2. Rise and fall times for the L2SYNC_IN input are measured from 0.5 to 1.5V.
3. Guaranteed by design and characterization, and not tested.
Figure 8. L2 Bus Input Timing Diagrams
29
L2SYNC_IN
30
VM
24
25
ALL INPUTS
VM
VM
Vm = 1.4 V for L2OVDD = 3.3 V., else Vm = L2OVDD/2
9/6/2002
Version 2.0
Page 22
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
L2 Bus Output AC Specifications
L2 Bus Output Interface AC Timing Specifications1
See ”Recommended Operating Conditions,” on page 11 for operating conditions, CL = 20pF3.
Num
Characteristic
L2CR[14:15] is equivalent to:
01
002
Unit
10
Notes
11
Min
Max
Min
Max
Min
Max
Min
Max
26
L2SYNC_IN to output valid,
Fmax7 up through 375 MHz.
—
3.2
—
3.7
—
Rsv5
—
Rsv5
ns
26
L2SYNC_IN to output valid, Fmax
= 400 MHz.
—
3.0
—
3.5
—
Rsv5
—
Rsv5
ns
26
L2SYNC_IN to output valid, Fmax
= 433 and 450 MHz.
—
2.6
—
3.1
—
Rsv5
—
Rsv5
ns
26
L2SYNC_IN to output valid, Fmax
= 466 and above.
—
2.4
—
2.9
—
Rsv5
—
Rsv5
ns
27
L2SYNC_IN to output hold
0.5
—
1.0
—
Rsv5
—
Rsv5
—
ns
4, 6
28
L2SYNC_IN to high impedance
—
3.5
—
4.0
—
Rsv5
—
Rsv5
ns
6
Note:
1. All outputs are measured from the Vm of the rising edge of L2SYNC_IN to the Vm of the signal in question. The output timings are measured at the pins
(see Figure 9).
2. The outputs are valid for both single-ended and differential L2CLK modes. For flow-through and pipelined reg-reg synchronous burst SRAMs,
L2CR[14:15] = 00 is recommended. For pipelined late-write synchronous burst SRAMs, L2CR[14:15] = 01 is recommended.
3. All maximum timing specifications assume CL = 20pF.
4. This measurement assumes CL= 5pF.
5. Reserved for future use.
6. Guaranteed by design and characterization, and not tested.
7. Specifications are shown as a Function of Maximum Core Frequency (Fmax). They refer to the effective Fmax of the part after derating for application
conditions. For example, a nominal 450 MHz part running at application conditions that derate its Fmax to 400 MHz will meet or exceed the specifications shown for Fmax = 400 MHz.
Page 23
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 9. L2 Bus Output Timing Diagrams
VM
VM
L2SYNC_IN
26
27
ALL OUTPUTS
VM
VM
28
L2DATA BUS
Vm = 1.4 V for L2OVDD = 3.3 V., else Vm = L2OVDD/2
9/6/2002
Version 2.0
Page 24
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
IEEE 1149.1 AC Timing Specifications
The table below provides the IEEE 1149.1 (JTAG) AC timing specifications as defined in Figure 10,
Figure 11, Figure 12, and Figure 13. The five JTAG signals are; TDI, TDO, TMS, TCK, and TRST.
JTAG AC Timing Specifications (Independent of SYSCLK)
See ”Recommended Operating Conditions,” on page 11 for operating conditions, CL = 50pF.
Num
Characteristic
Min
Max
Unit
Notes
TCK frequency of operation
0
25
MHz
1
TCK cycle time
40
—
ns
2
TCK clock pulse width measured at 1.4V
15
—
ns
3
TCK rise and fall times
0
2
ns
4
4
spec 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
16
—
ns
2
8
TCK to output data valid
4
20
ns
3, 5
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
16
—
ns
12
TCK to TDO data valid
2.5
12
ns
5
13
TCK to TDO high impedance
3
9
ns
4
Note:
1. TRST is an asynchronous level sensitive signal. Guaranteed by design.
2. Non-JTAG signal input timing with respect to TCK.
3. Non-JTAG signal output timing with respect to TCK.
4. Guaranteed by characterization and not tested.
5. Minimum spec guaranteed by characterization and not tested.
Figure 10. JTAG Clock Input Timing Diagram
1
2
TCK
3
VM
2
VM
VM
3
Vm = 1.4 V for OVDD = 3.3 V., else Vm = OVDD/2
Page 25
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 11. TRST Timing Diagram
TRST
5
Figure 12. Boundary-Scan Timing Diagram
TCK
7
6
Data Inputs
Input Data Valid
8
Data Outputs
Output Data Valid
9
Data Outputs
Figure 13. Test Access Port Timing Diagram
TCK
10
TDI, TMS
11
Input Data Valid
12
Output Data Valid
TDO
13
9
TDO
9/6/2002
Version 2.0
Page 26
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
PowerPC 740 Microprocessor Pin Assignments
The following sections contain the pinout diagrams for the PowerPC 740, a 255 pin ceramic ball grid array
(BGA) package.
Figure 14 (in part A) shows the pinout of the PPC 740, a 255 pin Ceramic Ball Grid Array (CBGA) package as
viewed from the top surface. Part B shows the side profile.
Figure 14. Pinout of the 740 255 CBGA Package as Viewed from the Top Surface
01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16
Part A
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
Not to Scale
Part B
Substrate Assembly.
Encapsulation
Page 27
Version 2.0
View
Die
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pinout Listing for the PowerPC 740 255 CBGA Package
Signal Name
Pin Number
Active
I/O
A[0:31]
C16, E04, D13, F02, D14, G01, D15, E02, D16, D04, E13,
GO2, E15, H01, E16, H02, F13, J01, F14, J02, F15, H03,
F16, F04, G13, K01, G15, K02, H16, M01, J15, P01
High
I/O
AACK
L02
Low
Input
ABB
K04
Low
I/O
AP[0:3]
C01, B04, B03, B02
High
I/O
ARTRY
J04
Low
I/O
AVDD
A10
—
—
BG
L01
Low
Input
B06
Low
Output
BR
BVSEL
H04
CI
E01
Low
Output
CKSTP_IN
D08
Low
Input
CKSTP_OUT
A06
Low
Output
CLK_OUT
D07
—
Output
DBB
J14
Low
I/O
DBG
N01
Low
Input
DBDIS
H15
Low
Input
DBWO
G04
Low
Input
DH[0:31]
P14, T16, R15, T15, R13, R12, P11, N11, R11, T12, T11, R10, High
P09, N09, T10, R09, T09, P08, N08, R08, T08, N07, R07,
T07, P06, N06, R06, T06, R05, N05, T05, T04
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, P03, N03, N04, R03, T01, T02, P04, T03, R04
High
I/O
DP[0:7]
M02, L03, N02, L04, R01, P02, M04, R02
High
I/O
DRTRY
G16
Low
Input
GBL
F01
Low
I/O
GND
C05, C12, E03, E06, E08, E09, E11, E14, F05, F07, F10,
—
F12, G06, G08, G09, G11, H05, H07, H10, H12, J05, J07,
J10, J12, K06, K08, K09, K11, L05, L07, L10, L12, M03, M06,
M08, M09, M11, M14, P05, P12
—
HRESET
A07
Low
Input
1
INT
Input
B15
Low
Input
2
D11
High
Input
L2_TSTCLK 2
D12
High
Input
LSSD_MODE 2
B10
Low
Input
MCP
C13
Low
Input
L1_TSTCLK
9/6/2002
Version 2.0
Page 28
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pinout Listing for the PowerPC 740 255 CBGA Package (cont.)
Signal Name
Pin Number
Active
I/O
NC (No-Connect)
B07, B08, C03, C06, C08, D05, D06, J16, A04, A05, A02, A03, B01, —
B05
—
OVDD
C07, E05, E07, E10, E12, G03, G05, G12, G14, K03, K05,
K12, K14, M05, M07, M10, M12, P07, P10
—
—
PLL_CFG[0:3]
A08, B09, A09, D09
High
Input
QACK
D03
Low
Input
QREQ
J03
Low
Output
RSRV
D01
Low
Output
SMI
A16
Low
Input
SRESET
B14
Low
Input
SYSCLK
C09
—
Input
TA
H14
Low
Input
TBEN
C02
High
Input
TBST
A14
Low
I/O
TCK
C11
High
Input
TDI
A11
High
Input
TDO
A12
High
Output
TEA
H13
Low
Input
TLBISYNC
C04
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
D02
Low
Output
VDD 3
F06, F08, F09, F11, G07, G10, H06, H08, H09, H11, J06,
J08, J09, J11, K07, K10, L06, L08, L09, L11
—
—
VOLTDET4
F03
Low
Output
Note:
1. BVSEL Function:
a. Unconnected or Pulled to OVDD — OVDD = 3.3 V nominal
b. Connected to HRESET — OVDD = 2.5 V nominal
c. Connected to GND — OVDD = 1.8 V nominal
If BVSEL is connected to GND with a series resistor, the resistor value must be 10 Ω or less.
2. These are test signals for factory use only and must be pulled up to OVDD for normal operation.
3. OVDD inputs supply power to the I/O drivers and VDD inputs supply power to the processor core.
4. Internally tied to GND in the 255 CBGA package. This is NOT a supply pin.
Page 29
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
PowerPC 740 Package
Package Type
Ceramic Ball Grid Array (CBGA)
Package outline
21 x 21mm
Interconnects
255 (16 x 16 ball array - 1)
Pitch
1.27mm (50mil)
Minimum module height
2.45mm
Maximum module height
3.00mm
Ball diameter
0.89mm (35mil)
9/6/2002
Version 2.0
Page 30
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Mechanical Dimensions of the PowerPC 740 255 CBGA Package
Figure 15. Mechanical Dimensions and Bottom Surface Nomenclature of the 255 CBGA Package
2X
Top View
0.2
D
A1 CORNER
A
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. DIMENSIONS IN MILLIMETERS.
3. 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.
MILLIMETERS
E
E1
DIM
A
A1
A2
b
D
D1
e
E
E1
MIN
MAX
2.45
3.00
0.80
1.00
0.90
1.10
0.82
0.93
21.00 BSC
5.443 BSC
1.27 BSC
21.00 BSC
8.075 BSC
C
0.15 C
2X
0.2
D1
B
A1 CORNER
1 2 3 4 5 6 7 8 9 10 111213141516
There is no ball
in the A01 position
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
e/2
X-ray view of balls
from top of package
e
e/2
255X
b
0.3 C A B
A2
A1
0.15 C
A
Page 31
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
PowerPC 750 Microprocessor Pin Assignments
The following sections contain the pinout diagrams for the PowerPC 750 ceramic ball grid array 360 CBGA
packages.
Figure 16 (in part A) shows the pinout of the 360 CBGA package as viewed from the top surface. Part B
shows the side profile of the 360 CBGA package to indicate the direction of the top surface view.
Figure 16. Pinout of the 750 360 CBGA Package as Viewed from the Top Surface
01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19
Part A
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
Part B
W
Substrate Assembly.
Encapsulation
9/6/2002
Version 2.0
Not to Scale
View
Die
Page 32
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pinout Listing for the PowerPC 750 360 CBGA Package
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 1
A8
—
—
BG
H1
Low
Input
BR
E7
Low
Output
BVSEL2
W012
—
Input
CKSTP_OUT
D7
Low
Output
CI
C2
Low
Output
CKSTP_IN
B8
Low
Input
CLKOUT
E3
—
Output
DBB
K5
Low
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_TSTCLK3
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
—
Output
Page 33
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pinout Listing for the PowerPC 750 360 CBGA Package (cont.)
Signal Name
Pin Number
Active
I/O
—
Output
L2CLKOUTB
L16
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
—
Input
L2SYNC_OUT
M14
—
Output
L2_TSTCLK3
F7
High
Input
L2VSEL
A192
—
Input
L2WE
N16
Low
Output
L2ZZ
G17
High
Output
LSSD_MODE3
F9
Low
Input
MCP
B11
Low
Input
—
—
—
—
NC (No-Connect)
B3, B4, B5, W19, K9,
OVDD 2
D5, D8, D12, E4, E6, E9, E11, F5, H4, J5, L5, M4, P5, R4, R6, R9,
R11, T5, T8, T12
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
9/6/2002
K114,
K194
Version 2.0
Page 34
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pinout Listing for the PowerPC 750 360 CBGA Package (cont.)
Signal Name
Pin Number
Active
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 5
G8, G10, G12, J8, J10, J12, L8, L10, L12, N8, N10, N12
—
—
VOLTDET6
K13
High
Output
Note:
1. For dd3.x on the 750 only, AVDD is no longer connected to the BGA pin. AVDD is filtered on the module from VDD. The 740 dd3.2 does require AVDD.
2. BVSEL Function:
a. Unconnected or Pulled to OVDD — L2OVDD = 3.3 V nominal
b. Connected to HRESET — OVDD = 2.5 V nominal
c. Connected to GND — OVDD = 1.8 V nominal
If BVSEL or L2VSEL is connected to GND with a series resistor, the resistor value must be 10 Ω or less.
3. These are test signals for factory use only and must be pulled up to OVDD for normal operation. During normal operation, L2_TSTCLK can be connected
to GND if required.
4. These pins are reserved for potential future use as additional L2 address pins.
5. OVDD inputs supply power to the I/O drivers and VDD inputs supply power to the processor core.
6. Internally tied to L2OVDD in the 750 360 CBGA package. This is NOT a supply pin.
PowerPC 750 Package
Package Type
Ceramic Ball Grid Array (CBGA)
Package outline
25 x 25mm
Interconnects
360 (19 x 19 ball array - 1)
Pitch
1.27mm (50mil)
Minimum module height
2.65mm
Maximum module height
3.20mm
Ball diameter
0.89mm (35mil)
Page 35
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Mechanical Dimensions of the PowerPC 750 360 CBGA Package
Figure 17. Mechanical Dimensions and Bottom Surface Nomenclature of the 360 CBGA Package
2X
0.2
Top View
A
D
CAPACITOR
D1
CHIP
MILLIMETERS
E3
E2
E1
E
E2
E3
D2
D2
D3
D3
NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. DIMENSIONS IN MILLIMETERS.
3. 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.
2X
0.2
A01 Corner Locator
B
A01 Corner
DIM
Minimum
Maximum
A
2.65
3.20
A1
0.80
1.00
A2
1.10
1.30
b
0.82
0.93
D
25.00 BSC
D1
5.443
D2
2.48
D3
6.3
e
1.27 BSC
E
25.00 BSC
E1
8.075
E2
2.48
E3
7.43
C
19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2
1
0.15 C
W
V
U
T
R
P
N
M
X-ray view of balls
L
from top of package
K
J
H
G
F
E
D
C
B
(18x)
A
e
There is no ball in the A01 position
(18x)
360X
b
A1
A
Not To Scale
9/6/2002
A2
A01 Corner
0.3 C A B
0.15 C
Note: All caps on the SCM are lower in height than the processor die.
Version 2.0
Page 36
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Figure 18. 360 CBGA Decoupling Capacitors
C4
C3
GND
GND
0.51 (typical)
1.85 (typical)
VDD
0.83 (typical)
OVDD
3.45 typical
C5
VDD
GND
L2OVDD
GND
C2
GND
C1
CHIP
OVDD
C6
GND
VDD
L2OVDD
See note 1.
GND
GND
C7
C8
A0 Corner
Chip Carrier (pins down)
Notes:
1. For PID8 - 750 dd2.x, this capacitor is connected to VDD. For dd3.x, this capacitor is connected to AVDD.
2. For dd3.x, AVDD is no longer brought to the BGA pin.
3. All installed caps are 47 nF.
Page 37
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
System Design Information
Thermal Assist Unit Specifications
Num
Characteristic
Minimum
Maximum
Unit
Notes
1
Temperature range
0
128
°C
1
2
Comparator settling time
20
—
ms
2
3
Resolution
4
—
°C
3
Note:
1. The temperature is the junction temperature of the die. The thermal assist unit's (TAU) raw output does not indicate an absolute temperature, but it must
be interpreted by software to derive the absolute junction temperature. For information on how to use and calibrate the TAU, contact [email protected]. This specification reflects the temperature span supported by the 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. For parts with nominal operating frequencies (speed sort) above 266 MHz, the settling time = 20 µs × (266/nominal frequency). For example: for 500 MHz parts, settling
time = 20 µs × (266/500) = 10.6 µs. It is recommended that the maximum value be set in THRM3 under all conditions.
3. This value is guaranteed by design and is not tested.
Thermal Assist Unit Accuracy
Some previous versions of this Datasheet incorrectly specified the accuracy of the Thermal Assist Unit (TAU).
See the PowerPC 750-PID8p Microprocessor Errata List, Version 4.4 for details.
A Design Margin has been issued, which describes a fault in the TAU of certain dd3.2 parts, which prevents
them from attaining the accuracy specified in this Datasheet. See Design Margin, PPC750L dd3.2 TAU False
High Reading Fault for more details.
The TAU is an analog device whose accuracy can be affected by various error sources. The cumulative
effects of these error sources is shown in the table sin this section. IBM strongly recommends that at least a
single-point calibration be performed on the TAU before use. More information on calibrating and improving
the accuracy of the TAU is provided in the IBM Application Note, Calibrating the Thermal Assist Unit in the
IBM25PPC750L Processors.
The table “Selected Worst Case Maximum and Minimum Readings” shows, for selected actual junction temperatures, the highest and lowest TAU reading at which an exception could be signalled by the TAU. This
table applies only to uncalibrated units. Readings for temperatures not shown can be extrapolated from the
points in the table.
Selected Worst Case Maximum and Minimum Readings
9/6/2002
Actual
Highest TAU Reading
Lowest TAU Reading
22
32
2
35
46
13
45
56
21
55
67
29
65
77
37
75
88
45
85
98
53
95
109
61
105
119
69
Version 2.0
Page 38
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
The table “Worst Case Actual Junction Temperature for Selected TAU Readings” shows, for selected TAU
readings (register settings at which the TAU is programmed to signal an exception), the worst case highest
and lowest actual junction temperatures at which the TAU could signal the interrupt. This table applies only to
uncalibrated units. Readings for temperatures not shown can be extrapolated from the points in the table.
Worst Case Actual Junction Temperature for Selected TAU Readings
Tau Reading
Lowest Actual
Highest Actual
Tau Reading
Lowest Actual
Highest Actual
22
12
47
76
64
113
24
14
49
80
68
118
28
18
54
84
72
123
32
22
59
88
75
128
36
26
64
92
79
133
40
30
69
96
83
138
44
33
74
100
87
143
48
37
79
104
91
148
52
41
84
108
94
153
56
45
89
112
98
158
60
49
94
116
102
163
64
52
99
120
106
168
68
56
103
124
110
173
72
60
108
128
113
178
Page 39
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
PLL Configuration
The 750 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.
PLL Configuration
PLL_CFG
(0:3)
Processor to Bus Frequency Ratio
bin
dec
0000
0
Rsv1
0001
1
7.5x
0010
2
7x
0011
3
PLL Bypass3
0100
4
2x6
0101
5
6.5x
0110
6
10x
0111
7
4.5x
1000
8
3x
1001
9
5.5x
1010
10
4x
1011
11
5x
1100
12
8x
1101
13
6x
1110
14
3.5x
1111
15
Off4
Note:
1. Reserved settings.
2. SYSCLK min is limited by the lowest frequency that manufacturing will support, see Section , “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 the document do not apply in PLL-bypass mode.
4. In Clock-off mode, no clocking occurs inside the 750 regardless of the SYSCLK input.
5. The VCO to core clock ratio is 2x for 740/750. This simplifies clock frequency calculations so the user can disregard the VCO frequency. The VCO will
operate correctly when the core clock is within specification.
6. Not tested.
9/6/2002
Version 2.0
Page 40
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
PLL Power Supply Filtering
The AVDD and L2AVdd are power signals provided on the 750 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 AVDD input signal should be filtered using a circuit similar to the one shown in
Figure 19. The circuit should be placed as close as possible to the AVDD pin to ensure it filters out as much
noise as possible.
For dd3.2, AVdd is filtered on the module from VDD for the 750 only and can be connected or not, at the
designer’s convenience. For the 750, the L2AVDD must be connected as shown. The 740 requires AVDD to be
supplied as usual.
Figure 19. PLL Power Supply Filter Circuit
10 Ω
VDD
AVDD (or L2AVDD)
10µF
0.1µF
GND
Decoupling Recommendations
Due to the dynamic power management of the 750, which features large address and data buses, as well as
high operating frequencies, the 750 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 750 system, and the 750 itself requires a clean, tightly regulated source of power.
Therefore, it is strongly recommended that the system designer place at least one decoupling capacitor with
a low ESR (effective series resistance) rating at each VDD and OVDD pin (and L2OVDD for the 360 CBGA) of
the 750. 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.
These capacitors should range in value from 220pF to 10µF to provide both high- and low-frequency filtering,
and should be placed as close as possible to their associated VDD or OVDD pins. Suggested values for the VDD
pins – 220pF (ceramic), 0.01µF (ceramic), and 0.1µf (ceramic). Suggested values for the OVDD and L2OVDD
pins – 0.01µF (ceramic), 0.1µf (ceramic), and 10µF (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 – 100µF (tantalum) or 330µF (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.
Page 41
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Power and ground connections must be made to all external VDD, OVDD, and GND, pins of the 750.
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 750. 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 750 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 OVDD or GND. Then the value of such resistor is
varied until the pad voltage is OVDD/2; see Figure 20, “Driver Impedance Measurement,” below.
The output impedance is actually the average of two components, the resistances of the pull-up and pulldown 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.
Figure 20. Driver Impedance Measurement
OVDD
RN
SW2
Pad
Data
SW1
RP
GND
The following table summarizes the impedance a board designer would design to for a typical process. These
values were derived by simulation at 65°C. As the process improves, the output impedance will be lower by
several ohms than this typical value.
Impedance Characteristics
VDD = 1.9V, L2OVDD=OVDD = 3.3V, TJ = 65°C
Process
60x
L2
Symbol
Unit
Typical
43
38
Z0
Ω
9/6/2002
Version 2.0
Page 42
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Pull-up Resistor Requirements
The 750 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
750 or other bus masters. These signals are: TS, ABB, DBB, TBST, GBL, and ARTRY.
In addition, the 750 has one open-drain style output (CKSTP_OUT) that requires a pull-up resistor (weak or
strong: 4.7KΩ–1KΩ) if it is used by the system.
If address or data parity is not used by the system, it should be disabled using HID0. This also disables the
parity input receivers. In most systems, the unused (and disabled) parity pins can be left unconnected; however, in some systems, these parity pins must be pulled up to OVDD by a weak (or stronger) pull-up.
No pull-up resistors are normally required for the L2 interface, the 60x bus address and AP lines, or the 60x
bus data and DP lines. 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.
HRESET and GBL must be actively driven.
Resistor Pull-up / Pull-down Requirements
Required or Recommended Actions
Signals
Strong pull-up required
CKSTP_OUT
Weak pull-up required
TLBISYNC, LSSD_MODE, L1_TSTCLK, L2TSTCLK, TS, ABB, DBB, ARTRY,
GBL, TBST
Weak pull-up or pull-down required
TCK
Weak pull-up recommended
SRESET, SMI, INT, MCP, CKSTP_IN
Weak pull-up recommended if pin not used
Page 43
AP[0:3], DP[0:3]
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Errata Summary
For errata details, see the PowerPC 750-PID 8p Microprocessor Errata List
#
Problem
Description
Impact
Solution(s)
Applies to
Version 3.2
1
L2 cache invalidate may If DPM is enabled during a Possible system failure after Turn DPM off during a
fail with DPM enabled.
global invalidate of the L2 L2 initialization and start-up. L2 tag invalidate.
cache, the global invalidate may not invalidate all
the L2’s tags.
Yes
3
dcbz that hits in L1
cache may not retry
snoop.
If a dcbz hits in the L1
cache, a snoop received
at the same time to that
address may not be serviced or get retried.
Stale data from system
memory may be read by the
other bus master, and the
line may become valid in
multiple caches.
Limit use of dcbz to
data that is protected
through software synchronization.
Yes
5
Segment register
updates may corrupt
data translation.
mtsr<in> followed by an
instruction causing a page
data address translation
can cause contention for
the segment registers.
Possible access to incorrect
real address locations or
false translation and data
access exceptions.
Insert isync, sc, or rfi
between andy mtsr<in>
and instructions that
cause a page data
address translation.
Yes
Initialize all FPRs at
POR.
Yes
Re-evaluate system
thermal design requirements and calibrate the
TAU.
Yes
8
Stfd of uninitialized FPR A stfd will hang the part if Any system using a stfd.
(Advisory) can hang part.
its source FPR has powered up in a certain state.
11
9/6/2002
Thermal Assist Unit
(TAU) accuracy specification error in dd3.2
Datasheet
Actual TAU errors are dif- If TAU reads higher than
ferent than those speciexpected, false temperature
ficed.
alarms can occur.
If TAU reads lower than
expected, it can fail to signal
a temperature alarm.
Version 2.0
Page 44
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Thermal Management Information
This section provides thermal management information for the CBGA package for air cooled applications.
Proper thermal control design is primarily dependent upon the system-level design; that is, the heat sink, air
flow, and the 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 21.
Figure 21. 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
Maximum Heatsink Weight Limit for the 360 CBGA
Force
Maximum (pounds)
Dynamic Compression
10.0
Dynamic Tensile
2.5
Static Constant (Spring Force)
8.2
Page 45
Version 2.0
9/6/2002
PowerPC 740 and PowerPC 750 Microprocessor
CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Internal Package Conduction Resistance
For the exposed-die packaging technology, shown in ”Package Thermal Characteristics1,” on page 11, the
intrinsic conduction thermal resistance paths are as follows.
• Die junction-to-case thermal resistance
• Die junction-to-ball thermal resistance
Figure 22 depicts the primary heat transfer path for a package with an attached heat sink mounted to a
printed-circuit board.
Figure 22. C4 Package with Heat Sink Mounted to a Printed-Circuit Board
Radiation
External Resistance
Convection
Heat Sink
Thermal Interface Material
Die/Package
Chip Junction
Internal Resistance
Package/Leads
Printed-Circuit Board
Radiation
External Resistance
Convection
(Note the internal versus external package resistance.)
Heat generated on the active side (ball) 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 forcedair 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.
Adhesives and Thermal Interface Materials
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 a spring clip mechanism,
Figure 23 shows the thermal performance of three thin-sheet thermal-interface materials (silicon, graphite/oil,
flouroether 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
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CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
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 printed-circuit board (see
Figure 21). Therefore the synthetic grease offers the best thermal performance, considering the low interface
pressure. Of course, the selection of any thermal interface material depends on many factors—thermal performance requirements, manufacturability, service temperature, dielectric properties, cost, etc.
Figure 23. 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
+
2
+
Specific Thermal Resistance (Kin2/W)
+
1.5
+
1
0.5
0
0
10
20
30
40
50
60
70
80
Contact Pressure (PSI)
Heat sink adhesive materials should be selected based upon high conductivity, yet adequate mechanical
strength to meet equipment shock/vibration requirements.
The following section provides a heat sink selection example using one of the commercially available heat
sinks.
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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 system cabinet
θJC is the junction-to-case thermal resistance
θINT is the thermal resistance of the thermal interface material
θSA is the heat sink-to-ambient thermal resistance
PD is the power dissipated by the device
Typical die-junction temperatures (TJ) should be maintained less than the value specified in Table “Package
Thermal Characteristics1,” on page 11. The temperature of the air cooling the component greatly depends
upon the ambient inlet air temperature and the air temperature rise within the computer 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 interface material (θINT) is typically about 1°C/
W. Assuming a TA of 30°C, a TR of 5°C, a CBGA package θJC = 0.03, and a power dissipation (PD) of 5.0 watts,
the following expression for TJ is obtained.
Die-junction temperature: TJ = 30°C + 5°C + (0.03°C/W +1.0°C/W + θSA) × 5W
For a Thermalloy heat sink #2328B, the heat sink-to-ambient thermal resistance (θSA) versus air flow velocity
is shown in Figure 24.
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Figure 24. Thermalloy #2328B Pin-Fin Heat Sink-to-Ambient Thermal Resistance vs. Air flow Velocity
Thermalloy #2328B Pin-fin Heat Sink
(25 x 28 x 15 mm)
Heat Sink Thermal Resistance (×°C/W)
8
7
6
5
4
3
2
1
0
0.5
1
1.5
2
2.5
3
3.5
Approach Air Velocity (m/s)
Assuming an air velocity of 0.5m/s, we have an effective θSA of 7°C/W, thus
TJ = 30°C + 5°C + (.03°C/W +1.0°C/W + 7°C/W) × 4.5W,
resulting in a junction temperature of approximately 71°C which is well within the maximum operating temperature of the component.
Other heat sinks are offered by other manufacturers.
Though the junction-to-ambient and the heat sink-to-ambient thermal resistances are a common figure-ofmerit 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 chip-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 dissipation, a number of factors affect the final
operating die-junction temperature. These factors might include air flow, board population (local heat flux of
adjacent components), heat sink efficiency, heat sink attach, next-level interconnect technology, system air
temperature rise, etc.
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Product Manufacturers
The following companies advertise thermal management products that may be of interest to PowerPC
designers:
3M
http://www.3m.com
Aavid Thermal Technologies
Thermalloy
http://www.aavid.com/
The Berquist Company
http://www.bergquistcompany.com/
ChipCoolers
http://www.chipcoolers.com/
Chromerics, Division of Parker Hannifin Corporation
http://www.chomerics.com/
Dow Corning
http://www.dowcorning.com/
IERC (CTS Corporation)
http://www.ctscorp.com/
Loctite, A Henkel Company
http://www.loctite.com/
Power Devices, Incorporated
http://www.powerdevices.com/
Thermagon, Inc.
http://www.thermagon.com/script/templates/default.asp
Wakefield Engineering
http://www.wakefield.com/
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PowerPC 740 and PowerPC 750 Microprocessor
Ordering Information
This section provides the part numbering nomenclature for the 750. Note that the individual part numbers correspond to a maximum processor core frequency. For available devices contact your local IBM sales office.
Figure 25. Part Number Key
IBM25PPC750L-GBYYYA2ST
The CMOS 0.20 µm
Copper Technology,
PID-8p, Implementation
of the PowerPC 740
or PowerPC 750
Shipping Container
T=Tray
R=Tape and Reel
Modifier
blank=standard
S=SER Enhancements
Revision Levels:
Level: (G=3.2)
Revision
E= 2.2
Package (B=CBGA)
Reliability Grade (2=25FIT)
Application Conditions:
A=2.0 - 2.2V, -40 - 65C
C=2.0 - 2.2V, -40 - 105C
D=2.05 - 2.2V, -40 - 65C
Processor Frequency (MHz)
Revision Level
Letter
G
Page 51
Rev
dd 3.2
Processor Version Register
0008 8302
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CMOS 0.20 µm Copper Technology, PID-8p, PPC740L and PPC750L, dd3.2
Inside of back cover
Page 53
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© International Business Machines Corporation 2001, 2002
Printed in the United States of America
9/02
All Rights Reserved
The information contained in this document is subject to change without notice. The products described in this document
are NOT intended for use in implantation, life support, or other hazardous uses where malfunction could result in death,
bodily injury, or catastrophic property damage. The information contained in this document does not affect or change IBM’s
product specifications or warranties. Nothing in this document shall operate as an express or implied license or indemnity
under the intellectual property rights of IBM or third parties. All information contained in this document was obtained in specific environments, and is presented as illustration. The results obtained in other operating environments may vary.
While the information contained herein is believed to be accurate, such information is preliminary, and should not be relied
upon for accuracy or completeness, and no representations or warranties of accuracy or completeness are made.
THE INFORMATION CONTAINED IN THIS DOCUMENT IS PROVIDED ON AN “AS IS” BASIS. In no event will IBM be liable for any damages arising directly or indirectly from any use of the information contained in this document.
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The IBM home page can be found at http://www.ibm.com
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