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Intel Itanium 2 Processor
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Intel Itanium 2 Processor 1.66 GHz with 9 MB L3 Cache
Intel Itanium 2 Processor 1.66 GHz with 6 MB L3 Cache
Intel Itanium 2 Processor 1.6 GHz with 9 MB L3 Cache
Intel Itanium 2 Processor 1.6 GHz with 6 MB L3 Cache
Intel Itanium 2 Processor 1.5 GHz with 6 MB L3 Cache
Intel Itanium 2 Processor 1.5 GHz with 4 MB L3 Cache
Intel Itanium 2 Processor 1.4 GHz with 4 MB L3 Cache
Intel Itanium 2 Processor 1.3 GHz with 3 MB L3 Cache
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Intel Itanium 2 Processor 1.0 GHz with 3 MB L3 Cache
Intel Itanium 2 Processor 900 MHz with 1.5 MB L3 Cache
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Datasheet
February 2006
Document Number: 250945-005
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Contents
Introduction.......................................................................................................................11
Overview .............................................................................................................11
Processor Abstraction Layer ...............................................................................11
Terminology.........................................................................................................12
State of Data .......................................................................................................12
Reference Documents.........................................................................................13
Electrical Specifications....................................................................................................15
®
Itanium 2 Processor System Bus......................................................................15
2.1.1 System Bus Power Pins.........................................................................15
2.1.2 System Bus No Connect ........................................................................15
System Bus Signals ............................................................................................15
2.2.1 Signal Groups.........................................................................................15
2.2.2 Signal Descriptions.................................................................................16
Package Specifications .......................................................................................17
Signal Specifications ...........................................................................................18
2.4.1 Maximum Ratings...................................................................................22
2.5.3 Activity Factor.........................................................................................24
2.5.5 Determining if a System Meets the Overshoot/Undershoot
Specifications .........................................................................................25
2.5.6 Wired-OR Signals...................................................................................28
Power Pod Connector Signals ............................................................................30
®
Pinout Specifications........................................................................................................37
Mechanical Specifications................................................................................................69
Mechanical Dimensions ......................................................................................69
Package Marking.................................................................................................72
4.2.1 Processor Top-Side Marking..................................................................72
Thermal Specifications.....................................................................................................75
Thermal Features................................................................................................75
5.1.1 Thermal Alert..........................................................................................75
5.1.3 Thermal Trip...........................................................................................76
Case Temperature ..............................................................................................76
System Management Feature Specifications...................................................................79
System Management Bus ...................................................................................79
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6.1.3 SMBus Device Addressing.....................................................................81
Processor Information ROM................................................................................82
Scratch EEPROM ...............................................................................................85
Processor Information ROM and Scratch EEPROM Supported
6.4
SMBus Transactions...........................................................................................85
Thermal Sensing Device.....................................................................................86
Thermal Sensing Device Registers.....................................................................88
6.7.1 Thermal Reference Registers ................................................................88
6.7.2 Thermal Limit Registers .........................................................................89
6.7.3 Status Register.......................................................................................89
6.7.4 Configuration Register ...........................................................................89
6.7.5 Conversion Rate Register ......................................................................90
Signals Reference............................................................................................................91
Alphabetical Signals Reference ..........................................................................91
A.1.1 A[49:3]# (I/O)..........................................................................................91
A.1.2 A20M# (I) ...............................................................................................91
A.1.3 ADS# (I/O)..............................................................................................91
A.1.4 AP[1:0]# (I/O) .........................................................................................91
A.1.5 ASZ[1:0]# (I/O) .......................................................................................91
A.1.6 ATTR[3:0]# (I/O).....................................................................................92
A.1.7 BCLKp/BCLKn (I) ...................................................................................92
A.1.8 BE[7:0]# (I/O) .........................................................................................92
A.1.9 BERR# (I/O) ...........................................................................................93
A.1.10 BINIT# (I/O)............................................................................................94
A.1.11 BNR# (I/O) .............................................................................................94
A.1.12 BPM[5:0]# (I/O) ......................................................................................94
A.1.13 BPRI# (I) ................................................................................................94
A.1.14 BR[0]# (I/O) and BR[3:1]# (I)..................................................................94
A.1.15 BREQ[3:0]# (I/O)....................................................................................95
A.1.16 CCL# (I/O)..............................................................................................96
A.1.17 CPUPRES# (O)......................................................................................96
A.1.18 D[127:0]# (I/O) .......................................................................................96
A.1.19 D/C# (I/O)...............................................................................................96
A.1.20 DBSY# (I/O) ...........................................................................................96
A.1.21 DBSY_C1# (O).......................................................................................96
A.1.22 DBSY_C2# (O).......................................................................................97
A.1.23 DEFER# (I).............................................................................................97
A.1.24 DEN# (I/O) .............................................................................................97
A.1.25 DEP[15:0]# (I/O).....................................................................................97
A.1.26 DHIT# (I) ................................................................................................97
A.1.27 DPS# (I/O)..............................................................................................98
A.1.28 DRDY# (I/O)...........................................................................................98
A.1.29 DRDY_C1# (O) ......................................................................................98
A.1.30 DRDY_C2# (O) ......................................................................................98
A.1.31 DSZ[1:0]# (I/O).......................................................................................98
A.1.32 EXF[4:0]# (I/O) .......................................................................................98
A.1.33 FCL# (I/O) ..............................................................................................99
A.1.34 FERR# (O) .............................................................................................99
A.1.35 GSEQ# (I) ..............................................................................................99
A.1.36 HIT# (I/O) and HITM# (I/O) ....................................................................99
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A.1.37 ID[9:0]# (I) ..............................................................................................99
A.1.38 IDS# (I)...................................................................................................99
A.1.39 IGNNE# (I)............................................................................................100
A.1.40 INIT# (I) ................................................................................................100
A.1.41 INT (I) ...................................................................................................100
A.1.42 IP[1:0]# (I).............................................................................................100
A.1.43 LEN[2:0]# (I/O) .....................................................................................100
A.1.44 LINT[1:0] (I) ..........................................................................................101
A.1.45 LOCK# (I/O) .........................................................................................101
A.1.46 NMI (I) ..................................................................................................101
A.1.47 OWN# (I/O) ..........................................................................................101
A.1.48 PMI# (I).................................................................................................101
A.1.49 PWRGOOD (I)......................................................................................101
A.1.50 REQ[5:0]# (I/O) ....................................................................................101
A.1.51 RESET# (I)...........................................................................................102
A.1.52 RP# (I/O) ..............................................................................................102
A.1.53 RS[2:0]# (I)...........................................................................................103
A.1.54 RSP# (I)................................................................................................103
A.1.55 SBSY# (I/O)..........................................................................................103
A.1.56 SBSY_C1# (O).....................................................................................103
A.1.57 SBSY_C2# (O).....................................................................................103
A.1.58 SPLCK# (I/O) .......................................................................................103
A.1.60 TCK (I)..................................................................................................104
A.1.61 TDI (I) ...................................................................................................104
A.1.62 TDO (O)................................................................................................104
A.1.63 THRMTRIP# (O)...................................................................................104
A.1.64 THRMALERT# (O) ...............................................................................105
A.1.65 TMS (I) .................................................................................................105
A.1.66 TND# (I/O)............................................................................................105
A.1.67 TRDY# (I) .............................................................................................105
A.1.68 TRST# (I)..............................................................................................105
A.1.69 WSNP# (I/O) ........................................................................................105
Signal Summaries .............................................................................................105
Figures
Generic Clock Waveform ....................................................................................22
SMSC Clock Waveform.......................................................................................22
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Itanium 2 Processor Pinout...............................................................................37
®
Itanium 2 Processor Package ...........................................................................69
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Itanium 2 Processor Package ...........................................................................70
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Processor Top-Side Marking on IHS...................................................................72
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®
Logical Schematic of SMBus Circuitry ................................................................80
Tables
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2-13
AGTL+ Signals DC Specifications.......................................................................18
Power Good Signal DC Specifications................................................................19
TAP Connection DC Specifications.....................................................................19
SMBus DC Specifications ...................................................................................20
LVTTL Signal DC Specifications.........................................................................20
SMBus AC Specifications ...................................................................................21
®
Source Synchronous AGTL+ Signal Group and Wired-OR Signal Group
®
Itanium 2 Processors (900 MHz, 1.0 GHz, 1.3 GHz, 1.4 GHz, 1.5 GHz/6 MB)
Source Synchronous AGTL+ Signal Group Time Dependent
Overshoot/Undershoot Tolerance for 400 MHz System Bus ..............................26
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Itanium 2 Processors (1.5 GHz/4 MB, 1.6 GHz) Source
Synchronous AGTL+ Signal Group Time-Dependent
Overshoot/Undershoot Tolerance for 400 MHz System Bus ..............................27
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Itanium 2 (9 MB) Processors Source Synchronous AGTL+
Signal Group Time-Dependent Overshoot/Undershoot Tolerance
for 533 MHz System Bus ....................................................................................27
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Itanium 2 Processors (1.66 GHz) Source Synchronous AGTL+
Signal Group Time-Dependent Overshoot/Undershoot Tolerance
for 667 MHz System Bus ....................................................................................28
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Itanium 2 Processors (900 MHz, 1.0 GHz, 1.3 GHz, 1.4 GHz,
1.5 GHz/6 MB) Wired-OR Signal Group
(BINIT#, HIT#, HITM#, BNR#, TND#, BERR#)
Overshoot/Undershoot Tolerance for 400 MHz System Bus ..............................28
®
Itanium 2 Processors (1.5 GHz/4 MB, 1.6 GHz) Wired-OR Signal
Group (BINIT#, HIT#, HITM#, BNR#, TND#, BERR#)
Overshoot/Undershoot Tolerance for 400 MHz System Bus ..............................29
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Itanium 2 (9 MB) Processors Wired-OR Signal Group
(BINIT#, HIT#, HITM#, BNR#, TND#, BERR#) Overshoot/Undershoot
Tolerance for 533 MHz System Bus ...................................................................29
®
Itanium 2 (1.66 GHz) Processors Wired-OR Signal Group
(BINIT#, HIT#, HITM#, BNR#, TND#, BERR#) Overshoot/Undershoot
Tolerance for 667 MHz System Bus ...................................................................29
®
Processor Core Voltage Identification Code .......................................................31
Processor Power States......................................................................................32
®
Connection for Unused Pins ...............................................................................35
Case Temperature Specification.........................................................................76
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®
®
Processor Information ROM Format ...................................................................82
Byte Write SMBus Packet ...................................................................................86
Write Byte SMBus Packet ...................................................................................87
Read Byte SMBus Packet...................................................................................87
Send Byte SMBus Packet ...................................................................................87
Receive Byte SMBus Packet...............................................................................87
ARA SMBus Packet ............................................................................................87
Command Byte Bit Assignment...........................................................................88
Thermal Sensing Device Status Register............................................................89
Address Space Size............................................................................................92
Effective Memory Type Signal Encoding.............................................................92
BR[3:0]# Signals and Agent IDs..........................................................................95
DID[9:0]# Encoding .............................................................................................97
Extended Function Signals..................................................................................99
Length of Data Transfers...................................................................................100
A-11 STBp[7:0]# and STBn[7:0]# Associations .........................................................104
A-12 Output Signals...................................................................................................105
A-13 Input Signals......................................................................................................106
A-14 Input/Output Signals (Single Driver)..................................................................107
A-15 Input/Output Signals (Multiple Driver) ...............................................................107
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Revision History
Revision No.
Description
Initial release of this document.
Date
July 2002
-001
-002
Updated content to include information pertaining to Itanium 2 processor June 2003
(1.5 GHz, 6 MB), Itanium 2 processor (1.4 GHz, 4 MB) and Itanium 2
processor (1.3 GHz, 3 MB).
-003
Updated content to include information pertaining to Itanium®
2
November 2004
processor (1.5 GHz, 4 MB) and Itanium 2 processor (1.6 GHz, 6 MB and
9 MB).
-004
-005
Updated content to include information pertaining to Itanium®
processor (1.66 GHz, 6 MB and 9 MB).
Updated content to include information pertaining to Itanium®
processor (533 MHz system bus speed).
2
July 2005
2
February 2006
8
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Intel® Itanium® 2 Processor
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Intel Itanium 2 Processor 1.66 GHz with 9 MB L3 Cache
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Intel Itanium 2 Processor 1.66 GHz with 6 MB L3 Cache
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Intel Itanium 2 Processor 1.6 GHz with 9 MB L3 Cache
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Intel Itanium 2 Processor 1.6 GHz with 6 MB L3 Cache
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®
Intel Itanium 2 Processor 1.5 GHz with 6 MB L3 Cache
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Intel Itanium 2 Processor 1.5 GHz with 4 MB L3 Cache
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®
Intel Itanium 2 Processor 1.4 GHz with 4 MB L3 Cache
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Intel Itanium 2 Processor 1.3 GHz with 3 MB L3 Cache
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Intel Itanium 2 Processor 1.0 GHz with 3 MB L3 Cache
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Intel Itanium 2 Processor 900 MHz with 1.5 MB L3 Cache
Product Features
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®
■ Wide, parallel hardware based on Intel Itanium
■ High bandwidth system bus for multiprocessor
architecture for high performance:
scalability:
— Integrated on-die cache of up to 9 MB; cache
hints for L1, L2, and L3 caches for reduced
memory latency.
— 128 general and 128 floating-point registers
supporting register rotation.
— Register stack engine for effective management
of processor resources.
— Support for predication and speculation.
— Up to 10.6 GB/s bandwidth.
— 128-bit wide data bus.
— 50-bits of physical memory addressing and 64-
bits of virtual addressing.
— Up to four processors on the same system bus at
400 MHz data bus frequency.
— Up to two processors on the same system bus at
533 MHz or 667 MHz data bus frequency.
■ Extensive RAS features for business-critical
— Expandable to systems with multiple system
buses.
applications:
— Full SMBus compatibility.
■ Features to support flexible platform environments:
— Support for IA-32 application binaries.
— Bi-endian support.
— Enhanced machine check architecture with
extensive ECC and parity protection.
— Enhanced thermal management.
— Built-in processor information ROM (PIROM).
— Built-in programmable EEPROM.
— Processor abstraction layer eliminates processor
dependencies.
®
®
The Intel Itanium 2 processor is designed to address the needs of high-performance servers and workstations.
The Itanium architecture goes beyond RISC and CISC approaches by employing Explicitly Parallel Instruction
Computing (EPIC), which pairs extensive processing resources with intelligent compilers that enable parallel
execution explicit to the processor. The processor’s large internal resources combine with predication and
speculation to enable optimization for high performance applications running on multiple operating systems,
including versions of Microsoft Windows*, HP-UX* and Linux*. The Itanium 2 processor is designed to support
very large scale systems, including those employing thousands of processors, to provide the processing power and
performance head room for the most demanding enterprise and technical computing applications. SMBus
compatibility and comprehensive reliability, availability and serviceability (RAS) features make the Itanium 2
processor ideal for applications requiring high up-time. For high performance servers and workstations, the
Itanium 2 processor offers outstanding performance and reliability for today’s applications and the scalability to
address the growing e-business needs of tomorrow.
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1 Introduction
1.1
Overview
The Itanium 2 processor employs Explicitly Parallel Instruction Computing (EPIC) design
concepts for a tighter coupling between hardware and software. In this design style, the interface
between hardware and software is designed to enable the software to exploit all available compile-
time information, and efficiently deliver this information to the hardware. It addresses several
fundamental performance bottlenecks in modern computers, such as memory latency, memory
address disambiguation, and control flow dependencies. The EPIC constructs provide powerful
architectural semantics, and enable the software to make global optimizations across a large
scheduling scope, thereby exposing available Instruction Level Parallelism (ILP) to the hardware.
The hardware takes advantage of this enhanced ILP, and provides abundant execution resources.
Additionally, it focuses on dynamic run-time optimizations to enable the compiled code schedule
to flow at high throughput. This strategy increases the synergy between hardware and software, and
leads to greater overall performance.
The Itanium 2 processor provides a 6-wide and 8-stage deep pipeline, running at up to 1.66 GHz.
This provides a combination of abundant resources to exploit ILP as well as increased frequency
for minimizing the latency of each instruction. The resources consist of six integer units, six
multimedia units, two load and two store units, three branch units, two extended-precision floating
point units, and one additional single-precision floating point unit. The hardware employs dynamic
prefetch, branch prediction, a register scoreboard, and non-blocking caches to optimize for
compile-time non-determinism. Three levels of on-die cache minimize overall memory latency.
This includes up to a 9 MB L3 cache, accessed at core speed, providing up to 84.8 Gb/sec of data
bandwidth. The system bus is designed to support up to four processors (on a single system bus),
and can be used as an effective building block for very large systems. The balanced core and
memory subsystem provide high performance for a wide range of applications ranging from
commercial workloads to high performance technical computing.
The Itanium 2 processor supports a range of computing needs and configurations from a 2-way to
large SMP servers. This document provides the electrical, mechanical and thermal specifications
for the Itanium 2 processor for use while using systems with Itanium 2 processors.
1.2
Processor Abstraction Layer
The Itanium 2 processor requires implementation-specific Processor Abstraction Layer (PAL)
firmware. PAL firmware supports processor initialization, error recovery, and other functionality. It
provides a consistent interface to system firmware and operating systems across processor
®
®
hardware implementations. The Intel Itanium Architecture Software Developer’s Manual,
Volume 2: System Architecture, describes PAL. Platforms must provide access to the firmware
address space and PAL at reset to allow Itanium 2 processors to initialize.
The System Abstraction Layer (SAL) firmware contains platform-specific firmware to initialize
the platform, boot to an operating system, and provide runtime functionality. Further information
®
®
about SAL is available in the Intel Itanium Processor Family System Abstraction Layer
Specification.
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Introduction
1.3
Mixing Processors of Different Frequencies and
Cache Sizes
All Itanium 2 processors on the same system bus are required to have the same cache size (9 MB,
6 MB, 4 MB, 3 MB or 1.5 MB) and identical core frequency. Mixing components of different core
frequencies and cache sizes is not supported and has not been validated by Intel. Operating system
support for multiprocessing with mixed components should also be considered.
While Intel has done nothing to specifically prevent processors within a multiprocessor
environment from operating at differing frequencies and differing cache sizes, there may be
uncharacterized errata that exist in such configurations. Customers would be fully responsible for
validation of system configurations with mixed components other than the supported
configurations described above.
1.4
Terminology
In this document, a ‘#’ symbol after a signal name refers to an active low signal. This means that a
signal is in the active state (based on the name of the signal) when driven to a low level. For
example, when RESET# is low, a processor reset has been requested. When NMI is high, a non-
maskable interrupt has occurred. In the case of lines where the name does not imply an active state
but describes part of a binary sequence (such as address or data), the ‘#’ symbol implies that the
signal is inverted. For example, D[3:0] = ‘HLHL’ refers to a hex ‘A’, and D [3:0] # = ‘LHLH’ also
refers to a hex ‘A’ (H = High logic level, L = Low logic level).
The term “system bus” refers to the interface between the processor, system core logic and other
bus agents. The system bus is a multiprocessing interface to processors, memory and I/O.
A signal name has all capitalized letters, for example, VCTERM.
A symbol referring to a voltage level, current level, or a time value carries a plain subscript, e.g.,
V
, or a capitalized abbreviated subscript, for example, T
.
CC,core
CO
1.5
State of Data
The data contained in this document is subject to change. It is the best information that Intel is able
to provide at the publication date of this document.
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Introduction
1.6
Reference Documents
The reader of this specification should also be familiar with material and concepts presented in the
following documents:
Title
Document Number
Intel® Itanium® 2 Processor Specification Update
251141
245317
Intel® Itanium® Architecture Software Developer’s Manual, Volume 1:
Application Architecture
Intel® Itanium® Architecture Software Developer’s Manual, Volume 2: System
Architecture
245318
245319
251110
Intel® Itanium® Architecture Software Developer’s Manual,
Volume 3: Instruction Set Reference
Intel® Itanium® 2 Processor Reference Manual for Software Development and
Optimization
Intel® Itanium® Processor Family System Abstraction Layer Specification
245359
249679
ITP700 Debug Port Design Guide
System Management Bus Specification
http://www.smbus.org/specs
Note: Contact your Intel representative or check http://developer.intel.com for the latest revision of the
reference documents.
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2 Electrical Specifications
This chapter describes the electrical specifications of the Itanium 2 processor.
®
2.1
Itanium 2 Processor System Bus
Most Itanium 2 processor signals use the Itanium processor’s assisted gunning transceiver logic
(AGTL+) signaling technology. The termination voltage, V
, is generated on the baseboard
CTERM
and is the system bus high reference voltage. The buffers that drive most of the system bus signals
on the Itanium 2 processor are actively driven to V during a low-to-high transition to
CTERM
improve rise times and reduce noise. These signals should still be considered open-drain and
require termination to V , which provides the high level. The Itanium 2 processor system bus
CTERM
is terminated to V
at each end of the bus. There is also support of off-die termination in
CTERM
which case the termination is provided by external resistors connected to V
.
CTERM
AGTL+ inputs use differential receivers which require a reference signal (V ). V
is used by
REF
REF
the receivers to determine if a signal is a logical 0 or a logical 1. The Itanium 2 processor generates
on-die, thereby eliminating the need for an off-chip reference voltage source.
V
REF
2.1.1
2.1.2
System Bus Power Pins
VCTERM (1.2 V) input pins on the Itanium 2 processor provide power to the driver buffers and
on-die termination. The GND pins, in addition to the GND input at the power tab connector,
provide ground to the processor. Power for the processor core is provided through the power tab
connector by V
. The 3.3 V pin is included on the processor to provide power to the system
CC,PS
management bus (SMBus). The V
, 3.3 V, and GND pins must remain electrically separated
CTERM
from each other.
System Bus No Connect
All pins designated as “N/C” or “No Connect” must remain unconnected.
2.2
System Bus Signals
2.2.1
Signal Groups
Table 2-1 contains Itanium 2 processor system bus signals that have been combined into groups by
buffer type and whether they are inputs, outputs or bidirectional with respect to the processor.
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Electrical Specifications
..
®
Table 2-1. Itanium 2 Processor System Bus Signal Groups
Group Name
Signals
AGTL+ Input Signals
AGTL+ I/O Signals
BPRI#, BR[3:1]#, DEFER#, GSEQ#, ID[9:0]#, IDS#, RESET#1, RS[2:0]#,
RSP#, TRDY#
D[127:0]#, DBSY#, DEP[15:0]#, DRDY#, HIT#, HITM#, LOCK#, REQ[5:0]#,
RP#, SBSY#, STBN[7:0]#, STBP[7:0]#, TND#
AGTL+ Output Signals
FERR#, THRMTRIP#, DBSY[1:0]#, DRDY[1:0]#, SBSY[1:0]#
A20M#, IGNNE#, INIT#, LINT[1,0], PMI#
Special AGTL+ Asynchronous
Interrupt Input Signals
Power Good Signal1
HSTL Clock Signals
TAP Input Signals1
TAP Output Signals1
System Management Signals1
Power Signals
PWRGOOD
BCLKn, BCLKp
TCK, TDI, TMS, TRST#
TDO
3.3V, SMA[2:0], SMSC, SMSD, SMWP, THRMALERT#
GND, VCTERM
LVTTL Power Pod Signals1
CPUPRES#, OUTEN, PPODGD#
TERMA, TERMB, TUNER1, TUNER2, VCCMON, VSSMON
Other
NOTES:
®
®
1. Signals will not be terminated on-die even when on-die termination (ODT) is enabled. See Intel Itanium 2 Processor
Hardware Developer’s Manual for further details.
All system bus outputs should be treated as open drain signals and require a high level source
provided by the V
supply.
CTERM
AGTL+ inputs have differential input buffers which use V
as a reference level. AGTL+ output
REF
signals require termination to V
. In this document, “AGTL+ Input Signals” refers to the
CTERM
AGTL+ input group as well as the AGTL+ I/O group when receiving. Similarly, “AGTL+ Output
Signals” refers to the AGTL+ output group as well as the AGTL+ I/O group when driving.
The Power Good (PWRGOOD) signal and Test Access Port (TAP) connection input signals use a
non-differential receiver with levels that are similar to AGTL+. No reference voltage is required for
these signals. The TAP Connection Output signals are AGTL+ output signals.
The Itanium 2 processor system bus requires termination on both ends of the bus. The Itanium 2
processor system bus supports both on-die and off-die termination controlled by two pins, TERMA
The HSTL clock signals are the differential clock inputs for the Itanium 2 processor. The SMBus
signals and LVTTL power pod signals are driven using the 3.3 V CMOS logic levels listed in
2.2.2
Signal Descriptions
Appendix A, “Signals Reference”contains functional descriptions of all system bus signals and
LVTTL power pod signals. Further descriptions of the system management signals are contained in
Chapter 6. The signals listed under the “Power” and “Other” group are described here:
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Electrical Specifications
V
System bus termination voltage.
System ground.
CTERM
GND
N/C
No connection can be made to these pins.
TERMA, TERMB
The Itanium 2 processor uses two pins to control the on-die termination
function, TERMA and TERMB. Both of these termination pins must be
pulled to VCTERM in order to terminate the system bus using the on-die
termination resistors. Both of these termination pins must be pulled to
GND in order to use off-die termination.
TUNER1, TUNER2
TUNER1 is used to control the slew rate of the system bus I/O buffers.
The nominal value for the TUNER1 resistor is 150 ohms. A lower
resistance will cause a faster slew rate. TUNER2 is used to control the
termination resistance for the system bus I/O buffers. The nominal value
for the TUNER2 resistor is 150 ohms. A lower resistance will cause a
lower on-die termination resistance. On-die termination mode will only
be selected if the TERMA and TERMB pins are terminated as indicated
above.
VCCMON, VSSMON
These pins provide a remote sense connection from the processor to the
power pod. No connections that constitute a current load can be made to
these pins.
2.3
Package Specifications
processor. The voltage and current specifications are defined at the Itanium 2 processor pins.
specifications for case temperature, clock frequency, and input voltages.
®
Table 2-2. Itanium 2 Processor Package Specifications
Core
Frequency
Symbol
Parameter
Minimum
Typ Maximum Unit Notes
1
VCTERM
RTERM
Termination Voltage
All
All
1.2 –1.5%
1.2
45
1.2 +1.5%
V
2
Recommended Termination
Resistance
W
VTAP
Test Access Port Voltage
All
1.2 –1.5%
1.2
1.5
V
(VCCTAP
)
3
4
5
6
ICTERM
Termination Voltage Current
Maximum Processor Power
Thermal Design Envelope
Thermal Design Power
All
7.2
130
130
90
A
PWRMAX
PWRTDE
PWRTDP
All
W
W
W
W
W
W
W
W
W
All
900 MHz
1.0 GHz
1.3 GHz
1.4 GHz
1.5 GHz
1.6 GHz
1.66 GHz
100
97
91
107
122
122
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NOTES:
1. This is the tolerance requirement, across a 200 MHz bandwidth, at the processor pins. The requirement at the processor pins
accounts for voltage drops (and impedance discontinuities) at the processor pins and to the processor core. In addition to the
±1.5% DC tolerance, there is a ±3.5% AC tolerance for a total of ±5% tolerance.
®
2. The Itanium 2 processor system bus is terminated at each end of the system bus. The Itanium 2 processor supports both on-
die and off-die termination which is selected by the TERMA and TERMB pins. Termination tolerance is ±15% for on-die
termination measured at V and ±1% for off-die termination.
OL
3. Maximum termination voltage current on one terminating agent.
4. For all core frequencies and cache sizes.
5. Maximum thermal design envelope is provided for the design of thermal/chassis solutions.
6. Maximum thermal design power is an estimate of the power dissipation for the Itanium 2 processor offering while executing a
worst-case application mix under nominal V
and worst-case temperature.
CC,PS
®
Table 2-3. Itanium 2 Processor Power Supply Specifications
Symbol
VCC,PS
Parameter
Minimum
Typ
Maximum
Unit Notes
1, 2
VCC from the Power Supply
VID –1.5%
VID
VID +1.5%
100
V
3
ICC,PS
Current Required from Power Supply
A
PSslew_rate
Power Supply Slew Rate at the
Processor Power Pod Connector
100
A/µs
PSTT
Power Supply Slew Rate for the
Termination Voltage at the Processor
Pins
0.05
A/ns
NOTES:
1. The power pod DC set point accuracy is ±1.5%. Included for reference only, under worst case switching activity, the power pod
tolerance is ±7%.
2. The V
CC,PS
3. The maximum current (I
) specification is intended for system power supply design. The maximum current values are
CC,PS
defined to be based on worst-case V
, temperature and application mix.
CC,PS
2.4
Signal Specifications
This section describes the DC specifications of the system bus signals. The processor signal’s DC
specifications are defined at the Itanium 2 processor pins. Table 2-4 through Table 2-9 describe the
DC specifications for the AGTL+, PWRGOOD, HSTL clock, TAP port, system management, and
LVTTL signals. Please refer to the ITP700 Debug Port Design Guide for the TAP connection
signals DC specifications at the debug port.
Table 2-4. AGTL+ Signals DC Specifications (Sheet 1 of 2)
Core
Frequency
Symbol
Parameter
Minimum
Typ
Maximum Unit Notes
1
VIL
Input Low Voltage
Input High Voltage
All
All
All
0.625
0.65
V
V
V
VIH
VIL
0.875
Input Low Voltage
(1.6x GHz, I.5 GHz/4 MB
Itanium® 2 Processors)
2
VIH
Input High Voltage
(1.6x GHz, I.5 GHz/4 MB
Itanium 2 Processors)
All
0.85
V
VOL
VOH
Output Low Voltage
Output High Voltage
All
All
0.3
0.4
V
V
VCTERM
,
VCTERM
VCTERM,
minimum
maximum
3
4
IOL
IOL
Output Low Current @ 0.3V
Output Low Current @ 0.3V
All
All
34
17
mA
mA
18
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Table 2-4. AGTL+ Signals DC Specifications (Sheet 2 of 2)
Core
Frequency
Symbol
Parameter
Minimum
Typ
Maximum Unit Notes
5
IL
Leakage Current
AGTL+ Pad Capacitance
All
±100
3
µA
pF
pF
pF
pF
pF
pF
pF
6
CAGTL+
900 MHz
1.0 GHz
1.3 GHz
1.4 GHz
1.5 GHz
1.6 GHz
1.66 GHz
3
1.5
1.5
1.5
1.5
1.5
NOTES:
1. The typical transition point between V and V assuming 125 mV V
uncertainty for ODT. V
and V
levels are
IL
IH
REF
REF_high
REF_low
V
±100 mV respectively, for a system bus agent using on-board termination. V
and V
levels are V
±125
REF
REF_high
REF_low
REF
mV respectively, for a system bus agent using on-die termination.
2. Parameter measured into a 22.5 ohm resistor to 1.2V. Minimum V and I are guaranteed by design/characterization.
OL
OL
3. Calculated using off-die termination through two 45 ohm ±1% resistors in parallel.
4. Calculated using on-die termination to a 45 ±15% resistor measured at V
.
OL
5. At 1.2V ±1.5%. V
, minimum ≤Vpin ≤V
, maximum.
CTERM
CTERM
6. Total of I/O buffer with ESD structure and processor parasitics if applicable. Capacitance values guaranteed by design for all
AGTL+ buffers.
Table 2-5. Power Good Signal DC Specifications
Symbol
VIL
VIH
Parameter
Input Low Voltage
Input High Voltage
Minimum
Maximum
Unit
Notes
0.440
V
V
0.875
Table 2-6. System Bus Clock Differential HSTL DC Specifications
Symbol
VIH
Parameter
Input High Voltage
Minimum
Maximum
Unit
Notes
0.78
–0.3
0.55
1.3
0.5
V
V
VIL
Input Low Voltage
VX
Input Crossover Voltage
Input (Pad) Capacitance
0.85
1.75
V
CCLK
pF
Table 2-7. TAP Connection DC Specifications
Symbol
VIL
Parameter
Input Low Voltage
Minimum
Maximum
Unit
Notes
1
–0.3
1.1
0.5
1.57
0.3
V
V
1, 2
2, 3
4
VIH
VOL
Input High Voltage
Output Low Voltage
Output High Voltage
Output Low Current
Input Current
V
VOH
IOL
1.2
20
V
mA
uA
IIC
690
NOTES:
1. There is a 100 mV hysteresis on TCK.
2. VIH, MAX = 1.5V + 5%, VOH, MAX = 1.2V +5%.
3. There is no internal pull-up. An external pull-up is always assumed. Max voltage tolerated at TDO is 1.5V.
4. Per input pin.
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Table 2-8. SMBus DC Specifications
Symbol
Parameter
Minimum
Typ
Maximum
Unit
Notes
3.3V
VCC for the System Management
3.14
3.3
3.47
V
3.3V ±5%
Components
VIL
VIH
Input Low Voltage
Input High Voltage
–0.3
2.31
0.3*3.3V
3.47
V
V
Max =
3.3 +5%
Min +
0.7*3.3V
VOL
I3.3V
IOL
Output Low Voltage
3.3V Supply Current
Output Low Current
Output Low Current
Input Leakage Current
Output Leakage Current
0.4
30.0
3
V
5.0
mA
mA
mA
µA
µA
1
2
IOL2
ILI
6
10
10
ILO
NOTES:
1. The value specified for I applies to all signals except for THRMALERT#.
OL
2. The value specified for I
applies only to THRMALERT# which is an open drain signal.
OL2
Table 2-9. LVTTL Signal DC Specifications
Symbol
VIL
Parameter
Input Low Voltage
Minimum
Maximum
Unit
Notes
0.8
3.63
0.4
V
V
V
V
VIH
Input High Voltage
Output Low Voltage
Output High Voltage
2.0
2.4
VOL
VOH
clocking scheme with a frequency of 200, 266 or 333 MHz. The SMBus is a subset of the I2C*
interface which supports operation of up to 100 kHz.
Table 2-10. System Bus Clock Differential HSTL AC Specifications (Sheet 1 of 2)
System
Bus
Clock
(MHz)
Symbol
Parameter
Minimum
Typ
Maximum
Unit
Figure
Notes
Tperiod
Tskew
fBCLK
Tjitter
Thigh
Tlow
BCLKp Period
200
200
200
200
200
200
266
266
266
266
266
5.0
ns
ps
1
2
3
4
System Clock Skew
BCLKp Frequency
BCLKp Input Jitter
BCLKp High Time
BCLKp Low Time
BCLKp Period
100
200
200
100
MHz Figure 2-1
ps
ns
ns
ns
ps
2.25
2.25
2.5
2.5
2.75
2.75
Tperiod
Tskew
fBCLK
Tjitter
Thigh
3.75
5
System Clock Skew
BCLKp Frequency
BCLKp Input Jitter
BCLKp High Time
60
266
50
266
MHz Figure 2-1
ps
ns
1.69
1.88
2.06
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Table 2-10. System Bus Clock Differential HSTL AC Specifications (Sheet 2 of 2)
System
Bus
Clock
(MHz)
Symbol
Parameter
Minimum
Typ
Maximum
Unit
Figure
Notes
Tlow
BCLKp Low Time
BCLKp Period
266
333
333
333
333
333
333
All
1.69
1.88
3.0
2.06
ns
ns
Tperiod
Tskew
fBCLK
Tjitter
Thigh
Tlow
System Clock Skew
BCLKp Frequency
BCLKp Input Jitter
BCLKp High Time
BCLKp Low Time
BCLKp Rise Time
BCLKp Fall Time
Minimum Input Swing
60
333
50
ps
333
MHz
ps
1.35
1.35
333
333
1.5
1.5
1.65
1.65
667
667
ns
ns
Trise
500
500
600
ps
Tfall
All
ps
6
VPP
All
mV
NOTES:
1. The system clock skew is ±100 ps.
2. Measured on cross point of rising edge of BCLKp and falling edge of BCLKn. Long term jitter is defined as peak-to-peak variation measured by
accumulating a large number of clock cycles and recording peak-to-peak jitter.
3. Cycle-to-cycle jitter is defined as peak-to-peak variation measured over 10000 cycles peak-to-peak jitter.
4. Measured on cross point of rising edge of BCLKp and falling edge of BCLKn.
5. The system clock skew is ±60 ps.
6. V
is defined as the minimum input differential voltage which will cause no increase in the clock receiver timing.
PPmin
Table 2-11. SMBus AC Specifications
Symbol
fSMSC
TSMSC
thigh
Parameter
Minimum
Maximum
Unit
Notes
SMSC Clock Frequency
SMSC Clock Period
100
kHz
µs
µs
µs
µs
µs
µs
ns
ns
µs
10
4.0
4.7
1
SMSC Clock High Time
SMSC Clock Low Time
SMSC Clock Rise Time
SMSC Clock Fall Time
SMBus Output Valid Delay
SMBus Input Setup Time
SMBus Input Hold Time
Bus Free Time
tlow
trise
1.0
0.3
1.0
tfall
tVALID
tSU
250
0
tHLD
2
tFREE
4.7
NOTES:
2. Bus Free Time is the minimum time allowed between request cycles.
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Figure 2-1. Generic Clock Waveform
T
high
T
low
T
jitter
T
T
fall
rise
BCLKN
BCLKP
80%
20%
V
pp
T
period
T
T
= Period
= Rise Time
= Fall Time
= High Time
= Low Time
period
rise
T
fall
T
jitter
= Long Term Peak-to-Peak Jitter
= Peak-to-Peak Swing
V
pp
T
high
T
low
000615
Figure 2-2. SMSC Clock Waveform
T
high
T
rise
V
cc
(3.3V)
90% V
cc
75% V
cc
SMSC
25% V
cc
T
fall
T
low
T
T
T
T
= Rise Time
= Fall Time
= High Time
rise
high
= Low Time
fall
low
000618
2.4.1
Maximum Ratings
Table 2-12 contains the Itanium 2 processor stress ratings. Functional operation at the absolute
maximum and minimum is neither implied nor guaranteed. The processor should not receive a
clock while subjected to these conditions. Functional operating conditions are given in the DC
tables. Extended exposure to the maximum ratings may affect device reliability. Furthermore,
although the processor contains protective circuitry to resist damage from static electric discharge,
one should always take precautions to avoid static voltages or electric fields.
®
Table 2-12. Itanium 2 Processor Absolute Maximum Ratings (Sheet 1 of 2)
Symbol
Tstorage
Parameter
Minimum
Maximum
Unit
Notes
1
Processor Storage Temperature
Processor Shipping Temperature
–10
–45
–0.1
45
75
°C
°C
V
2
3
Tshipping
VCC,Processor
Any VCC,Processor Voltage with Respect
to GND
2.1
4
3.3V
Any 3.3V Supply Voltage with Respect to
GND
–0.3
5.5
V
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®
Table 2-12. Itanium 2 Processor Absolute Maximum Ratings (Sheet 2 of 2)
Symbol
Parameter
Minimum
Maximum
Unit
Notes
Vin, SMBus
SMBus Buffer DC Input Voltage with
Respect to GND
–0.1
6.0
V
5, 6
Vin, AGTL+
VCTERM
Vin,TAP
AGTL+ Buffer DC Input Voltage with
Respect to GND
–0.1
–0.1
–0.1
1.9
1.9
2.1
V
V
V
Any VCTERM Voltage with Respect to
GND
TAP Buffer DC Input Voltage with
Respect to GND.
NOTES:
1. Storage temperature is temperature in which the processor can be stored for up to one year.
2. Shipping temperature is temperature in which the processor can be shipped for up to 24 hours.
4. Parameters are from third party vendor specifications.
5. Maximum instantaneous voltage at receiver buffer input.
6. Specification includes Vin,AGTL+ and Vin,AGTL+ ASYNCHRONOUS (AGTL+ asynchronous buffer DC input voltage with
respect to GND.
2.5
System Bus Signal Quality Specifications and
Measurement Guidelines
Overshoot (or undershoot) is the absolute value of the maximum voltage above the nominal
V
CTERM
limit transitions beyond V
or GND due to the fast signal edge rates. The processor can be
CTERM
permanently damaged by repeated overshoot or undershoot events on any input, output, or I/O
buffer if the charge is large enough (that is, if the overshoot/undershoot is great enough).
Determining the impact of an overshoot/undershoot condition requires knowledge of the
magnitude, the pulse duration, and the activity factor (AF).
2.5.1
Overshoot/Undershoot Magnitude
Magnitude describes the maximum potential difference between a signal and its voltage reference
important to note that overshoot and undershoot conditions are separate and their impact must be
determined independently. Overshoot/undershoot magnitude levels must observe the absolute
violated at any time regardless of bus activity or system state. Within these specifications are
threshold levels that define different allowed pulse duration. Provided that the magnitude of the
overshoot/undershoot is within the absolute maximum specifications (1.8 V for overshoot and
–0.60 V for undershoot), the pulse magnitude, duration and activity factor must all be used to
determine if the overshoot/undershoot pulse is within specifications.
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Figure 2-3. System Bus Signal Waveform Exhibiting Overshoot/Undershoot
Maximum
Absolute
Overshoot
Time-dependent
Overshoot
VMAX
VCTERM
VREF
VOL
GND
VMIN
Time-dependent
Undershoot
Maximum
Absolute
Undershoot
000588
2.5.2
2.5.3
Overshoot/Undershoot Pulse Duration
Pulse duration describes the total time an overshoot/undershoot event exceeds the
overshoot/undershoot reference voltage (V /GND). The total time could encompass several
CTERM
oscillations above the reference voltage. Multiple overshoot/undershoot pulses within a single
overshoot/undershoot event may need to be measured to determine the total pulse duration.
Note: Oscillations below the reference voltage cannot be subtracted from the total overshoot/undershoot
pulse duration.
Activity Factor
Activity factor (AF) describes the frequency of overshoot (or undershoot) occurrence relative to a
clock. Since the highest frequency of assertion of any common clock signal is every other clock, an
AF = 1 indicates that the specific overshoot (or undershoot) waveform occurs every other clock
cycle. Thus, an AF = 0.01 indicates that the specific overshoot (or undershoot) waveform occurs
one time in every 200 clock cycles. For source synchronous signals (data, and associated strobes),
the activity factor is in reference to the strobe edge. The highest frequency of assertion of any
source synchronous signal is every active edge of its associated strobe. So, an AF = 1 indicates that
the specific overshoot (or undershoot) waveform occurs every other strobe cycle. The
allowed for a given overshoot/undershoot magnitude at a specific activity factor. Each table entry is
independent of all others, meaning that the pulse duration reflects the existence of
overshoot/undershoot events of that magnitude ONLY. A platform with an overshoot/undershoot
that just meets the pulse duration for a specific magnitude where the AF <1, means that there can
be no other overshoot/undershoot events, even of lesser magnitude (if AF = 1, then the event
occurs at all times and no other events can occur).
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Note: AF for the common clock AGTL+ signals is referenced to BCLKn, and BCLKp frequency.
The wired-OR Signals (BINIT#, HIT#, HITM#, BNR#, TND#, BERR#) are common clock
AGTL+ signals.
Note: AF for source synchronous (2x) signals is referenced to STBP#[7:0], and STBN#[7:0].
2.5.4
Reading Overshoot/Undershoot Specification Tables
The overshoot/undershoot specification for the processor is not a simple single value. Instead,
many factors are needed in order to correctly interpret the overshoot/undershoot specification. In
addition to the magnitude of the overshoot, the following parameters must also be known: the
width of the overshoot and the AF. To determine the allowed overshoot for a particular overshoot
event, the following must be done:
1. Determine the signal group that the particular signal falls into. For AGTL+ signals operating
2. Determine the magnitude of the overshoot, or the undershoot (relative to GND).
3. Determine the activity factor (how often does this overshoot occur?).
4. Next, from the appropriate specification table, determine the maximum pulse duration (in
nanoseconds) allowed. The pulse duration shown in the table are referring to the period where
either the maximum overshoot (for high phase) and undershoot (for low phase) occurred.
5. Compare the specified maximum pulse duration to the signal being measured. If the pulse
duration measured is less than the pulse duration shown in the table, then the signal meets the
specifications.
6. Undershoot events must be analyzed separately from overshoot events as they are
mutually exclusive.
NOTES: The following notes also apply when reading the Overshoot/Undershoot tables.
1. Absolute Maximum Overshoot magnitude must never be exceeded.
2. Absolute Maximum Overshoot magnitude is measured referenced to GND. Pulse Duration of overshoot is
measured relative to VCTERM.
3. Absolute Maximum Undershoot magnitude and Pulse Duration of undershoot is measured relative to
VCTERM.
4. Ringback below VCTERM cannot be subtracted from overshoots/undershoots.
5. Lesser undershoot does not allocate overshoot with longer duration or greater magnitude.
6. OEM’s are strongly encouraged to follow Intel layout guidelines.
7. All values specified by design characterization.
2.5.5
Determining if a System Meets the Overshoot/Undershoot
Specifications
allowable overshoot/undershoot for a single overshoot/undershoot event. However, most systems
will have multiple overshoot and/or undershoot events that each have their own set of parameters
(duration, AF and magnitude). While each overshoot on its own may meet the overshoot
specification, the total impact of all overshoot events may cause the system to fail. A guideline to
ensure a system passes the overshoot and undershoot specifications is shown below:
1. Ensure no signal ever exceeds V
or GND.
CTERM
2. If only one overshoot/undershoot event magnitude occurs, ensure it meets the specifications
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3. If multiple overshoots and/or multiple undershoots occur, measure the worst-case pulse
duration for each magnitude and compare the results against the AF = 1 specifications. If all of
these worst-case overshoot or undershoot events meet the specifications (measured time <
specifications) in the table (where AF = 1), then the system passes.
Table 2-13. Source Synchronous AGTL+ Signal Group and Wired-OR Signal Group Absolute
Overshoot/Undershoot Tolerance
Parameter
VCTERM
VMAX
Description
Specification
Units
I/O power supply voltage (nominal).
1.20
1.80
V
V
Maximum absolute voltage for system bus signals at the input
of the receiver buffers.
VMIN
Minimum absolute voltage for system bus signals at the input of
the receiver buffers.
–0.60
V
1
Overshoot
Undershoot
NOTES:
Time dependent overshoot amount above VCTERM .
Time dependent undershoot amount below GND.
1. These parameters cannot be specified in absolute terms.
1. Absolute Maximum Overshoot magnitude of 1.8V must never be exceeded.
2. Absolute Maximum Overshoot is measured referenced to GND. Pulse duration of overshoot is measured
relative to VCTERM
.
3. Absolute Maximum Undershoot and Pulse Duration of undershoot is measured relative to VCTERM
4. Ringback below VCTERM cannot be subtracted from overshoots/undershoots.
5. Lesser undershoot does not allocate overshoot with longer duration or greater magnitude.
6. All values specified by design characterization.
.
®
Table 2-14. Itanium 2 Processors (900 MHz, 1.0 GHz, 1.3 GHz, 1.4 GHz, 1.5 GHz/6 MB) Source
Synchronous AGTL+ Signal Group Time Dependent Overshoot/Undershoot
Tolerance for 400 MHz System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0083
0.0206
0.0621
0.1851
0.5477
1.6100
2.5
0.0089
0.0276
0.0828
0.2470
0.7296
2.1451
2.5
0.0137
0.0413
0.1239
0.3702
1.0972
2.5
0.02750
0.0827
0.2480
0.7392
2.1915
2.5
0.0688
0.2067
0.6207
1.8500
2.5
0.1376
0.4139
1.2420
2.5
0.6863
2.0680
2.5
1.65
1.6
–0.45
–0.4
2.5
2.5
2.5
1.55
1.5
–0.35
–0.3
2.5
2.5
2.5
2.5
2.5
2.5
2.5
2.5
1.45
–0.25
2.5
2.5
2.5
2.5
2.5
2.5
2.5
NOTES:
1. Activity factor = 1 means signal toggles every 5 ns.
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®
Table 2-15. Itanium 2 Processors (1.5 GHz/4 MB, 1.6 GHz) Source Synchronous AGTL+
Signal Group Time-Dependent Overshoot/Undershoot Tolerance for 400 MHz
System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0083
0.0216
0.0646
0.1925
0.5713
1.1.676
2.5
0.0090
0.0287
0.0861
0.2572
0.7625
2.2351
2.5
0.0143
0.0430
0.1291
0.3858
1.1408
2.5
0.0287
0.0861
0.2584
0.7700
2.2831
2.5
0.0717
0.2157
0.6457
1.9264
2.5
0.1431
0.4313
1.2914
2.5
0.7169
2.1552
2.5
1.65
1.6
–0.45
–0.4
2.5
2.5
2.5
1.55
1.5
–0.35
–0.3
2.5
2.5
2.5
2.5
2.5
2.5
2.5
2.5
1.45
NOTES:
–0.25
2.5
2.5
2.5
2.5
2.5
2.5
2.5
1. Activity Factor = 1 means signal toggles every 5 ns.
®
Table 2-16. Itanium 2 (9 MB) Processors Source Synchronous AGTL+ Signal Group Time-
Dependent Overshoot/Undershoot Tolerance for 533 MHz System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0032
0.0161
0.0494
0.1444
0.4279
1.2573
1.875
0.0035
0.0215
0.0646
0.1924
0.5705
1.6763
1.875
0.0107
0.0323
0.0969
0.2894
0.8561
1.875
0.0214
0.0647
0.1937
0.5776
1.7130
1.875
0.0538
0.1619
0.4853
1.4465
1.875
0.1074
0.3230
0.9692
1.875
1.875
1.875
1.875
1.875
0.5371
1.6161
1.875
1.875
1.875
1.875
1.875
1.875
1.65
1.6
–0.45
–0.4
1.55
1.5
–0.35
–0.3
1.875
1.875
1.875
1.875
1.45
NOTES:
–0.25
1.875
1.875
1.875
1.875
1.875
1. Activity Factor = 1 means signal toggles every 3.75 ns.
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®
Table 2-17. Itanium 2 Processors (1.66 GHz) Source Synchronous AGTL+ Signal Group
Time-Dependent Overshoot/Undershoot Tolerance for 667 MHz System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0050
0.0129
0.0387
0.1158
0.3429
1.0065
1.5
0.0054
0.0172
0.0516
0.1544
0.4562
1.3411
1.5
0.0086
0.0258
0.0775
0.2311
0.6845
1.5
0.0172
0.0517
0.1553
0.4629
1.3728
1.5
0.0423
0.1292
0.3882
1.1564
1.5
0.0858
0.2585
0.7748
1.5
0.4297
1.2953
1.5
1.65
1.6
–0.45
–0.4
1.5
1.5
1.5
1.55
1.5
–0.35
–0.3
1.5
1.5
1.5
1.5
1.5
1.5
1.5
1.5
1.45
NOTES:
–0.25
1.5
1.5
1.5
1.5
1.5
1.5
1.5
1. Activity Factor = 1 means signal toggles every 3 ns.
2.5.6
Wired-OR Signals
System bus signals must meet certain overshoot and undershoot requirements. The maximum
absolute overshoot voltage is 1.8V and the minimum absolute undershoot voltage is
–0.6V. The system bus wired-OR signals (BINIT#, HIT#, HITM#, BNR#, TND#, BERR#) have
the same absolute overshoot and undershoot specification as the Source Synchronous AGTL+
Signals, but they have different time dependent overshoot/undershoot requirements. Please refer to
®
Table 2-18. Itanium 2 Processors (900 MHz, 1.0 GHz, 1.3 GHz, 1.4 GHz, 1.5 GHz/6 MB) Wired-
1
OR Signal Group (BINIT#, HIT#, HITM#, BNR#, TND#, BERR#)
Overshoot/Undershoot Tolerance for 400 MHz System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 12
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0493
0.1485
0.4444
1.3290
3.9270
5
0.06576
0.1977
0.5932
1.7670
5
0.0985
0.2966
0.8898
2.6529
5
0.1968
0.4923
0.9852
4.9228
0.5933
1.4834
2.9659
5
5
5
5
5
5
1.7798
4.4448
5
5
5
5
5
1.65
1.6
–0.45
–0.4
5
5
5
5
5
5
5
5
1.55
1.5
–0.35
–0.3
5
5
5
5
5
NOTES:
1. Wired-OR signals operate at 200 MHz.
2. Activity factor = 1 means signal toggles every 10ns.
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®
Table 2-19. Itanium 2 Processors (1.5 GHz/4 MB, 1.6 GHz) Wired-OR Signal Group (BINIT#,
HIT#, HITM#, BNR#, TND#, BERR#) Overshoot/Undershoot Tolerance for 400 MHz
System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0513
0.1547
0.4640
1.3836
4.0947
5
0.0685
0.2059
0.6191
1.8410
5
0.1026
0.3088
0.9265
2.7641
5
0.2054
0.5129
1.0258
5
5
5
5
5
5
5
0.6192
1.5458
3.0902
1.8536
4.6313
5
5
5
5
5
1.65
1.6
–0.45
–0.4
5
5
5
5
5
5
5
5
1.55
1.5
–0.35
–0.3
5
5
5
5
5
NOTES:
1. Activity Factor = 1 means signal toggles every 10 ns.
®
Table 2-20. Itanium 2 (9 MB) Processors Wired-OR Signal Group (BINIT#, HIT#, HITM#, BNR#,
TND#, BERR#) Overshoot/Undershoot Tolerance for 533 MHz System Bus
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0385
0.1161
0.3473
1.0365
3.0710
3.75
0.0513
0.1548
0.4643
1.3801
3.75
0.0770
0.2317
0.6945
2.0731
3.75
0.1541
0.4641
1.3895
3.75
0.3853
1.1593
3.4738
3.75
0.7690
2.3177
3.75
3.75
3.75
3.75
3.75
3.75
3.75
3.75
1.65
1.6
–0.45
–0.4
3.75
3.75
3.75
3.75
1.55
1.5
-0.35
–0.3
3.75
3.75
3.75
3.75
3.75
3.75
3.75
3.75
3.75
3.75
3.75
NOTES:
1. Activity Factor = 1 means signal toggles every 7.5 ns.
®
Table 2-21. Itanium 2 (1.66 GHz) Processors Wired-OR Signal Group (BINIT#, HIT#, HITM#,
BNR#, TND#, BERR#) Overshoot/Undershoot Tolerance for 667 MHz System Bus
(Sheet 1 of 2)
Absolute
Pulse Duration (ns)
Maximum (V)
Over-
shoot
Under-
shoot
AF = 11
AF = 0.75
AF = 0.5
AF = 0.25
AF = 0.1
AF = 0.05 AF = 0.01
1.8
1.75
1.7
–0.6
–0.55
–0.5
0.0308
0.0928
0.2780
0.8288
0.0411
0.1237
0.3714
1.1056
0.0615
0.1855
0.5568
1.6585
0.1231
0.3706
1.1136
3
0.3079
0.9291
2.7783
3
0.6167
3
3
3
3
1.8546
3
3
1.65
–0.45
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®
Table 2-21. Itanium 2 (1.66 GHz) Processors Wired-OR Signal Group (BINIT#, HIT#, HITM#,
BNR#, TND#, BERR#) Overshoot/Undershoot Tolerance for 667 MHz System Bus
(Sheet 2 of 2)
Absolute
Pulse Duration (ns)
Maximum (V)
1.6
1.55
–0.4
–0.35
–0.3
2.4567
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
3
1.5
NOTES:
1. Activity Factor = 1 means signal toggles every 6 ns.
2.6
Power Pod Connector Signals
Power delivery for the Itanium 2 processor is from a DC-DC converter called the “power pod”. The
power pod consists of a DC-DC converter and a semi-flexible connector which delivers the voltage
to the processor.
Table 2-22 lists all of the signals which are part of the Itanium 2 processor power pod connector.
®
Table 2-22. Itanium 2 Processor Power Pod Connector Signals
Group Name
Signals
OUTEN, CPUPRES#, PPODGD#, VCC, VCCMON, GND, VSSMON, VID[4:0]
Power Pod Connector
Warning: If the power supply cannot supply the voltages requested by the components in the Itanium 2
processor, then it must disable itself.
Figure 2-4 shows the top and bottom views of the power tab connector. The processor ground,
V
, connection is provided on the power tab connector as well.
SS,Processor
®
Figure 2-4. Itanium 2 Processor Power Tab Physical Layout
Reserved
OUTEN
VSSMON
VCCMON
PPODGD#
CPUPRES#
Processor
Pins
To Power Pod
To Power Pod
Processor
Reserved
VID[4]
VID[3]
VID[2]
VID[1]
VID[0]
Top View of Processor
Bottom View of Processor
000983a
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The power pod provides a selectable output voltage controlled via multiple binary weighted
VID pads shall be considered as LVTTL inputs to the power pod, having resistive pull-ups (5 kΩ)
included inside the power pod to the internal 3.3 V power supply. The VID pads on the power
connector tab will be pulled low with 10 Ωresistors that are internal to the processor. The 10 Ω
resistive pulldowns are controlled by Intel and will not be externally adjustable.
1
Table 2-23. Processor Core Voltage Identification Code
Processor Pins: 0 = Connected to GND; 1 = Open
VCC (VDC)
VID4
VID3
VID2
VID1
VID0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
Output Off
0.95
0.975
1.0
1.025
1.05
1.075
1.1
1.125
1.15
1.175
1.2
1.225
1.250
1.275
1.3
1.325
1.35
1.375
1.4
1.425
1.45
1.475
1.5
1.525
1.55
1.575
1.6
1.625
1.65
1.675
1.7
NOTES:
1. Nominal settings require regulation to ±7% at VCC,PS pins at the power tab under all conditions.
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Table 2-24. Processor Power States
State Transition
Ramp Rate
10 μs
Comment
Zero to 1st Power State (A)
Off state to initial power on.
1st Power State to 2nd Power State (B) 10 μs
1st power state is defined as the system
minimum operating load. Fastest power up
sequence.
2nd Power State to 3rd Power State (C) 10 μs
3rd Power State to 2nd Power State (D) 10 μs
2nd Power State to 1st Power State (E) 10 μs
2nd power state is defined as 75% of full
power.
3rd power state is defined as 40% of full
power.
Typical fast power down to initial power on.
Defined as 75% to 100% of full power.
Processor over temperature condition
Normal Operating Range (F)
Thermal Trip (G)
100 A/μs max
1ns ±250 ps or one
processor core cycle. emergency shutdown.
Figure 2-5. Processor Full, Normal and Low Power Mode with Timings
Current Level
Current Level
100A
B
D
100A
75A
75A
40A
F
F
40A
5A
0A
5A
0A
C
A
E
G
000672b
®
2.7
Itanium 2 Processor System Bus Clock and
Processor Clocking
The BCLKn and BCLKp inputs control the operating frequency of the Itanium 2 processor system
bus interface. All Itanium 2 processor system bus timing parameters are specified with respect to
the falling edge of BCLKn and rising edge of BCLKp. The Itanium 2 processor core to bus ratio
these pins during the system reset sequence determines the multiplier that the PLL will use for the
internal core clock. Because the A[21:17]# signals pins have different uses after a system reset is
complete, these signals must be multiplexed for configuration during reset and for normal use after
®
®
reset. See the Intel Itanium 2 Processor Hardware Developer’s Manual for complete
information on Itanium 2 processor system bus clock and processor clocking.
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processor supports bus ratios of 2/9, 2/10, 2/13, 2/14, 2/15 and 2/16. Table 2-25 lists the system bus
ratios defined for the Itanium 2 processor. Each particular implementation of the Itanium 2
defined below:
• The Itanium 2 processor 900 MHz with 1.5 MB L3 cache supports a bus ratio of 2/9.
• The Itanium 2 processor 1.0 GHz with 3 MB L3 cache supports a bus ratio of 2/10.
• The Itanium 2 processor 1.30 GHz with 3 MB L3 cache supports a bus ratio of 2/13.
• The Itanium 2 processor 1.40 GHz with 4 MB L3 cache supports a bus ratio of 2/14.
• The Itanium 2 processor 1.50 GHz with 6 MB L3 cache supports a bus ratio of 2/15.
• All other Itanium 2 processors will be locked at the correct supported ratios.
®
Table 2-25. Itanium 2 Processor System Bus Ratios
Ratio of Bus Frequency
to Processor Frequency
Core Frequency
A21#
A20#
A19#
A18#
A17#
900 MHz
1.0 GHz
1.3 GHz
1.4 GHz
1.5 GHz
2/9
2/10
1(L)
1(L)
1(L)
1(L)
1(L)
0(H)
0(H)
0(H)
0(H)
0(H)
1(L)
1(L)
0(H)
0(H)
0(H)
1(L)
0(H)
1(L)
0(H)
0(H)
0(H)
1(L)
0(H)
1(L)
0(H)
2/13
2/14
2/15
Reserved1
All other possible encodings
NOTES:
1. Reserved bus ratio encodings should never be driven on the bus during reset, otherwise it may cause damage to the
processor.
The Itanium 2 processor bus to core ratio is configured during system reset by using the A[21:17]#
signal pins. These bus ratio configuration pins are required to be stable and valid during the
duration of the reset sequence as defined below.
Cold Reset Sequence:
• The bus ratio configuration pins (A[21:17]#) must be asserted the entire time RESET# is
asserted.
• RESET# must be asserted before PWRGOOD is asserted.
• The duration from the assertion of PWRGOOD to the deassertion of RESET# must be 1
millisecond minimum.
• After RESET# is deasserted, all the configuration, including the bus ratio configuration pins
A[21:17]#, must remain valid for 2 BCLKs (minimum) to 3 BCLKs (maximum).
• BCLK is shown as a time reference to the BCLK period. It is not a requirement that this is
BCLKn or BCLKp signal.
• Configuration signals other than A[21:17]# must be asserted 4 BCLKs prior to the deasserted
edge of RESET# and must remain valid for 2 BCLKs (minimum) to 3 BCLKs (maximum)
after the deasserted edge of RESET#.
Figure 2-6 outlines the timing relationship between the bus ratio configuration pins, RESET# and
PWRGOOD for cold reset.
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Figure 2-6. System Bus Reset and Configuration Timings for Cold Reset
t-4
t-3
t-2
t-1
t0
t1
t2
t3
BCLK
PWRGOOD
RESET#
T
A
T
C
T
B
T
D
Bus Ratio
(A[21:17]#)
T
T
F
E
Additional
Configuration
Signals
T
= 1.15 ns minimum; (set up time to BCLK for deassertion edge of RESET#)
= 1 ms minimum for cold reset
A
T
B
T
= Bus ratio signals must be asserted no later than RESET#
= 2 BCLKs minimum, 3 BCLKs maximum
= 4 BCLKs minimum
C
T
D
T
E
T
F
= 2 BCLKs minimum, 3 BCLKs maximum
000859b
Warm Reset Sequence:
• PWRGOOD remains high throughout the entire sequence as power is already available and
stable to the processor.
• The bus ratio configuration pins (A[21:17]#) must be asserted the entire time RESET# is
asserted.
• The duration from the assertion of RESET# to the deassertion of RESET# must be 1
millisecond minimum.
• After RESET# is deasserted, the configuration pins must remain valid for two BCLKs
(minimum) to three BCLKs (maximum).
• BCLK is shown as a time reference to the BCLK period. It is not a requirement that this is
BCLKn or BCLKp signal.
• Configuration signals other than A[21:17]# must be asserted four BCLKs prior to the
deasserted edge of RESET# and must remain valid for two BCLKs (minimum) to three
BCLKs (maximum) after the deasserted edge of RESET#.
Figure 2-7 outlines the timing relationship between the bus ratio configuration pins, RESET# and
PWRGOOD for warm reset.
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Figure 2-7. System Bus Reset and Configuration Timings for Warm Reset
t-4
t-3
t-2
t-1
t0
t1
t2
t3
BCLK
PWRGOOD
RESET#
T
A
T
T
T
D
C
B
Bus Ratio
(A[21:17]#)
T
T
E
F
Additional
Configuration
Signals
T
= 1.15 ns minimum; (set up time to BCLK for deassertion edge of RESET#)
= 1 ms minimum for warm reset
A
T
B
T
= Bus ratio signals must be asserted no later than RESET#
= 2 BCLKs minimum, 3 BCLKs maximum
= 4 BCLKs minimum
C
T
D
T
E
T
F
= 2 BCLKs minimum, 3 BCLKs maximum
000777b
2.8
Recommended Connections for Unused Pins
Pins that are unused in an application environment (as opposed to testing environment) should be
connected to the states listed in Table 2-26. Pins that must be used in an application are stated as
such and do not have a recommended state for unused connection.
Table 2-26. Connection for Unused Pins (Sheet 1 of 2)
Recommended
Connections
Pins/Pin Groups
Notes
1, 2
AGTL+ pins
H
HSTL Clock Signals
All Power Signals
PWRGOOD
Must be used
Must be used
Must be used
Must be used
TUNER[2:1]
TAP Signals
1, 3
TCK
L
L
TRST#
TDI
H
H
H
TDO
TMS
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Table 2-26. Connection for Unused Pins (Sheet 2 of 2)
Pins/Pin Groups
Recommended
Connections
Notes
System Management Signals
3.3V
GND
N/C
N/C
N/C
N/C
H
SMA[2:0]
SMSC
SMSD
SMWP
1, 4
THRMALERT#
LVTTL Power Pod Signals
OUTEN
Must be used
Must be used
Must be used
PPODGD#
CPUPRES#
Reserved Pins
N/C
N/C
NOTES:
1. L = GND, H = VCTERM
.
2. AGTL+ output signals SBSY[0:1]#, DBSY[0:1]#, and DRDY[0,1]# may be left as N/C if not used on platform.
3. Should be properly terminated through a resistor.
4. THRMALERT# should be pulled up to 3.3V through a resistor.
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3 Pinout Specifications
This chapter describes the Itanium 2 processor signals and pinout.
Note: The pins labeled “N/C” must remain unconnected. The Itanium 2 processor uses a JEDEC standard
pin naming convention.
In this chapter, pin names are the actual names given to each physical pin of the processor.
System bus signal names are the names associated with the functions of those pins. For those pins
associated with multiple functions, their pin names and system bus signal names are not
necessarily identical.
Figure 3-1 shows the Itanium 2 processor pin location diagram from the top view.
®
Figure 3-1. Itanium 2 Processor Pinout
AH AG AF AE AD AC AB AA
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
1
2
1
GND
GND
GND
GND
GND
GND
GND VC GND
TERM
GND VC
TERM
GND
VC GND
TERM
GND VC
TERM
GND
2
GND TERMA GND ID0# GND ID1# GND A07# GND A04# VC D30# GND D27# VC D20# GND NC VC D11# GND D07# VC D04# GND 3.3V VC
TERM TERM TERM TERM TERM
3
3
TUNER[1] TUNER[2]
TERMB GND ID2# GND ID3# GND A06# GND A05# GND D25# GND D23# GND D17# GND D13# GND D14# GND D01# GND NC GND GND
4
4
GND OUTEN
ID4#
ID5#
A13#
A10# GND DEP3# VC D24# GND STBP1# VC D16# GND D12# VC STBN0# GND D03# VC NC NC
TERM TERM TERM TERM
5
5
NC
NC
ID6# GND ID7# GND A11# GND A12# GND NC GND D29# GND STBN1# GND D19# GND DEP1# GND D08# GND STBP0# GND D02# GND GND
GND
6
6
GND RSP#
ID8#
GND
ID9#
A08#
A03# VC DEP2#
TERM
D26# VC D28#
TERM
D18# VC D09#
TERM
D06# VC D05# GND NC VC
TERM TERM
7
7
TDO
TDI
RS0#
IDS# GND DRDY0# GND A14# GND A09# GND D31# GND D22# GND D21# GND DEP0# GND D15# GND D10# GND D00# GND THRM
ALERT#
GND
8
8
GND INIT#
RS1#
RS2#
A17#
A15#
DEP6# VC D54#
TERM
D48# VC D49# GND D42# VC D45# GND D37# VC NC GND
TERM
TERM
TERM
9
9
REQ0# GND DBSY# GND
GND D63# GND
GND D53#
DEP4#
GND GND
D38#
TMS TCK
DSBY0# GND A21# GND A18#
D58#
GND D40# GND D35# GND VSSMON
GND
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
GND REQ1#
REQ2#
HIT#
A24#
A20# VC DEP7#
TERM
D61# VC STBP3#
TERM
D50# VC D32#
TERM
STBN2# VC D34# GND GND VCTERM
TERM
NC
NC GND REQ3# GND DRDY# GND A23# GND A26# GND NC GND D60# GND STBN3# GND D56# GND DEP5# GND D41# GND STBP2# GND D33# GND VCCMON
GND REQ4#
REQ5#
HITM#
A25#
A19#
D62# VC D57#
TERM
D51# VC NC GND D46# VC D44# GND D36# VC
TERM TERM TERM
BCLKN BCLKP
SBSY# GND RP# GND SBSY0# GND A22# GND A16# GND D59# GND D55# GND D52# GND D47# GND D43# GND D39# GND NC GND GND
GND
GND TRDY#
GSEQ#
DEFER#
A34#
A31# VC D94#
TERM
D87# VC D84#
TERM
NC VC D75#
TERM
D68# VC D65# GND NC VC
TERM TERM
PWR PROC GND LOCK# GND TND# GND BINIT# GND A37# GND A28# GND D92# GND D91# GND D81# GND D78# GND D71# GND D67# GND NC GND SMA2
GOOD PRES#
GND BREQ0#
BREQ1#
NC
A36#
A38#
DEP11# VC D93#
TERM
STBP5# VC D83# GND D76# VC STBN4# GND D66# VC NC GND
TERM TERM TERM
NC
NC GND NC GND NC GND A33# GND A32# GND BNR# GND D89# GND STBN5# GND D88# GND DEP9# GND D72# GND STBP4# GND D73# GND SMA1
GND BREQ3#
NC
BREQ2#
A35#
A29# VC DEP10#
TERM
D95# VC D86#
TERM
D80# VC D77#
TERM
D69# VC D64# GND SMA0 VC
TERM TERM
NC
NC
NC GND BPRI# GND SBSY1# GND DBSY1# GND A30# GND A27# GND D90# GND D85# GND D82# GND DEP8# GND D79# GND D74# GND D70# GND GND
GND PPOD
GD#
RESET#
ADS# GND A39#
A45# GND DEP14# VC D122# GND D118# VC D117# GND D111# VC D106# GND D102# VC NC GND
TERM TERM TERM TERM
NC
TRST# GND NC GND DRDY1# GND A44# GND A48# GND D124# GND D127# GND D112# GND DEP12# GND D101# GND D96# GND D99# GND SMWP
GND
GND LINT0
A20M# IGNNE#
GND LINT1 GND BPM4# GND BPM5# GND A43#
BPM0#
BERR#
A49#
A47# VC DEP15#
TERM
D125# VC STBP7#
TERM
D114# VC D105#
TERM
STBN6# VC D98# GND SMSD VC
TERM TERM
BPM2# GND BPM3# GND AP1# GND A46# GND A42# GND D126# GND STBN7# GND D116# GND DEP13# GND D108# GND STBP6# GND D97# GND GND
A40# GND D123# VC D120# GND D115# VC NC GND D109# VC D103# GND D104# VC SMSC GND
TERM TERM TERM TERM
FERR# TH_TRIP#
PMI# GND BPM1# GND AP0# GND A41# GND VC GND D121# GND D119# GND D113# GND D110# GND D107# GND D100# GND NC GND VC
TERM TERM
AH AG AF AE AD AC AB AA
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
Power Pod
000638b
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Pinout Specifications
Table 3-1 provides the Itanium 2 processor pin list in alphabetical order.
Table 3-2 provides the Itanium 2 processor pin list by pin location.
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 1 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
3.3V
B02
V06
V02
U03
W03
Y02
Y06
U07
V04
AA05
W05
Y04
W07
V08
U13
Y08
U09
V12
V10
W09
W13
AA11
Y10
Y12
W11
U19
U15
V18
W19
V14
W17
AA17
Y14
Y18
Y16
W15
V16
Y20
IN
SMBus supply voltage
A003#
A004#
A005#
A006#
A007#
A008#
A009#
A010#
A011#
A012#
A013#
A014#
A015#
A016#
A017#
A018#
A019#
A020#
A021#
A022#
A023#
A024#
A025#
A026#
A027#
A028#
A029#
A030#
A031#
A032#
A033#
A034#
A035#
A036#
A037#
A038#
A039#
AA03#/EXF0#
AA04#/EXF1#
AA05#/EXF2#
AA06#/EXF3#
AA07#/EXF4#
AA08#/BE0#
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
AA09#/BE1#
AA10#/BE2#
AA11#/BE3#
AA12#/BE4#
AA13#/BE5#
AA14#/BE6#
AA15#/BE7#
AA16#/DID0#
AA17#/DID1#
AA18#/DID2#
AA19#/DID3#
AA20#/DID4#
AA21#/DID5#
AA22#/DID6#
AA23#/DID7#
AA24#/DID8#
AA25#/DID9#
AA26#/AB26#
AA27#/xTPRValue0#
AA28#/xTPRValue1#
AA29#/xTPRValue2#
AA30#/xTPRValue3#
AA31#/xTPRDisable#
AA32#/ATTR0#
AA33#/ATTR1#
AA34#/ATTR2#
AA35#/ATTR3#
AA36#/AB36#
AA37#/AB37#
AA38#/AB38#
AA39#/AB39#
38
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 2 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
A040#
A041#
A042#
A043#
A044#
A045#
A046#
A047#
A048#
A049#
A20M#
ADS#
AA40#/AB40#
AA41#/AB41#
AA42#/AB42#
AA43#/AB43#
AA44#/AB44#
AA45#/AB45#
AA46#/AB46#
AA47#/AB47#
AA48#/AB48#
AA49#/AB49#
A20M#
V24
W25
U23
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN
Y24
W21
V20
W23
V22
U21
Y22
AH23
AB20
AA25
AA23
AH13
AG13
AB22
AA15
U17
ADS#
IN/OUT
IN/OUT
IN/OUT
IN
AP0#
AP0#
AP1#
AP1#
BCLKn
BCLKp
BERR#
BINIT#
BNR#
BCLKN
BCLK
IN
BERR#
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN
BINIT#
BNR#
BPM0#
BPM1#
BPM2#
BPM3#
BPM4#
BPM5#
BPRI#
BR0#
BPM0#
AD22
AC25
AE23
AC23
AD24
AB24
AE19
AF16
AD16
AB18
AF18
AG15
C07
BPM1#
BPM2#
BPM3#
BPM4#
BPM5#
BPRI#
BREQ0#
BREQ1#
BREQ2#
BREQ3#
CPUPRES#
D00#
IN/OUT
IN
BR1#
BR2#
IN
BR3#
IN
CPUPRES#
D000#
D001#
D002#
D003#
D004#
D005#
D006#
D007#
D008#
D009#
OUT
Power pod signal
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
D01#
E03
D02#
C05
D03#
D04
D04#
D02
D05#
D06
D06#
F06
D07#
F02
D08#
G05
D09#
H06
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 3 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
D010#
D011#
D012#
D013#
D014#
D015#
D016#
D017#
D018#
D019#
D020#
D021#
D022#
D023#
D024#
D025#
D026#
D027#
D028#
D029#
D030#
D031#
D032#
D033#
D034#
D035#
D036#
D037#
D038#
D039#
D040#
D041#
D042#
D043#
D044#
D045#
D046#
D047#
D048#
D049#
D050#
D10#
D11#
D12#
D13#
D14#
D15#
D16#
D17#
D18#
D19#
D20#
D21#
D22#
D23#
D24#
D25#
D26#
D27#
D28#
D29#
D30#
D31#
D32#
D33#
D34#
D35#
D36#
D37#
D38#
D39#
D40#
D41#
D42#
D43#
D44#
D45#
D46#
D47#
D48#
D49#
D50#
E07
H02
H04
J03
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
G03
G07
K04
L03
K06
L05
M02
L07
N07
N03
P04
R03
P06
P02
M06
R05
T02
R07
H10
C11
D10
C09
D12
D08
G09
E13
E09
G11
H08
G13
F12
F08
H12
J13
M08
K08
K10
40
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 4 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
D051#
D052#
D053#
D054#
D055#
D056#
D057#
D058#
D059#
D060#
D061#
D062#
D063#
D064#
D065#
D066#
D067#
D068#
D069#
D070#
D071#
D072#
D073#
D074#
D075#
D076#
D077#
D078#
D079#
D080#
D081#
D082#
D083#
D084#
D085#
D086#
D087#
D088#
D089#
D090#
D091#
D51#
D52#
D53#
D54#
D55#
D56#
D57#
D58#
D59#
D60#
D61#
D62#
D63#
D64#
D65#
D66#
D67#
D68#
D69#
D70#
D71#
D72#
D73#
D74#
D75#
D76#
D77#
D78#
D79#
D80#
D81#
D82#
D83#
D84#
D85#
D86#
D87#
D88#
D89#
D90#
D91#
M12
L13
L09
P08
N13
L11
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
P12
N09
R13
R11
P10
T12
R09
D18
D14
D16
E15
F14
F18
C19
G15
G17
C17
E19
H14
H16
H18
J15
G19
K18
L15
L19
K16
M14
N19
M18
P14
L17
R17
R19
N15
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 5 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
D092#
D093#
D094#
D095#
D096#
D097#
D098#
D099#
D100#
D101#
D102#
D103#
D104#
D105#
D106#
D107#
D108#
D109#
D110#
D111#
D112#
D113#
D114#
D115#
D116#
D117#
D118#
D119#
D120#
D121#
D122#
D123#
D124#
D125#
D126#
D127#
DBSY#
DBSY0#
DBSY1#
DEFER#
DEP00#
D92#
D93#
R15
P16
T14
P18
E21
C23
D22
C21
E25
G21
D20
F24
D24
H22
F20
G25
G23
H24
J25
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
OUT
D94#
D95#
D96#
D97#
D98#
D99#
D100#
D101#
D102#
D103#
D104#
D105#
D106#
D107#
D108#
D109#
D110#
D111#
D112#
D113#
D114#
D115#
D116#
D117#
D118#
D119#
D120#
D121#
D122#
D123#
D124#
D125#
D126#
D127#
DBSY#
DBSY_C1#
DBSY_C2#
DEFER#
DEP0#
H20
L21
L25
K22
M24
L23
K20
M20
N25
P24
R25
P20
T24
R21
P22
R23
N21
AC09
AA09
AA19
AB14
J07
OUT
IN
IN/OUT
42
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 6 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
DEP01#
DEP02#
DEP03#
DEP04#
DEP05#
DEP06#
DEP07#
DEP08#
DEP09#
DEP10#
DEP11#
DEP12#
DEP13#
DEP14#
DEP15#
DRDY#
DRDY0#
DRDY1#
FERR#
GND
DEP1#
DEP2#
DEP3#
DEP4#
DEP5#
DEP6#
DEP7#
DEP8#
DEP9#
DEP10#
DEP11#
DEP12#
DEP13#
DEP14#
DEP15#
DRDY#
DRDY_C1#
DRDY_C2#
FERR#
GND
J05
T06
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
OUT
OUT
OUT
IN
T04
J09
J11
T08
T10
J19
J17
T18
T16
J21
J23
T20
T22
AC11
AA07
AA21
AH25
A01
GND
GND
A03
IN
GND
GND
A05
IN
GND
GND
A08
IN
GND
GND
A13
IN
GND
GND
A16
IN
GND
GND
A19
IN
GND
GND
A20
IN
GND
GND
A23
IN
GND
GND
A24
IN
GND
GND
AA02
AA20
AA24
AB01
AB03
AB05
AB07
AB09
AB11
AB13
AB15
AB17
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
GND
GND
IN
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 7 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
AB19
AB21
AB23
AB25
AC02
AC24
AD01
AD03
AD05
AD07
AD09
AD11
AD13
AD15
AD17
AD19
AD21
AD23
AD25
AE02
AE24
AF01
AF05
AF07
AF09
AF11
AF13
AF15
AF17
AF19
AF21
AG02
AG04
AG06
AG08
AG10
AG12
AG14
AG16
AG18
AG20
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
44
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 8 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
AG22
AG24
AH01
B03
B05
B07
B09
B10
B11
B13
B15
B17
B19
B21
B23
B25
C02
C06
C10
C14
C18
C22
D01
D03
D05
D07
D09
D11
D13
D15
D17
D19
D21
D23
D25
E04
E08
E12
E16
E20
E24
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 9 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
F01
F03
F05
F07
F09
F11
F13
F15
F17
F19
F21
F23
F25
G02
H03
H05
H07
H09
H11
H13
H15
H17
H19
H21
H23
H25
J01
J04
J08
J12
J16
J20
J24
K03
K05
K07
K09
K11
K13
K15
K17
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
46
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 10 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
K19
K21
K23
K25
L02
M01
M03
M05
M07
M09
M11
M13
M15
M17
M19
M21
M23
M25
N04
N20
N24
P01
P03
P05
P07
P09
P11
P13
P15
P17
P19
P21
P23
P25
R02
T01
T03
T05
T07
T09
T11
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 11 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GSEQ#
HIT#
HITM#
ID0#
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GSEQ#
HIT#
HITM#
IDA0#/IP0#
T13
T15
T17
T19
T21
T23
T25
U04
U20
U24
V01
V03
V05
V07
V09
V11
V13
V15
V17
V19
V21
V23
V25
W02
Y01
Y03
Y05
Y07
Y09
Y11
Y13
Y15
Y17
Y19
Y21
Y23
Y25
AD14
AB10
AB12
AD02
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN/OUT
IN/OUT
IN
48
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 12 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
ID1#
ID2#
ID3#
ID4#
ID5#
ID6#
ID7#
ID8#
ID9#
IDS#
IGNNE#
INIT#
LINT0
LINT1
LOCK#
N/C
IDA1#/IP1#
IDA2#/DHIT#
IDA3#/IDB3#
IDA4#/IDB4#
IDA5#/IDB5#
IDA6#/IDB6#
IDA7#/IDB7#
IDA8#/IDB8#
IDA9#/IDB9#
IDS#
AB02
AC03
AA03
AD04
AB04
AE05
AC05
AD06
AB06
AC07
AG23
AF08
AF22
AF24
AE15
A04
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IGNNE#
IN
INIT#
IN
INT
IN
NMI
IN
LOCK#
IN/OUT
N/C
AB16
AC17
AC21
AD18
AE17
AG05
AG11
AG17
AG19
AG21
AH05
AH11
AH17
AH19
AH21
B04
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
B06
N/C
B08
N/C
B14
N/C
B16
N/C
B20
N/C
C03
N/C
C13
N/C
C15
N/C
C25
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 13 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
N/C
N/C
K02
K12
N/C
K14
N/C
K24
N/C
U05
N/C
U11
OUTEN
PMI#
OUTEN
PMI#
AF04
AE25
AF20
AH15
AE09
AF10
AD10
AE11
AF12
AD12
AD20
AC13
AE07
AD08
AB08
AF06
AE13
AA13
AC19
B18
IN
Power pod signal
Power pod signal
IN
PPODGD#
PWRGOOD
REQ0#
REQ1#
REQ2#
REQ3#
REQ4#
REQ5#
RESET#
RP#
PPODGD#
PWRGOOD
REQA0#/LEN0#
WSNP#, D/C#/LEN1#
REQA2#/ REQB2#
ASZ0#/DSZ0#
ASZ1#/DSZ1#
REQ5#
OUT
IN
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN
RESET#
RP#
IN/OUT
IN
RS0#
RS0#
RS1#
RS1#
IN
RS2#
RS2#
IN
RSP#
RSP#
IN
SBSY#
SBSY0#
SBSY1#
SMA0
SBSY#
IN/OUT
OUT
SBSY_C1#
SBSY_C2#
SMA0
OUT
IN
SMBus signal
SMBus signal
SMBus signal
SMBus signal
SMBus signal
SMBus signal
SMA1
SMA1
A17
IN
SMA2
SMA2
A15
IN
SMSC
SMSD
SMWP
STBN0#
STBN1#
STBN2#
STBN3#
STBN4#
STBN5#
STBN6#
STBN7#
STBP0#
STBP1#
SMSC
B24
IN
SMSD
B22
IN/OUT
IN
SMWP
A21
STBN0#
STBN1#
STBN2#
STBN3#
STBN4#
STBN5#
STBN6#
STBN7#
STBP0#
F04
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OuT
IN/OUT
IN/OUT
N05
F10
N11
F16
N17
F22
N23
E05
STBP1#
M04
50
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 14 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
STBP2#
STBP3#
STBP4#
STBP5#
STBP6#
STBP7#
TCK
STBP2#
STBP3#
STBP4#
STBP5#
STBP6#
STBP7#
TCK
E11
M10
E17
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN
M16
E23
M22
AG09
AG07
AH07
AF02
AE03
AG25
A07
JTAG
JTAG
JTAG
TDI
TDI
IN
TDO
TDO
OUT
IN
TERMA
FSBT1
TERMB
FSBT2
IN
THRMTRIP#
THRMALERT#
TMS
THRMTRIP#
THRMALERT#
TMS
OUT
OUT
IN
AH09
AC15
AF14
AE21
AH03
AG03
A11
JTAG
JTAG
TND#
TND#
IN/OUT
IN
TRDY#
TRDY#
TRST#
TRST#
IN
TUNER[1]
TUNER[2]
VCCMON
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
TUNER[1]
TUNER[2]
VCCMON
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
OUT
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
Power pod signal
A02
A06
A10
A14
A18
A22
A25
C01
C04
C08
C12
C16
C20
C24
E02
E06
E10
E14
E18
E22
G01
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Pinout Specifications
Table 3-1. Pin/Signal Information Sorted by Pin Name (Sheet 15 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VSSMON
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VCTERM
VSSMON
G04
G08
G12
G16
G20
G24
J02
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
IN
OUT
J06
J10
J14
J18
J22
L01
L04
L08
L12
L16
L20
L24
N02
N06
N10
N14
N18
N22
R01
R04
R08
R12
R16
R20
R24
U02
U06
U10
U14
U18
U22
U25
A09
Power pod signal
52
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 1 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
VCTERM
GND
GND
VCTERM
GND
A01
A02
A03
A04
A05
A06
A07
A08
A09
A10
A11
A13
A14
A15
A16
A17
A18
A19
A20
A21
A22
A23
A24
A25
B02
B03
B04
B05
B06
B07
B08
B09
B10
B11
B13
B14
B15
B16
B17
B18
B19
IN
IN
IN
N/C
GND
GND
VCTERM
THRMALERT#
GND
IN
IN
VCTERM
THRMALERT#
GND
OUT
IN
VSSMON
VCTERM
VCCMON
GND
VSSMON
VCTERM
VCCMON
GND
OUT
IN
Power pod signal
Power pod signal
OUT
IN
VCTERM
SMA2
GND
VCTERM
SMA2
IN
IN
SMBus signal
SMBus signal
GND
IN
SMA1
VCTERM
GND
SMA1
IN
VCTERM
GND
IN
IN
GND
GND
IN
SMWP
VCTERM
GND
SMWP
IN
SMBus signal
VCTERM
GND
IN
IN
GND
GND
IN
VCTERM
3.3V
VCTERM
IN
IN
SMBus supply voltage
GND
GND
GND
IN
N/C
GND
IN
IN
N/C
GND
GND
RSVD
GND
GND
GND
GND
RSVD
GND
IN
IN
IN
IN
GND
GND
GND
N/C
GND
GND
IN
N/C
GND
GND
SMA0
GND
IN
IN
IN
SMA0
GND
SMBus signal
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 2 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
N/C
GND
B20
B21
B22
B23
B24
B25
C01
C02
C03
C04
C05
C06
C07
C08
C09
C10
C11
C12
C13
C14
C15
C16
C17
C18
C19
C20
C21
C22
C23
C24
C25
D01
D02
D03
D04
D05
D06
D07
D08
D09
D10
GND
SMSD
GND
IN
IN/OUT
IN
SMSD
GND
SMBus signal
SMBus signal
SMSC
GND
SMSC
GND
IN
IN
VCTERM
GND
VCTERM
GND
IN
IN
N/C
VCTERM
D002#
GND
VCTERM
D02#
IN
IN/OUT
IN
GND
D000#
VCTERM
D035#
GND
D00#
IN/OUT
IN
VCTERM
D35#
IN/OUT
IN
GND
D033#
VCTERM
N/C
D33#
IN/OUT
IN
VCTERM
GND
GND
IN
N/C
VCTERM
D073#
GND
VCTERM
D73#
IN
IN/OUT
IN
GND
D070#
VCTERM
D099#
GND
D70#
IN/OUT
IN
VCTERM
D99#
IN/OUT
IN
GND
D097#
VCTERM
N/C
D97#
IN/OUT
IN
VCTERM
GND
GND
D04#
GND
D03#
GND
D05#
GND
D37#
GND
D34#
IN
IN/OUT
IN
D004#
GND
D003#
GND
IN/OUT
IN
D005#
GND
IN/OUT
IN
D037#
GND
IN/OUT
IN
D034#
IN/OUT
54
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 3 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
D036#
GND
GND
D36#
D11
D12
D13
D14
D15
D16
D17
D18
D19
D20
D21
D22
D23
D24
D25
E02
E03
E04
E05
E06
E07
E08
E09
E10
E11
E12
E13
E14
E15
E16
E17
E18
E19
E20
E21
E22
E23
E24
E25
F01
F02
IN
IN/OUT
IN
GND
D065#
GND
D65#
IN/OUT
IN
GND
D066#
GND
D66#
IN/OUT
IN
GND
D064#
GND
D64#
IN/OUT
IN
GND
D102#
GND
D102#
GND
IN/OUT
IN
D098#
GND
D98#
IN/OUT
IN
GND
D104#
GND
D104#
GND
IN/OUT
IN
VCTERM
D001#
GND
VCTERM
D01#
IN
IN/OUT
IN
GND
STBP0#
VCTERM
D010#
GND
STBP0#
VCTERM
D10#
IN/OUT
IN
IN/OUT
IN
GND
D040#
VCTERM
STBP2#
GND
D40#
IN/OUT
IN
VCTERM
STBP2#
GND
IN/OUT
IN
D039#
VCTERM
D067#
GND
D39#
IN/OUT
IN
VCTERM
D67#
IN/OUT
IN
GND
STBP4#
VCTERM
D074#
GND
STBP4#
VCTERM
D74#
IN/OUT
IN
IN/OUT
IN
GND
D096#
VCTERM
STBP6#
GND
D96#
IN/OUT
IN
VCTERM
STBP6#
GND
IN/OUT
IN
D100#
GND
D100#
GND
IN/OUT
IN
D007#
D07#
IN/OUT
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 4 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
STBN0#
GND
GND
STBN0#
GND
F03
F04
F05
F06
F07
F08
F09
F10
F11
F12
F13
F14
F15
F16
F17
F18
F19
F20
F21
F22
F23
F24
F25
G01
G02
G03
G04
G05
G07
G08
G09
G11
G12
G13
G15
G16
G17
G19
G20
G21
G23
IN
IN/OUT
IN
D006#
GND
D06#
IN/OUT
IN
GND
D045#
GND
D45#
IN/OUT
IN
GND
STBN2#
GND
STBN2#
GND
IN/OUT
IN
D044#
GND
D44#
IN/OUT
IN
GND
D068#
GND
D68#
IN/OUT
IN
GND
STBN4#
GND
STBN4#
GND
IN/OUT
IN
D069#
GND
D69#
IN/OUT
IN
GND
D106#
GND
D106#
GND
IN/OUT
IN
STBN6#
GND
STBN6#
GND
IN/OUT
IN
D103#
GND
D103#
GND
IN/OUT
IN
VCTERM
GND
VCTERM
GND
IN
IN
D014#
VCTERM
D008#
D015#
VCTERM
D038#
D041#
VCTERM
D043#
D071#
VCTERM
D072#
D079#
VCTERM
D101#
D108#
D14#
IN/OUT
IN
VCTERM
D08#
IN/OUT
IN/OUT
IN
D15#
VCTERM
D38#
IN/OUT
IN/OUT
IN
D41#
VCTERM
D43#
IN/OUT
IN/OUT
IN
D71#
VCTERM
D72#
IN/OUT
IN/OUT
IN
D79#
VCTERM
D101#
D108#
IN/OUT
IN/OUT
56
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 5 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
VCTERM
D107#
D011#
GND
VCTERM
D107#
D11#
G24
G25
H02
H03
H04
H05
H06
H07
H08
H09
H10
H11
H12
H13
H14
H15
H16
H17
H18
H19
H20
H21
H22
H23
H24
H25
J01
J02
J03
J04
J05
J06
J07
J08
J09
J10
J11
IN
IN/OUT
IN/OUT
IN
GND
D012#
GND
D12#
IN/OUT
IN
GND
D009#
GND
D09#
IN/OUT
IN
GND
D042#
GND
D42#
IN/OUT
IN
GND
D032#
GND
D32#
IN/OUT
IN
GND
D046#
GND
D46#
IN/OUT
IN
GND
D075#
GND
D75#
IN/OUT
IN
GND
D076#
GND
D76#
IN/OUT
IN
GND
D077#
GND
D77#
IN/OUT
IN
GND
D111#
GND
D111#
GND
IN/OUT
IN
D105#
GND
D105#
GND
IN/OUT
IN
D109#
GND
D109#
GND
IN/OUT
IN
GND
GND
IN
VCTERM
D013#
GND
VCTERM
D13#
IN
IN/OUT
IN
GND
DEP01#
VCTERM
DEP00#
GND
DEP1#
VCTERM
DEP0#
GND
IN/OUT
IN
IN/OUT
IN
DEP04#
VCTERM
DEP05#
GND
DEP4#
VCTERM
DEP5#
GND
IN/OUT
IN
IN/OUT
IN
J12
J13
J14
J15
D047#
VCTERM
D078#
D47#
IN/OUT
IN
VCTERM
D78#
IN/OUT
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 6 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
DEP09#
VCTERM
DEP08#
GND
GND
DEP9#
VCTERM
DEP8#
GND
J16
J17
J18
J19
J20
J21
J22
J23
J24
J25
K02
K03
K04
K05
K06
K07
K08
K09
K10
K11
K12
K13
K14
K15
K16
K17
K18
K19
K20
K21
K22
K23
K24
K25
L01
L02
L03
L04
L05
L07
L08
IN
IN/OUT
IN
IN/OUT
IN
DEP12#
VCTERM
DEP13#
GND
DEP12#
VCTERM
DEP13#
GND
IN/OUT
IN
IN/OUT
IN
D110#
N/C
D110#
IN/OUT
GND
GND
D16#
GND
D18#
GND
D49#
GND
D50#
GND
IN
IN/OUT
IN
D016#
GND
D018#
GND
IN/OUT
IN
D049#
GND
IN/OUT
IN
D050#
GND
IN/OUT
IN
N/C
GND
GND
IN
N/C
GND
GND
D83#
GND
D80#
GND
D117#
GND
D114#
GND
IN
IN/OUT
IN
D083#
GND
D080#
GND
IN/OUT
IN
D117#
GND
IN/OUT
IN
D114#
GND
IN/OUT
IN
N/C
GND
GND
VCTERM
GND
IN
IN
VCTERM
GND
IN
D017#
VCTERM
D019#
D021#
VCTERM
D17#
IN/OUT
IN
VCTERM
D19#
IN/OUT
IN/OUT
IN
D21#
VCTERM
58
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 7 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
D053#
D056#
VCTERM
D052#
D081#
VCTERM
D088#
D082#
VCTERM
D112#
D116#
VCTERM
D113#
GND
D53#
D56#
L09
L11
IN/OUT
IN/OUT
IN
VCTERM
D52#
L12
L13
IN/OUT
IN/OUT
IN
D81#
L15
VCTERM
D88#
L16
L17
IN/OUT
IN/OUT
IN
D82#
L19
VCTERM
D112#
D116#
VCTERM
D113#
GND
L20
L21
IN/OUT
IN/OUT
IN
L23
L24
L25
IN/OUT
IN
M01
M02
M03
M04
M05
M06
M07
M08
M09
M10
M11
M12
M13
M14
M15
M16
M17
M18
M19
M20
M21
M22
M23
M24
M25
N02
N03
N04
D020#
GND
D20#
IN/OUT
IN
GND
STBP1#
GND
STBP1#
GND
IN/OUT
IN
D028#
GND
D28#
IN/OUT
IN
GND
D048#
GND
D48#
IN/OUT
IN
GND
STBP3#
GND
STBP3#
GND
IN/OUT
IN
D051#
GND
D51#
IN/OUT
IN
GND
D084#
GND
D84#
IN/OUT
IN
GND
STBP5#
GND
STBP5#
GND
IN/OUT
IN
D086#
GND
D86#
IN/OUT
IN
GND
D118#
GND
D118#
GND
IN/OUT
IN
STBP7#
GND
STBP7#
GND
IN/OUT
IN
D115#
GND
D115#
GND
IN/OUT
IN
VCTERM
D023#
GND
VCTERM
D23#
IN
IN/OUT
IN
GND
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 8 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
STBN1#
VCTERM
D022#
D058#
VCTERM
STBN3#
D055#
VCTERM
D091#
STBN5#
VCTERM
D085#
GND
STBN1#
VCTERM
D22#
N05
N06
N07
N09
N10
N11
N13
N14
N15
N17
N18
N19
N20
N21
N22
N23
N24
N25
P01
P02
P03
P04
P05
P06
P07
P08
P09
P10
P11
P12
P13
P14
P15
P16
P17
P18
P19
P20
P21
P22
P23
IN/OUT
IN
IN/OUT
IN/OUT
IN
D58#
VCTERM
STBN3#
D55#
IN/OUT
IN/OUT
IN
VCTERM
D91#
IN/OUT
IN/OUT
IN
STBN5#
VCTERM
D85#
IN/OUT
IN
GND
D127#
VCTERM
STBN7#
GND
D127#
VCTERM
STBN7#
GND
IN/OUT
IN
IN/OuT
IN
D119#
GND
D119#
GND
IN/OUT
IN
D027#
GND
D27#
IN/OUT
IN
GND
D024#
GND
D24#
IN/OUT
IN
GND
D026#
GND
D26#
IN/OUT
IN
GND
D054#
GND
D54#
IN/OUT
IN
GND
D061#
GND
D61#
IN/OUT
IN
GND
D057#
GND
D57#
IN/OUT
IN
GND
D087#
GND
D87#
IN/OUT
IN
GND
D093#
GND
D93#
IN/OUT
IN
GND
D095#
GND
D95#
IN/OUT
IN
GND
D122#
GND
D122#
GND
IN/OUT
IN
D125#
GND
D125#
GND
IN/OUT
IN
60
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 9 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
D120#
GND
D120#
GND
P24
P25
R01
R02
R03
R04
R05
R07
R08
R09
R11
R12
R13
R15
R16
R17
R19
R20
R21
R23
R24
R25
T01
T02
T03
T04
T05
T06
T07
T08
T09
T10
T11
T12
T13
T14
T15
T16
T17
T18
T19
IN/OUT
IN
VCTERM
GND
VCTERM
GND
IN
IN
D025#
VCTERM
D029#
D031#
VCTERM
D063#
D060#
VCTERM
D059#
D092#
VCTERM
D089#
D090#
VCTERM
D124#
D126#
VCTERM
D121#
GND
D25#
IN/OUT
IN
VCTERM
D29#
IN/OUT
IN/OUT
IN
D31#
VCTERM
D63#
IN/OUT
IN/OUT
IN
D60#
VCTERM
D59#
IN/OUT
IN/OUT
IN
D92#
VCTERM
D89#
IN/OUT
IN/OUT
IN
D90#
VCTERM
D124#
D126#
VCTERM
D121#
GND
IN/OUT
IN/OUT
IN
IN/OUT
IN
D030#
GND
D30#
IN/OUT
IN
GND
DEP03#
GND
DEP3#
GND
IN/OUT
IN
DEP02#
GND
DEP2#
GND
IN/OUT
IN
DEP06#
GND
DEP6#
GND
IN/OUT
IN
DEP07#
GND
DEP7#
GND
IN/OUT
IN
D062#
GND
D62#
IN/OUT
IN
GND
D094#
GND
D94#
IN/OUT
IN
GND
DEP11#
GND
DEP11#
GND
IN/OUT
IN
DEP10#
GND
DEP10#
GND
IN/OUT
IN
Datasheet
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 10 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
DEP14#
GND
DEP14#
GND
T20
T21
T22
T23
T24
T25
U02
U03
U04
U05
U06
U07
U09
U10
U11
U13
U14
U15
U17
U18
U19
U20
U21
U22
U23
U24
U25
V01
V02
V03
V04
V05
V06
V07
V08
V09
V10
V11
V12
V13
V14
IN/OUT
IN
DEP15#
GND
DEP15#
GND
IN/OUT
IN
D123#
GND
D123#
IN/OUT
IN
GND
VCTERM
A005#
GND
VCTERM
AA05#/EXF2#
GND
IN
IN/OUT
IN
N/C
VCTERM
A009#
A018#
VCTERM
N/C
VCTERM
AA09#/BE1#
AA18#/DID2#
VCTERM
IN
IN/OUT
IN/OUT
IN
A016#
VCTERM
A028#
BNR#
VCTERM
A027#
GND
AA16#/DID0#
VCTERM
IN/OUT
IN
AA28#/xTPRValue1#
BNR#
IN/OUT
IN/OUT
IN
VCTERM
AA27#/xTPRValue0#
GND
IN/OUT
IN
A048#
VCTERM
A042#
GND
AA48#/AB48#
VCTERM
IN/OUT
IN
AA42#/AB42#
GND
IN/OUT
IN
VCTERM
GND
VCTERM
IN
GND
IN
A004#
GND
AA04#/EXF1#
GND
IN/OUT
IN
A010#
GND
AA10#/BE2#
GND
IN/OUT
IN
A003#
GND
AA03#/EXF0#
GND
IN/OUT
IN
A015#
GND
AA15#/BE7#
GND
IN/OUT
IN
A020#
GND
AA20#/DID4#
GND
IN/OUT
IN
A019#
GND
AA19#/DID3#
GND
IN/OUT
IN
A031#
AA31#/xTPRDisable#
IN/OUT
62
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 11 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
A038#
GND
GND
AA38#/AB38#
GND
V15
V16
V17
V18
V19
V20
V21
V22
V23
V24
V25
W02
W03
W05
W07
W09
W11
W13
W15
W17
W19
W21
W23
W25
Y01
Y02
Y03
Y04
Y05
Y06
Y07
Y08
Y09
Y10
Y11
Y12
Y13
Y14
Y15
Y16
Y17
IN
IN/OUT
IN
A029#
GND
AA29#/xTPRValue2#
GND
IN/OUT
IN
A045#
GND
AA45#/AB45#
GND
IN/OUT
IN
A047#
GND
AA47#/AB47#
GND
IN/OUT
IN
A040#
GND
AA40#/AB40#
GND
IN/OUT
IN
GND
GND
IN
A006#
A012#
A014#
A021#
A026#
A022#
A037#
A032#
A030#
A044#
A046#
A041#
GND
AA06#/EXF3#
AA12#/BE4#
AA14#/BE6#
AA21#/DID5#
AA26#/AB26#
AA22#/DID6#
AA37#/AB37#
AA32#/ATTR0#
AA30#/xTPRValue3#
AA44#/AB44#
AA46#/AB46#
AA41#/AB41#
GND
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN/OUT
IN
A007#
GND
AA07#/EXF4#
GND
IN/OUT
IN
A013#
GND
AA13#/BE5#
GND
IN/OUT
IN
A008#
GND
AA08#/BE0#
GND
IN/OUT
IN
A017#
GND
AA17#/DID1#
GND
IN/OUT
IN
A024#
GND
AA24#/DID8#
GND
IN/OUT
IN
A025#
GND
AA25#/DID9#
GND
IN/OUT
IN
A034#
GND
AA34#/ATTR2#
GND
IN/OUT
IN
A036#
GND
AA36#/AB36#
GND
IN/OUT
IN
Datasheet
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 12 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
A035#
GND
AA35#/ATTR3#
GND
Y18
Y19
IN/OUT
IN
A039#
GND
AA39#/AB39#
GND
Y20
IN/OUT
IN
Y21
A049#
GND
AA49#/AB49#
GND
Y22
IN/OUT
IN
Y23
A043#
GND
AA43#/AB43#
GND
Y24
IN/OUT
IN
Y25
GND
GND
AA02
AA03
AA05
AA07
AA09
AA11
AA13
AA15
AA17
AA19
AA20
AA21
AA23
AA24
AA25
AB01
AB02
AB03
AB04
AB05
AB06
AB07
AB08
AB09
AB10
AB11
AB12
AB13
AB14
AB15
AB16
AB17
AB18
IN
ID3#
IDA3#/IDB3#
AA11#/BE3#
DRDY_C1#
DBSY_C1#
AA23#/DID7#
SBSY_C1#
BINIT#
IN
A011#
DRDY0#
DBSY0#
A023#
SBSY0#
BINIT#
A033#
DBSY1#
GND
IN/OUT
OUT
OUT
IN/OUT
OUT
IN/OUT
IN/OUT
OUT
IN
AA33#/ATTR1#
DBSY_C2#
GND
DRDY1#
AP1#
GND
DRDY_C2#
AP1#
OUT
IN/OUT
IN
GND
AP0#
GND
AP0#
IN/OUT
IN
GND
ID1#
IDA1#/IP1#
GND
IN
GND
IN
ID5#
IDA5#/IDB5#
GND
IN
GND
IN
ID9#
IDA9#/IDB9#
GND
IN
GND
IN
RS2#
GND
RS2#
IN
GND
IN
HIT#
HIT#
IN/OUT
IN
GND
GND
HITM#
GND
HITM#
IN/OUT
IN
GND
DEFER#
GND
DEFER#
GND
IN
IN
N/C
GND
GND
IN
IN
BR2#
BREQ2#
64
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Pinout Specifications
Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 13 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
ADS#
GND
GND
ADS#
AB19
AB20
AB21
AB22
AB23
AB24
AB25
AC02
AC03
AC05
AC07
AC09
AC11
AC13
AC15
AC17
AC19
AC21
AC23
AC24
AC25
AD01
AD02
AD03
AD04
AD05
AD06
AD07
AD08
AD09
AD10
AD11
AD12
AD13
AD14
AD15
AD16
AD17
AD18
AD19
AD20
IN
IN/OUT
IN
GND
BERR#
GND
BERR#
GND
IN/OUT
IN
BPM5#
GND
BPM5#
GND
IN/OUT
IN
GND
GND
IN
ID2#
IDA2#/DHIT#
IDA7#/IDB7#
IDS#
IN
ID7#
IN
IDS#
IN
DBSY#
DRDY#
RP#
DBSY#
DRDY#
RP#
IN/OUT
IN/OUT
IN/OUT
IN/OUT
TND#
N/C
TND#
SBSY1#
N/C#
SBSY_C2#
OUT
BPM3#
GND
BPM3#
GND
IN/OUT
IN
BPM1#
GND
BPM1#
GND
IN/OUT
IN
ID0#
IDA0#/IP0#
GND
IN
GND
IN
ID4#
IDA4#/IDB4#
GND
IN
GND
IN
ID8#
IDA8#/IDB8#
GND
IN
GND
IN
RS1#
GND
RS1#
IN
GND
IN
REQ2#
GND
REQA2#/ REQB2#
GND
IN/OUT
IN
REQ5#
GND
REQ5#
GND
IN/OUT
IN
GSEQ#
GND
GSEQ#
GND
IN
IN
BR1#
GND
BREQ1#
GND
IN
IN
N/C
GND
GND
IN
IN
RESET#
RESET#
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Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 14 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
BPM0#
GND
GND
BPM0#
AD21
AD22
AD23
AD24
AD25
AE02
AE03
AE05
AE07
AE09
AE11
AE13
AE15
AE17
AE19
AE21
AE23
AE24
AE25
AF01
AF02
AF04
AF05
AF06
AF07
AF08
AF09
AF10
AF11
AF12
AF13
AF14
AF15
AF16
AF17
AF18
AF19
AF20
AF21
AF22
AF24
IN
IN/OUT
IN
GND
BPM4#
GND
BPM4#
IN/OUT
IN
GND
GND
GND
IN
TERMB
ID6#
FSBT2
IDA6#/IDB6#
RS0#
IN
RS0#
REQ0#
REQ3#
SBSY#
LOCK#
N/C
IN
REQA0#/LEN0#
ASZ0#/DSZ0#
SBSY#
IN/OUT
IN/OUT
IN/OUT
IN/OUT
LOCK#
BPRI#
TRST#
BPM2#
GND
BPRI#
TRST#
BPM2#
GND
IN
IN
IN/OUT
IN
PMI#
PMI#
IN
GND
GND
IN
TERM
OUTEN
GND
FSBT
IN
OUTEN
GND
IN
Power pod signal
IN
RSP#
GND
RSP#
IN
GND
IN
INIT#
INIT#
IN
GND
GND
IN
REQ1#
GND
WSNP#, D/C#/LEN1#
GND
IN/OUT
IN
REQ4#
GND
ASZ1#/DSZ1#
GND
IN/OUT
IN
TRDY#
GND
TRDY#
GND
IN
IN
BR0#
GND
BREQ0#
GND
IN/OUT
IN
BR3#
GND
BREQ3#
GND
IN
IN
PPODGD#
GND
PPODGD#
GND
OUT
IN
Power pod signal
LINT0
LINT1
INT
IN
NMI
IN
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Table 3-2. Pin/Signal Information Sorted by Pin Location (Sheet 15 of 15)
System Bus
Signal Name
Pin
Location
Pin Name
Input/Output
Notes
GND
TUNER[2]
GND
GND
AG02
AG03
AG04
AG05
AG06
AG07
AG08
AG09
AG10
AG11
AG12
AG13
AG14
AG15
AG16
AG17
AG18
AG19
AG20
AG21
AG22
AG23
AG24
AG25
AH01
AH03
AH05
AH07
AH09
AH11
AH13
AH15
AH17
AH19
AH21
AH23
AH25
IN
GND
IN
N/C
GND
GND
TDI
IN
IN
IN
IN
IN
TDI
JTAG
JTAG
GND
GND
TCK
GND
TCK
GND
N/C
GND
GND
CLK
IN
IN
BCLKp
GND
GND
IN
CPUPRES#
GND
CPUPRES#
GND
OUT
IN
Power pod signal
N/C
GND
GND
GND
IN
IN
N/C
GND
N/C
GND
GND
IGNNE#
GND
IN
IN
IGNNE#
GND
IN
THRMTRIP#
GND
THRMTRIP#
GND
OUT
IN
Thermal trip
TUNER[1]
N/C
TDO
TDO
TMS
OUT
IN
JTAG
JTAG
TMS
N/C
BCLKn
PWRGOOD
N/C
BCLKN
IN
IN
PWRGOOD
N/C
N/C
A20M#
FERR#
A20M#
FERR#
IN
OUT
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4 Mechanical Specifications
This chapter provides the mechanical specifications of the Itanium 2 processor.
4.1
Mechanical Dimensions
The Itanium 2 processor package is comprised of an interposer, a processor package substrate, and
socket and the power pod and contains 611 pins which are positioned in a 25 x 28 grid. The IHS,
which is mounted on the top surface of the processor package substrate, efficiently transfers the
heat generated by the die to its surface.
®
Figure 4-1. Itanium 2 Processor Package
IHS
Processor
Package
Substrate
(OLGA)
Interposer
001160e
Figure 4-2 contains mechanical drawings and dimensions for the Itanium 2 processor package.
Figure 4-3 contains mechanical drawing for the power tab. All dimensions are measured in mm
and are not to scale.
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®
Figure 4-2. Itanium 2 Processor Package
90.00
42.50
38.50
48.26
42.50
38.50
Top View
Integrated Heat Spreader
IHS Height (See Note)
Processor Package Substrate
Substrate Height (See Note)
Interposer
1.43
0.00
2.03
Pins
Side View
34.29
28 x 1.27 Pitch
25 x 1.27 Pitch
Ø
611 x 0.305 Pins
30.48
Bottom View
All dimensions are measured in mm. Not to scale.
000655g
NOTE:
IHS
Processor
Substrate
Height
Units
Height
900 MHz (1.5 MB)
1.0 GHz (3 MB)
5.575
5.575
5.825
5.825
5.825
5.825
5.825
3.397
3.397
3.447
3.447
3.447
3.447
3.447
mm
mm
mm
mm
mm
mm
mm
1.3 GHz (3 MB)
1.4 GHz (4 MB)
1.5 GHz (4 MB/6 MB)
1.6 GHz (6 MB/9 MB)
1.66 GHz (6 MB/9 MB)
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®
Figure 4-3. Itanium 2 Processor Package Power Tab
C
L
2.48
2x R1.20
2x 25.85
12x 2.92
24.13
12x 0.86
10x 1.15
46.96
C
L
46.74
48.26
2x 16.10
12x 38.76
42.46
45.00
90.00
Top View
C
L
2.98
2x 9.10
2x 12.91
46.96
46.00
42.21
4x R1.00
Bottom View
All dimensions are measured in mm. Not to scale.
001159a
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4.2
Package Marking
The following section details the processor top-side and bottom-side markings for the Itanium 2
processor and is provided as an identification aid. The processor top-side mark for the product is a
laser marking on the IHS.
4.2.1
Processor Top-Side Marking
Figure 4-4 shows an example of the laser marking on the IHS. The processor top-side mark
provides the following information:
• INTEL CONFIDENTIAL
• Legal Mark
• Assembly Process Order (APO) number
• Serial Number
Figure 4-4. Processor Top-Side Marking on IHS
INTEL CONFIDENTIAL
i M C 'YY
APO NUMBER
SERIAL NUMBER
001088b
4.2.2
Processor Bottom-Side Marking
The processor bottom-side mark for the product is a laser marking on the pin side of the interposer.
Figure 4-5 shows the placement of the laser marking on the pin side of interposer. The processor
bottom-side mark provides the following information:
• Product ID
• Finish Process Order (FPO)
• Serial Number
• S-Spec
• Country of origin
• 2D Matrix Mark (on Itanium 2 processor [1.30 GHz, 1.40 GHz, 1.50 GHz, 1.60 GHz],
Itanium 2 (9 MB) class of processors and Montecito class of processors only. Not included on
the Itanium 2 [900 MHz, 1.0 GHz] processor).
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Figure 4-5. Processor Bottom-Side Marking Placement on Interposer
Laser Mark including
2D Matrix Mark
AH25
A25
AH1
A1
Pin 1
Indicator
001267b
NOTE: 2D Matrix Mark only present on Itanium 2 processor (6 MB), Itanium 2 processor (4 MB) and Itanium 2
processor (1.3 GHz, 3 MB).
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5 Thermal Specifications
This chapter provides a description of the thermal features relating to the Itanium 2 processor.
5.1
Thermal Features
The Itanium 2 processor has an internal thermal circuit which senses when a certain temperature is
reached on the processor core. This circuit is used for controlling various thermal states. In
addition, an on-chip thermal diode is available for use by the thermal sensing device on the
alert, enhanced thermal management (ETM), and thermal trip points.
Note: Figure 5-1 is not intended to show a linear relationship in time or temperature as a processor's
thermal state advances from one state to the next state when the cooling solution fails to control the
processor temperature, as this is affected by many factors such as cooling solution performance
degradation and processor workload variations.
®
Figure 5-1. Itanium 2 Processor Thermal Features
Thermal Trip
ETM
Thermal Alert
Time
000653b
5.1.1
Thermal Alert
THRMALERT# is a programmable thermal alert signal which is part of the Itanium 2 processor
system management feature. THRMALERT# is asserted when the measured temperature from the
processor thermal diode equals or exceeds the temperature threshold data programmed in the high
temp (THIGH) or low temp (TLOW) registers on the sensor. Intel recommends using the upper
temperature reference byte listed in the Processor Information ROM when programming the
implement thermal regulation features such as generating an external interrupt to tell the operating
system that the processor core die temperature is increasing.
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5.1.2
Enhanced Thermal Management
ETM is a new feature that has been added to the Itanium 2 processor. ETM uses a thermal sensing
device on the die to monitor a thermal entry point, indicating dangerous operation exceeding the
thermal specification. Once the thermal sensing device observes the temperature rise above the
thermal entry point, the processor will enter a low power mode of execution and notify the system
by sending a Correctable Machine Check Interrupt (CMCI). The Itanium 2 processor will remain in
this low power mode until the temperature decreases below the thermal entry point and remains for
approximately one second, at which point the it will send an another CMCI and resume normal
operation. If the temperature cannot be reduced and continues to rise to critical levels, the
processor will assert the THRMTRIP# signal. The ETM feature may be disabled through the PAL.
5.1.3
Thermal Trip
The Itanium 2 processor protects itself from catastrophic overheating by use of an internal thermal
sensor. The sensor trip point is set well above the normal operating temperature to ensure that there
are no false trips. The Itanium 2 processor will stop all execution when the junction temperature
exceeds a safe operating level.
Warning: Data will be lost if the Itanium 2 processor goes into thermal trip (signaled to the system by the
THRMTRIP# pin).
Once thermal trip is activated, the Itanium 2 processor remains stopped until RESET# is asserted.
The processor case temperature must drop below the specified maximum before issuing a reset to
5.2
Case Temperature
temperature is defined as the temperature measured at the center of the top surface of the IHS.
Warning: Data may be lost if the case temperature exceeds the specified maximum.
Table 5-1. Case Temperature Specification
Core
Frequency
Symbol
Parameter
Minimum
Maximum
Unit
Notes
Tcase
Case Temperature
900 MHz
1.0 GHz
1.3 GHz
1.4 GHz
1.5 GHz
1.6 GHz
1.66 GHz
5
5
5
5
5
5
5
85
85
83
83
83
83
83
°C
°C
°C
°C
°C
°C
°C
Figure 5-2 contains dimensions for the thermocouple location on the Itanium 2 processor package.
This is the recommended location for placement of a thermocouple for case temperature
measurement.
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6 System Management Feature
Specifications
The Itanium 2 processor includes a system management bus (SMBus) interface. This chapter
describes the features of the SMBus and SMBus components.
6.1
System Management Bus
6.1.1
System Management Bus Interface
The Itanium 2 processor includes an Itanium processor family SMBus interface which allows
access to several processor features. The system management components on the processor include
two memory components (EEPROMs) and a thermal sensing device (digital thermometer). The
processor information EEPROM (PIROM) is programmed by Intel with manufacturing and feature
information specific to the Itanium 2 processor. This information is permanently write-protected.
Section 6.2 provides detail on the PIROM. The other EEPROM is a scratch EEPROM that is
available for other data at the system vendor’s discretion. The thermal sensor can be used in
conjunction with the information in the PIROM and/or the Scratch EEPROM for system thermal
monitoring and management. The thermal sensing device on the processor provides an accurate
means of acquiring an indicator of the junction temperature of the processor core die. The thermal
sensing device is connected to the anode and cathode of the Itanium 2 processor on-die thermal
diode. SMBus implementation on the Itanium 2 processor uses the clock and data signals as
defined by SMBus specifications.
6.1.2
System Management Interface Signals
Table 6-1 lists the system management interface signals and their descriptions. These signals are
used by the system to access the system management components via the SMBus.
Table 6-1. System Management Interface Signal Descriptions
Signal Name
3.3V
Pin Count
Description
1
3
1
1
1
1
Voltage supply for EEPROMs and thermal sensor.
Address select passed through from socket.
System management bus clock.
SMA[2:0]
SMSC
SMSD
System management serial address/data bus.
Scratch EEPROM write protect.
SMWP
THRMALERT#
Temperature alert from the thermal sensor.
Figure 6-1 shows the logical schematics of SMBus circuitry on the Itanium 2 processor and shows
how the various system management components are connected to the SMBus. The reference to
for multiple Itanium 2 processors can be realized with resistor stuffing options.
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Figure 6-1. Logical Schematic of SMBus Circuitry
Intel® Itanium® 2 Processor
3.3V
Core
THERMDA
10K
10K
10K
VCC
THERMDC
A0
A1
A2
SC
SD
Processor
Information
ROM
VCC
A0
STBY
SC
Thermal
Sensing
Device
A1
SD
10K
ALERT
VCC
A0
A1
A2
SC
SD
Scratch
EEPROM
10K
10K
WP
SMA0
SMA1
SMA2
SMWP
SMSD
SMSC
3.3V
THRMALERT#
3.3V
3.3V
10K
Stuffing
Options
System Board
System Board
NOTE:
1. Actual implementation may vary.
2. For use in general understanding of the architecture.
000668b
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6.1.3
SMBus Device Addressing
Of the addresses broadcast across the SMBus, the memory components claim those of the form
“1010XXYZb”. The “XX” and “Y” bits are used to enable the devices on the processor at adjacent
addresses. The Y bit is hard-wired on the processor to GND (‘0’) for the Scratch EEPROM and
pulled to 3.3V (‘1’) for the processor information ROM. The “XX” bits are defined by the
processor socket via the SMA0 and SMA1 pins on the Itanium 2 processor connector. These
address pins have a weak pull-down (10 kΩ) to ensure that the memory components are in a known
state in systems which do not support the SMBus, or only support a partial implementation. The
“Z” bit is the read/write bit for the serial bus transaction.
The thermal sensing device internally decodes 1 of 3 upper address patterns from the bus of the
form “0011XXXZb”, “1001XXXZb” or “0101XXXZb”. The device’s addressing, as implemented,
uses SMA2 and SMA1 and includes a Hi-Z state for the SMA2 address pin. Therefore, the thermal
sensing device supports six unique resulting addresses. To set the Hi-Z state for SMA2, the pin
must be left floating. The system should drive SMA1 and SMA0, and will be pulled low (if not
driven) by the 10 kΩpull-down resistor on the processor substrate. Attempting to drive either of
these signals to a Hi-Z state would cause ambiguity in the memory device address decode, possibly
resulting in the devices not responding, thus timing out or hanging the SMBus. As before, the “Z”
bit is the read/write bit for the serial bus transaction.
address pin connections and how they affect the addressing of the devices.
Note: Addresses of the form “0000XXXXb” are Reserved and should not be generated by an SMBus
master. Also, system management software must be aware of the processor select in the address for
the thermal sensing device.
®
Table 6-2. Thermal Sensing Device SMBus Addressing on the Itanium 2 Processor
Processor Select
8-Bit Address Word on Serial Bus
1
Address (Hex)
Upper Address
SMA2
SMA1
b[7:0]
3Xh
0011
0011
0101
0101
1001
1001
0
0
0
1
0
1
0
1
0011000Xb
0011010Xb
0101001Xb
0101011Xb
1001100Xb
1001110Xb
2
5Xh
9Xh
Z
b
Z
1
1
NOTES:
1. Upper address bits are decoded in conjunction with the select pins.
2. A tri-state or “Z” state on this pin is achieved by leaving this pin unconnected.
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®
Table 6-3. EEPROM SMBus Addressing on the Itanium 2 Processor
Memory
Device
Select
Upper
Address
Read/
Write
Processor Select
1
Address
(Hex)
Device Addressed
(SMA1)
Bit 3
(SMA0)
Bit 2
Bits 7–4
Bit 1
Bit 0
A0h/A1h
A2h/A3h
A4h/A5h
A6h/A7h
A8h/A9h
AAh/ABh
ACh/ADh
AEh/AFh
NOTES:
1010
1010
1010
1010
1010
1010
1010
1010
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
X
X
X
X
X
X
X
X
Scratch EEPROM 1
Processor Information ROM 1
Scratch EEPROM 2
Processor Information ROM 2
Scratch EEPROM 3
Processor Information ROM 3
Scratch EEPROM 4
Processor Information ROM 4
1. Though this addressing scheme is targeted for up to four-way MP systems, more processors can be supported by using a
multiplexed (or separate) SMBus implementation.
6.2
Processor Information ROM
An electrically programmed read-only memory (ROM) provides information about the Itanium 2
processor. The checksum bits for each category provide error correction and serve as a mechanism
to check whether data is corrupted or not. This information is permanently write-protected.
Table 6-4 shows the data fields and formats provided in the memory.
Note: The data, in byte format, is written and read serially with the most significant bit first.
Table 6-4. Processor Information ROM Format (Sheet 1 of 4)
Offset/
Section
# of
Bits
Function
Notes
Examples
Header
00h
01h
8
Data Format Revision
EEPROM Size
Two 4-bit hex digits
Start with 00h
16
Size in bytes (MSB first)
Use a decimal to hex
transfer; 128 bytes =
0080h:
•
•
•
•
02h[7:4] = 0000
02h[3:0] = 0000
01h[7:4] = 1000
01h[3:0] = 0000
03h
04h
05h
06h
07h
08h
8
8
8
8
8
8
Processor Data Address
Processor Core Address
Processor Cache Address
Processor Data Address
Part Number Data Address
Byte pointer, 00h if not present
Byte pointer, 00h if not present
Byte pointer, 00h if not present
Byte pointer, 00h if not present
Byte pointer, 00h if not present
Byte pointer, 00h if not present
0Eh
17h
28h
37h
3Eh
63h
Thermal Reference Data
Address
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Table 6-4. Processor Information ROM Format (Sheet 2 of 4)
Offset/
Section
# of
Bits
Function
Notes
Examples
09h
8
8
Feature Data Address
Other Data Address
Reserved
Byte pointer, 00h if not present
Byte pointer, 00h if not present
Reserved for future use
1 byte checksum
67h
0Ah
0Bh
0Dh
7Ah
16
8
0000h
Checksum
Add up by byte and
take 2’s complement.
Processor
0Eh
48
S-spec Number
Six 8-bit ASCII characters
S-spec number of S123
would be:
•
•
•
•
•
•
13h = 00h
12h = 00h
11h = “3”
10h = “2”
0Fh = “1”
0Eh = “S”
14h
2
Sample/Production
00b = Sample only (MSB First)
00000001b =
Production
15h
16h
8
8
Reserved
Reserved for future use
1 byte checksum
00h
Checksum
Add up by byte and
take 2’s complement.
Core
1
17h
8
8
8
8
Architecture Revision
Processor Core Family
Processor Core Model
Processor Core Stepping
From CPUID
Taken from
CPUID[3].archrev.
18h
19h
1Ah
From CPUID
From CPUID
From CPUID
Taken from
CPUID[3].family.
Taken from
CPUID[3].model.
Taken from
CPUID[3].revision.
1Bh
1Eh
20h
24
16
12
Reserved
Reserved for future use
000000h
2
Maximum Core Frequency
Four 4-bit hex digits (in MHz)
Three 4-bit hex digits (in MHz)
1 GHz = 1000h
Maximum System Bus
Frequency
200 MHz = 200h
22h
24h
25h
16
8
Core Voltage ID
Voltage in four 4-bit hex digits
(in mV)
1500 mV = 1500h
Core Voltage Tolerance,
High
Edge finger tolerance in mV, +
two 4-bit hex digits
1.5% = 22 mV = 22h
1.5% = 22 mV = 22h
8
Core Voltage Tolerance,
Low
Edge finger tolerance in mV, –
two 4-bit hex digits
26h
27h
8
8
Reserved
Reserved for future use
1 byte checksum
00h
Checksum
Add up by byte and
take 2’s complement.
Cache
28h
2Ch
2Eh
36h
32
16
64
8
Reserved
Cache Size
Reserved
Checksum
Reserved for future use
Four 4-bit hex digits (in Kbytes)
Reserved for future use
1 byte checksum
00000000h
3072 Kbytes = 3072h
x0h
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Table 6-4. Processor Information ROM Format (Sheet 3 of 4)
Offset/
Section
# of
Bits
Function
Notes
Examples
Package
®
37h
32
Package Revision
Four 8-bit ASCII characters
Itanium 2 Package =
INT2b, (1.50 GHz 4MB
and above) = INT3b:
•
•
•
•
37h = I
38h = N
39h = T
3Ah = 2 or 3
3Bh
2
Substrate Revision
Software ID
2-bit revision number
00
3Ch
3Dh
8
8
Reserved
Reserved for future use
1 byte checksum
00h
Checksum
Add up by byte and
take 2’s complement
Part Numbers
3Eh 56
Processor Part Number
Seven 8-bit ASCII characters
Itanium 2 (900 MHz,
1.0 GHz) = 80542KC.
Itanium 2 processor
(1.30 GHz -1.66 GHz) =
80543KC:
•
•
•
•
•
•
•
3Eh = “8”
3Fh = “0”
40h = “5”
41h = “4”
42h = “2” or “3”
43h = “K”
44h = “C”
45h
64
Processor Electronic
Signature
64-bit identification number
May have padded
zeros
4Dh
62h
168 Reserved
Reserved for future use
1 byte checksum
x0h
8
Checksum
Add up by byte and
take 2’s complement
Thermal Reference
63h
8
Upper Temp Reference
Byte
Hex value of thermal upper temp Default = 113 for 1.66
limit
GHz through 1.5
GHz/4MB. Default =
105 for all others.
64h
8
Thermal Calibration Offset
Byte Present
Number of degrees in error (±)
Default = 0
65h
66h
8
8
Reserved
Reserved for future use
1 byte checksum
00h
Checksum
Add up by byte and
take 2’s complement.
Features
67h
32
64
IA-32 Processor Core
Feature Flags
From 32 bit CPUID
4387FBFFh
6Bh
Reserved
Reserved (Processor core
0000 0000 6380 811Bh
feature flags implemented in the
®
Itanium processor family)
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Table 6-4. Processor Information ROM Format (Sheet 4 of 4)
Offset/
Section
# of
Bits
Function
Notes
Examples
73h
32
Processor Feature Flags
All other are reserved:
1 indicates EEPROM
[4] =Upper temp reference byte data for specified field
[3] =Thermal calibration offset
byte present
is valid.
[2] =SCRATCH EEPROM
present
[1] =Core VID present
77h
4
Number of Devices in TAP
Chain
One 4-bit hex digit
78h
79h
4
8
Reserved
Reserved for future use
1 byte checksum
0h
Checksum
Add up by byte and
take 2’s complement.
Other
7Ah
16
Reserved
Reserved for future use
0000h
NOTES:
®
®
1. Refer to the Intel Itanium Architecture Software Developer’s Manual for details on CPUID registers.
2. The translation is using BCD.
6.3
6.4
Scratch EEPROM
Also available on the SMBus interface on the processor is an EEPROM which may be used for
other data at the system vendor’s discretion (Intel will not be using the scratch EEPROM). The data
in this EEPROM, once programmed, can be write-protected by asserting the active-high SMWP
signal. This signal has a weak pull-down (10 kΩ) to allow the EEPROM to be programmed in
systems with no implementation of this signal.
Processor Information ROM and Scratch EEPROM
Supported SMBus Transactions
The processor information ROM and scratch EEPROM responds to three of the SMBus packet
types: current address read, random address read, and sequential read.
Table 6-5 shows the format of the current address read SMBus packet. The internal address counter
keeps track of the address accessed during the last read or write operation, incremented by one.
Address “roll over” during reads is from the last byte of the last eight byte page to the first byte of
the first page. “Roll over” during writes is from the last byte of the current eight byte page to the
first byte of the same page.
Table 6-6 shows the format of the random read SMBus packet. The write with no data loads the
address desired to be read. Sequential reads may begin with a current address read or a random
address read. After the SMBus host controller receives the data word, it responds with an
acknowledge. This will continue until the SMBus host controller responds with a negative
acknowledge and a stop.
Table 6-7 shows the format of the byte write SMBus packet. The page write operates the same way
as the byte write except that the SMBus host controller does not send a stop after the first data byte
and acknowledge. The Scratch EEPROM internally increments its address. The SMBus host
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controller continues to transmit data bytes until it terminates the sequence with a stop. All data
bytes will result in an acknowledge from the Scratch EEPROM. If more than eight bytes are
written, the internal address will “roll over” and the previous data will be overwritten.
represents a read, ‘W’ represents a write bit, ‘A’ represents an acknowledge, and ‘///’ represents a
negative acknowledge. The shaded bits are transmitted by the processor information ROM or
Scratch EEPROM and the bits that are not shaded are transmitted by the SMBus host controller. In
the tables the data addresses indicate eight bits. The SMBus host controller should transmit eight
bits, but as there are only 128 addresses, the most significant bit is a don’t care.
Table 6-5. Current Address Read SMBus Packet
Device
Address
S
R
A
Data
///
P
1
7 bits
1
1
8 bits
1
1
Table 6-6. Random Address Read SMBus Packet
Device
Address
Data
Address
Device
Address
S
W
A
A
S
R
A
Data
///
P
1
7 bits
1
1
8 bits
1
1
7 bits
1
1
8 bits
1
1
Table 6-7. Byte Write SMBus Packet
Device
Address
Data
Address
S
W
A
A
Data
A
P
1
7 bits
0
1
8 bits
1
8 bits
1
1
6.5
Thermal Sensing Device
The Itanium 2 processor’s thermal sensing device provides a means of acquiring thermal data from
the processor. The accuracy of the thermal reading is expected to be better than ±3 °C. The thermal
sensing device is composed of control logic, SMBus interface logic, a precision analog to digital
converter, and a precision current source. The thermal sensing device drives a small current
through a thermal diode located on the processor core and measures the voltage generated across
the thermal diode by the current. With this information, the thermal sensing device computes a byte
of temperature data. Software running on the processor or on a micro-controller can use the
temperature data from the thermal sensing device to thermally manage the system.
The thermal sensing device provides a register with a data byte (seven bits plus sign) which
contains a value corresponding to the sampled output of the thermal diode in the Itanium 2
processor core. The value of the byte read from the thermal sensor gives an accurate reading of
processor core temperature at the time of the reading. This data can be used in conjunction with the
upper temperature reference byte (provided in the processor information ROM) for thermal
management purposes. The temperature data from the thermal sensor can be read out digitally
is applied to the processor, and resets itself at power up.
The thermal sensing device also contains alarm registers to store thermal reference threshold data.
These values can be individually programmed on the thermal sensor. If the measured temperature
equals or exceeds the alarm threshold value, the appropriate bit is set in the thermal sensing device
status register, which is also brought out to the Itanium 2 processor system bus via the
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register values need to be programmed into the thermal sensing device via the SMBus. It is
recommended that the upper thermal reference threshold byte (provided in the processor
information ROM) be used for setting the upper threshold value in the alarm register.
When polling the thermal sensing device on the processor to read the processor temperatures, it is
recommended that the polling frequency be every 0.5 to 1 second.
6.6
Thermal Sensing Device Supported SMBus
Transactions
The thermal sensing device responds to five of the SMBus packet types: write byte, read byte, send
byte, receive byte, and alert response address (ARA). The send byte packet is used for sending one-
shot commands only. The receive byte packet accesses the register commanded by the last read
byte packet. If a receive byte packet was preceded by a write byte or send byte packet more
diagram the five packet types. In these tables, ‘S’ represents the SMBus start bit, ‘P’ represents a
stop bit, ‘Ack’ represents an acknowledge, and ‘///’ represents a negative acknowledge. The shaded
bits are transmitted by the thermal sensor and the unshaded bits are transmitted by the SMBus host
Table 6-8. Write Byte SMBus Packet
S
Address Write
7 bits
Ack
Command
Ack
Data
Ack
P
1
1
1
8 bits
1
8 bits
1
1
Table 6-9. Read Byte SMBus Packet
S
Address Write
7 bits
Ack
Command
Ack
S
Address
7 bits
Read
Ack
Data
///
P
1
1
1
8 bits
1
1
1
1
8 bits
1
1
Table 6-10. Send Byte SMBus Packet
S
Address Write
7 bits
Ack
Command
Ack
P
1
1
1
8 bits
1
Table 6-11. Receive Byte SMBus Packet
S
Address Read
7 bits
Ack
Data
///
P
1
1
1
8 bits
1
1
Table 6-12. ARA SMBus Packet
S
ARA
Read
Ack
Address
///
P
1
0001 100
1
1
1001 1011
1
1
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Table 6-13. Command Byte Bit Assignment
Register
Command
Reset State
Function
Reserved for future use.
RESERVED
RRT
00h
01h
N/A
N/A
Read processor core thermal data.
Read status byte (flags, busy signal).
Read configuration byte.
RS
02h
N/A
RC
03h
0000 0000
0000 0010
0111 1111
1100 1001
0111 1111
1100 1001
N/A
RCR
04h
Read conversion rate byte.
RESERVED
RESERVED
RRHL
05h
Reserved for future use.
06h
Reserved for future use.
07h
Read processor core thermal diode T
Read processor core thermal diode T
Write configuration byte.
limit.
limit.
HIGH
LOW
RRLL
08h
WC
09h
WCR
0Ah
N/A
Write conversion rate byte.
RESERVED
RESERVED
WRHL
0Bh
N/A
Reserved for future use.
0Ch
0Dh
0Eh
N/A
Reserved for future use.
N/A
Write processor core thermal diode T
Write processor core thermal diode T
limit.
limit.
HIGH
WRLL
N/A
LOW
OSHT
0Fh
N/A
One shot command (use send byte packet).
Reserved for future use.
RESERVED
10h – FFh
N/A
All of the commands are for reading or writing registers in the thermal sensor except the one-shot
command (OSHT). The one-shot command forces the immediate start of a new voltage-to-
temperature conversion cycle. If a conversion is in progress when the one-shot command is
received, then the command is ignored. If the thermal sensing device is in standby mode when the
one-shot command is received, a conversion is performed and the sensor returns to standby mode.
If the thermal sensor is in auto-convert mode and is between conversions, then the conversion rate
timer resets, and the next automatic conversion takes place after a full delay elapses. Please refer to
Section 6.7.4 for further detail on standby and auto-convert modes.
The default command after reset is the reserved value (00h). After reset, receive byte packets will
return invalid data until another command is sent to the thermal sensing device.
6.7
Thermal Sensing Device Registers
The system management software can configure and control the thermal sensor by writing to and
interacting with different registers in the thermal sensor. These registers include a thermal
reference register, two thermal limit registers, a status register, a configuration register, a
conversion rate register, and other reserved registers. The following subsections describe the
registers in detail.
6.7.1
Thermal Reference Registers
The processor core and thermal sensing device internal thermal reference registers contain the
thermal reference value of the thermal sensing device and the processor core thermal diodes. This
value ranges from +127 to –128 decimal and is expressed as a two’s complement, eight-bit number.
These registers are saturating, that is, values above 127 are represented at 127 decimal, and values
below –128 are represented as –128 decimal.
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6.7.2
6.7.3
Thermal Limit Registers
The thermal sensing device has two thermal limit registers; they define high and low limits for the
processor core thermal diode. The encoding for these registers is the same as for the thermal
reference registers. If the diode thermal value equals or exceeds one of its limits, then its alarm bit
in the status register is triggered. This indication is also brought out to the Itanium 2 processor
system bus via the THRMALERT# signal.
Status Register
have been exceeded. It also indicates if a conversion is in progress or if an open circuit has been
detected in the processor core thermal diode connection. Once set, alarm bits stay set until they are
cleared by a status register read. A successful read to the status register will clear any alarm bits
that may have been set, unless the alarm condition persists. Note that the THRMALERT# interrupt
signal is latched and is not automatically cleared when the status flag bit is cleared. The latch is
cleared by sending the Alert Response Address (0001100) on the SMBus.
Table 6-14. Thermal Sensing Device Status Register
Bit
Name
Function
7 (MSB) BUSY
A one indicates that the device’s analog to digital converter is busy converting.
6
5
4
RESERVED Reserved for future use.
RESERVED Reserved for future use.
RHIGH
RLOW
OPEN
A one indicates that the processor core thermal diode high temperature alarm has
been activated.
3
A one indicates that the processor core thermal diode low temperature alarm has
been activated.
2
1
A one indicates an open fault in the connection to the processor core diode.
RESERVED Reserved for future use.
0 (LSB) RESERVED Reserved for future use.
6.7.4
Configuration Register
The configuration register controls the operating mode (standby vs. auto-convert) of the thermal
set (high) then the thermal sensing device immediately stops converting and enters standby mode.
The thermal sensing device will still perform analog-to-digital conversions in standby mode when
it receives a one-shot command. If the RUN/STOP bit is clear (low) then the thermal sensor enters
auto-conversion mode. The thermal sensing device starts operating in free running mode, auto-
converting at 0.25 Hz after power-up.
Table 6-15. Thermal Sensing Device Configuration Register
Reset
State
Bit
Name
Function
7 (MSB) RESERVED
0
0
Reserved for future use.
6
RUN/STOP
RESERVED
Standby mode control bit. If high, the device immediately stops
converting, and enters standby mode. If low, the device converts in either
one-shot or timer mode.
5–0
0
Reserved for future use.
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6.7.5
Conversion Rate Register
The contents of the conversion rate register determine the nominal rate at which analog-to-digital
the mapping between conversion rate register values and the conversion rate. As indicated in
Table 6-16, the conversion rate register is set to its default state of 02h (0.25 Hz nominally) when
the thermal sensing device is powered-up. There is a ±25% error tolerance between the conversion
rate indicated in the conversion rate register and the actual conversion rate.
Table 6-16. Thermal Sensing Device Conversion Rate Register
Register Contents
Conversion Rate (Hz)
00h
01h
0.0625
0.125
02h
0.25
03h
0.5
04h
1
05h
2
06h
4
07h
8
08h to FFh
Reserved for future use
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A Signals Reference
This appendix provides an alphabetical listing of all Itanium 2 processor system bus signals. The
tables at the end of this appendix summarize the signals by direction: output, input, and I/O.
For a complete pinout listing including processor specific pins, please refer to Chapter 3, “Pinout
A.1
Alphabetical Signals Reference
A.1.1
A[49:3]# (I/O)
The Address (A[49:3]#) signals, with byte enables, define a 250 Byte physical memory address
space. When ADS# is active, these pins transmit the address of a transaction. These pins are also
used to transmit other transaction related information such as transaction identifiers and external
functions in the cycle following ADS# assertion. These signals must connect the appropriate pins
of all agents on the Itanium 2 processor system bus. The A[49:27]# signals are parity-protected by
the AP1# parity signal, and the A[26:3]# signals are parity-protected by the AP0# parity signal.
On the active-to-inactive transition of RESET#, the processors sample the A[49:3]# pins to
determine their power-on configuration.
A.1.2
A.1.3
A20M# (I)
A20M# is ignored in the Itanium 2 processor system environment.
ADS# (I/O)
The Address Strobe (ADS#) signal is asserted to indicate the validity of the transaction address on
the A[49:3]#, REQ[5:0]#, AP[1:0]# and RP#pins. All bus agents observe the ADS# activation to
begin parity checking, protocol checking, address decode, internal snoop, or deferred reply ID
match operations associated with the new transaction.
A.1.4
A.1.5
Datasheet
AP[1:0]# (I/O)
The Address Parity (AP[1:0]#) signals can be driven by the request initiator along with ADS# and
A[49:3]#. AP[1]# covers A[49:27]#, and AP[0]# covers A[26:3]#. A correct parity signal is high if
an even number of covered signals are low and low if an odd number of covered signals are low.
This allows parity to be high when all the covered signals are high.
ASZ[1:0]# (I/O)
The ASZ[1:0]# signals are the memory address-space size signals. They are driven by the request
initiator during the first Request Phase clock on the REQa[4:3]# pins. The ASZ[1:0]# signals are
valid only when REQa[2:1]# signals equal 01B, 10B, or 11B, indicating a memory access
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Table A-1. Address Space Size
Memory Address
Space
Memory Access
Range
ASZ[1:0]#
0
0
1
0
1
0
Reserved
36-bit
Reserved
0 to (64 GByte - 1)
50-bit
64 GByte to
(1 Pbyte –1)
1
1
Reserved
Reserved
Any memory access transaction addressing a memory region that is less than 64 GB (that is,
Aa[49:36]# are all zeroes) must set ASZ[1:0]# to 01. Any memory access transaction addressing a
memory region that is equal to or greater than 64 GB (that is, Aa[49:36]# are not all zeroes) must
set ASZ[1:0]# to 10. All observing bus agents that support the 64 GByte (36-bit) address space
must respond to the transaction when ASZ[1:0]# equals 01. All observing bus agents that support
larger than the 64 GByte (36-bit) address space must respond to the transaction when ASZ[1:0]#
equals 01 or 10.
A.1.6
ATTR[3:0]# (I/O)
The ATTR[3:0]# signals are the attribute signals. They are driven by the request initiator during the
second clock of the Request Phase on the Ab[35:32]# pins. The ATTR[3:0]# signals are valid for
all transactions. The ATTR[3]# signal is reserved. The ATTR[2:0]# are driven based on the
Table A-2. Effective Memory Type Signal Encoding
ATTR[2:0]#
Description
000
Uncacheable
100
101
110
111
Write Coalescing
Write-Through
Write-Protect
Writeback
A.1.7
BCLKp/BCLKn (I)
The BCLKp and BCLKn differential clock signals determine the bus frequency. All agents drive
their outputs and latch their inputs on the differential crossing of BCLKp and BCLKn on the
signals that are using the common clock latched protocol.
BCLKp and BCLKn indirectly determine the internal clock frequency of the Itanium 2 processor.
Each Itanium 2 processor derives its internal clock by multiplying the BCLKp and BCLKn
frequency by a ratio that is defined and allowed by the power-on configuration.
A.1.8
BE[7:0]# (I/O)
The BE[7:0]# signals are the byte-enable signals for partial transactions. They are driven by the
request initiator during the second Request Phase clock on the Ab[15:8]# pins.
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For memory or I/O transactions, the byte-enable signals indicate that valid data is requested or
being transferred on the corresponding byte on the 128-bit data bus. BE[0]# indicates that the least
significant byte is valid, and BE[7]# indicates that the most significant byte is valid. Since
BE[7:0]# specifies the validity of only 8 bytes on the 16 byte wide bus, A[3]# is used to determine
which half of the data bus is validated by BE[7:0]#.
For special transactions ((REQa[5:0]# = 001000B) and (REQb[1:0]# = 01B)), the BE[7:0]# signals
Table A-3. Special Transaction Encoding on Byte Enables
Special Transaction
Byte Enables[7:0]#
NOP
0000 0000
0000 0001
0000 0010
0000 0011
0000 0100
0000 0101
0000 0110
0000 0111
0000 1000
Shutdown
Flush (INVD)
Halt
Sync (WBINVD)
Reserved
StopGrant Acknowledge
Reserved
xTPR Update
For Deferred Reply transactions, BE[7:0]# signals are reserved. The Defer Phase transfer length is
always the same length as that specified in the Request Phase except the Bus Invalidate Line (BIL)
transaction.
A BIL transaction may return one cache line (128 bytes).
A.1.9
BERR# (I/O)
The Bus Error (BERR#) signal can be asserted to indicate a recoverable error with global MCA.
BERR# assertion conditions are configurable at the system level. Configuration options enable
BERR# to be driven as follows:
• Asserted by the requesting agent of a bus transaction after it observes an internal error.
• Asserted by any bus agent when it observes an error in a bus transaction.
When the bus agent samples an asserted BERR# signal and BERR# sampling is enabled, the
processor enters a Machine Check Handler.
BERR# is a wired-OR signal to allow multiple bus agents to drive it at the same time.
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A.1.10
BINIT# (I/O)
If enabled by configuration, the Bus Initialization (BINIT#) signal is asserted to signal any bus
condition that prevents reliable future operation.
If BINIT# observation is enabled during power-on configuration, and BINIT# is sampled asserted,
all bus state machines are reset. All agents reset their rotating IDs for bus arbitration to the same
state as that after reset, and internal count information is lost. The L2 and L3 caches are not
affected.
If BINIT# observation is disabled during power-on configuration, BINIT# is ignored by all bus
agents with the exception of the priority agent. The priority agent must handle the error in a manner
that is appropriate to the system architecture.
BINIT# is a wired-OR signal.
A.1.11
BNR# (I/O)
The Block Next Request (BNR#) signal is used to assert a bus stall by any bus agent that is unable
to accept new bus transactions to avoid an internal transaction queue overflow. During a bus stall,
the current bus owner cannot issue any new transactions.
Since multiple agents might need to request a bus stall at the same time, BNR# is a wired-OR
signal. In order to avoid wired-OR glitches associated with simultaneous edge transitions driven by
multiple drivers, BNR# is asserted and sampled on specific clock edges.
A.1.12
A.1.13
A.1.14
BPM[5:0]# (I/O)
The BPM[5:0]# signals are system support signals used for inserting breakpoints and for
performance monitoring. They can be configured as outputs from the processor that indicate
programmable counters used for monitoring performance, or inputs from the processor to indicate
the status of breakpoints.
BPRI# (I)
The Bus Priority-agent Request (BPRI#) signal is used by the priority agent to arbitrate for
ownership of the system bus. Observing BPRI# asserted causes all other agents to stop issuing new
requests, unless such requests are part of an ongoing locked operation.The priority agent keeps
BPRI# asserted until all of its requests are completed, then releases the bus by deasserting BPRI#.
BR[0]# (I/O) and BR[3:1]# (I)
BR[3:0]# are the physical bus request pins that drive the BREQ[3:0]# signals in the system. The
BREQ[3:0]# signals are interconnected in a rotating manner to individual processor pins.
for both the 4P and 2P system bus topologies.
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Table A-4. BR0# (I/O), BR1#, BR2#, BR3# Signals for 4P Rotating Interconnect
Bus Signal
Agent 0 Pins
Agent 1 Pins
Agent 2 Pins
Agent 3 Pins
BREQ[0]#
BREQ[1]#
BREQ[2]#
BREQ[3]#
BR[0]#
BR[1]#
BR[2]#
BR[3]#
BR[3]#
BR[0]#
BR[1]#
BR[2]#
BR[2]#
BR[3]#
BR[0]#
BR[1]#
BR[1]#
BR[2]#
BR[3]#
BR[0]#
Table A-5. BR0# (I/O), BR1#, BR2#, BR3# Signals for 2P Rotating Interconnect
Bus Signal
Agent 0 Pins
Agent 3 Pins
BREQ[0]#
BREQ[1]#
BREQ[2]#
BREQ[3]#
BR[0]#
BR[1]#
BR[1]#
BR[0]#
Not Used
Not Used
Not Used
Not Used
During power-on configuration, the priority agent must assert the BR[0]# bus signal. All
symmetric agents sample their BR[3:0]# pins on asserted-to-deasserted transition of RESET#. The
pin on which the agent samples an asserted level determines its agent ID. All agents then configure
Table A-6. BR[3:0]# Signals and Agent IDs
Pin Sampled
Asserted on
RESET#
Arbitration ID
Agent ID Reported
BR[0]#
BR[3]#
BR[2]#
BR[1]#
0
1
2
3
0
2
4
6
A.1.15
BREQ[3:0]# (I/O)
The BREQ[3:0]# signals are the symmetric agent arbitration bus signals (called bus request). A
symmetric agent n arbitrates for the bus by asserting its BREQn# signal. Agent n drives BREQn#
as an output and receives the remaining BREQ[3:0]# signals as inputs.
The symmetric agents support distributed arbitration based on a round-robin mechanism. The
rotating ID is an internal state used by all symmetric agents to track the agent with the lowest
priority at the next arbitration event. At power-on, the rotating ID is initialized to three, allowing
agent 0 to be the highest priority symmetric agent. After a new arbitration event, the rotating ID of
all symmetric agents is updated to the agent ID of the symmetric owner. This update gives the new
symmetric owner lowest priority in the next arbitration event.
A new arbitration event occurs either when a symmetric agent asserts its BREQn# on an Idle bus
(all BREQ[3:0]# previously deasserted), or the current symmetric owner deasserts BREQn# to
release the bus ownership to a new bus owner n. On a new arbitration event, all symmetric agents
simultaneously determine the new symmetric owner using BREQ[3:0]# and the rotating ID. The
symmetric owner can park on the bus (hold the bus) provided that no other symmetric agent is
requesting its use. The symmetric owner parks by keeping its BREQn# signal asserted. On
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sampling BREQn# asserted by another symmetric agent, the symmetric owner deasserts BREQn#
as soon as possible to release the bus. A symmetric owner stops issuing new requests that are not
part of an existing locked operation on observing BPRI# asserted.
A symmetric agent can deassert BREQn# before it becomes a symmetric owner. A symmetric
agent can reassert BREQn# after keeping it deasserted for one clock.
A.1.16
A.1.17
A.1.18
CCL# (I/O)
CCL# is the Cache Cleanse signal. It is driven on the second clock of the Request Phase on the
EXF[2]#/Ab[5]# pin. CCL# is asserted for Memory Write transaction to indicate that a modified
line in a processor may be written to memory without being invalidated in its caches.
CPUPRES# (O)
CPUPRES# can be used to detect the presence of a Itanium 2 processor in a socket. A ground
indicates that a Itanium 2 processor is installed, while an open indicates that a Itanium 2 processor
is not installed.
D[127:0]# (I/O)
The Data (D[127:0]#) signals provide a 128-bit data path between various system bus agents.
Partial transfers require one data transfer clock with valid data on the byte(s) indicated by asserted
byte enables BE[7:0]# and A[3]#. Data signals that are not valid for a particular transfer must still
have correct ECC (if data bus error checking is enabled). The data driver asserts DRDY# to
indicate a valid data transfer.
A.1.19
A.1.20
D/C# (I/O)
The Data/Code (D/C#) signal is used to indicate data (1) or code (0) on REQa[1]#, only during
Memory Read transactions.
DBSY# (I/O)
The Data Bus Busy (DBSY#) signal is asserted by the agent that is responsible for driving data on
the system bus to indicate that the data bus is in use. The data bus is released after DBSY# is
deasserted.
DBSY# is replicated three times to enable partitioning of the data paths in the system agents. This
copy of the Data Bus Busy signal (DBSY#) is an input as well as an output.
A.1.21
DBSY_C1# (O)
DBSY# is a copy of the Data Bus Busy signal. This copy of the Data Bus Busy signal
(DBSY_C1#) is an output only.
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A.1.22
A.1.23
A.1.24
DBSY_C2# (O)
DBSY# is a copy of the Data Bus Busy signal. This copy of the Data Bus Busy signal
(DBSY_C2#) is an output only.
DEFER# (I)
The DEFER# signal is asserted by an agent to indicate that the transaction cannot be guaranteed in-
order completion. Assertion of DEFER# is normally the responsibility of the priority agent.
DEN# (I/O)
The Defer Enable (DEN#) signal is driven on the bus on the second clock of the Request Phase on
the Ab[4]# pin. DEN# is asserted to indicate that the transaction can be deferred by the responding
agent.
A.1.25
A.1.26
DEP[15:0]# (I/O)
The Data Bus ECC Protection (DEP[15:0]#) signals provide optional ECC protection for Data Bus
(D[127:0]#). They are driven by the agent responsible for driving D[127:0]#. During power-on
configuration, bus agents can be enabled for either ECC checking or no checking.
The ECC error correcting code can detect and correct single-bit errors and detect double-bit or
nibble errors.
DHIT# (I)
The Deferred Hit (DHIT#) signal is driven during the Deferred Phase by the deferring agent. For
read transactions on the bus DHIT# returns the final cache status that would have been indicated on
HIT# for a transaction which was not deferred. DID[9:0]# (I/O)
DID[9:0]# are Deferred Identifier signals. The requesting agent transfers these signals by using
A[25:16]#. They are transferred on Ab[25:16]# during the second clock of the Request Phase on all
transactions, but Ab[20:16]# is only defined for deferrable transactions (DEN# asserted).
DID[9:0]# is also transferred on Aa[25:16]# during the first clock of the Request Phase for
Deferred Reply transactions.
The Deferred Identifier defines the token supplied by the requesting agent. DID[9]# and DID[8:5]#
carry the agent identifiers of the requesting agents (always valid) and DID[4:0]# carry a transaction
identifier associated with the request (valid only with DEN# asserted). This configuration limits the
bus specification to 32 logical bus agents with each one of the bus agents capable of making up to
Table A-7. DID[9:0]# Encoding
DID[9]#
Agent Type
DID[8:5]#
DID[4:0]#
Agent ID[3:0]
Transaction ID[4:0]
DID[9]# indicates the agent type. Symmetric agents use 0. Priority agents use 1. DID[8:5]#
indicates the agent ID. Symmetric agents use their arbitration ID. DID[4:0]# indicates the
transaction ID for an agent. The transaction ID must be unique for all deferrable transactions issued
by an agent which have not reported their snoop results.
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The Deferred Reply agent transmits the DID[9:0]# (Ab[25:16]#) signals received during the
original transaction on the Aa[25:16]# signals during the Deferred Reply transaction. This process
enables the original requesting agent to make an identifier match with the original request that is
awaiting completion.
A.1.27
A.1.28
DPS# (I/O)
The Deferred Phase Enable (DPS#) signal is driven to the bus on the second clock of the Request
Phase on the Ab[3]# pin. DPS# is asserted if a requesting agent supports transaction completion
using the Deferred Phase. A requesting agent that supports the Deferred Phase will always assert
DPS#. A requesting agent that does not support the Deferred Phase will always deassert DPS#.
DRDY# (I/O)
The Data Ready (DRDY#) signal is asserted by the data driver on each data transfer, indicating
valid data on the data bus. In a multi-cycle data transfer, DRDY# can be deasserted to insert
idle clocks.
DRDY# is replicated three times to enable partitioning of data paths in the system agents. This
copy of the Data Ready signal (DRDY#) is an input as well as an output.
A.1.29
A.1.30
A.1.31
DRDY_C1# (O)
DRDY# is a copy of the Data Ready signal. This copy of the Data Phase data-ready signal
(DRDY_C1#) is an output only.
DRDY_C2# (O)
DRDY# is a copy of the Data Ready signal. This copy of the Data Phase data-ready signal
(DRDY_C2#) is an output only.
DSZ[1:0]# (I/O)
The Data Size (DSZ[1:0]#) signals are transferred on REQb[4:3]# signals in the second clock of
the Request Phase by the requesting agent. The DSZ[1:0]# signals define the data transfer
capability of the requesting agent. For the Itanium 2 processor, DSZ# = 01, always.
A.1.32
EXF[4:0]# (I/O)
The Extended Function (EXF[4:0]#) signals are transferred on the A[7:3]# pins by the requesting
agent during the second clock of the Request Phase. The signals specify any special functional
requirement associated with the transaction based on the requestor mode or capability. The signals
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Table A-8. Extended Function Signals
Extended Function
Signal Name Alias
Function
Signal
EXF[4]#
EXF[3]#
EXF[2]#
EXF[1]#
EXF[0]#
Reserved
SPLCK#/FCL#
OWN#/CCL#
DEN#
Reserved
Split Lock / Flush Cache Line
Memory Update Not Needed / Cache Cleanse
Defer Enable
DPS#
Deferred Phase Supported
A.1.33
A.1.34
FCL# (I/O)
The Flush Cache Line (FCL#) signal is driven to the bus on the second clock of the Request Phase
on the A[6]# pin. FCL# is asserted to indicate that the memory transaction is initiated by the global
Flush Cache (FC) instruction.
FERR# (O)
The FERR# signal may be asserted to indicate a processor detected error when IERR mode is
enabled. If IERR mode is disabled, the FERR# signal will not be asserted in the Itanium 2
processor system environment.
A.1.35
A.1.36
GSEQ# (I)
Assertion of the Guaranteed Sequentiality (GSEQ#) signal indicates that the platform guarantees
completion of the transaction without a retry while maintaining sequentiality.
HIT# (I/O) and HITM# (I/O)
The Snoop Hit (HIT#) and Hit Modified (HITM#) signals convey transaction snoop operation
results. Any bus agent can assert both HIT# and HITM# together to indicate that it requires a snoop
stall. The stall can be continued by reasserting HIT# and HITM# together.
A.1.37
ID[9:0]# (I)
The Transaction ID (ID[9:0]#) signals are driven by the deferring agent. The signals in the two
clocks are referenced IDa[9:0]# and IDb[9:0]#. During both clocks, ID[9:0]# signals are protected
by the IP0# parity signal for the first clock, and by the IP[1]# parity signal on the second clock.
IDa[9:0]# returns the ID of the deferred transaction which was sent on Ab[25:16]# (DID[9:0]#).
A.1.38
IDS# (I)
The ID Strobe (IDS#) signal is asserted to indicate the validity of ID[9:0]# in that clock and the
validity of DHIT# and IP[1:0]# in the next clock.
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A.1.39
A.1.40
IGNNE# (I)
IGNNE# is ignored in the Itanium 2 processor system environment.
INIT# (I)
The Initialization (INIT#) signal triggers an unmasked interrupt to the processor. INIT# is usually
used to break into hanging or idle processor states. Semantics required for platform compatibility
are supplied in the PAL firmware interrupt service routine.
A.1.41
INT (I)
INT is the 8259-compatible Interrupt Request signal which indicates that an external interrupt has
been generated. The interrupt is maskable. The processor vectors to the interrupt handler after the
current instruction execution has been completed. An interrupt acknowledge transaction is
generated by the processor to obtain the interrupt vector from the interrupt controller.
The LINT[0] pin can be software configured to be used either as the INT signal or another local
interrupt.
A.1.42
A.1.43
IP[1:0]# (I)
The ID Parity (IP[1:0]#) signals are driven on the second clock of the Deferred Phase by the
deferring agent. IP0# protects the IDa[9:0]# and IDS# signals for the first clock, and IP[1]#
protects the IDb[9:2, 0]# and IDS# signals on the second clock.
LEN[2:0]# (I/O)
The Data Length (LEN[2:0]#) signals are transmitted using REQb[2:0]# signals by the requesting
agent in the second clock of Request Phase. LEN[2:0]# defines the length of the data transfer
signals together define the length of the actual data transfer.
Table A-9. Length of Data Transfers
LEN[2:0]#
Length
000
001
010
011
100
101
110
111
0 – 8 bytes
16 bytes
32 bytes
64 bytes
128 bytes
Reserved
Reserved
Reserved
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A.1.44
LINT[1:0] (I)
LINT[1:0] are local interrupt signals. These pins are disabled after RESET#. LINT[0] is typically
software configured as INT, an 8259-compatible maskable interrupt request signal. LINT[1] is
typically software configured as NMI, a non-maskable interrupt.Both signals are asynchronous
inputs.
A.1.45
A.1.46
LOCK# (I/O)
LOCK# is never asserted or sampled in the Itanium 2 processor system environment.
NMI (I)
The NMI signal is the Non-maskable Interrupt signal. Asserting NMI causes an interrupt with an
internally supplied vector value of 2. An external interrupt-acknowledge transaction is not
generated. If NMI is asserted during the execution of an NMI service routine, it remains pending
and is recognized after the EOI is executed by the NMI service routine. At most, one assertion of
NMI is held pending.
NMI is rising-edge sensitive. Recognition of NMI is guaranteed in a specific clock if it is asserted
synchronously and meets the setup and hold times. If asserted asynchronously, asserted and
deasserted pulse widths of NMI must be a minimum of two clocks.This signal must be software
configured to be used either as NMI or as another local interrupt (LINT1 pin).
A.1.47
A.1.48
OWN# (I/O)
The Guaranteed Cache Line Ownership (OWN#) signal is driven to the bus on the second clock of
the Request Phase on the Ab[5]# pin. OWN# is asserted if cache line ownership is guaranteed. This
allows a memory controller to ignore memory updates due to implicit writebacks.
PMI# (I)
The Platform Management Interrupt (PMI#) signal triggers the highest priority interrupt to the
processor. PMI# is usually used by the system to trigger system events that will be handled by
platform specific firmware.
A.1.49
A.1.50
PWRGOOD (I)
The Power Good (PWRGOOD) signal must be deasserted (L) during power-on, and must be
asserted (H) after RESET# is first asserted by the system.
REQ[5:0]# (I/O)
The REQ[5:0]# are the Request Command signals. They are asserted by the current bus owner in
both clocks of the Request Phase. In the first clock, the REQa[5:0]# signals define the transaction
type to a level of detail that is sufficient to begin a snoop request. In the second clock, REQb[5:0]#
signals carry additional information to define the complete transaction type. REQb[4:3]# signals
transmit DSZ[1:0]# or the data transfer information of the requestor for transactions that involve
data transfer. REQb[2:0]# signals transmit LEN[2:0]# (the data transfer length information). In
both clocks, REQ[5:0]# and ADS# are protected by parity RP#.
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All receiving agents observe the REQ[5:0]# signals to determine the transaction type and
Table A-10. Transaction Types Defined by REQa#/REQb# Signals
REQa[5:0]#
Transaction
REQb[5:0]#
5
4
3
2
1
0
5
4
3
2
1
0
Deferred Reply
Reserved
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
1
0
0
0
0
x
x
x
x
x
x
0
x
x
0
x
x
0
Interrupt
DSZ[1:0]#
Acknowledge
Special
0
0
1
0
0
0
0
DSZ[1:0]#
0
0
1
Transactions
Reserved
Reserved
Interrupt
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
1
1
1
0
1
x
0
0
0
0
0
0
0
0
0
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
0
0
1
1
1
x
x
x
1
x
x
0
1
x
x
x
x
x
0
Purge TC
Reserved
I/O Read
I/O Write
Reserved
0
1
x
x
x
Memory Read &
Invalidate
ASZ[1:0]#
0
LEN[2:0]#
Reserved
0
0
1
ASZ[1:0]#
ASZ[1:0]#
ASZ[1:0]#
0
1
1
1
D/C#
0
1
0
0
0
0
0
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
LEN[2:0]#
LEN[2:0]#
LEN[2:0]#
Memory Read
Memory Read
Current
Reserved
1
0
1
ASZ[1:0]#
ASZ[1:0]#
ASZ[1:0]#
1
1
1
1
0
1
1
0
0
0
DSZ[1:0]#
DSZ[1:0]#
DSZ[1:0]#
LEN[2:0]#
LEN[2:0]#
0
Memory Write
WSNP#
WSNP#
Cache Line
0
0
Replacement
A.1.51
RESET# (I)
Asserting the RESET# signal resets all processors to known states and invalidates all caches
without writing back Modified (M state) lines. RESET# must remain asserted for one millisecond
for a “warm” reset; for a power-on reset, RESET# must stay asserted for at least one millisecond
after PWRGOOD and BCLKp have reached their proper specifications. On observing asserted
RESET#, all system bus agents must deassert their outputs within two clocks.
A number of bus signals are sampled at the asserted-to-deasserted transition of RESET# for the
power-on configuration.
Unless its outputs are tristated during power-on configuration, after asserted-to-deasserted
transition of RESET#, the processor begins program execution at the reset-vector
A.1.52
RP# (I/O)
The Request Parity (RP#) signal is driven by the requesting agent, and provides parity protection
for ADS# and REQ[5:0]#.
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A correct parity signal is high if an even number of covered signals are low and low if an odd
number of covered signals are low. This definition allows parity to be high when all covered
signals are high.
A.1.53
A.1.54
RS[2:0]# (I)
The Response Status (RS[2:0]#) signals are driven by the responding agent (the agent responsible
for completion of the transaction).
RSP# (I)
The Response Parity (RSP#) signal is driven by the responding agent (the agent responsible for
completion of the current transaction) during assertion of RS[2:0]#, the signals for which RSP#
provides parity protection.
A correct parity signal is high if an even number of covered signals are low and low if an odd
number of covered signals are low. During the Idle state of RS[2:0]# (RS[2:0]#=000), RSP# is also
high since it is not driven by any agent guaranteeing correct parity.
A.1.55
SBSY# (I/O)
The Strobe Bus Busy (SBSY#) signal is driven by the agent transferring data when it owns the
strobe bus. SBSY# holds the strobe bus before the first DRDY# and between DRDY# assertions
for a multiple clock data transfer. SBSY# is deasserted before DBSY# to allow the next data
transfer agent to predrive the strobes before the data bus is released.
SBSY# is replicated three times to enable partitioning of data paths in the system agents. This copy
of the Strobe Bus Busy signal (SBSY#) is an input as well as an output.
A.1.56
A.1.57
A.1.58
SBSY_C1# (O)
SBSY# is a copy of the Strobe Bus Busy signal. This copy of the Strobe Bus Busy signal
(SBSY_C1#) is an output only.
SBSY_C2# (O)
SBSY# is a copy of the Strobe Bus Busy signal. This copy of the Strobe Bus Busy signal
(SBSY_C2#) is an output only.
SPLCK# (I/O)
The Split Lock (SPLCK#) signal is driven in the second clock of the Request Phase on the Ab[6]#
pin of the first transaction of a locked operation. It is driven to indicate that the locked operation
will consist of four locked transactions.
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A.1.59
STBn[7:0]# and STBp[7:0]# (I/O)
STBp[7:0]# and STBn[7:0]# (and DRDY#) are used to transfer data at the 2x transfer rate in lieu of
BCLKp. They are driven by the data transfer agent with a tight skew relationship with respect to its
corresponding bus signals, and are used by the receiving agent to capture valid data in its latches.
This functions like an independent double frequency clock constructed from a falling edge of either
STBp[7:0]# or STBn[7:0]#. The data is synchronized by DRDY#. Each strobe pair is associated
Table A-11. STBp[7:0]# and STBn[7:0]# Associations
Strobe Bits
Data Bits
ECC Bits
STBp[7]#, STBn[7]#
STBp[6]#, STBn[6]#
STBp[5]#, STBn[5]#
STBp[4]#, STBn[4]#
STBp[3]#, STBn[3]#
STBp[2]#, STBn[2]#
STBp[1]#, STBn[1]#
STBp[0]#, STBn[0]#
D[127:112]#
D[111:96]#
D[95:80]#
D[79:64]#
D[63:48]#
D[47:32]#
D[31:16]#
D[15:0]#
DEP[15:14]#
DEP[13:12]#
DEP[11:10]#
DEP[9:8]#
DEP[7:6]#
DEP[5:4]#
DEP[3:2]#
DEP[1:0]#
A.1.60
A.1.61
TCK (I)
The Test Clock (TCK) signal provides the clock input for the IEEE 1149.1 compliant TAP.
TDI (I)
The Test Data In (TDI) signal transfers serial test data into the Itanium 2 processor. TDI provides
the serial input needed for IEEE 1149.1 compliant TAP.
A.1.62
A.1.63
TDO (O)
The Test Data Out (TDO) signal transfers serial test data out from the Itanium 2 processor. TDO
provides the serial output needed for IEEE 1149.1 compliant TAP.
THRMTRIP# (O)
The Thermal Trip (THRMTRIP#) signal protects the Itanium 2 processor from catastrophic
overheating by use of an internal thermal sensor. This sensor is set well above the normal operating
temperature to ensure that there are no false trips. Data will be lost if the processor goes into
thermal trip (signaled to the system by the assertion of the THRMTRIP# signal). Once
THRMTRIP# is asserted, the platform must assert RESET# to protect the physical integrity of the
processor.
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A.1.64
THRMALERT# (O)
THRMALERT# is asserted when the measured temperature from the processor thermal diode
equals or exceeds the temperature threshold data programmed in the high-temp (THIGH) or low-
temp (TLOW) registers on the sensor. This signal can be used by the platform to implement
thermal regulation features.
A.1.65
A.1.66
A.1.67
A.1.68
A.1.69
TMS (I)
The Test Mode Select (TMS) signal is an IEEE 1149.1 compliant TAP specification support signal
used by debug tools.
TND# (I/O)
The TLB Purge Not Done (TND#) signal is asserted to delay completion of a TLB Purge
instruction, even after the TLB Purge transaction completes on the system bus.
TRDY# (I)
The Target Ready (TRDY#) signal is asserted by the target to indicate that it is ready to receive a
write or implicit writeback data transfer.
TRST# (I)
The TAP Reset (TRST#) signal is an IEEE 1149.1 compliant TAP support signal used by debug
tools.
WSNP# (I/O)
The Write Snoop (WSNP#) signal indicates that snooping agents will snoop the memory write
transaction
A.2
Signal Summaries
signals.
Table A-12. Output Signals (Sheet 1 of 2)
Name
Active Level
Clock
Signal Group
CPUPRES#
DBSY_C1#
DBSY_C2#
DRDY_C1#
DRDY_C2#
FERR#
Low
Low
Low
Low
Low
Low
—
BCLKp
Platform
Data
BCLKp
Data
BCLKp
Data
BCLKp
Data
Asynchronous
PC Compatibility,
IERR Mode
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Table A-12. Output Signals (Sheet 2 of 2)
Name
Active Level
Clock
Signal Group
SBSY_C1#
SBSY_C2#
TDO
Low
Low
High
Low
Low
BCLKp
BCLKp
Data
Data
TAP
TCK
THRMTRIP#
THRMALERT#
Asynchronous
Asynchronous
Error
Error
Table A-13. Input Signals
Name
Active Level
Clock
Signal Group
Qualified
BPRI#
BR1#
Low
Low
Low
Low
High
High
Low
Low
Low
Low
Low
Low
Low
High
Low
High
Low
Low
Low
Low
High
High
High
High
Low
Low
BCLKp
BCLKp
BCLKp
BCLKp
—
Arbitration
Arbitration
Arbitration
Arbitration
Control
Always
Always
BR2#
Always
BR3#
Always
BCLKp
BCLKn
D/C#
Always
—
Control
Always
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
Asynch
Asynch
BCLKp
Asynch
BCLKp
BCLKp
BCLKp
Asynch
Asynch
—
System Bus
Snoop
Request Phase (Mem Rd)
Snoop Phase
IDS#+1
DEFER#
DHIT#
System Bus
Snoop
GSEQ#
ID[9:0]#
IDS#
Snoop Phase
IDS#, IDS#+1
Always
Defer
Defer
1
INIT#
Exec Control
Exec Control
System Bus
Exec Control
Control
Always
INT (LINT0)
IP[1:0]#
NMI (LINT1)
RESET#
RS[2:0]#
RSP#
IDS#+1
Always
Always
Always
Response
Response
Exec Control
Control
PMI#
PWRGOOD
TCK
—
Always
Diagnostic
Diagnostic
Diagnostic
Diagnostic
Response
TDI
TCK
Always
TMS
TCK
Always
TRST#
TRDY#
NOTES:
Asynch
BCLKp
Always
Response Phase
1. Synchronous assertion with asserted RS[2:0]# guarantees synchronization.
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Table A-14. Input/Output Signals (Single Driver)
Name
Active Level
Clock
Signal Group
Qualified
A[49:3]#
ADS#
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
Low
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
—
Request
Request
ADS#, ADS#+1
Always
AP[1:0]#
ASZ[1:0]#
ATTR[3:0]#
BE[7:0]#
BR0#
Request
ADS#, ADS#+1
ADS#
System Bus
System Bus
System Bus
System Bus
Diagnostic
System Bus
Data
ADS#+1
ADS#+1
Always
BPM[5:0]#
CCL#
Always
ADS#+1
DRDY#
D[127:0]#
DBSY#
Data
Always
D/C#
System Bus
System Bus
System Bus
System Bus
Data
ADS#
DEN#
ADS#+1
DRDY#
DEP[15:0]#
DID[9:0]#
DRDY#
DPS#
ADS#+1
Always
System Bus
System Bus
System Bus
System Bus
System Bus
Arbitration
System Bus
Request
ADS#+1
ADS#+1
ADS#+1
ADS#+1
ADS#+1
Always
DSZ[1:0]#
EXF[4:0]#
FCL#
LEN[2:0]#
LOCK#
OWN#
ADS#+1
ADS#, ADS#+1
ADS#, ADS#+1
Always
REQ[5:0]#
RP#
Request
SBSY#
Data
SPLCK#
STBn[7:0]#
STBp[7:0]#
WSNP#
System Bus
Data
ADS#+1
Always
—
Data
Always
BCLKp
System Bus
ADS#
Table A-15. Input/Output Signals (Multiple Driver)
Name
Active Level
Clock
Signal Group
Qualified
BNR#
BERR#
BINIT#
HIT#
Low
Low
Low
Low
Low
Low
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
BCLKp
System Bus
Error
Always
Always
Error
Always
Snoop
Snoop
Snoop
Snoop Phase
Snoop Phase
Always
HITM#
TND#
Datasheet
107
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Signals Reference
108
Datasheet
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