Dual-Core Intel® Xeon® Processor
2.80 GHz
Datasheet
October 2005
Document Number: 309158-001
2Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
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Intel® Extended Memory 64 Technolo gy (Intel® EM64T) requires a computer system with a processor , chipset, BIOS, OS, device drivers and
applications enabled for Intel EM64T. Processor will not operate (including 32-bit operation) without an Intel EM64T-enabled BIOS. Perf ormance will
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Copyright © 2005, Intel Corporation
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 3
Contents
1 Introduction.......................................................................................................................11
1.1 Terminology.........................................................................................................12
1.2 References..........................................................................................................14
1.3 State of Data .......................................................................................................14
2 Electrical Specifications....................................................................................................15
2.1 Front Side Bus and GTLREF ....................... .... ... ... ... ... .... ... ... ... .... ................... ...15
2.2 Power and Ground Pins......................................................................................16
2.3 Decoupling Guidelines ........................................................................................16
2.3.1 VCC Decoupling.....................................................................................16
2.3.2 VTT Decoupling......................................................................................16
2.3.3 Front Side Bus AGTL+ Decoupling.............. ... .... ... ... ... .... ... ... ... ... .... ... ...17
2.4 Front Side Bus Clock (BCLK[1:0]) and Processor Clocking................................17
2.4.1 Front Side Bus Frequency Select Signals (BSEL[1:0])..........................17
2.4.2 Phase Lock Loop (PLL) and Filter..........................................................18
2.5 Voltage Identification (VID).............. .... ................................................................19
2.6 Reserved Or Unused Pins...................................................................................21
2.7 Front Side Bus Signal Groups................ ... ... .... ... ... ... ... .... ... ... ... .... ... ... ................21
2.8 GTL+ Asynchronous and AGTL+ Asynchronous Signals ......................... .... ... ...23
2.9 Test Access Port (TAP) Connection....................................................................23
2.10 Mixing Processors...............................................................................................24
2.11 Absolute Maximum and Minimum Ratings..........................................................24
2.12 Processor DC Specifications........................ .... ... ... ... ... .... ................... ... ... .... ... ...25
2.12.1 VCC Overshoot Specification....................... ... .... ... ... ... .... ... ... ... ... .... ... ...29
2.12.2 Die Voltage Validation............... ... ................... .... ... ... ... .... ................... ...30
3 Mechanical Specifications................................................................................................33
3.1 Package Mechanical Drawings...........................................................................34
3.2 Processor Component Keepout Zones...............................................................37
3.3 Package Loading Specifications .........................................................................37
3.4 Package Handling Guidelines.............................................................................38
3.5 Package Insertion Specifications ........................................................................38
3.6 Processor Mass Specifications ...........................................................................38
3.7 Processor Materials... ... .......................................................................................38
3.8 Processor Markings............ .... ... ... ... .... ... ... ................... .... ................... ................39
3.9 Processor Pin-Out Coordinates...........................................................................40
4 Signal Definitions.............................................................................................................43
4.1 Signal Definitions .... ... ... ... ... .... ... ................... .... ................... ................... ... ..........43
5 Pin Listing........ ... .... ... ................................................................ .... ... ... ... .... ... ... ................53
5.1 Dual-Core Inte l® Xeon® Processor Pin Assignments............. ... .... ... ... ... .............53
5.1.1 Pin Listing by Pin Name............ ... ... .... ... ... ................... .... ... ...................53
5.1.2 Pin Listing by Pin Number......... ... ... .... ... ... ................... .... ... ...................62
4Dual-Core In tel® Xeon® Processor 2.80 GHz Datasheet
6 Thermal Specifications....................................................................................................71
6.1 Package Thermal Specifications.................. ... .... ... ... ... ... .... ... ... ... .... ... ................71
6.1.1 Thermal Specifications...........................................................................71
6.1.2 Thermal Metrology .................................................................................75
6.2 Processor Thermal Features...............................................................................76
6.2.1 Thermal Monitor.....................................................................................76
6.2.2 On-Demand Mode. ... .... ... ... ... .................... ... ... ... .................... ... ... ... .... ...77
6.2.3 PROCHOT# Signal Pin..........................................................................77
6.2.4 FORCEPR# Signal Pin ................ ... ... .... ... ................... ... .... ... ................77
6.2.5 THERMTRIP# Signal Pin.......................................................................78
6.2.6 TCONTROL and Fan Speed Reduction.................................................78
6.2.7 Thermal Diode........................................................................................78
7 Features...........................................................................................................................79
7.1 Power-On Configuration Options ........................................................................79
7.2 Clock Control and Low Power States..................................................................79
7.2.1 Normal State ..........................................................................................80
7.2.2 HALT or Enhanced HALT States ...........................................................80
7.2.3 Stop-Grant State ....................................................................................81
7.2.4 Enhanced HALT Snoop or HALT Snoop State,
Stop Grant Snoop State.........................................................................82
7.2.5 Sleep State.............................................................................................82
7.3 Enhanced Intel SpeedStep® Technology..... ... .... ... ... ................... .................... ...83
8 Boxed Processor Specifications................ ... ... .... ... ... ... .... ................... ... ... .... ... ... ... ... .... ...85
8.1 Introduction .........................................................................................................85
8.2 Mechanical Specifications...................................................................................87
8.2.1 Boxed Processor Heat Sink Dimensions (CEK).....................................87
8.2.2 Boxed Processor Heat Sink Weight.......................................................95
8.2.3 Boxed Processor Retention Mechanism and Heat Sink Support (CEK) 95
8.3 Electrical Requirements ......................................................................................95
8.3.1 Power Supply Requirements..................... ... ... ... .... ... ... ... .... ... ... ... ... .... ...95
8.3.2 Fan Power Supply (Active CEK) .. ... ... .... ... ... ... ... .... ... ... ... .... ... ... .............96
8.3.3 Boxed Processor Cooling Requirements ...............................................97
8.4 Boxed Processor Contents .......... ... ... .................... ... ... ... .... ... ................... ... .... ...98
9 Debug Tools Specifications..............................................................................................99
9.1 Debug Port System Requirements......................................................................99
9.2 Target System Implementation ...........................................................................99
9.2.1 System Implementation..........................................................................99
9.3 Logic Analyzer Interface (LAI)............................................................................99
9.3.1 Mechanical Considerations..................................................................100
9.3.2 Electrical Considerations......................................................................100
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 5
Figures
2-1 On-Die Front Side Bus Termination....................................................................15
2-2 Phase Lock Loop (PLL) Filter Requirements ......................................................18
2-3 Dual-Core In te l ® Xeon® Processor Load Current Vs. Time................... ... .... ... ...27
2-4 VCC Static and Transient Tolerance......... ... .... ... ... ... ... .... ... ... ... .... ... ... ... ... .... ... ...29
2-5 VCC Overshoot Example Waveform................... ... ... ... .... ... ... ... .... ... ... ... ... .... ... ...30
3-1 Processor Package Assembly Sketch.................................................................33
3-2 Processor Package Drawing (Sheet 1 of 2) ........................................................35
3-3 Processor Package Drawing (Sheet 2 of 2) ........................................................36
3-4 Processor Top-Side Markings (Example) . ...........................................................39
3-5 Processor Bottom-Side Markings (Example) ......................................................39
3-6 Processor Pin-out Coordinates, Top View ..........................................................40
3-7 Processor Pin-out Coordinates, Bottom View.....................................................41
6-1 Dual-Core In te l ® Xeon® Processor Thermal Profiles A and B ......... ... ... ... .... ... ...73
6-2 Case Temperature (TCASE) Measurement Location .........................................76
7-1 Stop Clock State Machine...... ... ... ... .... ... ... ... .................................... ...................81
8-1 1U Passive CEK Heat Sink .................................................................................85
8-2 2U Passive CEK Heat Sink .................................................................................86
8-3 Active CEK Heat Sink (Representation Only) .....................................................86
8-4 Passive Thermal Solution (2U and larger) ..........................................................87
8-5 Top Side Board Keep-Out Zones (Part 1)........... ... ... ... .... ... ... ... .... ... ... ... ... .... ... ...88
8-6 Top Side Board Keep-Out Zones (Part 2)........... ... ... ... .... ... ... ... .... ... ... ... ... .... ... ...89
8-7 Bottom Side Board Keep-Out Zones...................................................................90
8-8 Board Mounting Hole Keep-Out Zones...............................................................91
8-9 Volumetric Height Keep-Ins .... ... ... ... .... ... ... ... .................... ... ... ... .... ... ...................92
8-10 4-Pin Fan Cable Connector (For Active CEK Heat Sink ) .... ... ... .... ... ... ... ... .... ... ...93
8-11 4-Pin Base Board Fan Header (For Active CEK Heat Sink)............. ... ... ... .... ... ...94
8-12 Fan Cable Connector Pin Out for 4-Pin Active CEK Thermal Solution...............97
6Dual-Core In tel® Xeon® Processor 2.80 GHz Datasheet
Tables
1-1 Features of the Dual-Core Intel® Xeon® Processor............................................12
2-1 BSEL[1:0] Frequency Table.. .................... ... ... .... ... ... ................... .... ... ... ... ... .......17
2-2 Voltage Identification Definition2,3......................................................................20
2-3 Front Side Bus Signal Groups.............................................................................22
2-4 Signal Description Table .....................................................................................23
2-5 Signal Reference Voltages..................................................................................23
2-6 Absolute Maximum and Minimum Ratings..........................................................24
2-7 Voltage and Current Specifications.....................................................................25
2-8 VCC Static and Transient Tolerance...................................................................28
2-9 VCC Overshoot Specifications............................................................................29
2-10 BSEL[1:0] and VID[5:0] Signal Group DC Specifications....................................30
2-11 AGTL+ Signal Group DC Specifications .............................................................31
2-12 PWRGOOD Input and TAP Signal Group DC Specifications .............................31
2-13 GTL+ Asynchronous and AGTL+ Asynchronous Signal Group DC
Specifications......................................................................................................32
2-14 VIDPWRGD DC Specifications.......... .................... ... ... ... .... ... ... ... .... ... ... ... ..........32
3-1 Processor Loading Specifications.......................................................................37
3-2 Package Handling Guidelines................ ... ... ... .... ... ... ... ... .... ................... ... ... .... ...38
3-3 Processor Materials ............................................................................................38
4-1 Signal Definitions ................................................................................................43
5-1 Pin Listing by Pin Name......................................................................................53
5-2 Pin Listing by Pin Number...................................................................................62
6-1 Dual-Core Intel® Xeon® Processor Thermal Specifications................................72
6-2 Dual-Core Intel® Xeon® Processor Thermal Profile A ........................................74
6-3 Dual-Core Intel® Xeon® Processor Thermal Profile B ........................................75
7-1 Power-On Configuration Option Pins..................................................................79
8-1 PWM Fan Freq uency Specifications for 4-Pin Active CEK Thermal Solution.....96
8-2 Fan Specifications for 4-pin Active CEK Thermal Solution .............. ... ... ... ... .... ...96
8-3 Fan Cable Connector Pin Out for 4-Pin Active CEK Thermal Solution...............97
8-4 Fan Cable Connector Supplier & Part Number...................................................97
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 7
Revision History
§
Order
Number Revision
Number Description Date
309158 -001 Initial release of the document. October 2005
8Dual-Core In tel® Xeon® Processor 2.80 GHz Datasheet
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 9
Features
Dual-Core processing
Available at 2.80 GHz processor speed
90 nm process technology
Dual processing (DP) server support
Binary compatible with app licati ons running on
previous members of Intel’s IA-32 microprocessor
line
Intel® NetBurst® micro-architecture
Hyper-Threading Technology allowing up to
8 threads per platform
Hardware support for multithreaded applicatio ns
800 MHz system bus
Rapid Execution Engine: Arithmetic Logic Unit s
(ALUs) run at twice the processor core frequency
Hyper Pipelined Technology
Advanced Dynamic Execution
Very deep out-of-order execution
Enhanced branch prediction
Includes 16-KB Level 1 data cache per core
(2x16-KB)
Intel® Extended Memory 64 Technology
(Intel®EM64T)
2-MB Advanced T ransfer Cache per core (2x2-MB,
On-die, full speed Level 2 (L2) Cache) with 8-way
associativity and Error Correcting Code (ECC)
Enables system support of up to 64 GB of physical
memory
144 Streaming SIMD Extensions 2 (SSE2)
instructions
13 Streaming SIMD Extensions 3 (SSE3)
instructions
Enhanced floating-point and multim edia unit for
enhanced video, audio, encryption, and 3D
performance
System Management mode
Thermal Monitor
Machine Check Architecture (MCA)
Demand-Based Switching (DBS) with Enhanced
Intel SpeedStep® Technology
The Dual-Core Intel® Xeon® processor is design ed for high-performance dual-processor server applications. Based
on the Intel NetBurst® microarchitecture and Hyper-Threading Technology (HT Technology), it is binary
compatible with previous Intel® Architecture (IA-32) processors. The Dual-Core Intel Xeon processor is scalable to
two processors in a multiprocessor system, providin g exceptional performance for applications running on
advanced operating systems such as Windows* XP, Windows Server 2003, Linux*, and UNIX*.
The Dual-Core Intel Xeon processor delivers compute power at unparalleled value and flexibility for powerful
servers, internet infrastructure, and departmental server applicatio ns. The Intel NetBurst micro-architecture and
Hyper-Threading Technology deliver outstanding performance and headroom for peak internet server workloads,
resulting in faster response times, support for more users, and improved scal ability.
§
10 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 11
1Introduction
The Dual-Core Intel® Xeon® processor is Intel’s first dual core product for dual-processor server
platforms and utilizes two physical Intel NetBurst® microarchitecture cores in one package. As
well, it maintains compatibility with IA-32 software while also supporting 64-bit computing with
Intel® Extended Memory 64 Technology (Intel® EM64T). The processor also features Hyper
Pipelined Technology, a Rapid Execution Engine, and an Execution Trace Cache. The 800 MHz
system bus is a quad-pumped bus running off a 200 MHz system clock making 6.4 GB per second
data transfer rates possible. The Execution Trace Cache is a level 1 cache that stores decoded
micro-operations, which removes the decoder from the main execution path, thereby increasing
performance.
In addition, enhanced thermal and pow er management capabilities are implemented including
Thermal Monitor and Enhanced Intel SpeedStep® Technology. These capabilities are targeted for
dual processor (DP) servers in data center and office environments. Thermal monitor provides
efficient and effective cooling in high temperature situations. Enhanced Intel SpeedStep ® allows
trade-offs to be made between performance and power consumption. This may lower average
power consumption (in conjunction with OS support).
The Dual-Core Intel® Xeon® processor supports Hyper-Threading Technology . This feature allows
a single, physical processor to function as four logical processors (2 logical processors per core).
While some execution resources such as caches, execution units, and buses are shared, each logical
processor has its own architecture state with its own set of general-purpose registers, control
registers to provide increased system responsiveness in multitasking environments, an d headroom
for next generation multithreaded applications. More information on Hyper-Threading Technology
can be found at http://www.intel.com/technology/hyperthread.
The Dual-Core Intel Xeon processor also includes the Execute Disable Bit capability previously
available in Intel® Itanium® processors. This feature, when combined with a supported operating
system, allows memory to be marked as executable or non-executable. If code attempts to run in
non-executable memory, the processor raises an error to the operating system. This feature can
prevent some classes of viruses or worms that exploit buffer overrun vulnerabilities and can thus
help improve the overall security of the system. See the IA-32 Intel® Architecture Software
Developers Manual for more detailed information.
Other features within the Intel NetBurst microarchitecture include Advanced Dynamic Execution,
Advanced Transfer Cache, enhanced floating point and multi -m edia unit, Streaming SIMD
Extensions 2 (SSE2) and Streaming SIMD Extensions 3 (SSE3). Advanced Dynamic Execu tion
improves speculative execution and branch prediction internal to the processor. The Advanced
T ransfer Cache in each core is a 2 MB level 2 (L 2) cache. The floating po int and multi-media units
include 128-bit wide registers and a separate register for data movement. Streaming SIMD2
(SSE2) instructions provide highly efficient double-precision floating point, SIMD integer, and
memory management operations. In addition, SSE3 instructions have been added to further extend
the capabilities of Intel processor technolog y. Other processor enhancements include core
frequency improvements and microarchitectural improvements.
The Dual-Core Intel Xeon processor supports Intel Ex tend ed Memory 64 Technology
(Intel EM64T) as an enhancement to Intel's IA-32 architecture. This enhancement allows the
processor to execute operating systems and applications written to take advantage of the 64-bit
extension technology. Further details on Intel Extended Memory 64 Technology and its
programming model can be fo und in the IA-32 Intel® Architecture Software Developer's Manual.
Introduction
12 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
The Dual-Core Intel Xeon processor is intended for high performance server systems with up to
two processors on one system bus. The processor will be packaged in a 604-p in Flip Chip Micro
Pin Grid Array (FC-mPGA4) package and will utilize a surface mount Zero Insertion Force (ZIF)
socket (mPGA604).
The Dual-Core Intel Xeon processor-based platforms im plement independent power planes for
each system bus agent. As a result, the processor core voltage (V CC) and system bus termination
voltage (VTT) must connect to sep arate supplies. The processor core voltage utilizes power
delivery guidelines denoted by VRM 10.1 and th e associat ed load line (see Voltage Regulator
Module (VRM) and Enterprise Voltage Regulat or-Down (EVRD) 10.1 Design Guid elin es for
further details). Implement a tion de tails can be obtained by referring to the applicab le platform
design guidelines.
The Dual-Core Intel Xeon processor uses a scalable system bus protocol referred to as the “system
bus” in this document. The system bus utilizes a split -transacti on, deferred reply protocol. The
system bus uses Source-Synchronous T ransfer (SST) of address and data to improve performance.
The processor transfers data four times per bus clock (4X data transfer rate, as in AGP 4X). Along
with the 4X data bus, the address bus can deliver addresses two times per bus clock and is referred
to as a ‘double-clocked’ or the 2X address bus. In additi on, the Request Phase comple tes in one
clock cycle. Working together , the 4X data bus and 2X address bus provide a data bus bandwidth of
up to 6.4 GBytes/second (6400 MBy tes/second ). Finally, the system bus is also used to deliver
interrupts.
1.1 Terminology
A ‘#’ symbol after a signal name re fers to an active low signal, indicating a signal is in the asserted
state when driven to a low level. For example, when RESET# is low, a reset has been requested.
Conversely, when NMI is high, a nonmaskable interrupt has occurred. In the case of signals 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).
“Front side bus” or “System bus” refers to the interface between the processor, system core logic
(a.k.a. the chipset components), and other bus agents. The system bus is a multiprocessing interface
to processors, memory, and I/O. For this document, “front side bus” or “system bus” are used as
generic terms for the “Dual-Core Int e l Xeon processor system bus”.
Commonly used terms are explained here for clarificatio n:
Dual-Core Intel Xeon processor — Intel’s first dual-core 64/32-bit microprocessor intended
for dual processor servers. The Dual-Core Intel Xeon processor is based on Intel’s 90
nanometer process and has a 2 MB per core level 2 (L2) cache. The Dual-Core Intel Xeon
processor will utilize the mPGA604 socket. For this document, “processor” is used as the
generic term for the “Dual-Core Intel® Xeon® Processor”.
Central Agent — The central agent is the host bridge to the processor and is typically known
as the chipset.
Table 1-1. Features of the Dual-Core Intel® Xeon® Processor
# of Supported
Symmetric Agents L2 Advanced
Transfer Cache Front Side Bus
Frequency Package
Dual-Core Intel®
Xeon® processor 1 - 4 2 MB per Core 800 MHz 604-pin FC-mPGA4
Introduction
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 13
EVRD (Enterprise Voltage Regulator Down) — DC-DC converter integrated onto the
system board that provide the correct voltage and current for the processor based on the logic
state of the VID bits.
FC-mPGA4 (Flip Chip Micro Pin Grid Array) Package — The processor package is a Flip
Chip Micro Pin Grid Array (FC-mPGA4), consisting of a processo r cores mounted on a
pinned substrate with an integrated heat spreader (IHS). This package technology employs a
1.27 mm [0.05 i n.] pitch for the processor pins.
Fr ont Side Bus (FSB) — The electrical interface that connects the processor to the chipset.
Also referred to as the processor system bus or the system bus. All memory and I/O
transactions, as well as interrupt messages, pass betwe en the processor and the chipset over the
FSB.
Functional Operation — Refers to th e norm al operating conditions in which all processor
specifications, incl uding DC, system bus, signal quality, mechanical and thermal are satisfied.
Integrated Heat Spreader (IHS) — A component of the processor package used to enhance
the thermal performance of the package. Component thermal solutions interface with the
processor at the IHS surface.
mPGA604 socket — The Dual-Core Intel Xeon processor mates with the baseboard through
this surface mount, 604-pin, zero insertion force (ZIF) socket. See the mPGA604 Socket
Design Guidelines for details regardi ng this socket.
Processor cores — The processors execution engines. All signal integrity specifications are
to the pads of the processor cores.
Storage Conditions — Refers to a non-operational state. The processor may be installed in a
platform, in a tray, or loose. Processors may be sealed in packaging or exposed to free air.
Under these conditions, processor pins should not be connected to any supply voltages, have
any I/Os biased or receive any clocks.
Symmetric agent — A symmetric agent is a processor which shares the same I/O subsystem
and memory array, and runs the same operating system as another processor in a system.
Systems using symmetric agents are known as Symmetric Multiprocessor (SMP) systems. The
Dual-Core Intel Xeon processor should only be used in SMP systems which have two or fewer
agents.
Thermal Design Power — Processor/chipset thermal soluti on should be designed to this
target. It is the highest expected sustainable power wh ile running known power-intensive real
applications. TDP is not the maximum power that the processor/ch ipset can dissipate.
VRM (Voltage Regulator Module) — DC-DC converter built onto a module that interfaces
with an appropriate card edge socket that supplies the correct voltage and current to the
processor.
VCC — The processor core power supply.
VSS — The processor ground.
VTT — The system bus termination voltage.
Introduction
14 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
1.2 References
Material and concepts available in the following documen ts may be beneficial when reading this
document.
NOTE: Contact your Intel representative for the latest revision of the documents without document numbers.
1.3 State of Data
The data contained within this document is subject to change. It is the most accurate information
available by the publication date of this document
§
Document Intel Order Number
mPGA604 Socket Design Guidelines 254239
AP-485, Intel® Processor Identification and CPUID Instruction 241618
ATX12V Power Supply Design Guide http://formfactors.org
Entry-Level Electronics-Bay Specifications: A Server System Infrastructure
(SSI) Specification for Entry Pedestal Servers and Workstations http://www.ssiforum.org
EPS12V Power Supply Design Guide: A Server System Infrastructure (SSI)
Specification for Entry Chassis Power Supplies http://www.ssiforum.org
IA-32 Intel® Architecture Optimization Reference Manual 248966
IA-32 Intel® Architecture Software Developer's Manual
Volume 1: Basic Architecture
Volume 2A: Instruction Set Reference, A-M
Volume 2B: Instruction Set Reference, N-Z
Volume 3: System Programming Guide
253665
253666
253667
253668
Dual-Core Intel® Xeon® Processor Boundary Scan Descriptor Language
(BSDL) Model (V1.0) and Cell Descriptor File (V1.0)
ITP700 Debug Port Design Guide 249679
Dual-Core Intel® Xeon® Processor 2.80 GHz Specification Update
Thin Electronics Bay Specification (A Server System Infrastructure (SSI)
Specification for Rack Optimized Servers) http://www.ssiforum.org
Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down
(EVRD) 10.1 Design Guidelines 302732
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 15
2Electrical Specifications
2.1 Front Side Bus and GTLREF
Most Dual-Core Intel Xeon processor front side bus (FSB) signals use Assisted Gunning
Transceiver Logic (AGTL+) signaling technology. This technology provides improved noise
margins and reduced ringing through low voltage swings and controlled edge rates. AGTL+ buffers
are open-drain and require pull-up resistors to provide the high logic level and termination. AGTL+
output buffers differ from GTL+ buffers with the addition of an active pMOS pull-up transistor to
“assist” the pull-up resistors during the fi rst clock of a low-to-high voltage transitio n. Platforms
implement a termination voltage level for AGTL+ signals defined as VTT. Because platforms
implement separate power planes for each processor (and chipset), separate VCC and VTT supplies
are necessary. This configuration allows for improved noise tolerance as processor frequency
increases. Speed enhancements to data and address busses have caused signal integrity
considerations and platform desig n met hods to become even more critical than with previous
processor families. Design guidelines for the processor front side bus are detailed in the appropriate
platform design guide (refer to Section 1.2).
The AGTL+ inputs require a reference voltage (GTLREF) which is used by the receivers to
determine if a sign al is a logical 0 or a logical 1. GTLREF mus t be generated on the baseboard.
Please refer to the applicable platform design guidelines for details. Termination resistors (R TT) for
AGTL+ signals are provided on the processor silicon and are terminated to VTT. The on-die
termination resistors are a selectable feature and can be enabled or disabled via the ODTEN signal.
For end bus agents, on-die termination resistors are enabled to control reflections on the
transmission line. For the middle bus agent, on-die termination RTT resistors must be disabled.
Intel chipsets will also provid e on-die termination, thus eliminati ng the need to terminate the bus
on the baseboard for most AGTL+ signals. Processor wired-OR signals may also include additional
on-die resistors (RL) to further insure proper noise margin and signal integrity. RL is not
configurable and is always enabled for these signals. Figure 2-1 illustrate the active on-die
termination.
Note: Some AGTL+ signals do not includ e on-d ie termination (RTT) and must be termin at ed on the
baseboard. See Table 2-4 for details regarding these signals.
Figure 2-1. On-Die Front Side Bus Termination
End Agent
Signal
VTT
M id dle A gent
RTT Signal
RL
RTT - On-die term ination resistors for AG TL+ signals
RL - A dditional on-die resistance im plem ented for proper noise m argin and
s ig n a l in t e g rity ( w ir e d -OR s ig n a ls on ly )
Electrical Specifications
16 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
The AGTL+ bus depends on incident wave switching. Therefore, timing calculations for AGTL+
signals are based on flight time as opposed to capacitive deratings. Analog signal simulation of the
front side bus, including trace lengths, is highly recommended when designing a system.
2.2 Power and Ground Pins
For clean on-chip power distribution, the processor has 181 VCC (power) and 185 VSS (ground)
inputs. All VCC pins must be connected to the processor power plane, while all VSS pins must be
connected to the system ground plane. The processor VCC pins must be supplied with the voltage
determined by the processor Voltage IDentification (VID) pins.
Eleven signals are denoted as VTT, which provide termination fo r the front side bus and pow er to
the I/O buf fers. The platform must implement a separate supply for these pins, which meets the VTT
specifications outlined in Table 2-7.
2.3 Decoupling Guidelines
Due to its large number of transistors and high internal clock speeds, the Dual-Core Intel Xeon
processor is capable of generating lar ge average current swings between low and full power states.
This may cause voltages on power planes to sag below their minimum values if bulk decoupling is
not adequate. Larger bulk storage (CBULK), such as electrolytic or aluminum-polymer capacitors,
supply current during longer lasting changes in current demand by the component, such as coming
out of an idle condition. Similarly, they act as a storage well for current when entering an idle
condition from a running condition. Care must be taken in the baseboard design to ensure that the
voltage provided to the processor remains within the specifications listed in Table 2-7. Failure to do
so can result in timing violations or reduced lifetime of the component. For further information and
guidelines, refer to the appropriate platform design gu idelines.
2.3.1 VCC Decoupling
Regulator solutions need to provide bulk capacitance with a low Effective Series Resistance (ESR)
and the baseboard designer must assure a low interconnect resistance from the voltage regulator
(VRD or VRM pins) to the mPGA604 socket. The power delivery solution must insure the voltage
and current specifications are met (defined in Table 2-7). For furt her information regarding power
delivery, decoupling, and layout guidelines, refer to the appropriate platform design guidel ines.
2.3.2 VTT Decoupling
Decoupling must be provided on the baseboard. Decoupling solutions must be sized to meet th e
expected load. To insure optimal performance, various factors associated with the power delivery
solution must be considered including regulator type, power plane and trace sizing, and component
placement. A conservative decoupling solution would consist of a combination of low ESR bulk
capacitors and high frequency ceramic capacitors. For further information regarding power
delivery, decoupling and layout guidelines, refer to the appropriate platform design guidelines.
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 17
2.3.3 Front Side Bus AGTL+ Decoupling
The Dual-Core Intel Xeon processor integrates signal termination on the die, as well as part of the
required high frequency decoupling capacitance on the processor package. However, addi tional
high frequency capacitance must be added to the baseboard to properly decouple the return
currents from the front side bus. Bulk decoupling must also be pro vided by the baseboard for
proper AGTL+ bus operation. Decoupling guidelines are described in the appropriate platform
design guidelines.
2.4 Front Side Bus Clock (BCLK[1:0]) and Processor
Clocking
BCLK[1:0] directly controls the front side bus interface speed as well as the core frequency of the
processor. As in previous processor generations, the Dual-Core Intel Xeon processor core
frequency is a multiple of the BCLK[1:0] frequency. The processor bus ratio multiplier will be set
during manufacturing. The default setting will be the maximu m speed for the processor. It will be
possible to override this setting using software (see the IA-32 Intel® Architecture Software
Developer's Manual, Volume 3). This will permit operation at a speed lower than the processor’s
tested frequency.
The BCLK[1:0] inputs directly control the operating speed of the front side bus interface. The
processor core frequency is configured during reset by using values stored internally during
manufacturing. The stored value sets the highest bus fraction at which the particular processor can
operate. If lower speeds are desired, the appropriate ratio can be configured by setting bits [15:8] of
the IA32_FLEX_BRVID_SEL MSR. For details of operation at core frequencies lower than the
maximum rated processor speed, refer to the IA-32 Intel® Architecture Software Developer's
Manual, Volume 3.
Clock multiplying within the processor is provided by the internal phase locked loop (PLL), which
requires a constant frequency BCLK[1:0] input, with exceptions for spread spectrum clocking.
The Dual-Core Intel Xeon processor utilizes differential clocks. Table 2-1 contains core frequency
to front side bus multipliers and their correspondi ng core frequencies.
2.4.1 Front Side Bus Frequency Select Signals (BSEL[1:0])
BSEL[1:0] are open-drain outputs, which must be pulled up to VTT, and are used to select the front
side bus frequency. Please refer to Table 2-10 for DC specifications. Table 2-1 defines the possible
combinations of the signals and the frequency associated with each combination. The frequency is
determined by the processor(s), chipset, and clock synthesizer. Al l front side bus agents must
operate at the same core and front side bus frequencies. Individual processors will only operate at
their specified front side bus clock frequency. See the appropriate platform design guide for further
details.
Table 2-1. BSEL[1:0] Frequency Table
BSEL1 BSEL0 Bus Clock Frequency
00Reserved
01Reserved
1 0 200 MHz
11Reserved
Electrical Specifications
18 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
2.4.2 Phase Lock Loop (PLL) and Filter
VCCA and VCCIOPLL are power sources required by the PLL clock ge nerat ors on the Dual-Core Intel
Xeon processor. Since these PLLs are analog in nature, they req uire quiet po wer supplies for
minimum jitter. Jitter is detriment a l to the system : it degrades external I/O timings as well as
internal core timings (i.e., maxim um frequency). To prevent this degradation, these supplies must
be low pass filtered from VTT.
The AC low-pass requirements are as follows:
< 0.2 dB gain in pass band
< 0.5 dB attenuation in pass band < 1 Hz
> 34 dB attenuation from 1 MHz to 66 MHz
> 28 dB attenuation from 66 MHz to core frequency
The filter requirements are illustrated in Figure 2-2. For recommendations on implementing the
filter refer to the appropriate platform design guidelines.
NOTES:
1. Diagram not to scale.
2. No specifications for frequencies beyond fcore (core frequency).
3. fpeak, if existent, should be less than 0.05 MHz.
4. fcore represents the maximum core frequency supported by the platform.
Figure 2-2. Phase Lock Loop (PLL) Filter Requirements
0 dB
-28 dB
-34 dB
0.2 dB
forbidden
zone
-0.5 dB
forbidden
zone
1 MHz 66 MHz
f
core
f
peak1 HzDC
passband high fr eq ue nc y
band
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 19
2.5 Voltage Identification (VID)
The Voltage Identification (VID) specification for the Dual-Core Intel Xeon processor is defined
by the Voltage Regulator Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.1
Design Guidelines. The voltage set by the VID signals is the maximum voltage allowed by the
processor (please see Section 2.12.1 for VCC overshoot specifications). VID signals are open drain
outputs, which must be pulled up to VTT. Please refer to Table 2-10 for the DC specifications for
these signals. A minimum voltage is provided in Table 2-7 and changes with frequency. This
allows processors running at a higher frequency to have a relaxed minimum voltage specification.
The specifications have been set such that one voltage regulator can operate with all supported
frequencies.
Individual processor VID values may be calibrated during manufacturing such that two devices at
the same core speed may have different default VID settings. This is reflected by the VID range
values provided in Table 2-7. Refer to the Dual-Core Intel® Xeon® Processor 2.80 GHz
Specification Update for further details on specific valid core frequency and VID values of the
processor.
The Dual-Core Intel Xeon processor uses six voltage identification signals, VID[5:0], to su pport
automatic selection of power supply voltages. Table 2-2 specifies the voltage level corresponding
to the state of VID[5:0]. A ‘1’ in this table refers to a high voltage level and a ‘0’ refers to a low
voltage level. If the proce ssor socket is empty (VID[5:0] = x11111), or the voltage regulation
circuit cannot supply the voltage that is requested, it must disable itself. See the Voltage Regulator
Module (VRM) and Enterprise Voltage Regulator-Down (EVRD) 10.1 Design Guidelines for
further details.
The Dual-Core Intel Xeon processor provides the ability to operate while transitioning to an
adjacent VID and its associated processor core voltage (VCC). This will represent a DC shift in the
load line. It should be noted that a low-to-high or high-to-low voltage state change may result in as
many VID transitions as necessary to reach the target core voltage. T ransitions above the specified
VID are not permitted. Table 2-7 includes VID step sizes and DC shift ranges. Minimum and
maximum voltages must be maintained as shown in Table 2-8 and Figure 2-4.
The VRM or VRD utilized must be capable of regulating its output to the value defined by the new
VID. DC specifications for dynamic VID transitions are included in Table 2-7 and Table 2-8.
Please refer to the Voltage Reg ulator Module (VRM) and Enterprise Voltage Regulator-Down
(EVRD) 10.1 Design Guidelines for further details.
Power source characteristics must be guaranteed to be stable whenever the supply to the voltage
regulator is stable.
Electrical Specifications
20 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. When this VID pattern is observed, the voltage regulator output should be disabled.
2. Shading denotes the expected default VID range during normal operation for the Dual-Core Intel Xeon processor [1.2875 V -
1.4125 V]. Please note this is subject to change.
3. Shaded areas do not represent the entire range of VIDs that may be driven by the processor. Events causing dynamic VID
transitions (See Section 2.5) may result in a more broad range of VID values.
Table 2-2. Voltage Identification Definition2,3
VID5 VID4 VID3 VID2 VID1 VID0 VCC_MAX VID5 VID4 VID3 VID2 VID1 VID0 VCC_MAX
0 0 1 0 1 0 0.8375 0110101.2125
1 0 1 0 0 1 0.8500 1110011.2250
0 0 1 0 0 1 0.8625 0110011.2375
1 0 1 0 0 0 0.8750 1110001.2500
0 0 1 0 0 0 0.8875 0110001.2625
1 0 0 1 1 1 0.9000 1101111.2750
0 0 0 1 1 1 0.9125 0101111.2875
1 0 0 1 1 0 0.9250 1101101.3000
0 0 0 1 1 0 0.9375 0101101.3125
1 0 0 1 0 1 0.9500 1101011.3250
0 0 0 1 0 1 0.9625 0101011.3375
1 0 0 1 0 0 0.9750 1101001.3500
0 0 0 1 0 0 0.9875 0101001.3625
1 0 0 0 1 1 1.0000 1100111.3750
0 0 0 0 1 1 1.0125 0100111.3875
1 0 0 0 1 0 1.0250 1100101.4000
0 0 0 0 1 0 1.0375 0100101.4125
1 0 0 0 0 1 1.0500 1100011.4250
0 0 0 0 0 1 1.0625 0100011.4375
1 0 0 0 0 0 1.0750 1100001.4500
0 0 0 0 0 0 1.0875 0100001.4625
111111OFF
11011111.4750
011111OFF
10011111.4875
1 1 1 1 1 0 1.1000 1011101.5000
0111101.1125 0011101.5125
1 1 1 1 0 1 1.1250 1011011.5250
0 1 1 1 0 1 1.1375 0011011.5375
1 1 1 1 0 0 1.1500 1011001.5500
0 1 1 1 0 0 1.1625 0011001.5625
1 1 1 0 1 1 1.1750 1010111.5750
0 1 1 0 1 1 1.1875 0010111.5875
1 1 1 0 1 0 1.2000 1010101.6000
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 21
2.6 Reserved Or Unused Pins
All Reserved pins must remain unconnected. Connection of these pins to VCC, VTT, VSS, or to any
other signal (including each other) can result in component mal fun ction or incompatibility with
future processors. See Section 5 for a pin listing of the processor and the location of all Reserved
pins.
For reliable operation, always connect unused inputs or bidirectional signals to an appropriate
signal level. In a system level design, on-die termination has been included by the processor to
allow end agents to be terminated within the processor silicon for most signals. In this context, end
agent refers to the bus agent that resides on either end of the daisy-chained front side bus interface
while a middle agent is any bus agent in between the two end agents . For end agents, most unused
AGTL+ inputs should be left as no connects as AGTL+ termination is provided on the processor
silicon. However, see Table 2-4 for details on AGTL+ signals that do not include on-die
termination. For middle agents, the on-die termination must be disabled, so the platform must
ensure that unused AGTL+ input signals which do not connect to end agents are connected to VTT
via a pull-up resistor. Unused active high inputs, should be connected throu gh a resistor to ground
(VSS). Unused outputs can be left unconnected, however this may interfere with some TAP
functions, complicate debug probing, and prevent boundary scan testin g. A resist or must be used
when tying bidirectional signal s to power or ground. Wh en tying any signal to power or ground, a
resistor will also allow for system testability. Resistor values should be within ±20% of the
impedance of the baseboard trace for front side bus signals. For unused AGTL+ input or I/O
signals, use pull-up resistors of the same value as the on-die termination resistors (RTT).
TAP, Asynchronous GTL+ inputs, and Asynchronous GTL+ outputs do not include on-die
termination. Inputs and utilized outputs must be terminated on the baseboard. Unused outputs may
be terminated on the baseboard or left unconnected. Note that leaving unused outputs unterminated
may interfere with some TAP functions, complicate debug probing, and prevent boundary scan
testing. Signal termination for these signal types is discussed in the ITP700 Debug Port Design
Guide (See Section 1.2)
All TESTHI[6:0] pins should be individually connected to VTT via a pull-up resistor which
matches the nominal trace impedance. TESTHI[3:0] and TESTHI[6:5] may be tied together and
pulled up to VTT with a single resistor if desired. However, utilization of boundary scan test will
not be functional if these pins are connected together. TESTH I4 mu st always be pulle d up
independently from the other TESTHI pins. For optimum noise margin, all pull-up resist or values
used for TESTHI[6:0] pins should have a resistance value within ± 20 % of the impedance of the
board transmission line traces. For example, if the nominal trace impedance is 50 , then a value
between 40 and 60 should be used.
N/C (no connect) pins of the processor are not utili zed by the processor. Th ere is no connection
from the pin to the die. These pins may perform functions in future processo rs intended for
platforms utilizing the Dual-Core Intel Xeon processor. Refer to the applicable platform design
guidelines for guidance that pertains to any pin labeled N/C in this documen t.
2.7 Front Side Bus Signal Groups
The front side bus signals have been combined into groups by buffer type. AGTL+ input signals
have differential input buffers, which use GTLREF as a reference level. In this document, the term
“AGTL+ Input” refers to the AGTL+ input group as well as the AGTL+ I/O group when receiving.
Similarly, “AGTL+ Output” refers to the AGTL+ output group as well as the AGTL+ I/O group
when driving. AGTL+ asynchronous outputs can become active anytime and include an active
pMOS pull-u p transistor to assist during the first clock of a low-to-high voltage transition.
Electrical Specifications
22 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
With the implementation of a source synchronous data bus comes the need to specify two sets of
timing parameters. One set is for common clock signals whose timings are specified with r espect to
rising edge of BCLK0 (ADS#, HIT#, HITM#, etc.) and the second set is for the source
synchronous signals which are relative to their respective strobe lines (data and address) as well as
rising edge of BCLK0. Asynchronous signals are still present (A20M#, IGNNE#, etc.) and can
become active at any time during the clock cycle. Table 2-3 identifies which signals are common
clock, source synchronous and asynchronous.
NOTES:
1. Refer to Section 4 for signal descriptions.
2. The Dual-Core Intel Xeon processor utilizes all four of the BR0#, BR1#, BR2# and BR3# signals. For
additional details regarding the BR[3:0]# signals, see Section 4 and Section 7.1.
3. The value of these pins during the active-to-inactive edge of RESET# defines the processor configuration
options. See Section 7.1 for details.
4. These signals may be driven simultaneously by multiple agents (wired-OR).
Table 2-4 outlines the signals which include on-die termi nation (RTT) and lists signals which
include additional on-die resistance (RL). Table 2-5 provides signal reference voltages.
Table 2-3. Front Side Bus Signal Groups
Signal Group Type Signals1
AGTL+ Common Clock
Input Synchronous to BCLK[1:0] BPRI#, BR[3:1]#2,3, DEFER#, RESET#,
RS[2:0]#, RSP#, TRDY#
AGTL+ Common Clock I/O Synchronous to BCLK[1:0] ADS#, AP[1:0]#, BINIT#4, BNR#4, BPM[5:0]#,
BR0#2,3, DBSY#, DP[3:0]#, DRDY#, HIT#4,
HITM#4, LOCK#, MCERR#4
AGTL+ Source
Synchronous I/O Synchronous to assoc.
strobe
AGTL+ Strobe I/O Synchronous to BCLK[1:0] ADSTB[1:0]#, DSTBP[3:0]#, DSTBN[3:0]#
AGTL Asynchronous Output Asynchronous FERR#/PBE#, IERR#, PROCHOT#
GTL+ Asynchronous Input Asynchronous A20M#, FORCEPR#, IGNNE#, INIT#3, LINT0/
INTR, LINT1/NMI, SMI#3, SLP#, STPCLK#
G TL+ Asynchronous Output Asynchronous THERMTRIP#
Front Side Bus Clock Clock BCLK1, BCLK0
TAP Input Synchronous to TCK TCK, TDI, TMS, TRST#
TAP Output Synchronous to TCK TDO
Power/Other Power/Other BOOT_SELECT, BSEL[1:0], COMP[0],
GTLREF[3:0], ODTEN, OPTIMIZED/COMPAT#,
PWRGOOD, Reserved, SKTOCC#,
SLEW_CTRL, SMB_PRT, TEST_BUS,
TESTHI[6:0], THERMDA, THERMDC, VCC,
VCCA, VCCIOPLL, VCCPLL, VCCSENSE, VID[5:0],
VSS, VSSA, VSSSENSE, VTT, VIDPWRGD,
VTTEN
Signals Associated Strobe
REQ[4:0]#,A[16:3]#3ADSTB0#
A[35:17]#3ADSTB1#
D[15:0]#, DBI0# DSTBP0#, DSTBN0#
D[31:16]#, DBI1# DSTBP1#, DSTBN1#
D[47:32]#, DBI2# DSTBP2#, DSTBN2#
D[63:48]#, DBI3# DSTBP3#, DSTBN3#
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 23
NOTES:
1. Signals that do not have RTT, nor are actively driven to their high voltage level.
2. The termination for these signals is not RTT. The OPTIMIZED/COMPAT# and BOOT_SELECT pins have a
500 - 5000pull-up to VTT.
NOTES:
1. These signals also have hysteresis added to the reference voltage. See Table 2-12 for more information.
2.8 GTL+ Asynchronous and AGTL+ Asynchronous
Signals
The Dual-Core Intel Xeon processor does not utilize CMOS voltage levels on any signals that
connect to the processor silicon. As a result, input signals such as A20M#, FORCEPR#, IGNNE#,
INIT#, LINT0/INTR, LINT1/NMI, SMI#, SLP#, and STPCLK# utilize GTL input buffers. Legacy
output THERMTRIP# utilizes a GTL+ output buffers. All of these Asynchronous GTL+ signals
follow the same DC requirements as GTL+ signals, however the outputs are not driven high
(during the logical 0-to-1 transi tion) by the processor. FERR#/PBE#, IERR# , and IGNNE# have
now been defined as AGTL+ asynchrnous signals as they include an activ e p-MOS device. GTL+
asynchronous and AGTL+ asynchronous signals do not have setup or hold time specifications in
relation to BCLK[1:0]. However , all of the GTL+ asynchronous and AGTL+ asynchronous signals
are required to be asserted/deasserted for at least six BCLKs in order for the processor to recognize
them. See Table 2-13 for the DC specifications for the asynchronous GTL+ signal groups.
2.9 Test Access Port (TAP) Connection
Due to the voltage levels supported by other components in the Test Access Port (TAP) logic, it is
recommended that the processor(s) be first in the TAP chain and followed by any other components
within the system. A translation buffer should be used to connect to the rest of the chain unless one
Table 2-4. Signal Description Table
Signals with RTT
A[35:3]#, ADS#, ADSTB[1:0]#, AP[1:0]#, BINIT#, BNR#, BOOT_SELECT2, BPRI#, D[63:0]#, DBI[3:0]#,
DBSY#, DEFER#, DP[3:0]#, DRDY#, DSTBN[3:0]#, DSTBP[3:0]#, FORCEPR#, HIT#, HITM#, LOCK#,
MCERR#, OPTIMIZED/COMPAT#2, REQ[4:0]#, RS[2:0]#, RSP#, TEST_BUS, TRDY#
Signals with RL
BINIT#, BNR#, HIT#, HITM#, MCERR#
Table 2-5. Signal Reference Voltages
GTLREF 0.5 * VTT
A20M#, A[35:3]#, ADS#, ADSTB[1:0]#, AP[1:0]#,
BINIT#, BNR#, BPM[5:0]#, BPRI#, BR[3:0]#,
D[63:0]#, DBI[3:0]#, DBSY#, DEFER#, DP[3:0]#,
DRDY#, DSTBN[3:0]#, DSTBP[3:0]#, FORCEPR#,
HIT#, HITM#, IGNNE#, INIT#, LINT0/INTR, LINT1/
NMI, LOCK#, MCERR#, ODTEN, RESET#,
REQ[4:0]#, RS[2:0]#, RSP#, SLP#, SMI#,
STPCLK#, TRDY#
BOOT_SELECT , OPTIMIZED/COMPA T#, PWRGOOD1,
TCK1, TDI1, TMS1, TRST#1, VIDPWRGD
Electrical Specifications
24 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
of the other components is capable of accepting an input of the appropriate voltage. Similar
considerations must be made for TCK, TMS, and TRST#. Two copies of each signal may be
required with each driving a different voltage level.
2.10 Mixing Processors
Intel only supports and validates dual processor configurations in which both Dual-Core Intel Xeon
processor operate with the same front side bus frequency, core frequency, and have the same
internal cache sizes. Mixing components operating at different internal clock frequencies is not
supported and will not be validated by Intel [Note: Processors within a system must operate at the
same frequency per bits [15:8] of the IA32_FLEX_BRVID_SEL MSR; however this does not
apply to frequency transitions initiated due to thermal events, Enhanced Intel SpeedStep
technology transitions, or assertion of the FORCEPR# signal (See Section 6)]. Not all operating
systems can support dual processors with mixed frequencies. Intel does not support or validat e
operation of processors with different cache sizes. Mixing processors of different steppings but the
same model (as per CPUID instruction) is supported. Please see the Dual-Core Intel® Xeon®
Pr ocessor 2.80 GHz Specification Update (see Section 1.2) for the applicable mixed stepping table.
Details regarding the CPUID instruction are provided in the IA-32 Intel® Ar chitecture Software
Developer's Manual, Volume 3: System Programmer's Guide and the AP-485 Intel® Processor
Identification and the CPUID Instruction application note.
2.11 Absolute Maximum and Minimum Ratings
Table 2-6 specifies absolute maximum and minimum ratings. Within functional operation limits,
functionality and long-term reliability can be expected.
At conditions outside functional operation condition limits, but within absolute maximum and
minimum ratings, neither functionality nor long term reliability can be expected. If a device is
returned to conditions within functional operation limits after having been subjected to conditions
outside these limits, bu t within the absolute maximum and minimum ratings, the device may be
functional, but with its lifetime degraded depending on exposure to conditions exceeding the
functional operation condition limits.
At conditions exceeding absolute maximum and minimum ratings, neither functionality nor long-
term reliability can be expected. Moreover, if a device is subjected to these conditions for any
length of time then, when returned to conditions within the functional operating condition limits, it
will either not function, or its reliability will be severely degraded.
Although the processor contains protective circuitry to resist damage from static electric discharge,
precautions should always be taken to avoid high static voltages or electric fields.
Table 2-6. Absolute Maximum and Minimum Ratings
Symbol Parameter Min Max Unit Notes1,2
VCC Core voltage with respect to VSS -0.30 1.55 V
VTT System bus termination voltage with
respect to VSS -0.30 1.55 V
TCASE Processor case temperature See Section 6 See Section 6 °C
TSTORAGE Storage temperature -40 85 °C3,4
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 25
NOTES:
1. For functional operation, all processor electrical, signal quality, mechanical and thermal specifications must
be satisfied.
2. Overshoot and undershoot voltage guidelines for input, output, and I/O signals are outlined in Section 3.
Excessive overshoot or undershoot on any signal will likely result in permanent damage to the processor.
3. Storage temperature is applicable to storage conditions only . In this scenario, the processor must not receive
a clock, and no pins can be connected to a voltage bias. Storage within these limits will not affect the long-
term reliability of the device. For functional operation, please refer to the processor case temperature
specifications.
4. This rating applies to the processor and does not include any tray or packaging.
2.12 Processor DC Specifications
The processor DC specifications in this section are def ined at the pr ocessor cor e (pads) unless
noted otherwise. See Section 5 for the Dual-Core Intel Xeon processor pin listings and Section 4
for signal definitions. Voltage and current specifications are detailed in Table 2-7. For platfor m
power delivery planning refer to Table 2-8, which provides VCC static and transient tolerances.
This same information is presented graphically in Figure 2-4.
BSEL[1:0] an d VID[5:0] signals are specified in Table 2-10. The DC specifications for the AGTL+
signals are listed in Table 2-11. The DC specifications for the PWRGOOD input and TAP signal
group are listed in Table 2-12 and the Asynchronous GTL+ signal group is listed in Table 2-13. The
VIDPWRGD signal is detailed in Table 2-14.
Table 2-7 through Table 2-14 list the DC specifications for the processor and are valid only while
meeting specifications for case temperature (TCASE as specified in Section 6), clock frequency, and
input voltages. Care should be taken to read all notes associated with each parameter.
Table 2-7. Voltage and Current Specifications (Sheet 1 of 2)
Symbol Parameter Min Typ Max Unit Notes 1
VID range VID range 1.2875 1.4125 V 2,3
VCC VCC for processors with
multiple VIDs See Table 2-8
and
Figure 2-4
VID - ICC (max) * 1.25 mV 3,4,5,6
VID
Transition VID step size during a
transition ±12.5 mV 17
Total allowable DC load
line shift from VID steps 450 mV 18
VTT Front Side Bus
termination voltage
(DC specification)
1.176 1.20 1.224 V 7
ICC ICC for processors with
multiple VIDs 120 A 6
ICC_RESET ICC_RESET for processor
with multiple VIDs 120 A 16
ITT Front Side Bus
end-agent VTT current 4.8 A 9
ITT Front Side Bus
mid-agent VTT current 1.5 A 10
ICC_VCCA ICC for
PLL power pins 120 mA 11
ICC_VCCIOPLL ICC for
PLL power pins 100 mA 11
Electrical Specifications
26 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. Unless otherwise noted, all specifications in this table apply to all processors. These specifications are based
on silicon characteristics, however they may be updated as further data becomes available. List frequencies
are not necessarily committed production frequencies.
2. Each processor is programmed with a maximum valid voltage identification (VID) values, which is set at
manufacturing and can not be altered. Individual maximum VID values are calibrated during manufacturing
such that two processors at the same frequency may have different settings within the VID range. Please
note this differs from the VID employed by the processor during a power management event (Enhanced
HALT State).
3. These voltages are targets only. A variable voltage source should exist on systems in the event that a
different voltage is required. See Section 2.5 for more information.
4. The voltage specification requirements are measured across vias on the platform for the VCCSENSE and
VSSSENSE pins close to the socket with a 100 MHz bandwidth oscilloscope, 1.5 pF maximum probe
capacitance, and 1 M minimum impedance. The maximum length of ground wire on the probe should be
less than 5 mm. Ensure external noise from the system is not coupled in the scope probe.
5. Refer to Table 2-8 and corresponding Figure 2-4. The processor should not be subjected to any static VCC
level that exceeds the VCC_MAX associated with any particular current. Failure to adhere to this specification
can shorten processor lifetime.
6. Minimum VCC a nd maximum ICC are specified at the maximum processor case temperature (TCASE) shown
in Table 6-1. ICC_MAX is specified at the relative VCC_MAX point on the VCC load line. The processor is capable
of drawing ICC_MAX for up to 10 ms. Refer to Figure 2-3 for further details on the average processor current
draw over various time durations.
7. VTT must be provided via a separate voltage source and must not be connected to VCC. This specification is
measured at the pin.
8. Baseboard bandwidth is limited to 20 MHz.
9. This specification refers to a single processor with RTT enabled. Please note the end agent and middle agent
may not require ITT(max) simultaneously. This parameter is based on design characterization and not tested.
10.This specification refers to a single processor with RTT disabled. Please note the end agent and middle agent
may not require ITT(max) simultaneously.
11.These specifications apply to the PLL power pins VCCA, VCCIOPLL, and VSSA. See Section 2.4.2 for
details. These parameters are based on design characterization and are not tested.
12.This specification represents a total current for all GTLREF pins.
13.The current specified is also for HALT State.
14.The maximum instantaneous current the processor will draw wh ile the thermal control circuit is active as
indicated by the assertion of the PROCHOT# signal is the maximum ICC for the processor.
15.ICC_TDC (Thermal Design Current) is the sustained (DC equivalent) current that the processor is capable of
drawing indefinitely and should be used for the voltage regulator temperature assessment. The voltage
regulator is responsible for monitoring its temperature and asserting the necessary signal to inform the
processor of a thermal excursion. Please see the applicable design guidelines for further details. The
processor is capable of drawing ICC_TDC indefinitely. Refer to Figure 2-3 for further details on the average
processor craw over various time durations. This parameter is based on design characterization and is not
tested.
16.ICC_RESET is specified while PWRGOOD and RESET# are asserted.
17.This specification represents the VCC reduction due to each VID transition. See Section 2.5.
18.This specification refers to the potential total reduction of the load line due to VID transitions below the
specified VID.
ICC_GTLREF ICC for GTLREF pins 200 µA12
ISGNT
ISLP ICC Stop Grant 56 A 13
ITCC ICC TCC Active ICC A14
ICC_TDC Thermal Design
Current 105 A 15
Table 2-7. Voltage and Current Specifications (Sheet 2 of 2)
Symbol Parameter Min Typ Max Unit Notes 1
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 27
NOTES:
1. Processor or voltage regulator thermal protection circuitry should not trip for load currents greater than
ICC_TDC.
2. Not 100% tested. Specified by design characterization.
Figure 2-3. Dual-Core Intel® Xeon® Processor Load Current Vs. Time
VRM 10.1 Curr ent
100
105
110
115
120
125
0.01 0.1 1 10 100 1000
Time Duration (s)
Sustained Current (A)
Electrical Specifications
28 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. The VCC_MIN and VCC_MAX loadlines represent static and transient limits. Please see Section 2.12.1 for VCC
overshoot specifications.
2. This table is intended to aid in reading discrete points on Figure 2-4.
3. The loadlines specify voltage limits at the die measured at the VCCSENSE and VSSSENSE pins. Voltage
regulation feedback for voltage regulator circuits must be taken from processor VCC and VSS pins. Refer to
the Enterprise Voltage Regulator-Down (E VRD) 10.1 Design Guidelines for socket loadline guidelines and
VR implementation.
Table 2-8. VCC Static and Transient Tolerance
VCC_Max VCC_Typ VCC_Min
0 VID - 0.000 VID - 0.020 VID - 0.040
5 VID - 0.006 VID - 0.026 VID - 0.046
10 VID - 0.013 VID - 0.033 VID - 0.052
15 VID - 0.019 VID - 0.039 VID - 0.059
20 VID - 0.025 VID - 0.045 VID - 0.065
25 VID - 0.031 VID - 0.051 VID - 0.071
30 VID - 0.038 VID - 0.058 VID - 0.077
35 VID - 0.044 VID - 0.064 VID - 0.084
40 VID - 0.050 VID - 0.070 VID - 0.090
45 VID - 0.056 VID - 0.076 VID - 0.096
50 VID - 0.063 VID - 0.083 VID - 0.103
55 VID - 0.069 VID - 0.089 VID - 0.109
60 VID - 0.075 VID - 0.095 VID - 0.115
65 VID - 0.081 VID - 0.101 VID - 0.121
70 VID - 0.087 VID - 0.108 VID - 0.128
75 VID - 0.094 VID - 0.114 VID - 0.134
80 VID - 0.100 VID - 0.120 VID - 0.140
85 VID - 0.106 VID - 0.126 VID - 0.146
90 VID - 0.113 VID - 0.133 VID - 0.153
95 VID - 0.119 VID - 0.139 VID - 0.159
100 VID - 0.125 VID - 0.145 VID - 0.165
105 VID - 0.131 VID - 0.151 VID - 0.171
110 VID - 0.138 VID - 0.158 VID - 0.178
115 VID - 0.144 VID - 0.164 VID - 0.184
120 VID - 0.150 VID - 0.170 VID - 0.190
Voltage Deviation from VID Setting (V) 1,2,3
ICC
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 29
NOTES:
1. The VCC_MIN and VCC_MAX loadlines represent static and transient limits. Please see Section 2.12.1 for VCC
overshoot specifications.
2. The VCC_MIN and VCC_MAX loadlines are plots of the discrete point found in Table 2-8.
3. Refer to Table 2-7 for processor VID information.
4. The loadlines specify voltage limits at the die measured at the VCCSENSE and VSSSENSE pins. Voltage
regulation feedback for voltage regulator circuits must be taken from processor VCC and VSS pins. Refer to
the Enterprise Voltage Regulator-Down (EVRD) 10.1 Design Guidelines for socket loadline guidelines and
VR implementation.
2.12.1 VCC Overshoot Specification
The Dual-Core Intel Xeon processor can tolerat e s hort transient overshoot events where VCC
exceeds the VID voltage when transitioning from a high-to-low current load condition. This
overshoot cannot exceed VID + VOS_MAX. (VOS_MAX is the maximum allowable overshoot above
VID). These specifications apply to the processor die voltage as measured across the VCCSENSE
and VSSSENSE pins.
Figure 2- 4. VCC Static and Transient Tolerance
VID - 0.000
VID - 0.020
VID - 0.040
VID - 0.060
VID - 0.080
VID - 0.100
VID - 0.120
VID - 0.140
VID - 0.160
VID - 0.180
VID - 0.200
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100 105 110 115 120
Icc [A]
Vcc [V]
VCC
Typical
VCC
Maximum
VCC
Minimum
Table 2-9. VCC Overshoot Specifications
Symbol Parameter Min Max Units Figure Notes
VOS_MAX Magnitude of VCC
overshoot above VID 0.050 V 2-5
TOS_MAX Time duration of VCC
overshoot above VID 25 µs2-5
Electrical Specifications
30 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. VOS is measured overshoot voltage.
2. TOS is measured time duration above VID.
2.12.2 Die Voltage Validation
Overshoot events from application testing on processor must meet the specifications in Table 2-9
when measured across the VCCSENSE and VSSSENSE pins. Overshoot events that are < 10 ns in
duration may be ignored. These measurement of processor die level overshoot should be taken with
a 100 MHz bandwidth limited oscilloscope.
NOTES:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
2. These parameters are based on design characterization and are not tested.
3. Leakage to VSS with pin held at VTT.
4. Please refer to the appr opriate platform design guide for implementation details.
Figure 2-5. VCC Overshoot Example Waveform
Example Overs hoot Wa veform
0 5 10 15 20 25
Time [us]
Voltage [V]
VID - 0.000
VID + 0.050 VOS
TOS
TOS: Overshoot time above VID
VOS: Overshoot above VI D
Table 2-10. BSEL[1:0] and VID[5:0] Signal Group DC Specifications
Symbol Parameter Min Typ Max Units Notes1
RON BSEL[1:0] and VID[5:0]
Buffer On Resistance N/A 60 2
IOL Maximum Pin Current N/A 8 mA 2
ILO Output Leakage Current N/A 200 µA2,3
RPULL_UP Pull-Up Resistor 500 4
VTOL Voltage Tolerance 0.95 * VTT VTT 1.05 * VTT V4
Electrical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 31
NOTES:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
2. The VTT represented in these specifications refers to instantaneous VTT.
3. VIL is defined as the voltage range at a receiving agent that will be interpreted as a logical low value.
4. VIH is defined as the voltage range at a receiving agent that will be int erpreted as a logical high value.
5. VIH and VOH may experience excursions above VTT. However, input signal drivers must comply with the
signal quality specifications in Section 3.
6. Refer to Table 2-4 to determine which signals include additional on-die termination resistance (RL).
7. Leakage to V SS with pin held at VTT.
8. Leakage to V TT with pin held at 300 mV.
NOTES:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
2. All outputs are open drain.
3. VHYS represents the amount of hysteresis, nominally centered about 0.5 * VTT for all PWRGOOD and TAP
inputs.
4. The VTT represented in these specifications refers to instantaneous VTT.
5. PWRGOOD input and the TAP signal group must meet system signal quality specification in Section 3.
6. The maximum output current is based on maximum current handling capability of the buffer and is not
specified into the test load.
Table 2-11. AGTL+ Signal Group DC Specifications
Symbol Parameter Min Max Unit Notes1
VIL Input Low Voltage 0.0 GTLREF - (0.10 * VTT)V2,3
VIH Input High Voltage GTLREF + (0.10 * VTT)V
TT V 2,4,5
VOH Output High Voltage 0.90 * VTT VTT V2,5
IOL Output Low Current N/A VTT /
(0.50 * RTT_MIN +
[RON_MIN || RL])
mA 2,6
ILI Input Leakage Current N/A ± 200 µA 7,8
ILO Output Leakage
Current N/A ± 200 µA 7,8
RON Buffer On Resistance 4 8
Table 2-12. PWRGOOD Input and TAP Signal Group DC Specifications
Symbol Parameter Min Max Unit Notes
1,2,5
VHYS Input Hysteresis 200 350 mV 3
Vt+ Input Low to High
Threshold Voltage 0.5 * (VTT + VHYS_MIN) 0.5 * (VTT + VHYS_MAX)V 4
Vt- Input High to Low
Threshold Voltage 0.5 * (VTT - VHYS_MAX) 0.5 * (VTT - VHYS_MIN)V 4
VOH Output High Voltage N/A VTT V4
IOL Output Low Current 45 mA 6
ILI Input Leakage Current N/A ± 200 µA
ILO Output Leakage Current N/A ± 200 µA
RON Buffer On Resistance 4 8
Electrical Specifications
32 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
2. The VTT represented in these specifications refers to instantaneous VTT.
3. VIL is defined as the voltage range at a receiving agent that will be interpreted as a logical low value.
4. VIH is defined as the voltage range at a receiving agent that will be interpreted as a logical high value.
5. VIH and VOH may experience excursions above VTT. However, input signal drivers must comply with the
signal quality specifications in Section 3.
6. Refer to Table 2-5 to determine which signals include additional on-die termination resistance (RL).
7. Leakage to VSS with pin held at VTT.
8. Leakage to VTT with pin held at 300 mV.
§
Table 2-13. GTL+ Asynchronous and AGTL+ Asynchronous Signal Group DC
Specifications
Symbol Parameter Min Max Unit Notes1
VIL Input Low Voltage 0.0 GTLREF - (0.10 * VTT)V2,3
VIH Input High Voltage GTLREF + (0.10 * VTT)V
TT V 2,4,5
VOH Output High Voltage 0.90 * VTT VTT V2,5
IOL Output Low Current N/A VTT /
(0.50 * RTT_MIN + [RON_MIN || RL]) mA 2,6
ILI Input Leakage Current N/A ± 200 µA 7,8
ILO Output Leakage
Current N/A ± 200 µA 7,8
Ron Buffer On Resistance 4 8
Table 2-14. VIDPWRGD DC Specifications
Symbol Parameter Min Max Unit Notes
VIL Input Low Voltage 0.0 0.30 V
VIH Input High Voltage 0.90 VTT V
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 33
3Mechanical Specifications
The Dual-Core Intel Xeon processor is packaged in Flip Chip Micro Pin Grid Array (FC-mPGA4)
package that interfaces to the baseboard via an mPGA604 socket. The package consists of a
processor core mounted on a substrate pin-carrier. An integrated heat spreader (IHS) is attached to
the package substrate and core and serves as the mating surface for processor component thermal
solutions, such as a heatsink. Figure 3-1 shows a sketch of the processor package components and
how they are assembled together. Refer to the mPGA604 Socket Desi gn Guidelines for complete
details on the mPGA604 socket.
The package components shown in Figure 3-1 include the following:
1. Integrated Heat Spreader (IHS)
2. Processor Die
3. Substrate
4. Pin Si de Capaci t ors
5. Package Pin
6. Die Side Capacitors
Note: This drawing is not to scale and is for reference only. The mPGA604 socket is not shown.
Figure 3-1. Processor Package Assembly Sketch
1
3
5
4
6
2
1
3
5
4
6
2
Mechanical Specifications
34 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
3.1 Package Mechanical Drawings
The package mechanical drawings are shown in Figure 3-2 and Figure 3-3. The drawings include
dimensions necessary to design a thermal solution for the processor. These dimensions include:
1. Package reference and tolerance dimensions (total height, length, width, etc.)
2. IHS parallelism and tilt
3. Pin dimensions
4. Top-side and back-side component keepout dim e nsions
5. Reference datums
All drawing dimensions are in m m [i n.].
Mechanical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 35
Figure 3-2. Processor Package Drawing (Sheet 1 of 2)
Mechanical Specifications
36 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 3-3. Processor Package Drawing (Sheet 2 of 2)
Mechanical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 37
3.2 Processor Component Keepout Zones
The processor may contain components on the substrate that define component keepout zone
requirements. A thermal and mechanical solution design must not intrude into the required keepout
zones. Decoupling capacitors are typically mounted to either the topside or pin-side of the package
substrate. See Figure 3-3 for keepout zones.
3.3 Package Loading Specifications
Table 3-1 provides dynamic and static load specifications for the processor package. These
mechanical load limits should not be exceeded during heatsink assembly, mechanical stress testing
or standard drop and shipping conditio ns. The heatsink attach solutions must not include
continuous stress onto the processor with the exception of a uniform load to maintain the heatsink-
to-processor thermal interface. Also, any mechanical system or component tes ting should not
exceed these limits. The processor package substrate should not be used as a mechanical reference
or load-bear ing surface for thermal or mechanical solutions.
NOTES:
1. These specifications apply to uniform compressive loading in a direction perpendicular to the IHS top
surface.
2. This is the minimum and maximum static force that can be applied by the heatsink and retention solution to
maintain the heatsink and processor interface.
3. These specifications are based on limited testing for design characterization. Loading limits are for the
package only and do not include the limits of the processor socket.
4. This specification applies for thermal retention solutions that allow baseboard deflection.
5. This specification applies either for thermal retention solutions that prevent baseboard deflection or for the
Intel enabled reference solution (CEK).
6. Dynamic loading is defined as an 11 ms duration average load superimposed on the static load requirement.
7. Experimentally validated test condition used a heatsink mass of 1 lbm (~0.45 kg) with 100 G acceleration
measured at heat sink mass. The dynamic portion of this specification in the product application can have
flexibility in specific values, but the ultimate product of mass times acceleration should not exceed this
validated dynamic load (1 lbm x 100 G = 100 lb). Allowable strain in the dynamic compressive load
specification is in addition to the strain allowed in static loading.
8. Transient loading is defined as a 2 second duration peak load superimposed on the static load requirement,
representative of loads experienced by the package during heatsink installation.
Table 3-1. Processor Loading Specifications
Parameter Min Max Unit Notes
Static
Compressive Load 44
10 222
50 N
lbf 1,2,3,4
44
10 288
65 N
lbf 1,2,3,5
Dynamic
Compressive Load NA
NA 222 N + 0.45 kg *100 G
50 lbf (static) + 1 lbm * 100 G N
lbf 1,3,4,6,7
NA
NA 288 N + 0.45 kg * 100 G
65 lbf (static) + 1 lbm * 100 G N
lbf 1,3,5,6,7
Transient NA 445
100 N
lbf 1,3,8
Mechanical Specifications
38 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
3.4 Package Handling Guidelines
Table 3-2 includes a list of guidelines on a package handling in terms of recommended maximu m
loading on the processor IHS relative to a fixed substrate. These package handling loads may be
experienced during heatsink removal.
NOTES:
1. A shear load is defined as a load applied to the IHS in a direction parallel to the IHS top surface.
2. A tensile load is defined as a pulling load applied to the IHS in a direction normal to the IHS surface.
3. A torque load is defined as a twisting load applied to the IHS in an axis of rotation normal to the IHS top
surface.
4. These guidelines are based on limited testing for design characterization and incidental applications (one
time only).
5. Handling guidelines are for the package only and do not include the limits of the processor socket.
3.5 Package Insertion Specifications
The Dual-Core Intel Xeon processor can be inserted and removed 15 times from an mPGA 604
socket, which meets the criteria outlined in the mPGA604 Socket Design Guidelines.
3.6 Processor Mass Specifications
The typical mass of the Dual-Core Intel Xeon processor is approximately 35.750 grams. This mass
[weight] includes all components which make up the entire processor product.
3.7 Processor Materials
The Dual-Core Intel Xeon processor is assembled from several components. The basic material
properties are described in Table 3-3.
Table 3-2. Package Handling Guidelines
Parameter Maximum Recommended Notes
Shear 356 N
80 lbf 1,4,5
Tensile 156 N
35 lbf 2,4,5
Torque 8 N-m
70 lbf-in 3,4,5
Table 3-3. Processor Materials
Component Material
Integrated Heat Spreader (IHS) Nickel Plated Copper
Substrate Fiber-Reinforced Resin
Substrate Pins Gold Plated Copper
Mechanical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 39
3.8 Processor Markings
Figure 3-4 shows the to pside m a rkings and Figure 3-5 shows the bottom-side markings on the
processor. These diagrams are to aid in the identification of the Dual-Core Intel Xeon processor.
NOTES:
1. All characters will be in upper case.
2. Drawing is not to scale.
NOTES:
1. All characters will be in upper case.
2. Drawing is not to scale.
Figure 3-4. Processor Top-Side Markings (Example)
Processor N am e
i(m) ©04
2D Matrix
Includes ATPO and Serial
Num ber (front end m ark)
Pin 1 Indicator
ATPO
Serial N um ber
Processor N am e
i(m) ©’04
2D Matrix
Includes ATPO and Serial
Num ber (front end m ark)
Pin 1 Indicator
ATPO
Serial N um ber
Figure 3-5. Processor Bottom-S ide Markings (Example)
2800DP/4MB/800/1.350V
SL6NY COSTA RICA
C0096109-0021
Speed / Cache / Bus / Voltage
S-Spec
Country of Assy
FPO Serial #
(13 Characters)
Pin Fie ld
Cavity
with
Components
Text Line1
Text Line2
Text Line3
Pin 1 Indicator
2800DP/4MB/800/1.350V
SL6NY COSTA RICA
C0096109-0021
Speed / Cache / Bus / Voltage
S-Spec
Country of Assy
FPO Serial #
(13 Characters)
Pin Fie ld
Cavity
with
Components
Text Line1
Text Line2
Text Line3
Pin 1 Indicator
Mechanical Specifications
40 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
3.9 Processor Pin-Out Coordinates
Figure 3-6 and Figure 3-7 show the top and bottom view of the processor pin coordinates,
respectively. The coordinates are referred to throug hou t the document to identify processor pins.
Figure 3-6. Processor Pin-out Coordinates, Top View
Vcc/Vss
ADDRESS
DATA
Vcc/Vss
CLOCKS
COMMON
CLOCK COMMON
CLOCK Async /
JTAG
Top View
= Signal
= Power
= Ground = Reserved/N o C onne ct
A
C
E
G
J
L
N
R
U
W
AA
AC
AE
B
D
F
H
K
M
P
T
V
Y
AB
AD
3 5 7 9 11 13 15 17 19 21 23 25 27 29 311
= GTLR E F
= VCC_3 .3
A
C
E
G
J
L
N
R
U
W
AA
AC
AE
B
D
F
H
K
M
P
T
V
Y
AB
AD
2 4 6 8 10 12 14 16 18 20 22 24 26 28 30
Dual Core
Intel® Xeon™
Processor
Dual-Core
Intel® Xeon®
Processor
Mechanical Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 41
§
Figure 3-7. Processor Pin-out Coordinates, Bottom View
Vcc/Vss
ADDRESS
DATA
Vcc/Vss
CLOCKS
COMMON
CLOCK
COMMON
CLOCK
Async /
JTAG
Bottom View
= Signal
= Power
= Ground = Reserved/N o C onne ct
A
C
E
G
J
L
N
R
U
W
AA
AC
AE
B
D
F
H
K
M
P
T
V
Y
AB
AD
357911131517192123252729 131
= GTLR E F
= VCC_VID
A
C
E
G
J
L
N
R
U
W
AA
AC
AE
B
D
F
H
K
M
P
T
V
Y
AB
AD
246810121416182022242628
30
Dual Core
Intel® Xeon™
Processor
Dual-Core
Intel® Xeon®
Processor
Mechanical Specifications
42 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 43
4 Signal Definitions
4.1 Signal Definitions
Table 4-1. Signal Definitions (Sheet 1 of 10)
Name Type Description Notes
A[35:3]# I/O A[35:3]# (Address) define a 236-byte physical memory address space. In
sub-phase 1 of the address phase, these pins transmit the address of a
transaction. In sub-phase 2, these pins transmit transaction type
information. These signals must connect the appropriate pins of all agents
on the front side bus. A[35:3]# are protected by parity signals AP[1:0]#.
A[35:3]# are source synchronous signals and are latched into the receiving
buffers by ADSTB[1:0]#.
On the active-to-inactive transition of RESET#, the processors sample a
subset of the A[35:3]# pins to determine their power-on configuration. See
Section 7.1.
3
A20M# I If A20M# (Address-20 Mask) is asserted, the processor masks physical
address bit 20 (A20#) before looking up a line in any internal cache and
before driving a read/write transaction on the bus. Asserting A20M#
emulates the 8086 processor's address wrap-around at the 1 MB
boundary. Assertion of A20M# is only supported in real mode.
A20M# is an asynchronous signal. However, to ensure recognition of this
signal following an I/O write instruction, it must be valid along with the
TRDY# assertion of the corresponding I/O write bus transaction.
2
ADS# I/O ADS# (Address Strobe) is asserted to indicate the validity of the
transaction address on the A[35:3]# 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. This signal must connect the appropriate pins on all (800
MHz) front side bus agents.
3
ADSTB[1:0]# I/O Address strobes are used to latch A[35:3]# and REQ[4:0]# on their rising
and falling edge. Strobes are associated with signals as shown below. 3
AP[1:0]# I/O AP[1:0]# (Address Parity) are driven by the request initiator along with
ADS#, A[35:3]#, and the transaction type on the REQ[4:0]# pins. 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. AP[1:0]# should connect the
appropriate pins of all Dual-Core Intel® Xeon® processor front side bus
agents. The following table defines the coverage model of these signals.
3
Signals Associated Strobes
REQ[4:0]#, A[16:3]# ADSTB0#
A[35:17]# ADSTB1#
Request Signals Subphase 1 Subphase 2
A[35:24]# AP0# AP1#
A[23:3]# AP1# AP0#
REQ[4:0]# AP1# AP0#
Signal Definitions
44 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
BCLK[1:0] I The differential bus clock pair BCLK[1:0] determines the front side bus
frequency. All processor front side bus agents must receive these signals
to drive their outputs and latch their inputs.
All external timing parameters are specified with respect to the rising edge
of BCLK0 crossing VCROSS.
3
BINIT# I/O BINIT# (Bus Initialization) may be observed and driven by all processor
front side bus agents and if used, must connect the appropriate pins of all
such agents. If the BINIT# driver is enabled during power on configuration,
BINIT# is asserted to signal any bus condition that prevents reliable future
information.
If BINIT# observation is enabled during power-on configuration (see
Figure 7.1) and BINIT# is sampled asserted, symmetric agents reset their
bus LOCK# activity and bus request arbitration state machines. The bus
agents do not reset their I/O Queue (IOQ) and transaction tracking state
machines upon observation of BINIT# assertion. Once the BINIT#
assertion has been observed, the bus agents will re-arbitrate for the front
side bus and attempt completion of their bus queue and IOQ entries.
If BINIT# observation is disabled during power-on configuration, a central
agent may handle an assertion of BINIT# as appropriate to the error
handling architecture of the system.
Since multiple agents may drive this signal at the same time, BINIT# is a
wired-OR signal which must connect the appropriate pins of all processor
front side bus agents. In order to avoid wired-OR glitches associated with
simultaneous edge transitions driven by multiple drivers, BINIT# is
activated on specific clock edges and sampled on specific clock edges
3
BNR# I/O BNR# (Block Next Request) is used to assert a bus stall by any bus agent
who is unable to accept new bus transactions. 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 which must connect the appropriate pins of all
processor front side bus agents. In order to avoid wired-OR glitches
associated with simultaneous edge transitions driven by multiple drivers,
BNR# is activated on specific clock edges and sampled on specific clock
edges.
3
BOOT_
SELECT I The BOOT_SELECT input informs the processor whether the platform
supports the Dual-Core Intel® Xeon® processor. The processor will not
operate if this signal is low. This input has a weak pull-up to VTT.
BPM[5:0]# I/O BPM[5:0]# (Breakpoint Monitor) are breakpoint and performance monitor
signals. They are outputs from the processor which indicate the status of
breakpoints and programmable counters used for monitoring processor
performance. BPM[5:0]# should connect the appropriate pins of all front
side bus agents.
BPM4# provides PRDY# (Probe Ready) functionality for the TAP port.
PRDY# is a processor output used by debug tools to determine processor
debug readiness.
BPM5# provides PREQ# (Probe Request) functionality for the TAP port.
PREQ# is used by debug tools to request debug operation of the
processors.
BPM[5:4]# must be bussed to all bus agents. Please refer to the
appropriate platform design guidelines for more detailed information.
These signals do not have on-die termination and must be terminated
at the end agent. See the appropriate platform design guideline for
additional information.
2
Table 4-1. Signal Definitions (Sheet 2 of 10)
Name Type Description Notes
Signal Definitions
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 45
BPRI# I BPRI# (Bus Priority Request) is used to arbitrate for ownership of the
processor front side bus. It must connect the appropriate pins of all
processor front side bus agents. Observing BPRI# active (as asserted by
the priority agent) causes all other agen ts 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#.
3
BR0#
BR[1:3]# I/O
IBR[1:0]# (Bus Request) drive the BREQ[1:0]# signals in the system. The
BREQ[1:0]# signals are interconnected in a rotating manner to individual
processor pins. BR[3:2}# are connected between the two processor
sockets and require termination. The tables below give the rotating
interconnect between the processor and bus signals for 2-way systems.
During power-on configuration, the central agent must assert the BREQ0#
bus signal. All symmetric agents sample their BR[3:0]# pins on the active-
to-inactive transition of RESET#. The pin which the agent samples
asserted determines its agent ID.
These signals do not have on-die termination and must be
terminated.
3
BSEL[1:0] O The BCLK[1:0] frequency select signals BSEL[1:0] are used to select the
processor input clock frequency. Table 2-1 defines the possible
combinations of the signals and the frequency associated with each
combination. The required frequency is determined by the processors,
chipset, and clock synthesizer. All front side bus agents must operate at
the same frequency. The Dual-Core Intel Xeon processor currently
operates at a 800 MHz front side bus frequency (200 MHz BCLK[1:0]
frequency). For more information about these pins, including termination
recommendations, refer to the appropriate platform design guideline.
COMP[0] I COMP[0] must be terminated to VSS on the baseboard using precision
resistors. These inputs configure the GTL+ drivers of the processor. Refer
to the appropriate platform design guidelines for implementation details.
Table 4-1. Signal Definitions (Sheet 3 of 10)
Name Type Description Notes
BR[3:0]# Signals Rotating Interconnect, 2-way system
Bus Signal Agent 0 Pins Agent 1 Pins
BREQ0# BR0# BR1#
BREQ1# BR1# BR0#
BR2# BR3#
BR3# BR2#
Signal Definitions
46 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
D[63:0]# I/O D[63:0]# (Data) are the data signals. These signals provide a 64-bit data
path between the processor front side bus agents, and must connect the
appropriate pins on all such agents. The data driver asserts DRDY# to
indicate a valid data transfer.
D[63:0]# are quad-pumped signals, and will thus be driven four times in a
common clock period. D[63:0]# are latched off the falling edge of both
DSTBP[3:0]# and DSTBN[3:0]#. Each group of 16 data signals correspond
to a pair of one DSTBP# and one DSTBN#. The following table shows the
grouping of data signals to strobes and DBI#.
Furthermore, the DBI# pins determine the polarity of the data signals. Each
group of 16 data signals corresponds to one DBI# signal. When the DBI#
signal is active, the corresponding data group is inverted and therefore
sampled active high.
3
DBI[3:0]# I/O DBI[3:0]# are source synchronous and indicate the polarity of the D[63:0]#
signals. The DBI[3:0]# signals are activated when the data on the data bus
is inverted. If more than half the data bits, within a 16-bit group, would have
been asserted electronically low, the bus agent may invert the data bus
signals for that particular sub-phase for that 16-bit group.
3
DBSY# I/O DBSY# (Data Bus Busy) is asserted by the agent responsible for driving
data on the processor front side bus to indicate that the data bus is in use.
The data bus is released after DBSY# is deasserted. This signal must
connect the appropriate pins on all processor front side bus agents.
3
DEFER# I DEFER# is asserted by an agent to indicate that a transaction cannot be
guaranteed in-order completion. Assertion of DEFER# is normally the
responsibility of the addressed memory or I/O agent. This signal must
connect the appropriate pins of all processor front side bus agents.
3
DP[3:0]# I/O DP[3:0]# (Data Parity) provide parity protection for the D[63:0]# signals.
They are driven by the agent responsible for driving D[63:0]#, and must
connect the appropriate pins of all processor front side bus agents.
3
DRDY# I/O DRDY# (Data Ready) is asserted by the data driver on each data transfer,
indicating valid data on the data bus. In a multi-common clock data
transfer, DRDY# may be deasserted to insert idle clocks. This signal must
connect the appropriate pins of all processor front side bus agents.
3
Table 4-1. Signal Definitions (Sheet 4 of 10)
Name Type Description Notes
Data Group DSTBN#/
DSTBP# DBI#
D[15:0]# 0 0
D[31:16]# 1 1
D[47:32]# 2 2
D[63:48]# 3 3
DBI[3:0] Assignment To Data Bus
Bus Signal Data Bus Signals
DBI0# D[15:0]#
DBI1# D[31:16]#
DBI2# D[47:32]#
DBI3# D[63:48]#
Signal Definitions
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 47
DSTBN[3:0]# I/O Data strobe used to latch in D[63:0]#. 3
DSTBP[3:0]# I/O Data strobe used to latch in D[63:0]#. 3
FERR#/PBE# O FERR#/PBE# (floating-point error/pending break event) is a multiplexed
signal and its meaning is qualified by STPCLK#. When STPCLK# is not
asserted, FERR#/PBE# indicates a floating-point error and will be asserted
when the processor detects an unmasked floating-point error. When
STPCLK# is not asserted, FERR#/PBE# is similar to the ERROR# signal
on the Intel 387 coprocessor , and is included for compatibility with systems
using MS-DOS*-type floating-point error reporting. When STPCLK# is
asserted, an assertion of FERR#/PBE# indicates that the processor has a
pending break event waiting for service. The assertion of FERR#/PBE#
indicates that the processor should be returned to the Normal state. For
additional information on the pending break event functionality, including
the identification of support of the feature and enable/disable information,
refer to V ol. 3 of the IA-32 Intel® Architecture Software Developer’s Manual
and the AP-485 Intel® Processor Identification and the CPUID Instruction
application note.
This signal does not have on-die termination and must be terminated
at the end agent. See the appropriate platform design guideline for
additional informatio n.
3
FORCEPR# I The FORCEPR# input can be used by the platform to force the Dual-Core
Intel Xeon processor to activate the Thermal Control Circuit (TCC). The
TCC will remain active until the system deasserts FORCEPR#.
GTLREF I GTLREF determines the signal reference level for GTL+ input pins.
GTLREF is used by the GTL+ receivers to determine if a signal is a logical
0 or a logical 1.
HIT#
HITM# I/O
I/O HIT# (Snoop Hit) and HITM# (Hit Modified) convey transaction snoop
operation results. Any front side bus agent may assert both HIT# and
HITM# together to indicate that it requires a snoop stall, which can be
continued by reasserting HIT# and HITM# together.
Since multiple agents may deliver snoop results at the same time, HIT#
and HITM# are wired-OR signals which must connect the appropriate pins
of all processor front side bus agents. In order to avoid wired-OR glitches
associated with simultaneous edge transitions driven by multiple drivers,
HIT# and HITM# are activated on specific clock edges and sampled on
specific clock edges.
3
Table 4-1. Signal Definitions (Sheet 5 of 10)
Name Type Description Notes
Signals Associated Strobes
D[15:0]#, DBI0# DSTBN0#
D[31:16]#, DBI1# DSTBN1#
D[47:32]#, DBI2# DSTBN2#
D[63:48]#, DBI3# DSTBN3#
Signals Associated Strobes
D[15:0]#, DBI0# DST BP0#
D[31:16]#, DBI1# DSTBP1#
D[47:32]#, DBI2# DSTBP2#
D[63:48]#, DBI3# DSTBP3#
Signal Definitions
48 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
IERR# O IERR# (Internal Error) is asserted by a processor as the result of an
internal error. Assertion of IERR# is usually accompanied by a
SHUTDOWN transaction on the processor front side bus. This transaction
may optionally be converted to an external error signal (e.g., NMI) by
system core logic. The processor will keep IERR# asserted until the
assertion of RESET#.
This signal does not have on-die termination and must be terminated
at the end agent. See the appropriate platform design guideline for
additional information.
2
IGNNE# I IGNNE# (Ignore Numeric Error) is asserted to force the processor to ignore
a numeric error and continue to execute noncontrol floating-point
instructions. If IGNNE# is deasserted, the processor generates an
exception on a noncontrol floating-point instruction if a previous floating-
point instruction caused an error . IGNNE# has no effect when the NE bit in
control register 0 (CR0) is set.
IGNNE# is an asynchronous signal. However, to ensure recognition of this
signal following an I/O write instruction, it must be valid along with the
TRDY# assertion of the corresponding I/O write bus transaction.
2
INIT# I INIT# (Initialization), when asserted, resets integer registers inside all
processors without affecting their internal caches or floating-point registers.
Each processor then begins execution at the power-on Reset vector
configured during power-on configuration. The processor continues to
handle snoop requests during INIT# assertion. INIT# is an asynchronous
signal and must connect the appropriate pins of all processor front side bus
agents.
If INIT# is sampled active on the active to inactive transition of RESET#,
then the processor executes its Built-in Self-Test (BIST).
2
LINT[1:0] I LINT[1:0] (Local APIC Interrupt) must connect the appropriate pins of all
front side bus agents. When the APIC functionality is disabled, the LINT0/
INTR signal becomes INTR, a maskable interrupt request signal, and
LINT1/NMI becomes NMI, a nonmaskable interrupt. INTR and NMI are
backward compatible with the signals of those names on the Pentium®
processor. Both signals are asynchronous.
These signals must be software configured via BIOS programming of the
APIC register space to be used either as NMI/INTR or LINT[1:0]. Because
the APIC is enabled by default after Reset, operation of these pins as
LINT[1:0] is the default configuration.
2
LOCK# I/O LOCK# indicates to the system that a transaction must occur atomically.
This signal must connect the appropriate pins of all processor front side
bus agents. For a locked sequence of transactions, LOCK# is asserted
from the beginning of the first transaction to the end of the last transaction.
When the priority agent asserts BPRI# to arbitrate for ownership of the
processor front side bus, it will wait until it observes LOCK# deasserted.
This enables symmetric agents to retain ownership of the processor front
side bus throughout the bus locked operation and ensure the atomicity of
lock.
3
Table 4-1. Signal Definitions (Sheet 6 of 10)
Name Type Description Notes
Signal Definitions
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 49
MCERR# I/O MCERR# (Machine Check Error) is asserted to indicate an unrecoverable
error without a bus protocol violation. It may be driven by all processor front
side bus agents.
MCERR# assertion conditions are configurable at a system level.
Assertion options are defined by the following options:
Enabled or disabled.
Asserted, if configured, for internal errors along with IERR#.
Asserted, if configured, by the request initiator of a bus transaction
after it observes an error.
Asserted by any bus agent when it observes an error in a bus
transaction.
For more details regarding machine check architecture, refer to the IA-32
Intel® Architecture Software Developer’s Manual, Volume 3: System
Programming Guide.
Since multiple agents may drive this signal at the same time, MCERR# is a
wired-OR signal which must connect the appropriate pins of all processor
front side bus agents. In order to avoid wired-OR glitches associated with
simultaneous edge transitions driven by multiple drivers, MCERR# is
activated on specific clock edges and sampled on specific clock edges.
ODTEN I ODTEN (On-die termination enable) should be connected to VTT to enable
on-die termination for end bus agents. For middle bus agents, pull this
signal down via a resistor to ground to disable on-die termination.
Whenever ODTEN is high, on-die termination will be active, regardless of
other states of the bus.
OPTIMIZED/
COMPAT# I This is an input pin to the processor to determine if the processor is in an
optimized platform or a compatible platform. This signal does includes a
weak on-die pull-up to VTT.
PROCHOT# O PROCHOT# (Processor Hot) will go active when the processor
temperature monitoring sensor detects that the processor die temperature
has reached its factory configured trip point. This indicates that the
processor Thermal Control Circuit (TCC) has been activated, if enabled.
See Section 6.2.3 for more details.
PWRGOOD I PWRGOOD (Power Good) is an input. The processor requires this signal
to be a clean indication that all processor clocks and power supplies are
stable and within their specifications. “Clean” implies that the signal will
remain low (capable of sinking leakage current), without glitches, from the
time that the power supplies are turned on until they come within
specification. The signal must then transition monotonically to a high st ate.
PWRGOOD can be driven inactive at any time, but clocks and power must
again be stable before a subsequent rising edge of PWRGOOD. It must
also meet the minimum pulse width specification in Table 2-13, and be
followed by a 1-10 ms RESET# pulse.
The PWRGOOD signal must be supplied to the processor; it is used to
protect internal circuits against voltage sequencing issues. It should be
driven high throughout boundary scan operation.
2
REQ[4:0]# I/O REQ[4:0]# (Request Command) must connect the appropriate pins of all
processor front side bus agents. They are asserted by the current bus
owner to define the currently active transaction type. These signals are
source synchronous to ADSTB[1:0]#. Refer to the AP[1:0]# signal
description for details on parity checking of these signals.
3
Table 4-1. Signal Definitions (Sheet 7 of 10)
Name Type Description Notes
Signal Definitions
50 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
RESET# I Asserting the RESET# signal resets all processors to known states and
invalidates their internal caches without writing back any of their contents.
For a power-on Reset, RESET# must stay active for at least 1 ms after VCC
and BCLK have reached their proper specifications. On observing active
RESET#, all front side bus agents will deassert their outputs within two
clocks. RESET# must not be kept asserted for more than 10 ms while
PWRGOOD is asserted.
A number of bus signals are sampled at the active-to-inactive transition of
RESET# for power-on configuration. These configuration options are
described in the Section 7.1.
This signal does not have on-die termination and must be terminated
at the end agent. See the appropriate platform design guideline for
additional information.
3
RS[2:0]# I RS[2:0]# (Response Status) are driven by the response agent (the agent
responsible for completion of the current transaction), and must connect
the appropriate pins of all processor front side bus agents.
3
RSP# I RSP# (Response Parity) is driven by the response agent (the agent
responsible for completion of the current transaction) during assert ion of
RS[2:0]#, the signals for which RSP# provides parity protection. It must
connect to the appropriate pins of all processor front side bus agents.
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 . While RS[2:0]# = 000,
RSP# is also high, since this indicates it is not being driven by any agent
guaranteeing correct parity.
3
SKTOCC# O SKTOCC# (Socket occupied) will be pulled to ground by the processor to
indicate that the processor is present. There is no connection to the
processor silicon for this signal.
SLP# I SLP# (Sleep), when asserted in Stop-Grant state, causes processors to
enter the Sleep state. During Sleep state, the processor stops providing
internal clock signals to all units, leaving only the Phase-Lock Loop (PLL)
still operating. Processors in this state will not recognize snoops or
interrupts. The processor will only recognize the assertion of the RESET#
signal, deassertion of SLP#, and removal of the BCLK input while in Sleep
state. If SLP# is deasserted, the processor exits Sleep state and returns to
Stop-Grant state, restarting its internal clock signals to the bus and
processor core units.
2
SMB_PRT O The SMBus present (SMB_PRT) pin is defined to inform the plat form if the
installed processor includes SMBus components such as the integrated
thermal sensor and the processor information ROM (PIROM). This pin is
tied to VSS by the processor if these features are not present. Platforms
utilizing this pin should use a pull up resistor to the appropriate voltage
level for the logic tied to this pin. Because this pin does not connect to the
processor silicon, any platform voltage and termination value is acceptable.
SMI# I SMI# (System Management Interrupt) is asserted asynchronously by
system logic. On accepting a System Management Interrupt, processors
save the current state and enter System Management Mode (SMM). An
SMI Acknowledge transaction is issued, and the processor begins program
execution from the SMM handler.
If SMI# is asserted during the deassertion of RESET# the processor will tri-
state its outputs.
2
STPCLK# I STPCLK# (Stop Clock), when asserted, causes processors to enter a low
power Stop-Grant state. The processor issues a Stop-Grant Acknowledge
transaction, and stops providing internal clock signals to all processor core
units except the front side bus and APIC unit s . The processor continues to
snoop bus transactions and service interrupts while in Stop-Grant state.
When STPCLK# is deasserted, the processor restarts its internal clock to
all units and resumes execution. The assertion of STPCLK# has no effect
on the bus clock; STPCLK# is an asynchronous input.
2
Table 4-1. Signal Definitions (Sheet 8 of 10)
Name Type Description Notes
Signal Definitions
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 51
TCK I TCK (Test Clock) provides the clock input for the processor Test Bus (also
known as the Test Access Port).
TDI I TDI (Test Data In) transfers serial test data into the processor. TDI provides
the serial input needed for JTAG specification support.
TDO O TDO (Test Data Out) transfers serial test data out of the processor. TDO
provides the serial output needed for JTAG specification support .
TEST_BUS I Must be connected to all other processor TEST_BUS signals in the
system. See the appropriate platform design guide for termination details.
TESTHI[6:0] I All TESTHI inputs should be individually connected to VTT via a pull-up
resistor which matches the trace impedance. TESTHI[3:0] and
TESTHI[6:5] may all be tied together and pulled up to VTT with a single
resistor if desired. However, utilization of boundary scan test will not be
functional if these pins are connected together. TESTHI4 must always be
pulled up independently from the other TESTHI pins. For optimum noise
margin, all pull-up resistor values used for TESTHI[6:0] should have a
resistance value within ± 20% of the impedance of the baseboard
transmission line traces. For example, if the trace impedance is 50 , than
a value between 40 and 60 should be used.
THERMDA Other Thermal Diode Anode. See Section 6.2.7.
THERMDC Other Thermal Diode Cathode. See Section 6.2.7.
THERMTRIP# O Assertion of THERMTRIP# (Thermal Trip) indicates the processor junction
temperature has reached a temper ature beyond which permanent silicon
damage may occur. Measurement of the temperature is accomplished
through an internal thermal sensor. Upon assertion of THERMTRIP#, the
processor will shut off its internal clocks (thus halting program execution) in
an attempt to reduce the processor junction temperature. To protect the
processor its core voltage (VCC) must be removed following the assertion
of THERMTRIP#.
Driving of the THERMTRIP# signals is enabled within 10 ms of the
assertion of PWRGOOD and is disabled on de-assertion of PWRGOOD.
Once activated, THERMTRIP# remains latched until PWRGOOD is de-
asserted. While the de-assertion of the PWRGOOD signal will de-assert
THERMTRIP#, if the processor’s junction temperature remains at or above
the trip level, THERMTRIP# will again be asserted within 10 ms of the
assertion of PWRGOOD.
1
TMS I TMS ( Test Mode Select) is a JTAG specification support signal used by
debug tools.
This signal does not have on-die termination and must be terminated
at the end agent.
TRDY# I TRDY# (Target Ready) is asserted by the target to indicate that it is ready
to receive a write or implicit writeback data transfer. TRDY# must connect
the appropriate pins of all front side bus agents.
TRST# I TRST# (Test Reset) resets the Test Access Port (TAP) logic. TRST# must
be driven low during power on Reset.
VCCA IV
CCA provides isolated power for the analog portion of the internal
processor core PLL’s. Refer to the appropriate platform design guidelines
for complete implementation details.
VCCIOPLL IV
CCIOPLL provides isolated power for digital portion of the internal
processor core PLL’s. Refer to the appropriate platform design guidelines
for complete implementation details.
VCCPLL I The on-die PLL filter solution will not be implemented on this platform. The
VCCPLL input should be left unconnected.
Table 4-1. Signal Definitions (Sheet 9 of 10)
Name Type Description Notes
Signal Definitions
52 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
NOTES:
1. For this pin on Dual-Core Intel Xeon processor, the maximum number of symmetric agents is one. Maximum
number of central agents is zero.
2. For this pin on Dual-Core Intel Xeon processor, the maximum number of symmetric agents is two. Maximum
number of central agents is zero.
3. For this pin on Dual-Core Intel Xeon processor, the maximum number of symmetric agents is two. Maximum
number of central agents is one.
VCCSENSE
VSSSENSE O VCCSENSE and VSSSENSE provide an isolated, low impedance connec-
tion to the processor core power and ground. They can be used to sense
or measure power near the silicon with little noise.
VID[5:0] O VID[5:0] (V oltage ID) pins are used to support automatic selection of power
supply voltages (VCC). These are open drain signals that are driven by the
processor and must be pulled up through a resistor. Conversely, the VR
output must be disabled prior to the voltage supply for these pins becomes
invalid. The VID pins are needed to support processor voltage specification
variations. See Table 2-2 for definitions of these pins. The VR must supply
the voltage that is requested by these pins, or disable itself.
VIDPWRGD I The processor requires this input to determine that the supply voltage for
BSEL[1:0] and VID[5:0] is stable and within specification.
VSSA IV
SSA provides an isolated, internal ground for internal PLL’s. Do not
connect directly to ground. This pin is to be connected to VCCA and
VCCIOPLL through a discrete filter circuit.
VTT P The front side bus termination voltage input pins. Refer to Table 2-7 for
further details.
VTTEN O The VTTEN can be used as an output enable for the VTT regulator in the
event an incompatible processor is inserted into the platform. There is no
connection to the processor silicon for this signal and it must be pulled up
through a resistor. Refer to the appropriate platform design guidelines for
implementation details.
Table 4-1. Signal Definitions (Sheet 10 of 10)
Name Type Description Notes
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 53
5Pin Listing
5.1 Dual-Core Intel® Xeon® Processor Pin Assignments
This section provides sorted pin lists in Table 5-1 and Table 5-2. Table 5-1 is a listing of all processor pin s ordered
alphabetically by pin name. Table 5-2 is a listing of all processor pins ordered by pin number .
5.1.1 Pin Listing by Pin Name
Table 5-1. Pin Listing by Pin Name
Pin Name Pin No. Signal
Buffer Type Direction
A3# A22 Source Sync Input/Output
A4# A20 Source Sync Input/Output
A5# B18 Source Sync Input/Output
A6# C18 Source Sync Input/Output
A7# A19 Source Sync Input/Output
A8# C17 Source Sync Input/Output
A9# D17 Source Sync Input/Output
A10# A13 Source Sync Input/Output
A11# B16 Source Sync Input/Output
A12# B14 Source Sync Input/Output
A13# B13 Source Sync Input/Output
A14# A12 Source Sync Input/Output
A15# C15 Source Sync Input/Output
A16# C14 Source Sync Input/Output
A17# D16 Source Sync Input/Output
A18# D15 Source Sync Input/Output
A19# F15 Source Sync Input/Output
A20# A10 Source Sync Input/Output
A21# B10 Source Sync Input/Output
A22# B11 Source Sync Input/Output
A23# C12 Source Sync Input/Output
A24# E14 Source Sync Input/Output
A25# D13 Source Sync Input/Output
A26# A9 Source Sync Input/Output
A27# B8 Source Sync Input/Output
A28# E13 Source Sync Input/Output
A29# D12 Source Sync Input/Output
A30# C11 Source Sync Input/Output
A31# B7 Source Sync Input/Output
A32# A6 Source Sync Input/Output
A33# A7 Source Sync Input/Output
A34# C9 Source Sync In put/Output
A35# C8 Source Sync In put/Output
A20M# F27 Async GTL+ Input
ADS# D19 Common Clk Input/Output
ADSTB0# F17 Source Sync Input/Output
ADSTB1# F14 Source Sync Input/Output
AP0# E10 Common Clk Input/Output
AP1# D9 Common Clk Input/Output
BCLK0 Y4 Sys Bus Clk Input
BCLK1 W5 Sys Bus Clk Input
BINIT# F11 Common Clk Input/Output
BNR# F20 Common Clk Input/Output
BOOT_SELECT G7 Power/Other Input
BPM0# F6 Common Clk Input/Output
BPM1# F8 Common Clk Input/Output
BPM2# E7 Common Clk Input/Output
BPM3# F5 Common Clk Input/Output
BPM4# E8 Common Clk Input/Output
BPM5# E4 Common Clk Input/Output
BPRI# D23 Commo n Cl k Input
BR0# D20 Common Clk Input/Output
BR1# F12 Common Clk Input
BR2# E11 Common Clk Input
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
54 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
BR3# D10 Common Clk Input
BSEL0 AA3 Power/Other Output
BSEL1 AB3 Power/Other Output
COMP0 AD16 Power/Other Input
D0# Y26 Source Sync Input/Output
D1# AA27 Source Sync Input/Output
D2# Y24 Source Sync Input/Output
D3# AA25 Source Sync Input/Output
D4# AD27 Source Sync Input/Output
D5# Y23 Source Sync Input/Output
D6# AA24 Source Sync Input/Output
D7# AB26 Source Sync Input/Output
D8# AB25 Source Sync Input/Output
D9# AB23 Source Sync Input/Output
D10# AA22 Source Sync Input/Output
D11# AA21 Source Sync Input/Output
D12# AB20 Source Sync Input/Output
D13# AB22 Source Sync Input/Output
D14# AB19 Source Sync Input/Output
D15# AA19 Source Sync Input/Output
D16# AE26 Source Sync Input/Output
D17# AC26 Source Sync Input/Output
D18# AD25 Source Sync Input/Output
D19# AE25 Source Sync Input/Output
D20# AC24 Source Sync Input/Output
D21# AD24 Source Sync Input/Output
D22# AE23 Source Sync Input/Output
D23# AC23 Source Sync Input/Output
D24# AA18 Source Sync Input/Output
D25# AC20 Source Sync Input/Output
D26# AC21 Source Sync Input/Output
D27# AE22 Source Sync Input/Output
D28# AE20 Source Sync Input/Output
D29# AD21 Source Sync Input/Output
D30# AD19 Source Sync Input/Output
D31# AB17 Source Sync Input/Output
D32# AB16 Source Sync Input/Output
D33# AA16 Source Sync Input/Output
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
D34# AC17 Source Sync Input/Output
D35# AE13 Source Sync Input/Output
D36# AD18 Source Sync Input/Output
D37# AB15 Source Sync Input/Output
D38# AD13 Source Sync Input/Output
D39# AD14 Source Sync Input/Output
D40# AD11 Source Sync Input/Output
D41# AC12 Source Sync Input/Output
D42# AE10 Source Sync Input/Output
D43# AC11 Source Sync Input/Output
D44# AE9 Source Sync Input/Output
D45# AD10 Source Sync Input/Output
D46# AD8 Source Sync Input/Output
D47# AC9 Source Sync Input/Output
D48# AA13 Source Sync Input/Output
D49# AA14 Source Sync Input/Output
D50# AC14 Source Sync Input/Output
D51# AB12 Source Sync Input/Output
D52# AB13 Source Sync Input/Output
D53# AA11 Source Sync Input/Output
D54# AA10 Source Sync Input/Output
D55# AB10 Source Sync Input/Output
D56# AC8 Source Sync Input/Output
D57# AD7 Source Sync Input/Output
D58# AE7 Source Sync Input/Output
D59# AC6 Source Sync Input/Output
D60# AC5 Source Sync Input/Output
D61# AA8 Source Sync Input/Output
D62# Y9 Source Sync Input/Output
D63# AB6 Source Sync Input/Output
DBSY# F18 Common Clk Input/Output
DEFER# C23 Common Clk Input
DBI0# AC27 Source Sync Input/Output
DBI1# AD22 Source Sync Input/Output
DBI2# A E12 Source Sync Input/Output
DBI3# AB9 Source Sync Input/Output
DP0# AC18 Common Clk Input/Output
DP1# AE19 Common Clk Input/Output
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 55
DP2# AC15 Common Clk Input/Output
DP3# AE17 Common Clk Input/Output
DRDY# E18 Common Clk Input/Output
DSTBN0# Y21 Source Sync Input/Output
DSTBN1# Y18 Source Sync Input/Output
DSTBN2# Y15 Source Sync Input/Output
DSTBN3# Y12 Source Sync Input/Output
DSTBP0# Y20 Source Sync Input/Output
DSTBP1# Y17 Source Sync Input/Output
DSTBP2# Y14 Source Sync Input/Output
DSTBP3# Y11 Source Sync Input/Output
FERR#/PBE# E27 Async GTL+ Output
FORCEPR# A15 Async GTL+ Input
GTLREF W23 Power/Other Input
GTLREF W9 Power/Other Input
GTLREF F23 Power/Other Input
GTLREF F9 Power/Other Input
HIT# E22 Common Clk Input/Output
HITM# A23 Common Clk Input/Output
IERR# E5 Async GTL+ Output
IGNNE# C26 Async GTL+ Input
INIT# D6 Async GTL+ Input
LINT0/INTR B24 Async GTL+ Input
LINT1/NMI G23 Async GTL+ Input
LOCK# A17 Common Clk Input/Output
MCERR# D7 Common Clk Input/Output
N/C Y29 N/C N/C
N/C AA28 N/C N/C
N/C AA29 N/C N/C
N/C AB28 N/C N/C
N/C AB29 N/C N/C
N/C AC28 N/C N/C
N/C AC29 N/C N/C
N/C AD28 N/C N/C
N/C AD29 N/C N/C
N/C AE30 N/C N/C
ODTEN B5 Power/Other Input
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
OPTIMIZED/
COMPAT# C1 Power/Other Input
PROCHOT# B25 Async GTL+ Output
PWRGOOD AB7 Async GTL+ Input
REQ0# B19 Source Sync Input/Output
REQ1# B21 Source Sync Input/Output
REQ2# C21 Source Sync Input/Output
REQ3# C20 Source Sync Input/Output
REQ4# B22 Source Sync Input/Output
Reserved A26 Reserved Reserved
Reserved D25 Reserved Reserved
Reserved W3 Reserved Reserved
Reserved Y3 Reserved Reserved
Reserved AC1 Reserved Reserved
Reserved AE15 Reserved Reserved
Reserved AE16 Reserved Reserved
Reserved AE28 Reserved Reserved
Reserved AE29 Reserved Reserved
RESET# Y8 Common Clk Input
RS0# E21 Common Clk Input
RS1# D22 Common Clk Input
RS2# F21 Common Clk Input
RSP# C6 Common Clk Input
SKTOCC# A3 Power/Other Output
SLP# AE6 Async GTL+ Input
SMB_PRT AE4 Power/Other Output
SMI# C27 Async GTL+ Input
STPCLK# D4 Async GTL+ Input
TCK E24 TAP Input
TDI C24 TAP Input
TDO E25 TAP Output
TEST_BUS A16 Power/Other Input
TESTHI0 W6 Power/Other Input
TESTHI1 W7 Power/Other Input
TESTHI2 W8 Power/Other Input
TESTHI3 Y6 Power/Other Input
TESTHI4 AA7 Power/Other Input
TESTHI5 AD5 Power/Other Input
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
56 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
TESTHI6 AE5 Power/Other Input
THERMDA Y27 Power/Other Output
THERMDC Y28 Power/Other Output
THERMTRIP# F26 Async GTL+ Output
TMS A25 TAP Input
TRDY# E19 Common Clk Input
TRST# F24 TAP Input
VCC A2 Power/Other
VCC A8 Power/Other
VCC A14 Power/Other
VCC A18 Power/Other
VCC A24 Power/Other
VCC A28 Power/Other
VCC A30 Power/Other
VCC B6 Power/Other
VCC B20 Power/Other
VCC B26 Power/Other
VCC B29 Power/Other
VCC B31 Power/Other
VCC C2 Power/Other
VCC C4 Power/Other
VCC C16 Power/Other
VCC C22 Power/Other
VCC C28 Power/Other
VCC C30 Power/Other
VCC D1 Power/Other
VCC D8 Power/Other
VCC D14 Power/Other
VCC D18 Power/Other
VCC D24 Power/Other
VCC D29 Power/Other
VCC D31 Power/Other
VCC E2 Power/Other
VCC E6 Power/Other
VCC E20 Power/Other
VCC E26 Power/Other
VCC E28 Power/Other
VCC E30 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VCC F1 Power/Other
VCC F4 Power/Other
VCC F16 Power/Other
VCC F22 Power/Other
VCC F29 Power/Other
VCC F31 Power/Other
VCC G2 Power/Other
VCC G4 Power/Other
VCC G6 Power/Other
VCC G8 Power/Other
VCC G24 Power/Other
VCC G26 Power/Other
VCC G28 Power/Other
VCC G30 Power/Other
VCC H1 Power/Other
VCC H3 Power/Other
VCC H5 Power/Other
VCC H7 Power/Other
VCC H9 Power/Other
VCC H23 Power/Other
VCC H25 Power/Other
VCC H27 Power/Other
VCC H29 Power/Other
VCC H31 Power/Other
VCC J2 Power/Other
VCC J4 Power/Other
VCC J6 Power/Other
VCC J8 Power/Other
VCC J24 Power/Other
VCC J26 Power/Other
VCC J28 Power/Other
VCC J30 Power/Other
VCC K1 Power/Other
VCC K3 Power/Other
VCC K5 Power/Other
VCC K7 Power/Other
VCC K9 Power/Other
VCC K23 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 57
VCC K25 Power/Other
VCC K27 Power/Other
VCC K29 Power/Other
VCC K31 Power/Other
VCC L2 Power/Other
VCC L4 Power/Other
VCC L6 Power/Other
VCC L8 Power/Other
VCC L24 Power/Other
VCC L26 Power/Other
VCC L28 Power/Other
VCC L30 Power/Other
VCC M1 Power/Other
VCC M3 Power/Other
VCC M5 Power/Other
VCC M7 Power/Other
VCC M9 Power/Other
VCC M23 Power/Other
VCC M25 Power/Other
VCC M27 Power/Other
VCC M29 Power/Other
VCC M31 Power/Other
VCC N1 Power/Other
VCC N3 Power/Other
VCC N5 Power/Other
VCC N7 Power/Other
VCC N9 Power/Other
VCC N23 Power/Other
VCC N25 Power/Other
VCC N27 Power/Other
VCC N29 Power/Other
VCC N31 Power/Other
VCC P2 Power/Other
VCC P4 Power/Other
VCC P6 Power/Other
VCC P8 Power/Other
VCC P24 Power/Other
VCC P26 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VCC P28 Power/Other
VCC P30 Power/Other
VCC R1 Power/Other
VCC R3 Power/Other
VCC R5 Power/Other
VCC R7 Power/Other
VCC R9 Power/Other
VCC R23 Power/Other
VCC R25 Power/Other
VCC R27 Power/Other
VCC R29 Power/Other
VCC R31 Power/Other
VCC T2 Power/Other
VCC T4 Power/Other
VCC T6 Power/Other
VCC T8 Power/Other
VCC T24 Power/Other
VCC T26 Power/Other
VCC T28 Power/Other
VCC T30 Power/Other
VCC U1 Power/Other
VCC U3 Power/Other
VCC U5 Power/Other
VCC U7 Power/Other
VCC U9 Power/Other
VCC U23 Power/Other
VCC U25 Power/Other
VCC U27 Power/Other
VCC U29 Power/Other
VCC U31 Power/Other
VCC V2 Power/Other
VCC V4 Power/Other
VCC V6 Power/Other
VCC V8 Power/Other
VCC V24 Power/Other
VCC V26 Power/Other
VCC V28 Power/Other
VCC V30 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
58 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
VCC W1 Power/Other
VCC W25 Power/Other
VCC W27 Power/Other
VCC W29 Power/Other
VCC W31 Power/Other
VCC Y2 Power/Other
VCC Y16 Power/Other
VCC Y22 Power/Other
VCC Y30 Power/Other
VCC AA1 Power/Other
VCC AA4 Power/Other
VCC AA6 Power/Other
VCC AA20 Power/Other
VCC AA26 Power/Other
VCC AA31 Power/Other
VCC AB2 Power/Other
VCC AB8 Power/Other
VCC AB14 Power/Other
VCC AB18 Power/Other
VCC AB24 Power/Other
VCC AB30 Power/Other
VCC AC3 Power/Other
VCC AC4 Power/Other
VCC AC16 Power/Other
VCC AC22 Power/Other
VCC AC31 Power/Other
VCC AD2 Power/Other
VCC AD6 Power/Other
VCC AD20 Power/Other
VCC AD26 Power/Other
VCC AD30 Power/Other
VCC AE3 Power/Other
VCC AE8 Power/Other
VCC AE14 Power/Other
VCC AE18 Power/Other
VCC AE24 Power/Other
VCCA AB4 Power/Other Input
VCCIOPLL AD4 Power/Other Input
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VCCPLL AD1 Power/Other Input
VCCSENSE B27 Power/Other Output
VID0 F3 Power/Other Output
VID1 E3 Power/Other Output
VID2 D3 Power/Other Output
VID3 C3 Power/Other Output
VID4 B3 Power/Other Output
VID5 A1 Power/Other Output
VIDPWRGD B1 Power/Other Input
VSS A5 Power/Other
VSS A11 Power/Other
VSS A21 Power/Other
VSS A27 Power/Other
VSS A29 Power/Other
VSS A31 Power/Other
VSS B2 Power/Other
VSS B9 Power/Other
VSS B15 Power/Other
VSS B17 Power/Other
VSS B23 Power/Other
VSS B28 Power/Other
VSS B30 Power/Other
VSS C7 Power/Other
VSS C13 Power/Other
VSS C19 Power/Other
VSS C25 Power/Other
VSS C29 Power/Other
VSS C31 Power/Other
VSS D2 Power/Other
VSS D5 Power/Other
VSS D11 Power/Other
VSS D21 Power/Other
VSS D27 Power/Other
VSS D28 Power/Other
VSS D30 Power/Other
VSS E9 Power/Other
VSS E15 Power/Other
VSS E17 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 59
VSS E23 Power/Other
VSS E29 Power/Other
VSS E31 Power/Other
VSS F2 Power/Other
VSS F7 Power/Other
VSS F13 Power/Other
VSS F19 Power/Other
VSS F25 Power/Other
VSS F28 Power/Other
VSS F30 Power/Other
VSS G1 Power/Other
VSS G3 Power/Other
VSS G5 Power/Other
VSS G9 Power/Other
VSS G25 Power/Other
VSS G27 Power/Other
VSS G29 Power/Other
VSS G31 Power/Other
VSS H2 Power/Other
VSS H4 Power/Other
VSS H6 Power/Other
VSS H8 Power/Other
VSS H24 Power/Other
VSS H26 Power/Other
VSS H28 Power/Other
VSS H30 Power/Other
VSS J1 Power/Other
VSS J3 Power/Other
VSS J5 Power/Other
VSS J7 Power/Other
VSS J9 Power/Other
VSS J23 Power/Other
VSS J25 Power/Other
VSS J27 Power/Other
VSS J29 Power/Other
VSS J31 Power/Other
VSS K2 Power/Other
VSS K4 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VSS K6 Power/Other
VSS K8 Power/Other
VSS K24 Power/Other
VSS K26 Power/Other
VSS K28 Power/Other
VSS K30 Power/Other
VSS L1 Power/Other
VSS L3 Power/Other
VSS L5 Power/Other
VSS L7 Power/Other
VSS L9 Power/Other
VSS L23 Power/Other
VSS L25 Power/Other
VSS L27 Power/Other
VSS L29 Power/Other
VSS L31 Power/Other
VSS M2 Power/Other
VSS M4 Power/Other
VSS M6 Power/Other
VSS M8 Power/Other
VSS M24 Power/Other
VSS M26 Power/Other
VSS M28 Power/Other
VSS M30 Power/Other
VSS N2 Power/Other
VSS N4 Power/Other
VSS N6 Power/Other
VSS N8 Power/Other
VSS N24 Power/Other
VSS N26 Power/Other
VSS N28 Power/Other
VSS N30 Power/Other
VSS P1 Power/Other
VSS P3 Power/Other
VSS P5 Power/Other
VSS P7 Power/Other
VSS P9 Power/Other
VSS P23 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
60 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
VSS P25 Power/Other
VSS P27 Power/Other
VSS P29 Power/Other
VSS P31 Power/Other
VSS R2 Power/Other
VSS R4 Power/Other
VSS R6 Power/Other
VSS R8 Power/Other
VSS R24 Power/Other
VSS R26 Power/Other
VSS R28 Power/Other
VSS R30 Power/Other
VSS T1 Power/Other
VSS T3 Power/Other
VSS T5 Power/Other
VSS T7 Power/Other
VSS T9 Power/Other
VSS T23 Power/Other
VSS T25 Power/Other
VSS T27 Power/Other
VSS T29 Power/Other
VSS T31 Power/Other
VSS U2 Power/Other
VSS U4 Power/Other
VSS U6 Power/Other
VSS U8 Power/Other
VSS U24 Power/Other
VSS U26 Power/Other
VSS U28 Power/Other
VSS U30 Power/Other
VSS V1 Power/Other
VSS V3 Power/Other
VSS V5 Power/Other
VSS V7 Power/Other
VSS V9 Power/Other
VSS V23 Power/Other
VSS V25 Power/Other
VSS V27 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VSS V29 Power/Other
VSS V31 Power/Other
VSS W2 Power/Other
VSS W4 Power/Other
VSS W24 Power/Other
VSS W26 Power/Other
VSS W28 Power/Other
VSS W30 Power/Other
VSS Y1 Power/Other
VSS Y5 Power/Other
VSS Y7 Power/Other
VSS Y13 Power/Other
VSS Y19 Power/Other
VSS Y25 Power/Other
VSS Y31 Power/Other
VSS AA2 Power/Other
VSS AA9 Power/Other
VSS AA15 Power/Other
VSS AA17 Power/Other
VSS AA23 Power/Other
VSS AA30 Power/Other
VSS AB1 Power/Other
VSS AB5 Power/Other
VSS AB11 Power/Other
VSS AB21 Power/Other
VSS AB27 Power/Other
VSS AB31 Power/Other
VSS AC2 Power/Other
VSS AC7 Power/Other
VSS AC13 Power/Other
VSS AC19 Power/Other
VSS AC25 Power/Other
VSS AD3 Power/Other
VSS AD9 Power/Other
VSS AD15 Power/Other
VSS AD17 Power/Other
VSS AD23 Power/Other
VSS AD31 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 61
VSS AE2 Power/Other
VSS AE11 Power/Other
VSS AE21 Power/Other
VSS AE27 Power/Other
VSSA AA5 Power/Other Input
VSSSENSE D26 Power/Other Output
VTT A4 Power/Other
VTT B4 Power/Other
VTT C5 Power/Other
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
VTT B12 Power/Other
VTT C10 Power/Other
VTT E12 Power/Other
VTT F10 Power/Other
VTT Y10 Power/Other
VTT AA12 Power/Other
VTT AC10 Power/Other
VTT AD12 Power/Other
VTTEN E1 Power/Other Output
Table 5-1. Pin Listing by Pin Name (Cont’d)
Pin Name Pin No. Signal
Buffer Type Direction
Pin Listing
62 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
5.1.2 Pin Listing by Pin Number
Table 5-2. Pin Listing by Pin Number
Pin No. Pin Name Signal
Buffer Type Direction
A1 VID5 Power/Other Output
A2 VCC Power/Other
A3 SKTOCC# Power/Other Output
A4 VTT Power/Other
A5 VSS Power/Other
A6 A32# Source Sync Input/Output
A7 A33# Source Sync Input/Output
A8 VCC Power/Other
A9 A26# Source Sync Input/Output
A10 A20# Source Sync Input/Output
A11 VSS Power/Other
A12 A14# Source Sync Input/Output
A13 A10# Source Sync Input/Output
A14 VCC Power/Other
A15 FORCEPR# Async GTL+ Input
A16 TEST_BUS Power/Other Input
A17 LOCK# Common Clk Input/Output
A18 VCC Power/Other
A19 A7# Source Sync Input/Output
A20 A4# Source Sync Input/Output
A21 VSS Power/Other
A22 A3# Source Sync Input/Output
A23 HITM# Common Clk Input/Output
A24 VCC Power/Other
A25 TMS TAP Input
A26 Reserved Reserved Reserved
A27 VSS Power/Other
A28 VCC Power/Other
A29 VSS Power/Other
A30 VCC Power/Other
A31 VSS Power/Other
B1 VIDPWRGD Power/Other Input
B2 VSS Power/Other
B3 VID4 Power/Other Output
B4 VTT Power/Other
B5 ODTEN Power/Other Input
B6 VCC Power/Other
B7 A31# Sour ce Sync Input/Output
B8 A27# Sour ce Sync Input/Output
B9 VSS Power/Other
B10 A21# Sour ce Sync Inpu t/Outp ut
B11 A22# Source Sync Inpu t/Outp ut
B12 VTT Power/Other
B13 A13# Sour ce Sync Inpu t/Outp ut
B14 A12# Sour ce Sync Inpu t/Outp ut
B15 VSS Power/Other
B16 A11# Source Sync Input/Output
B17 VSS Power/Other
B18 A5# Source Sync Inpu t/Outp ut
B19 REQ0# Source Sync Inpu t/Outp ut
B20 VCC Power/Other
B21 REQ1# Source Sync Inpu t/Outp ut
B22 REQ4# Source Sync Inpu t/Outp ut
B23 VSS Power/Other
B24 LINT0/INTR Async GTL+ Input
B25 PROCHOT# Power/Other Output
B26 VCC Power/Other
B27 VCCSENSE Power/Other Output
B28 VSS Power/Other
B29 VCC Power/Other
B30 VSS Power/Other
B31 VCC Power/Other
C1 OPTIMIZED/
COMPAT# Power/Other Input
C2 VCC Power/Other
C3 VID3 Power/Other Output
C4 VCC Power/Other
C5 VTT Power/Other
C6 RSP# Common Clk Input
C7 VSS Power/Other
C8 A35 # Source Sync Input/Output
C9 A34 # Source Sync Input/Output
C10 VTT Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 63
C11 A30# Source Sync Input/Output
C12 A23# Source Sync Input/Output
C13 VSS Power/Other
C14 A16# Source Sync Input/Output
C15 A15# Source Sync Input/Output
C16 VCC Power/Other
C17 A8# Source Sync Input/Output
C18 A6# Source Sync Input/Output
C19 VSS Power/Other
C20 REQ3# Source Sync Input/Output
C21 REQ2# Source Sync Input/Output
C22 VCC Power/Other
C23 DEFER# Common Clk Input
C24 TDI TAP Input
C25 VSS Power/Other
C26 IGNNE# Async GTL+ Input
C27 SMI# Async GTL+ Input
C28 VCC Power/Other
C29 VSS Power/Other
C30 VCC Power/Other
C31 VSS Power/Other
D1 VCC Power/Other
D2 VSS Power/Other
D3 VID2 Power/Other Output
D4 STPCLK# Async GTL+ Input
D5 VSS Power/Other
D6 INIT# Async GTL+ Input
D7 MCERR# Common Clk Input/Output
D8 VCC Power/Other
D9 AP1# Common Clk Input/Output
D10 BR3# Common Clk Input
D11 VSS Power/Other
D12 A29# Source Sync Input/Output
D13 A25# Source Sync Input/Output
D14 VCC Power/Other
D15 A18# Source Sync Input/Output
D16 A17# Source Sync Input/Output
D17 A9# Source Sync Input/Output
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
D18 VCC Power/Other
D19 ADS# Common Clk Input/Output
D20 BR0# Common Clk Input/Output
D21 VSS Power/Other
D22 RS1# Common Clk Input
D23 BPRI# Common Clk Input
D24 VCC Power/Other
D25 Reserved Reserved Reserved
D26 VSSSENSE Power/Other Output
D27 VSS Power/Other
D28 VSS Power/Other
D29 VCC Power/Other
D30 VSS Power/Other
D31 VCC Power/Other
E1 VTTEN Power/Other Output
E2 VCC Power/Other
E3 VID1 Power/Other Output
E4 BPM5# Common Clk Input/Output
E5 IERR# Async GTL+ Output
E6 VCC Power/Other
E7 BPM2# Common Clk Input/Output
E8 BPM4# Common Clk Input/Output
E9 VSS Power/Other
E10 AP0# Common Clk Input/Output
E11 BR2# Common Clk Input
E12 VTT Power/Other
E13 A28# Source Sync Input/Output
E14 A24# Source Sync Input/Output
E15 VSS Power/Other
E17 VSS Power/Other
E18 DRDY# Common Clk Input/Output
E19 TRDY# Common Clk Input
E20 VCC Power/Other
E21 RS0# Common Clk Input
E22 HIT# Common Clk Input/Output
E23 VSS Power/Other
E24 TCK TAP Input
E25 TDO TAP Output
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
64 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
E26 VCC Power/Other
E27 FERR#/PBE# Async GTL+ Output
E28 VCC Power/Other
E29 VSS Power/Other
E30 VCC Power/Other
E31 VSS Power/Other
F1 VCC Power/Other
F2 VSS Power/Other
F3 VID0 Power/Other Output
F4 VCC Power/Other
F5 BPM3# Common Clk Input/Output
F6 BPM0# Common Clk Input/Output
F7 VSS Power/Other
F8 BPM1# Common Clk Input/Output
F9 GTLREF Power/Other Input
F10 VTT Power/Other
F11 BINIT# Common Clk Input/Output
F12 BR1# Common Clk Input
F13 VSS Power/Other
F14 ADSTB1# Source Sync Input/Output
F15 A19# Source Sync Input/Output
F16 VCC Power/Other
F17 ADSTB0# Source Sync Input/Output
F18 DBSY# Common Clk Input/Output
F19 VSS Power/Other
F20 BNR# Common Clk Input/Output
F21 RS2# Common Clk Input
F22 VCC Power/Other
F23 GTLREF Power/Other Input
F24 TRST# TAP Input
F25 VSS Power/Other
F26 THERMTRIP# Async GTL+ Output
F27 A20M# Async GTL+ Input
F28 VSS Power/Other
F29 VCC Power/Other
F30 VSS Power/Other
F31 VCC Power/Other
G1 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
G2 VCC Power/Other
G3 VSS Power/Other
G4 VCC Power/Other
G5 VSS Power/Other
G6 VCC Power/Other
G7 BOOT_SELECT Power/Other Input
G8 VCC Power/Other
G9 VSS Power/Other
G23 LINT1/NMI Async GTL+ Input
G24 VCC Power/Other
G25 VSS Power/Other
G26 VCC Power/Other
G27 VSS Power/Other
G28 VCC Power/Other
G29 VSS Power/Other
G30 VCC Power/Other
G31 VSS Power/Other
H1 VCC Power/Other
H2 VSS Power/Other
H3 VCC Power/Other
H4 VSS Power/Other
H5 VCC Power/Other
H6 VSS Power/Other
H7 VCC Power/Other
H8 VSS Power/Other
H9 VCC Power/Other
H23 VCC Power/Other
H24 VSS Power/Other
H25 VCC Power/Other
H26 VSS Power/Other
H27 VCC Power/Other
H28 VSS Power/Other
H29 VCC Power/Other
H30 VSS Power/Other
H31 VCC Power/Other
J1 VSS Power/Other
J2 VCC Power/Other
J3 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 65
J4 VCC Power/Other
J5 VSS Power/Other
J6 VCC Power/Other
J7 VSS Power/Other
J8 VCC Power/Other
J9 VSS Power/Other
J23 VSS Power/Other
J24 VCC Power/Other
J25 VSS Power/Other
J26 VCC Power/Other
J27 VSS Power/Other
J28 VCC Power/Other
J29 VSS Power/Other
J30 VCC Power/Other
J31 VSS Power/Other
K1 VCC Power/Other
K2 VSS Power/Other
K3 VCC Power/Other
K4 VSS Power/Other
K5 VCC Power/Other
K6 VSS Power/Other
K7 VCC Power/Other
K8 VSS Power/Other
K9 VCC Power/Other
K23 VCC Power/Other
K24 VSS Power/Other
K25 VCC Power/Other
K26 VSS Power/Other
K27 VCC Power/Other
K28 VSS Power/Other
K29 VCC Power/Other
K30 VSS Power/Other
K31 VCC Power/Other
L1 VSS Power/Other
L2 VCC Power/Other
L3 VSS Power/Other
L4 VCC Power/Other
L5 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
L6 VCC Power/Other
L7 VSS Power/Other
L8 VCC Power/Other
L9 VSS Power/Other
L23 VSS Power/Other
L24 VCC Power/Other
L25 VSS Power/Other
L26 VCC Power/Other
L27 VSS Power/Other
L28 VCC Power/Other
L29 VSS Power/Other
L30 VCC Power/Other
L31 VSS Power/Other
M1 VCC Power/Other
M2 VSS Power/Other
M3 VCC Power/Other
M4 VSS Power/Other
M5 VCC Power/Other
M6 VSS Power/Other
M7 VCC Power/Other
M8 VSS Power/Other
M9 VCC Power/Other
M23 VCC Power/Other
M24 VSS Power/Other
M25 VCC Power/Other
M26 VSS Power/Other
M27 VCC Power/Other
M28 VSS Power/Other
M29 VCC Power/Other
M30 VSS Power/Other
M31 VCC Power/Other
N1 VCC Power/Other
N2 VSS Power/Other
N3 VCC Power/Other
N4 VSS Power/Other
N5 VCC Power/Other
N6 VSS Power/Other
N7 VCC Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
66 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
N8 VSS Power/Other
N9 VCC Power/Other
N23 VCC Power/Other
N24 VSS Power/Other
N25 VCC Power/Other
N26 VSS Power/Other
N27 VCC Power/Other
N28 VSS Power/Other
N29 VCC Power/Other
N30 VSS Power/Other
N31 VCC Power/Other
P1 VSS Power/Other
P2 VCC Power/Other
P3 VSS Power/Other
P4 VCC Power/Other
P5 VSS Power/Other
P6 VCC Power/Other
P7 VSS Power/Other
P8 VCC Power/Other
P9 VSS Power/Other
P23 VSS Power/Other
P24 VCC Power/Other
P25 VSS Power/Other
P26 VCC Power/Other
P27 VSS Power/Other
P28 VCC Power/Other
P29 VSS Power/Other
P30 VCC Power/Other
P31 VSS Power/Other
R1 VCC Power/Other
R2 VSS Power/Other
R3 VCC Power/Other
R4 VSS Power/Other
R5 VCC Power/Other
R6 VSS Power/Other
R7 VCC Power/Other
R8 VSS Power/Other
R9 VCC Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
R23 VCC Power/Other
R24 VSS Power/Other
R25 VCC Power/Other
R26 VSS Power/Other
R27 VCC Power/Other
R28 VSS Power/Other
R29 VCC Power/Other
R30 VSS Power/Other
R31 VCC Power/Other
T1 VSS Power/Other
T2 VCC Power/Other
T3 VSS Power/Other
T4 VCC Power/Other
T5 VSS Power/Other
T6 VCC Power/Other
T7 VSS Power/Other
T8 VCC Power/Other
T9 VSS Power/Other
T23 VSS Power/Other
T24 VCC Power/Other
T25 VSS Power/Other
T26 VCC Power/Other
T27 VSS Power/Other
T28 VCC Power/Other
T29 VSS Power/Other
T30 VCC Power/Other
T31 VSS Power/Other
U1 VCC Power/Other
U2 VSS Power/Other
U3 VCC Power/Other
U4 VSS Power/Other
U5 VCC Power/Other
U6 VSS Power/Other
U7 VCC Power/Other
U8 VSS Power/Other
U9 VCC Power/Other
U23 VCC Power/Other
U24 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 67
U25 VCC Power/Other
U26 VSS Power/Other
U27 VCC Power/Other
U28 VSS Power/Other
U29 VCC Power/Other
U30 VSS Power/Other
U31 VCC Power/Other
V1 VSS Power/Other
V2 VCC Power/Other
V3 VSS Power/Other
V4 VCC Power/Other
V5 VSS Power/Other
V6 VCC Power/Other
V7 VSS Power/Other
V8 VCC Power/Other
V9 VSS Power/Other
V23 VSS Power/Other
V24 VCC Power/Other
V25 VSS Power/Other
V26 VCC Power/Other
V27 VSS Power/Other
V28 VCC Power/Other
V29 VSS Power/Other
V30 VCC Power/Other
V31 VSS Power/Other
W1 VCC Power/Other
W2 VSS Power/Other
W3 Reserved Reserved Reserved
W4 VSS Power/Other
W5 BCLK1 Sys Bus Clk Input
W6 TESTHI0 Power/Other Input
W7 TESTHI1 Power/Other Input
W8 TESTHI2 Power/Other Input
W9 GTLREF Power/Other Input
W23 GTLREF Power/Other Input
W24 VSS Power/Other
W25 VCC Power/Other
W26 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
W27 VCC Power/Other
W28 VSS Power/Other
W29 VCC Power/Other
W30 VSS Power/Other
W31 VCC Power/Other
Y1 VSS Power/Other
Y2 VCC Power/Other
Y3 Reserved Reserved Reserved
Y4 BCLK0 Sys Bus Clk Input
Y5 VSS Power/Other
Y6 TESTHI3 Power/Other Input
Y7 VSS Power/Other
Y8 RESET# Common Clk Input
Y9 D62 # Source Sync Input/Output
Y10 VTT Power/Other
Y11 DSTBP3# Source Sync Input/Output
Y12 DSTBN3# Source Sync Input/Output
Y13 VSS Power/Other
Y14 DSTBP2# Source Sync Input/Output
Y15 DSTBN2# Source Sync Input/Output
Y16 VCC Power/Other
Y17 DSTBP1# Source Sync Input/Output
Y18 DSTBN1# Source Sync Input/Output
Y19 VSS Power/Other
Y20 DSTBP0# Source Sync Input/Output
Y21 DSTBN0# Source Sync Input/Output
Y22 VCC Power/Other
Y23 D5# Source Sync Input/Output
Y24 D2# Source Sync Input/Output
Y25 VSS Power/Other
Y26 D0# Source Sync Input/Output
Y27 THERMDA Power/Other Output
Y28 THERMDC Power/Other Output
Y29 N/C N/C N/C
Y30 VCC Power/Other
Y31 VSS Power/Other
AA1 VCC Power/Other
AA2 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
68 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
AA3 BSEL0 Power/Other Output
AA4 VCC Power/Other
AA5 VSSA Power/Other Input
AA6 VCC Power/Other
AA7 TESTHI4 Power/Other Input
AA8 D61# Source Sync Input/Output
AA9 VSS Power/Other
AA10 D54# Source Sync Input/Output
AA11 D53# Source Sync Input/Output
AA12 VTT Power/Other
AA13 D48# Source Sync Input/Output
AA14 D49# Source Sync Input/Output
AA15 VSS Power/Other
AA16 D33# Source Sync Input/Output
AA17 VSS Power/Other
AA18 D24# Source Sync Input/Output
AA19 D15# Source Sync Input/Output
AA20 VCC Power/Other
AA21 D11# Source Sync Input/Output
AA22 D10# Source Sync Input/Output
AA23 VSS Power/Other
AA24 D6# Source Sync Input/Output
AA25 D3# Source Sync Input/Output
AA26 VCC Power/Other
AA27 D1# Source Sync Input/Output
AA28 N/C N/C N/C
AA29 N/C N/C N/C
AA30 VSS Power/Other
AA31 VCC Power/Other
AB1 VSS Power/Other
AB2 VCC Power/Other
AB3 BSEL1 Power/Other Output
AB4 VCCA Power/Other Input
AB5 VSS Power/Other
AB6 D63# Source Sync Input/Output
AB7 PWRGOOD Async GTL+ Input
AB8 VCC Power/Other
AB9 DBI3# Source Sync Input/Output
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
AB10 D55# Source Sync Inpu t/Outp ut
AB11 VSS Power/Other
AB12 D51# Source Sync Inpu t/Outp ut
AB13 D52# Source Sync Inpu t/Outp ut
AB14 VCC Power/Other
AB15 D37# Source Sync Inpu t/Outp ut
AB16 D32# Source Sync Inpu t/Outp ut
AB17 D31# Source Sync Inpu t/Outp ut
AB18 VCC Power/Other
AB19 D14# Source Sync Inpu t/Outp ut
AB20 D12# Source Sync Inpu t/Outp ut
AB21 VSS Power/Other
AB22 D13# Source Sync Inpu t/Outp ut
AB23 D9# Source Sync Inpu t/Outp ut
AB24 VCC Power/Other
AB25 D8# Source Sync Inpu t/Outp ut
AB26 D7# Source Sync Inpu t/Outp ut
AB27 VSS Power/Other
AB28 N/C N/C N/C
AB29 N/C N/C N/C
AB30 VCC Power/Other
AB31 VSS Power/Other
AC1 Reserved Reserved Reserved
AC2 VSS Power/Other
AC3 VCC Power/Other
AC4 VCC Power/Other
AC5 D60# Source Sync Input/Output
AC6 D59# Source Sync Input/Output
AC7 VSS Power/Other
AC8 D56# Source Sync Input/Output
AC9 D47# Source Sync Input/Output
AC10 VTT Power/Other
AC11 D43# Source Sync Input/Output
AC12 D41# Source Sync Input/Output
AC13 VSS Power/Other
AC14 D50# Source Sync Input/Output
AC15 DP2# Common Clk Input/Output
AC16 VCC Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 69
AC17 D34# Source Sync Input/Output
AC18 DP0# Common Clk Input/Output
AC19 VSS Power/Other
AC20 D25# Source Sync Input/Output
AC21 D26# Source Sync Input/Output
AC22 VCC Power/Other
AC23 D23# Source Sync Input/Output
AC24 D20# Source Sync Input/Output
AC25 VSS Power/Other
AC26 D17# Source Sync Input/Output
AC27 DBI0# Source Sync Input/Output
AC28 N/C N/C N/C
AC29 N/C N/C N/C
AC30 SLEW_CTRL Power/Other Input
AC31 VCC Power/Other
AD1 VCCPLL Power/Other Input
AD2 VCC Power/Other
AD3 VSS Power/Other
AD4 VCCIOPLL Power/Other Input
AD5 TESTHI5 Power/Other Input
AD6 VCC Power/Other
AD7 D57# Source Sync Input/Output
AD8 D46# Source Sync Input/Output
AD9 VSS Power/Other
AD10 D45# Source Sync Input/Output
AD11 D40# Source Sync Input/Output
AD12 VTT Power/Other
AD13 D38# Source Sync Input/Output
AD14 D39# Source Sync Input/Output
AD15 VSS Power/Other
AD16 COMP0 Power/Other Input
AD17 VSS Power/Other
AD18 D36# Source Sync Input/Output
AD19 D30# Source Sync Input/Output
AD20 VCC Power/Other
AD21 D29# Source Sync Input/Output
AD22 DBI1# Source Sync Input/Output
AD23 VSS Power/Other
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
AD24 D21# Source Sync Input/Output
AD25 D18# Source Sync Input/Output
AD26 VCC Power/Other
AD27 D4# Source Sync Input/Output
AD28 N/C N/C N/C
AD29 N/C N/C N/C
AD30 VCC Power/Other
AD31 VSS Power/Other
AE2 VSS Power/Other
AE3 VCC Power/Other
AE4 SMB_PRT Power/Other Output
AE5 TESTHI6 Power/Other Input
AE6 SLP# Async GTL+ Input
AE7 D58# Source Sync Input/Output
AE8 VCC Power/Other
AE9 D44# Source Sync Input/Output
AE10 D42# Source Sync Input/Output
AE11 VSS Power/Other
AE12 DBI2# Source Sync Input/Output
AE13 D35# Source Sync Input/Output
AE14 VCC Power/Other
AE15 Reserved Reserved Reserved
AE16 Reserved Reserved Reserved
AE17 DP3# Common Clk Input/Output
AE18 VCC Power/Other
AE19 DP1# Common Clk Input/Output
AE20 D28# Source Sync Input/Output
AE21 VSS Power/Other
AE22 D27# Source Sync Input/Output
AE23 D22# Source Sync Input/Output
AE24 VCC Power/Other
AE25 D19# Source Sync Input/Output
AE26 D16# Source Sync Input/Output
AE27 VSS Power/Other
AE28 Reserved Reserved Reserved
AE29 Reserved Reserved Reserved
AE30 N/C N/C N/C
Table 5-2. Pin Listing by Pin Number (Cont’d)
Pin No. Pin Name Signal
Buffer Type Direction
Pin Listing
70 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
§
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 71
6 Thermal Specifications
6.1 Package Thermal Specifications
The Dual-Core Intel Xeon processor requires a thermal solution to maintain temperatures within
operating limits. Any attempt to operate the processor outside these operating limits may result in
permanent damage to the processor and potentially other components within the system. As
processor technology changes, thermal mana gem en t becom es increasin gly crucial when building
computer systems. Maintaining the proper thermal environment is key to reliable, long-term
system operation.
A complete solution includes both component and system level thermal management features.
Component level thermal so lut ions can include active or passive heatsinks attached to the
processor Integrated Heat Spreader (IHS). Typical system level thermal solution s ma y consist of
system fans combined wit h ducting and venting.
For more information on designing a component level thermal solution, refer to the Dual-Core
Intel® Xeon® Processor 2.80 GHz Thermal/Mechanical Design Guidelines.
Note: The boxed processor will ship with a componen t thermal solu tion.
6.1.1 Thermal Specifications
To allow the optimal operation and long-term reliability of Intel processor-based systems, the
processor must remain within the minimum and maximum case temperature (TCASE) specifications
as defined by the applicable thermal profile (see Figure 6-1, Table 6-2 and Table 6-3). Thermal
solutions not designed to provide this level of thermal capability may affect the long-term
reliability of the processor and system. For more details on thermal solution design, please refer to
the appropriate processor thermal/mechanical design guideline.
The Dual-Core Intel Xeon processor utilizes a methodology for managing processor temperatures
which is intended to support acou stic noise reduction through fan speed control and assure
processor reliability. Selection of the approp riate fan speed will be based on the temperature
reported by the processors Thermal Diode. If the diode temperature is greater than or equal to
Tcontrol (s ee Section 6.2.6), then the processor case temperature must remain at or below the
temperature as specified by the thermal profile (see Figure 6-1). If the diode temperature is less
than Tcontrol, then the case temperature is permitted to exceed the thermal profile, but the diode
temperature must remain at or below Tcontrol. Systems that implement fan speed control must be
designed to take these conditions into account. Systems that do not alter the fan speed only need to
guarantee the case temperature meets the thermal profile specifications.
Intel has developed two therm a l profiles, either of which can be implemented with the Dual-Core
Intel Xeon processor. Both ensure adherence to Intel reliability requirements. Thermal Profile A is
representative of a volumetrically unconstrained thermal solution (i.e. industry enab led 2U heat
sink). In this scenario , it is expected that the Thermal Control Circuit (TCC) would only be
activated for very brief periods of time when running the most pow er intensive applications.
Thermal Profile B is indicative of a constrained thermal environment (i.e. 1U). Because of the
reduced cooling capability represented by this thermal solution, the probability of TCC activation
and performance loss is increased. Additionally, utilization of a thermal solution that does not meet
Thermal Profile B will violate the thermal specifications and may result in permanent damage to
Thermal Specifications
72 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
the processor. Intel has developed these thermal profiles to allow OEMs to choose the thermal
solution and environmental parameters that best suit their platform implementation. Refer to the
appropriate thermal/mechanical design guide for details on system thermal solution design, thermal
profiles, and environmental considerations.
The upper point of the thermal profile consists of the Thermal Design Power (TDP) defined in
Table 6-1 and the associated TCASE value. It should be noted that the upper point associated with
Thermal Profile B (x = TDP and y = TCASE_MAX_B @ TDP) represents a thermal solution design
point. In actuality the processor case temperature will never reach this value due to TCC activation
(see Figure 6-1). The lower point of the thermal profile consis ts of x = PCONTROL_BASE and
y=T
CASE_MAX @ PCONTROL_BASE. Pcontrol is defined as the processor power at which TCASE,
calculated from the thermal profile, corresponds to the lowest possible value of T control. This point
is associated with the Tcontrol value (see Section 6.2.6) However, because Tcontrol represents a
diode temperature, it is necessary to define the associated case temperature. This is TCASE_MAX @
PCONTROL_BASE. Please see Section 6.2.6 and the appropriate thermal/mechanical design guide for
proper usage of the Tcontrol specification.
The case temperature is defined at the geometric top center of the processor IHS. Analysis
indicates that real applications are unlikely to cause the processor to consume maximum power
dissipation for su stained time periods. Intel recommends that complete thermal solution designs
target the Thermal Design Power (TDP) indicated in Table 6-1, instead of the maximum processor
power consumption. The Thermal Monitor feature is intended to help protect the processor in the
event that an application exceeds the TDP recommendation for a sustained time period. For more
details on this feature, refer to Section 6.2. Thermal Monitor feature must be enabled for the
processor to remain within specification.
NOTES:
1. These values are specified at VCC_MAX for all processor frequencies. Systems must be designed to ensure
the processor is not to be subjected to any static VCC and ICC combination wherein VCC exceeds VCC_MAX at
specified ICC. Please refer to the VCC static and transient tolerance specifications in Section 2.
2. Listed frequencies are not necessarily committed production frequencies.
3. Maximum Power is the maximum thermal power that can be dissipated by the processor through the
integrated heat spreader (IHS). Maximum Power is measured at maximum TCASE.
4. Thermal Design Power (TDP) should be used for processor/chipset thermal solution design targets. TDP is
not the maximum power that the processor can dissipate. TDP is measured at maximum TCASE.
5. These specifications are based on final silicon characterization.
6. Power specifications are defined at all VIDs found in Table 2-7. The Dual-Core Intel Xeon processor may be
shipped under multiple VIDs listed for each frequency.
Table 6-1. Dual-Core Intel® Xeon® Processor Thermal Specifications
Core
Frequency
(GHz)
Maximum
Power
(W)
Thermal
Design Power
(W)
Minimum
TCASE
(°C)
Maximum
TCASE
(°C) Notes
2.80 GHz 150 135 5 See Figure 6-1; Table 6-2
or Table 6-3 1, 2, 3, 4,
5, 6
Thermal Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 73
NOTES:
1. Thermal Profile A is representative of a volumetrically unconstrained platform. Please refer to Table 6-2 for
discrete points that constitute the thermal profile.
2. Implementation of Thermal Profile A should result in virtually no TCC activation. Furthermore, utilization of
thermal solutions that do not meet processor Thermal Profile A will result in increased probability of TCC
activation and may incur measurable performance loss. (See Section 6.2 for details on TCC activation).
3. Thermal Profile B is representative of a volumetrically constrained platform. Please refer to Table 6-2 for
discrete points that constitute the thermal profile.
4. Implementation of Thermal Profile B will result in increased probability of TCC activation and may incur
measurable performance loss. Furthermore, utilization of thermal solutions that do not meet Thermal Profile
B do not meet the processor’s thermal specifications and may result in permanent damage to the processor.
5. Refer to the Dual-Core Intel® Xeon® Processor 2.80 GHz Thermal/Mechanical Design Guidelines for system
and environmental implementation details.
Figure 6-1. Dual-Core Intel® Xeon® Processor Thermal Profiles A and B
0
10
20
30
40
50
60
70
80
90
0 10 20 30 40 50 60 70 80 90 100 110 120 130 140
Power [W]
Tcase [°C]
Thermal Profile A: PCONTROL_BASE = 31 W; TCASE @ PCONTROL_BASE = 50 °C
Thermal Profile B: PCONTROL_BASE = 22 W; TCASE @ PCONTROL_BASE = 50 °C
TDP
PCONTROL_BASE_B
TCASE_MAX_B
@ TDP
TCASE_MAX @
Pcontrol_base
TCASE_MAX_A
@ TDP
PCONTROL_BASE_A
0
10
20
30
40
50
60
70
80
90
0 10 20 30 40 50 60 70 80 90 100 110 120 130 140
Power [W]
Tcase [°C]
Thermal Profile A: PCONTROL_BASE = 31 W; TCASE @ PCONTROL_BASE = 50 °C
Thermal Profile B: PCONTROL_BASE = 22 W; TCASE @ PCONTROL_BASE = 50 °C
TDP
PCONTROL_BASE_B
TCASE_MAX_B
@ TDP
TCASE_MAX @
Pcontrol_base
TCASE_MAX_A
@ TDP
PCONTROL_BASE_A
Thermal Specifications
74 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Table 6-2. Dual-Core Intel® Xeon® Processor Thermal Profile A
Powe r [W] TCASE_MAX [d eg C] P o wer [W] T CASE_MAX [d eg C]
PCONTROL_BASE_A = 31 43 82 60
32 50 84 61
34 50 86 61
36 51 88 62
38 51 90 62
40 52 92 63
42 52 94 63
44 52 96 63
46 53 98 64
48 53 100 64
50 54 102 65
52 54 104 65
54 54 106 65
56 55 108 66
58 55 110 66
60 56 112 67
62 56 114 67
64 57 116 68
66 57 118 68
64 57 120 68
66 57 122 69
68 57 124 69
70 58 126 70
72 58 128 70
74 59 130 71
76 59 132 71
78 60 134 71
80 60 135 72
Thermal Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 75
6.1.2 Thermal Metrology
The maximum case temperatures (TCASE) are specified in Table 6-2 and Table 6-3 measured at the
geometric top center of the processor integrated heat spreader (IHS). Figure 6-2 illustrates the
location where TCASE temperature measurements should be made. For detailed guidelines on
temperature measurement methodology, refer to the appropriate thermal/mechanical design guide.
Table 6-3. Dual-Core Intel® Xeon® Processor Thermal Profile B
Powe r [W ] TCASE_MAX [de
g
C] Po wer [W] T CASE_MAX [de
g
C]
PCONTROL_BASE_B = 22 44 80 65
24 50 82 65
26 51 84 66
28 51 86 66
30 52 88 67
32 52 90 67
34 53 92 68
36 53 94 69
38 54 96 69
40 54 98 70
42 55 100 70
44 55 102 71
46 56 104 71
48 57 106 72
50 57 108 72
52 58 110 73
54 58 112 73
56 59 114 74
58 59 116 74
60 60 118 75
62 60 120 75
64 61 122 76
66 61 124 76
68 62 126 77
70 62 128 77
72 63 130 78
74 63 132 78
76 64 134 79
78 64 135 79
Thermal Specifications
76 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Note: Figure is not to scale and is for reference only.
6.2 Processor Thermal Features
6.2.1 Thermal Monitor
The Thermal Monitor feature helps con tro l the pr ocessor temperature by activating the Thermal
Control Circuit (TCC) when the processor silicon reaches its maximum operating temperature. The
TCC reduces processor powe r consumpti on a s needed by mo dulating (starting and stopp i ng ) the
internal processor core clocks. The Thermal Monitor feature must be enabled for the processor to
be operating within specifications. The temperature at which Thermal Monitor activates the
thermal control circuit is not user configurable and is not software visible. Bus traffic is snooped in
the normal manner, and interrupt requests are latched (and serviced during the time that the clocks
are on) while the TCC is active.
When the Thermal Monitor is enabled, and a high temperature situation exists (i.e. TCC is active),
the clocks will be modulated by alternately turning the clocks off and on at a duty cycle specific to
the processor (typically 30 -50%). Clocks will not be off for more than 3 microseconds when the
TCC is active. Cycle times are processor speed dependent and will decrease as processor core
frequencies increase. A small amount of hysteresis has been included to prevent rapid active/
inactive transitions of the TCC when the processor temperature is near its maximum operating
temperature. Once the temperature has dropped below the maximum operati ng temperature, and
the hysteresis timer has expired, the TCC goes inactive and clock modulation ceases.
With a thermal solution designed to meet Thermal Profile A, it is anticipated that the TCC would
only be activated for very short periods of time when running the most pow er intensive
applications. The processor performance impact due to these brief periods of TCC activatio n is
expected to be so minor that it would be immeasurable. A thermal soluti on that is designed to
Thermal Profile B may cause a noticeable performance loss due to increased TCC activation.
Thermal Solutions that exceed Thermal Profile B will exceed the maximum temperature
specification and affect the long-term reliability of the processor. In addition, a thermal solution
Figure 6-2. Case Temperature (TCASE) Measuremen t Location
Measure from edge of processor
Measure T
at th is p oint.
CASE
15.5 m m
[0.61 in]
15 .5 m m
[0.61 in]
53.34 m m FC-m PGA4 Package
Thermal Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 77
that is significantly under designed may not be capable of cooling the processor even when the
TCC is active continuously. Refer to the appropriate thermal/mechanical design guide for
information on designing a therm a l solution.
The duty cycle for the TCC, when activated by the Thermal Monitor, is factory configured and
cannot be modified. The Thermal Monitor does not require any additional hardware, software
drivers, or interrupt handling routines.
6.2.2 On-Demand Mode
The processor provides an auxiliary mechanism that allows system software to force the processor
to reduce its power consumption. This mechanism is referred to as “On-Demand” mode and is
distinct from the Thermal Monitor feature. On-Demand mode is intended as a means to reduce
system level power consumption. Systems utilizing the Dual-Core Intel Xeon processor must not
rely on software usage of this mechanism to limi t the processor temperature.
If bit 4 of the IA32_CLOCK_MODULATION MSR is written to a ‘1’, the processor will
immediately reduce its power consumpti on vi a modulati on (starting and stopping) of the internal
core clock, independent of the processor temperature. When using On-Demand mode, the duty
cycle of the clock modulation is programmable via bits 3:1 of the same
IA32_CLOCK_MODULATION MSR. In On-Demand mode, the duty cycle can be programmed
from 12.5% on/ 87.5% off to 87.5% on/12.5% off in 12.5% increments. On-Demand mode may be
used in conjunction with the Thermal Monito r. If the system tries to enable On-Demand mode at
the same time the TCC is engaged, the factory configured duty cycle of the TCC will override the
duty cycle selected by the On-Demand mode.
6.2.3 PROCHOT# Signal Pin
An external signal, PROCHOT# (processor hot) is asserted when the processor die temperature has
reached its factory configured trip point. If Thermal Monitor is enabled (note that Thermal Monitor
must be enabled for the processor to be operating within specification), the TCC will be active
when PROCHOT# is asserted. The processor can be configured to generate an interrupt upon the
assertion or de-assertion of PROCHOT#. Refer to the IA-32 Intel® Architecture Software
Developer's Manual, Volume 3: System Programmer's Guide for specific register and programming
details.
PROCHOT# is designed to assert at or a few degrees higher than maximum TCASE (as specified by
Thermal Profile A) when dissipating TDP power, and cannot be interpreted as an indication of
processor case temperature. This temperature delta accounts for processor package, lifetime and
manufacturing variations and attempts to ensure the Thermal Control Circuit is not activated below
maximum TCASE when dissipating TDP power. There is no defined or fixed correlation between
the PROCHOT# trip temperature, the case temperature or the thermal diode temperature. Thermal
solutions must be designed to the processor specifications and cannot be adjusted based on
experimental measurements of TCASE, PROCHOT#, or Tdiode on random processor samples.
6.2.4 FORCEPR# Signal Pin
The FORCEPR# (force power reduction) input can be used by the platform to cause the Dual-Core
Intel Xeon processor to activate the TCC of each core. If the Thermal Monitor is enabled, t he TCC
will be activated upon the assertion of the FORCEPR# signal. The TCC will remain active until the
system deasserts FORCEPR#. FORCEPR# is an asynchronous in put . FORCEPR# can be used to
Thermal Specifications
78 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
thermally protect other system components. To use the VR as an example, when the FORCEPR#
pin is asserted, the TCC circuit of each core within the processor will activate, reducing the current
consumption of the processor and the corresponding temperature of the VR.
If should be noted that assertion of the FORCEPR# does not automatically assert PROCHOT#. As
mentioned previously, the PROCHOT# signal is asserted when a high temperature situation is
detected. A minimum pulse width of 500 µs is recommend when the FORCEPR# is asserted by the
system. Sustained activation of the FORCEPR# pin may cause noticeable platform performance
degradation.
Refer to the appropriate platform design guidelin es for details on implementing the FORCEPR#
signal feature.
6.2.5 THERMTRIP# Signal Pin
Regardless of whether or not Thermal Monitor is enabled, in the event of a catastrophic cooling
failure, the processor will automatically shut down when the silicon has reached an elevated
temperature (refer to the THERMTRIP# definition in Table 4-1). At this point, the system bus
signal THERMTRIP# will go active and stay active as described in Table 4-1. THERMTRIP#
activation is independent of processor activity and does not generate any bus cycles.
6.2.6 TCONTROL and Fan Speed Reduction
Tcontrol is a temperature specification bas ed on a temperature reading from the thermal diode. The
value for Tcontrol will be calibrated in manufacturing and configured for each processor. The
Tcontrol temperature for a given processor can be obtained by reading the
IA32_TEMPERATURE_T ARGET MSR in the processor . Each core within the processor will have
an IA32_TEMPERATU RE_TARGET MSR that will be programmed to the same value. The
Tcontrol value that is read from the IA32_TEMPERATURE_TARGET MSR must be converted
from Hexadecimal to Decimal and added to a base value. The base value is 50 °C for the
Dual-Core Intel Xeon processor.
The value of Tcontrol may vary from 0x00h to 0x1Eh. Refer to the IA-32 Intel® Architecture
Software Developer's Manual, Volume 3: System Programmer's Guide for specific register and
implementation detail s.
When Tdiode is above Tcontrol, then TCASE must be at or below TCASE_MAX as defined by the
thermal profile. (See Figure 6-1; Table 6-2 and Table 6-3). Otherwise, the processor temperature
can be maintained at Tcontrol.
6.2.7 Thermal Diode
The processor incorporates an on-die thermal diode. A thermal sensor located on the system board
may monitor the die temperature of th e processor for thermal manag e ment/long term die
temperature change purposes. This thermal diode is separate from the Thermal Monitors thermal
sensor and cannot be used to predict the behavior of the Thermal Monitor.
§
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 79
7Features
7.1 Power-On Configuration Options
Several configuration options can be configured by hardware. The Dual-Core Intel Xeon processor
samples its hardware configuration at reset, on the active-to-inactive transition of RESET#. For
specifics on these options, please refer to Table 7-1.
The sampled information configures the processor for subsequent operation. These configuration
options cannot be changed except by another reset . All resets reconfigure the processor, for reset
purposes, the processor does not distinguish between a “warm” reset and a “power-on” reset.
NOTES:
1. Asserting this signal during RESET# will select the corresponding option.
2. Address pins not identified in this table as configuration options should not be asserted during RESET#.
3. The Dual-Core Intel Xeon processor utilizes all four BR0#, BR1#, BR2# and BR3# signals. Please refer to the
appropriate platform design guide for further details
4. All power-on configuration settings affect both cores of the processor.
5. This mode not tested.
7.2 Clock Control and Low Power States
The processor allows the use of HALT, Stop-Grant and Sleep states to reduce power consumption
by stopping the clock to internal sections of the processor, depending on each particular state. See
Figure 7-1 for a visual representation of the processor low power states.
The Dual-Core Intel Xeon processor adds supports for the Enhanced HALT state. Refer to
Figure 7-1 and the following sections. For more configuration details also refer to the IA-32 Intel®
Architecture Software Developer's Manual, Volume 3: System Programmer's Guide.
The Stop Grant state requires chipset and BIOS support on multiprocessor systems. In a
multiprocessor system, all the STPCLK# signals are bussed together, thus all processors are
affected in unison. The Hyper-Threading Technolog y feature adds the conditions that all logical
processors share the same STPCLK# signal internally. When the STPCLK# signal is asserted, the
processor enters the Stop Grant state, issuing a Stop Grant Special Bus Cycle (SBC) for each
processor or logical processor. The chipset needs to account for a variable number of processors
asserting the Stop Grant SBC on the bus before allowing the processor to be transitioned into one
Table 7-1. Power-On Configuration Option Pins
Configuration Option Pin Notes
Output tri state SMI# 1,2,4
Execute BIST (Built-In Self Test) INIT# 1,2,4
In Order Queue de-pipelining (set IOQ depth to 1) A7# 1,2,4
Disable MCERR# observation A9# 1,2,4
Disable BINIT# observation A10# 1,2,4
Disable bus parking A 15# 1,2,4
Symmetric agent arbitration ID BR[3: 0]# 1,2,3,4
Enable Single Logical Processor Mode A31# 1,2,5
Features
80 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
of the lower processor power states. Refer to the applicable chipset specification and the IA-32
Intel® Ar chitectur e Software Developer's Manual, Volume 3: System Programmer's Guide for more
information.
Due to the inability of processors to recognize bus transactions during the Sleep state,
multiprocessor systems are not allowed to simultaneously have one processor in Sleep state and the
other processors in Normal or Stop-Grant state.
7.2.1 Normal State
This is the normal operating state for the processor.
7.2.2 HALT or Enhanced HALT States
The Enhanced HALT power down state is enabled by default in the Dual-Core Intel Xeon
processor. The Enhanced HALT power down state must remain enabled via the BIOS. Refer to the
IA-32 Intel® Architecture Software Developer's Manual, Volume 3: System Programmer's Guide.
The Enhanced HALT state requires support for dynamic VID transiti ons in the platform.
7.2.2.1 HALT Powerdown State
HALT is a low power state entered when the processor executes the HALT or MWAIT instruction.
When one of the logical processors executes the HALT or MWAIT instruction, that logical
processor is halted; however, the other processor continues normal operation. The processor will
transition to the Normal state upon the occurrence of SMI#, BINIT#, INIT#, LINT[1:0] (NMI,
INTR), or an interrupt delivered over the front side bus. RESET# will cause the processor to
immediately ini tialize itself.
The return from a System Management In terrupt (SMI) handler can be to either No rmal Mode or
the HALT Power Down state. See the IA-32 Intel® Arch itecture Software Developer's Manual,
Volume 3: System Programmer's Guide for more information.
The system can generate a STPCLK# while the processor is in t he HALT Power Down state. When
the system deasserts the STPCLK# interrupt, the processor will return execution to the HALT state.
While in HALT Power Down state, the processor will process front side bus snoops and int e rrupts.
7.2.2.2 Enhanced HALT Powerdown State
Enhanced HALT state is a low power state entered when all logical processors have executed the
HALT or MWAIT instruction and Enhanced HALT state has been enabled via the BIOS. When one
of the logical processors executes the HALT instruction, that logical processor is halted; however,
the other processor continues normal operation. The Enhanced HALT state is generally a lower
power state than the Stop Grant state.
The processor will automatically transition to a lower core frequency and voltage operating point
before entering the Enhanced HALT state. Note that the processor FSB frequency is not altered;
only the internal core frequency is changed. When entering the low power state, the processor will
first switch to the lower bus ratio and then transition to the lower VID.
While in the Enhanced HALT state, the processor will process bus snoops.
Features
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 81
The processor exits the Enhanced HALT state when a break event occurs. When the processor
exists the Enhanced HALT state, it will first transition the VID to the original value and then
change the bus ratio back to the original value.
7.2.3 Stop-Grant State
When the STPCLK# pin is asserted, the Stop-Grant state of the processor is entered 20 bus clocks
after the response phase of the processor-issued Stop Grant Acknowledge special bus cycle. Once
the STPCLK# pin has been asserted, it may only be deasserted once the processor is in the Stop
Grant state. For the Dual-Core Intel Xeon processor, all logical processors must be in the Stop
Grant state before the deassertion of STPCLK#.
Since the AGTL+ signal pins receive power from the front side bus, these pins should not be driven
(allowing the level to return to VTT) for minimum power drawn by the termination resistors in this
state. In addition, all other input pins on the front side bus should be driven to the inactive state.
BINIT# will not be serviced while the processor is in Stop-Grant state. The event will be latched
and can be serviced by software upon exit from the Stop Grant state.
Figure 7-1. Stop Clock State Machine
Enhanced HALT or HALT State
BCLK running
Snoops and interrupts allowed
Normal State
Normal execution
Enhanced HALT Snoop or HALT
Snoop State
BCLK running
Service snoops to caches
Stop Grant State
BCLK running
Snoops and interrupts allowed
Sleep State
BCLK running
No snoops or interrupts
allowed
Snoop
Event
Occurs
Snoop
Event
Serviced
INIT#, BINIT# , INTR, NM I, SMI# ,
RESET#, FSB interrupts
STPCLK#
Asserted STPCLK#
De-asserted
STPCLK#
Asserted
STPCLK#
De-asserted
SLP#
Asserted SLP#
De-asserted
Snoop Event Occurs
Snoop Event Serviced
HALT or MWAIT Instruction and
HALT Bus Cycle Generated
Stop Grant Snoop State
BCLK running
Service snoops to caches
Features
82 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
RESET# will cause the processor to immediately initialize itself, but the processor will stay in
Stop-Grant state. A transition back to the Normal state will occur with the de-assertion of the
STPCLK# signal. When re-entering the Stop-Grant state from the Sleep state, STPCLK# should
only be deasserted one or more bus clocks after the deassertion of SLP#.
A transition to the Grant Snoop state will occur when the processor detects a snoop on the front
side bus (see Section 7.2.4). A transition to the Sleep state (see Section 7.2.5) will occur with the
assertion of the SLP# signal.
While in the Stop-Grant state, SMI#, INIT#, BINIT# and LINT[1:0] will be latched by the
processor, and only serviced when the processor returns to the Normal state. Only one occurrence
of each event will be recognized upon return to the Normal state.
While in Stop-Grant state, the processor will process snoops on the front side bus and it will latch
interrupts delivered on the front side bus.
The PBE# signal can be driven when the processor is in Stop-Grant state. PBE# will be asserted if
there is any pending interrupt latched within the processor. Pending interrupts that are blocked by
the EFLAGS.IF bit being clear will still cause assertion of PBE#. Assertion of PBE# indicates to
system logic that it should return the processor to the Normal state.
7.2.4 Enhanced HALT Snoop or HALT Snoop State,
Stop Grant Snoop State
The Enhanced HALT Snoop state is used in conjunction with the Enhanced HALT state. If
Enhanced HALT state is not enabled in the BIOS, the default Snoop state entered will be the HALT
Snoop state. Refer to the sections below for details on HALT Snoop state, Grant Snoop state and
Enhanced HALT Snoop state.
7.2.4.1 HALT Snoop State, Stop Grant Snoop State
The processor will respond to snoop or in terrupt transactions on the front side bus while in Stop-
Grant state or in HALT Power Down state. During a snoop or interrupt transaction, the processor
enters the HALT/Grant Snoop state. The processor will stay in this state until the snoop on the front
side bus has been serviced (whether by the processor or another agent on the front side bus) or the
interrupt has been latched. After the snoop is serviced or the interrupt is latched, the processor will
return to the Stop-Grant state or HALT Po wer Down state, as appropriate.
7.2.4.2 Enhanced HALT Snoop State
The Enhanced HALT Snoop state is the default Snoop state when the Enhanced HALT state is
enabled via the BIOS. The processor will remain in the lower bus ratio and VID operating point of
the Enhanced HALT state.
While in the Enhanced HALT Snoop state, snoops and interrupt transacti ons are hand led the same
way as in the HALT Snoop state. After the snoo p is serviced or the interrupt is latched, the
processor will return to the Enhanced HALT state.
7.2.5 Sleep State
The Sleep state is a very low power state in which each processor maintains its context, maintains
the phase-locked loop (PLL), and has stopped most of internal clocks. The Sleep state can only be
entered from Stop-Grant state. Once in the S top-Grant state, the processor will enter the Sleep state
Features
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 83
upon the assertion of the SLP# signal. The SLP# pin has a minimum assertion of one BCLK
period. The SLP# pin should only be asserted when th e processor is in the Stop Grant state. For
Dual-Core Intel® Xeon® processors, the SLP# pin may only be asserted when all logical
processors are in the Stop-Grant state. SLP# assertions while the processors are not in the Stop-
Grant state are out of specification and may results in illegal operati on.
Snoop events that occur while in Sleep state or during a transition into or out of Sleep state will
cause unpredictab le behavior.
In the Sleep state, the processor is incapable of responding to snoop transactions or latching
interrupt signals. No transitions or assertions of signals (with the exception of SLP# or RESET#)
are allowed on the front side bus while the pro cessor is in Sleep state. Any transition on an input
signal before the processor has returned to Stop-Grant state will result in unpredictable behavior.
If RESET# is driven active while the processor is in the Sleep state, and held active as specified in
the RESET# pin specification, then the processor will reset itself, ignoring the transition through
Stop-Grant state. If RESET# is driven active while the processor is in the Sleep state, the SLP# and
STPCLK# signals should be deasserted imme diat ely after RESET# is asserted to ensure the
processor correctly executes the reset sequence.
When the processor is in Sleep state, it will not respond to interrupts or snoop transactions.
7.3 Enhanced Intel SpeedStep® Technology
Enhanced Intel SpeedStep Technology enables the processor to switch between multiple frequency
and voltage points, which may result in platform power savings. In order to support this
technology, the system must support dynamic VID transitions. Switching between voltage /
frequency states is software controlled. For more configuration details also refer to the IA-32 Intel®
Architecture Software Developer's Manual, Volume 3: System Programmer's Guide.
Note: Not all processors are capable of supporting Enhanced Intel SpeedStep Technology. Details
on which processor frequencies support this feature are provided in the Dual-Core Intel® Xeon®
Processor 2.80 GHz Specificat ion Updat e .
Enhanced Intel SpeedStep Technology is a technology that creates processor performance states
(P-states). P-states are power consumption and capability states within the Normal s tate. Enhanced
Intel SpeedStep Technology enables real-time dynamic switch ing between frequency and voltage
points. It alters the performance of the processor by changing the bu s to core frequency ratio and
voltage. This allows the processor to run at different core frequencies and voltages to best serve the
performance and power requirements of the processor and system. Note that the front side bus is
not altered; only the internal core frequency is changed. In order to run at reduced power
consumption, the voltage is altered in step with the bus ratio. The Dual-Core Intel Xeon processor
includes hardware logic that coordinates the requested processor voltage between the cores. The
highest voltage that is requested for either of the processor cores is selected for that processor.
The following are key features of Enhanced Intel SpeedStep Technology:
1. Multiple voltage / frequency operating points pro vide optimal performance at reduced power
consumption.
2. Voltage / Frequency selection is software controlled by writing to processor MSR’s (Model
Specific Registers), thus eliminating chipset dependency.
If the target frequency is higher than the current frequency, VCC is incremented in steps
(+12.5 mV) by placing a new value on the VID signals. The Phase Lock Loop (PLL) then locks to
the new frequency. Note that the top frequency for the processor can not be exceeded.
Features
84 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
If the target frequency is lower than the current frequency, the PL L locks to the new frequency . The
VCC is then decremented in step (-12.5 mV) by changing the target VID through the VID signals.
Refer to the IA-32 Intel® Architecture Software Developer's Manual, Volume 3: System
Programmer's Gui de for specific information to enable and configure Enhanced Intel SpeedStep
Technology in BIOS.
§
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 85
8Boxed Processor Specifications
8.1 Introduction
Intel boxed processors are intended for system integrators who build systems from components
available through distribution channels. The Dual-Core Intel Xeon processor is offered as an Intel
boxed processor.
Intel offers boxed processors with three product configurations available for each processor
frequency: 1U passive, 2U passive and 2U+ Active. Although the active thermal solution
mechanically fits into a 2U keepout, additional design considerations may need to be addressed to
provide sufficient airflow to the fan inlet.
The active thermal solution is primarily designed to be used in a pedestal chassis where sufficient
air inlet space is present and side directional airflow is not an issue. The 1U and 2U passive thermal
solutions require the use of chassis ducting and are targeted for use in rack mount servers. The
retention solution used for these products is called the Common Enabling Kit, or CEK. The CEK
base is compatible with all three thermal solutions.
The active heat sink solution for the boxed processor will be a 4-pin pulse width modulated (PWM)
T-diode controlled solution. Use of a 4-pin PWM T-diode controlled active thermal solution helps
customers meet acoustic targ ets in pedestal platforms through the platform’s ability to directly
control the active thermal solution. It may be necessary to modify existing baseboard designs with
4-pin CPU fan headers and other required circuitry for PWM operation. If a 4-pin PWM T-diode
controlled active thermal solution is connected to an older 3-pin CPU fan header, the thermal
solution will reve rt back to a thermistor controlled mode. Please see the Section 8 .3, “Electrical
Requirements” on page 8-95 for more details.
Figure 8-1 through Figure 8-3 are representations of the three heat sink solutions that will be
offered as part of a boxed processor. Figure 8-4 shows an exploded view of th e boxed processor
thermal solution and the other CEK retention components.
Figure 8-1. 1U Passive CEK Heat Sink
Boxed Processor Specifications
86 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 8-2. 2U Passive CEK Heat Sink
Figure 8-3. Active CEK Heat Sink (Representation Only)
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 87
NOTE:
1. The heat sink in this image is for reference only, and may not represent any of the actual boxed processor
heat sinks.
2. The screws, springs, and standoffs will be captive to the heat sink. This image shows all of the components in
an exploded view.
3. It is intended that the CEK spring will ship with the base board and be pre-attached prior to shipping.
8.2 Mechanical Specifications
This section documents the mechanical specifications of the boxed processor.
8.2.1 Boxed Processor Heat Sink Dimensions (CEK)
The boxed processor will be shipped with an unattached thermal solution. Clearance is required
around the thermal solution to ensure unimpeded airflow for proper cooling. The physical space
requirements and dimensions for the box ed processor and assembled heat sink are show n in
Figure 8-5 through Figure 8-9. Figure 8-10 through Figure 8-11 are the mechanical drawings for
the 4-pin server board fan header and 4-pin connector used for the active CEK fan heat sink
solution.
Figure 8-4. Pass iv e The rmal Solution (2U and la rge r)
Heat sink
Heat sink standoffs
Heat sink screw
springs
Thermal Interface
Material
Heat sink
screws
Motherboard
and
processor
Chassi s pan
Protective Tape
CEK spring
Heat sink
Heat sink standoffs
Heat sink screw
springs
Thermal Interface
Material
Heat sink
screws
Motherboard
and
processor
Chassi s pan
Protective Tape
CEK spring
Boxed Processor Specifications
88 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 8-5. Top Side Board Keep-Out Zones (Part 1)
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 89
Figure 8-6. Top Side Board Keep-Out Zones (Part 2)
Boxed Processor Specifications
90 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 8-7. Bottom Side Board Keep-Out Zones
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 91
Figure 8-8. Board Mounting Hole Keep-Out Zones
Boxed Processor Specifications
92 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 8-9. Volumetric Height Keep-Ins
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 93
Figure 8-10. 4-Pin Fan Cable Connector (For Active CEK Heat Sink)
Boxed Processor Specifications
94 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
Figure 8-11. 4-Pin Base Board Fan Header (For Active CEK Heat Sink)
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 95
8.2.2 Boxed Processor Heat Sink Weight
8.2.2.1 Thermal Solution Weight
The 2U passive and 2U+ active heat sink solutions will not exceed a mass of 1050 grams. Note that
this is per processor, therefore a dual processor system will likely have up to 2100 grams of total
mass for the heat sinks alone. The 1U CEK heat sink will not exceed a mass of 700 grams, for a
total of 1400 grams of heat sink mass in a dual processor system. This large mass requires that
minimum chassis stiffness be met in order to withstand reasonable shock and vibration forces.
Please refer to Section 3.6 for details on the weight of the processor.
8.2.3 Boxed Processor Retention Mechanism and Heat Sink
Support (CEK)
Baseboards and chassis designed for use by a system integrator should include holes that are in
proper alignment with each other to support the boxed processor. Refer to the Server System
Infrastructure Specification (SSI-EEB 3.51) or see http://www.ssiforum.org for details on the hole
locations.
Figure 8-4 illustrates the new Common Enabling Kit (CEK) retention solution. The CEK is
designed to extend air-cooling capability through the use of larger heat sinks with minimal airflow
blockage and bypass. CEK retention mechanisms can allow the use of much heavier heat sink
masses compared to legacy limits by using a load path directly attached to the chassis pan. The
CEK spring on the secondary side of the baseboard provides the necessary compressive load for
the thermal interface material. The baseboard is intended to be isolated such that the dynamic loads
from the heat sink are transferred to the chassis pan via the stiff screws and standof fs. The retention
scheme reduces the risk of package pullout and solder joint failures.
The baseboard mounting holes for the CEK solution are the same location as the legacy server
processor hole locations, as specified by the SSI EEB 3.5. However, the CEK assembly requires
larger diameter holes to compensate for the CEK spring embosses. The holes now need to be
10.2 mm [0.402 in.] in diameter.
All components of the CEK heat sink solution will be captive to the heat sink and will only require
a Phillips screwdriver to attach to the chassis pan. When installing the CEK, the CEK screws
should be tightened until they will no longer turn easily. This should represent approx imately 8
inch-pounds of torque. Avoid applying more than 10 inch-pounds of torque; otherwise, damage
may occur to retention mechanism components.
For further details on the CEK thermal solution, refer to the Dual-Co re Intel® Xeon® Processor
2.80 GHz Thermal/Mechanical Design Guidelines (see Section 1.2).
8.3 Electrical Requirements
8.3.1 Power Supply Requirements
Due to the design differences between the Dual-Core Intel Xeon pro cessor and the 64-bit Intel®
Xeon® processor with 2MB L2 cache, the Dual-Core Intel Xeon processor has slightly greater
+12V rail current requirements. Systems using Dual-Core Intel Xeon processors require power
supply designs with sp lit +12V rails capable of supplying a minimum of 15 amp s of continuous
Boxed Processor Specifications
96 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
current while also being able to supply up to 17.5 am ps at peak load ti mes. Power suppl ies not
meeting these criteria should not be used in systems using the Dual-Core Intel Xeon processor as
these systems may exhibit unstable behavior, particularly during peak load times.
8.3.2 Fan Power Supply (Active CEK)
The 4-pin PWM/T-diode controlled active thermal solution is being offered to help provide better
control over pedestal chassis acoustics. This is achieved though more accurate measurement of
processor die temperature through the processors temperature diode (T-diode). Fan RPM is
modulated through th e use of an ASIC located on the baseboard, that sends out a PWM control
signal to the 4th pin of the connector labeled as Control. This thermal solution requires a constant
+12 V supplied to pin 2 of the active thermal solution and does not support variable voltage control
or 3-pin PWM control. See Table 8-2 for details on the 3- and 4-pin active heat sink solut ion
connectors.
If the new 4-pin active fan heat sink solution is connected to an older 3-pin baseboard CPU fan
header it will default back to a thermistor controlled mode, allowing compatibility with exist ing
designs. When operating in thermistor controlled mode, fan RPM is automatically varied based on
the TINLET temperature measured by a thermistor located at the fan inlet. It may be necessary to
change existing baseboard designs to support the new 4-pin active heat sink solution if PWM/
T-diode control is desired. It may also be necessary to verify that the larger 4-pin fan connector will
not interfere with other components installed on the baseboard.
The fan power header on the baseboard must be positioned to allow the fan heat sink power cab le
to reach it. The fan power header identification and location must be documented in the suppliers
platform documentation, or on the baseboard its elf. The baseboard fan power header should be
positioned within 177.8 mm [7 in.] from the center of the processor socket.
Table 8-1. PWM Fan Frequency Specifications for 4-Pin Active CEK Thermal Solution
Description Min Frequ ency Nominal Frequency Max Frequency Unit
PWM Control
Frequency Range 21,000 25,000 28,000 Hz
Table 8-2. Fan Specifications for 4-pin Active CEK Thermal Solution
Description Min Typ
Steady Max
Steady Max
Startup Unit
+12 V: 12 volt fan power supply 10.8 12 12 13.2 V
IC: Fan Current Draw N/A 1 1.25 1.5 A
SENSE: SENSE frequency 2 2 2 2 Pulses per fan
revolution
Boxed Processor Specifications
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 97
This section describes the cooling requirements of the heat sink solution utilized by the boxed
processor.
8.3.3 Boxed Processor Cooling Requirements
As previously stated the boxed processor will be available in three product configurations. Each
configuration will require un ique design considerations. Meeting the processors temperature
specifications is also the function of the thermal design of the entire system, and ultimately the
responsibility of the system integrator. The processor temperature specifications are found in
Section 6 of this document.
8.3.3.1 1U Passive CEK Heat Sink (1U form factor)
In the 1U configuration it is assum e d that a chassis duct will be implemented to provide 15 CFM
[x m3/hr] of airflow to pass through the heat sink fins. The duct should be designed as precisely as
possible and should not allow any air to bypass the heat sink (0” bypass) and a back pressure of
0.375 in. H2O [y dP] (25.5m3/hr @ 93.3Pa). It is assumed that a 40° C TLA is met. This requires a
Figure 8-12. Fan Cable Connector Pin Out for 4-Pin Active CEK Thermal Solution
Table 8-3. Fan Cable Connector Pin Out for 4-Pin Active CEK Thermal Solution
Pin Number Signal Color
1 Ground Black
2Power: (+12 V) Yellow
3Sense: 2 pulses per revolution Green
4Control: 21 KHz-28 KHz Blue
Table 8-4. Fan Cable Connector Supplier & Part Number
Vendor 3-Pin Connector Part Number 4-Pin Connector Part Number
AMP Fan Connector: 643815-3
Header: 640456-3 N/A
Walden
Molex Fan Connector: 22-01-3037
Header: 22-23-2031 Fan Connector: 47054-1000
Header: 47053-1000
Wieson N/A Fan Connector: 2510C888-001
Header: 2366C888-007
Foxconn N/A Fan Connector: N/A
Header: HF27040-M1
Boxed Processor Specifications
98 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
superior chassis design to limit the TRISE at or below 5° C with an external ambient temperature of
35° C. Following these guideli nes will allow the designer to meet Thermal Profile B and conform
to the thermal requirements of the processor.
8.3.3.2 2U Passive CEK Heat Sink (2U and above form factor)
Once again a chassis duct is required for the 2U passive heat sink. In this configuration Thermal
Profile A (see Section 6) should be followed by supplying 22 CFM [x m3/hr] of airflow through the
fins of the heat sink with a 0” or no duct bypass and a back pressure of 0.142 in. H2O [y dP ]
(37.4m3/hr @ 35.5 Pa). The TLA temperature of 40° C should be met. This may require the use of
superior design techniques to keep TRISE at or below 5° C based on an ambient external
temperature of 35° C.
8.3.3.3 2U+ Active CEK Thermal Solution (2U+ and above pedestal)
This thermal solution was design ed to help pedestal chassis users to meet the thermal processor
requirements without the use of chassis ducting. It may be necessary to implement some form of
chassis air guide or air duct to meet the TLA temperature of 40° C depending on the pedestal
chassis layout. Also, while the active thermal solution is designed to mechanically fit into a 2U
chassis, it may require additional space at the top of the thermal solution to allow sufficient airflow
into the heat sink fan. Therefore, additional design criteria may need to be considered if this
thermal solution is used in a 2U rack mou nt chassi s, or in a chassis that has drive bay obstructions
above the inlet to the fan heat sink.
Thermal Profile A should be used to help determine the thermal performance of the platform.
Once again it is recommended that the ambient air temperature outside of the chassis be kept at or
below 35° C. The air passing directly over the processor therm a l solution should not be preheat ed
by other system components. Meeting the processors temperature specification is the
responsibility of the system integrator.
8.4 Boxed Processor Contents
A direct chassis attach method must be used to avoid problems relate d to shock and vibration, due
to the weight of the thermal solution required to cool the processor. The board must not bend
beyond specification in order to avoid damage. The boxed processor contains the components
necessary to solve both issues. The boxed processor will include the following items:
Dual-Core Intel Xeon processor
Unattached (Active or Passive) Thermal Solution
4 screws, 4 springs, and 4 heat sink standoffs (all captive to the heat sink)
Thermal Interface Material (pre-applied on heat sink)
Installation Manual
Intel Inside®‚ Logo
The other items listed in Figure 8-4 that are required to compete this solution will be shipped with
either the chassis or boards. They are as follows:
Heat sink standoffs (supplied by chassis vendors)
§
Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet 99
9Debug Tools Specifications
Please refer to the ITP700 Debug Port Design Guide for information regarding debug tool
specifications. Section 1.2 provides collat e ral det ails.
9.1 Debug Port System Requirements
The Dual-Core Intel Xeon processor debug port is the command and control interface for the In-
Tar get Probe (ITP) debugger. The ITP enables run-time control of the processors for system debug.
The debug port, which is connected to the front side bus, is a combination of the system, JTAG and
execution signals. There are several mechanical, electrical and functional constraints on the debug
port that must be followed. The mechanical constraint requires the debug port connector to be
installed in the system with adequate physical clearance. Electrical constraints exist due to the
mixed high and low speed signals of the deb ug port for the processor. While the JTAG signals
operate at a maximum of 75 MHz, the execution signals operate at the common clock front side bus
frequency (200 MHz). The functional constraint requires the debug port to use the JTAG system
via a handshake and multiplexing scheme.
In general, the information in this chapter may be used as a basis for including all run-control tools
in Dual-Core Intel Xeon processor-based system designs, including tools from vendors other than
Intel.
Note: The debug port and JTAG signal chain must be designed into the processor board to utilize the ITP
for debug purposes.
9.2 Target System Implementation
9.2.1 System Implementation
Specific connectivity and layout guidelines for the Debug Port are provided in the ITP700 Debug
Port Design Guide.
9.3 Logic Analyzer Interface (LAI)
Intel is working with two logic analyzer vendors to provide logic analyzer interfaces (LAIs) for use
in debugging Dual-Core Intel Xeon processor system s. Tektronix and Agilent should be contacted
to obtain specific information about their logic analyzer interfaces. The following information is
general in nature. Specific information must be obtained from the logic analyzer vendor.
Due to the complexity of Dual-Core Intel Xeon processor-based multiprocessor systems, the LAI is
critical in providing the ability to prob e and capture front side bus signals. There are two sets of
considerations to keep in mind when design ing a Dual-Core Intel Xeon processor-based system
that can make use of an LAI: mechanical and electrical.
Debug Tools Specifications
100 Dual-Core Intel® Xeon® Processor 2.80 GHz Datasheet
9.3.1 Mechanical Considerations
The LAI is installed between the processor socket and the processor. The LAI pins plug in to the
socket, while the processor pins plug into a socket on the LAI. Cabling that is part of the LAI
egresses the system to allow an electrical connection between the processor and a logic analyzer.
The maximum volume occupied by the LAI, known as the keepout volume, as well as the cable
egress restrictions, should be obtai ned from the logi c analyzer vendor. System designers must
make sure that the keepout volume remains unobstructed inside the system. Note that it is possible
that the keepout volume reserved for the LAI may include differerent requirements from the space
normally occupied by the heat sink . If this is the case, the logic analyzer vendor will provide a
cooling solution as part of the LAI.
9.3.2 Electrical Considerations
The LAI will also affect the electrical performance of the front side bus, therefore it is critical to
obtain electrical load models from each of the logic analyzer vendors to be able to run system level
simulations to prove that their tool will work in the system. Contact the logic analyzer vendor for
electrical specifications and load models for the LAI solution they provide.
§