Reference Number: 329187-002
Intel® Xeon® Processor E5-1600/E5-
2600/E5-4600 v2 Product Families
Datasheet - Volume One of Two
March 2014
2Intel
® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
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The Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families, Intel® C600 Series chipset, and the Intel® Xeon®
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Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 3
Datasheet Volume One of Two
Table of Contents
1Overview.................................................................................................................11
1.1 Introduction .....................................................................................................11
1.1.1 Processor Feature Details ........................................................................15
1.1.2 Supported Technologies ..........................................................................15
1.2 Interfaces ........................................................................................................ 16
1.2.1 System Memory Support.........................................................................16
1.2.2 PCI Express* ......................................................................................... 17
1.2.3 Direct Media Interface Gen 2 (DMI2)......................................................... 19
1.2.4 Intel® QuickPath Interconnect (Intel® QPI) ............................................... 19
1.2.5 Platform Environment Control Interface (PECI)...........................................19
1.3 Power Management Support ............................................................................... 20
1.3.1 Processor Package and Core States...........................................................20
1.3.2 System States Support ........................................................................... 20
1.3.3 Memory Controller................. .................................................................20
1.3.4 PCI Express* ......................................................................................... 20
1.3.5 Intel® QPI.............................................................................................20
1.4 Thermal Management Support ............................................................................20
1.5 Package Summary......... .. .. .. ............. .. .. ............. .. .. ......................... .. ... ..............21
1.6 Terminology .....................................................................................................21
1.7 Related Documents ...........................................................................................24
1.8 Statement of Volatility (SOV)..............................................................................24
1.9 State of Data... .. ... .. ............ .. ... ............ .. .. .......................... .. .. ......................... ..24
2Interfaces................................................................................................................25
2.1 System Memory Interface ..................................................................................25
2.1.1 System Memory Technology Sup p ort ................................. .. ............... .. .... 25
2.1.2 System Memory Timing Sup p ort............... .. .. .. ............... ...........................25
2.2 PCI Express* Interface.......................................................................................26
2.2.1 PCI Express* Architecture ....................................................................... 26
2.2.2 PCI Express* Configuration Mechanism .....................................................27
2.3 DMI2/PCI Express* Interface..............................................................................28
2.3.1 DMI2 Error Flow.....................................................................................28
2.3.2 Processor/PCH Compatibility Assumptions..................................................28
2.3.3 DMI2 Link Down.....................................................................................28
2.4 Intel® QuickPath Interconnect (Intel® QPI) ......................................................... 28
2.5 Platform Environment Control Interface (PECI)...................................................... 29
2.5.1 PECI Client Capabilities ........................................................................... 30
2.5.2 Client Command Suite ................... .. ............. .. .. .. ............. .. .. .. ............. .. ..31
2.5.3 Client Manag e me nt................ ............. .. .. ......................... .. .. ............. .. .. ..69
2.5.4 Multi-Domain Commands ........................................................................74
2.5.5 Client Responses........ ... .. .......................................................................75
2.5.6 Originator Responses.............................................................................. 76
2.5.7 DTS Temperature Data ...........................................................................76
3 Technologies ...........................................................................................................79
3.1 Intel® Virtualization Technology (Intel® VT).........................................................79
3.1.1 Intel® VT-x Objectives............................................................................79
3.1.2 Intel® VT-x Features ..............................................................................80
3.1.3 Intel® VT-d Objectives ...........................................................................80
3.1.4 Intel® Virtualization Technology Processor Extensions ................................ 81
3.2 Security Technologies ........................................................................................81
3.2.1 Intel® Trusted Execution Technology........................................................81
3.2.2 Intel® Trusted Execution Technology – Server Extensions ...........................82
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Datasheet Volume One of Two
3.2.3 AES Instructions.....................................................................................82
3.2.4 Execute Disable Bit .................................................................................83
3.3 Intel® Secure Key............................. .. .. ............. .. .. ............. .. .. ............ ... .. ..........83
3.4 Intel® OS Guard............ ............. .. .. ............ .. ... ............ .. .. ............. .. .. ............. .. ..83
3.5 Intel® Hype r-T hre ading Te chnolog y............ .. .. ............................ ............... ..........83
3.6 Intel® Turbo Boost Technology................. .. .. ............................ ...........................84
3.6.1 Intel® Turbo Boost Operating Frequency..................... .. .. ............... .. .. .. ......84
3.7 Enhanced Intel SpeedStep® Technology...............................................................84
3.8 Intel® Intelligent Power Technology.....................................................................85
3.9 Intel® Advanced Vector Extensions (Intel® AVX) .... .. ......................... .. .. ... ............85
3.10 Intel® Dynamic Power Technology .......................................................................86
4 Power Management .................................................................................................87
4.1 ACPI States Supported .......................................................................................87
4.1.1 System States................. ............ .. .. .. ............. .. .. ............. .. .. ...................87
4.1.2 Processor Package and Core States...........................................................87
4.1.3 Integrated Me mory Controller States............... ............... ............... ............88
4.1.4 DMI2/PCI Exp re ss* Link States.................................................................89
4.1.5 Intel® QuickPath Interconnect States........................................................89
4.1.6 G, S, and C State Combinations................................................................89
4.2 Processor Core/Package Power Management ......................................................... 90
4.2.1 Enhanced Intel SpeedStep® Technology....................................................90
4.2.2 Low-Power Idle States.............................................................................90
4.2.3 Requesting Low - Po we r Idle State s .............. .. ............... ........................... ..91
4.2.4 Core C-states.........................................................................................92
4.2.5 Package C-States ...................................................................................93
4.2.6 Package C-State Power Specifications........................................................97
4.2.7 Processor Package Power Specifications.....................................................97
4.3 System Memory Power Management ....................................................................98
4.3.1 CKE Power-Down......................... .. .. ............. .. .. ............. .. .. ............. .. .. ....98
4.3.2 Self Refresh...........................................................................................99
4.3.3 DRAM I/O Power Management..................................................................99
4.4 DMI2/PCI Expr e ss* Pow e r Ma nage me nt.................... ........................... ...............100
5 Thermal Management Specifications......................................................................101
5.1 Package Thermal Specifications .........................................................................101
5.1.1 Thermal Specifications.......... .. .. .. ............... ........................... ............... ..101
5.1.2 TCASE and DTS Based Thermal Specifications...........................................103
5.1.3 Processor Operational Thermal Specifications ...........................................104
5.1.4 Embedded Server Thermal Profiles..........................................................108
5.1.5 Thermal Metrology...... ............................ ..............................................111
5.2 Processor Core Thermal Features.......................................................................112
5.2.1 Processor Temperature..........................................................................112
5.2.2 Adaptive The r mal Monitor.............................................................. .. .. ....112
5.2.3 On-Demand Mode.................................................................................115
5.2.4 PROCHOT_N Signal...............................................................................116
5.2.5 THERMTRIP_N Signal ............................................................................116
5.2.6 Integrated Memory Controller (IMC) Thermal Features...............................117
6 Signal Desc riptions ................................................................................................119
6.1 System Memory Interface Signals......................................................................119
6.2 PCI Express* Based Interface Signals.................................................................120
6.3 DMI2/PCI Exp re ss* Port 0 Sig n als..... .. .. ........................... ..................................122
6.4 Intel® QuickPath Interconnect Signals ...............................................................122
6.5 PECI Signal.....................................................................................................123
6.6 System Reference Clock Signals ........................................................................123
6.7 JTAG and TAP Signals.......................................................................................123
6.8 Serial VID Interface (SVID) Signals....................................................................124
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 5
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6.9 Processor Asynchronous Sideband and Miscellaneous Signals ................................ 124
6.10 Processor Power and Ground Supplies................................................................ 127
7 Electrical Specifications......................................................................................... 129
7.1 Processor Signaling ......................................................................................... 129
7.1.1 System Memory Interface Sig n al Groups ............... ............... .. .. ... ............ 129
7.1.2 PCI Express Signals.............................................................................. 129
7.1.3 DMI2/PCI Express Signals ..................................................................... 129
7.1.4 Intel® QuickPath Interconnect ............................................................... 129
7.1.5 Platform Environmental Control Interface (PECI) ...................................... 130
7.1.6 System Reference Clocks (BCLK{0/1}_DP, BCLK{0/1}_DN)..................... .. 130
7.1.7 JTAG and Test Access Port (TAP) Signals .................. .. .. .. ............... .. .. ...... 131
7.1.8 Processor Sideband Signals . .................................................................. 131
7.1.9 Power, Ground and Sense Signals........................................................... 131
7.1.10 Reserved or Unused Signals................................................................... 136
7.2 Signal Group Summary................... ............... .................................................. 136
7.3 Power-On Configuration (POC) Options............................................................... 140
7.4 Fault Resilient Booting (FRB)............................................................................. 140
7.5 Mixing Processors............................................................................................ 141
7.6 Flexible Motherb oard Guidelines (FMB)................... .. ............... .. ............... .......... 142
7.7 Absolute Maximum and Minimum Ratings ........................................................... 142
7.7.1 Storage Condition Specifications............................................................. 142
7.8 DC Specifications ............................................................................................ 143
7.8.1 Voltage and Current Specifications.......................................................... 143
7.8.2 Die Voltage Validation.......... ............... ........................... ............... ........ 148
7.8.3 Signal DC Specifications....... .. .. .. .. .. .. ............... ............... ............... .. ...... 149
7.9 Signal Quality............. .. ...................................... .. .. .. ............. .. .. .. ............. .. .. .. 156
7.9.1 DDR3 Signal Quality Specifications ......................................................... 156
7.9.2 I/O Signal Quality Specifications............................................................. 156
7.9.3 Intel® QuickPath Interconnect Signal Quality Specifications ....................... 156
7.9.4 Input Reference Clock Signal Quality Specifications................................... 156
7.9.5 Overshoot/Undershoot Tolerance............................................................ 157
8 Processor Land Listing........................................................................................... 161
8.1 Listing by Land Name ................... ......................... .. .. .. ............. .. .. .. ............. .. .. 161
8.2 Listing by Land Number ....................................... .. .. ............. .. .. ....................... 185
9 Package Mechanical Specifications ........................................................................ 211
9.1 Package Size and SKUs.......... ... ......................... .. .. ......................... .. ... ............ 211
9.2 Package Mechanical Drawin g (PM D )...... .. .. .. .. ... ........................... ....................... 212
9.3 Processor Component Ke ep -Out Zone s.................................. .............. ............... 217
9.4 Package Loading Specifications ........ .. ............... .............. ............... ............... .... 217
9.5 Package Handling Guidelin es.............. .. .. ............... ........................... ................. 217
9.6 Package Insertion Specifications........... ............... .. .. .. .. ............... .. .. ............... .. .. 217
9.7 Processor Mass Specification............................................................................. 218
9.8 Processor Materials.......................................................................................... 218
9.9 Processor Markings.......................................................................................... 218
10 Boxed Processor Specifications ............................................................................. 219
10.1 Introduction ................................................................................................... 219
10.1.1 Available Boxed Thermal Solution Configurations...................................... 219
10.1.2 Intel Thermal Solution STS200C
(Passive/Active Combination Heat Sink Solution)...................................... 219
10.1.3 Intel Thermal Solution STS200P and STS200PNRW
(Boxed 25.5 mm Tall Passive Heat Sink Solutions).................................... 220
10.2 Mechanical Specifications ................................................................................. 221
10.2.1 Boxed Processor Heat Sink Dimensions and Baseboard Keepout Zones........ 221
10.2.2 Boxed Processor Retention Mechanism and Heat Sink Support (ILM-RS) ...... 230
6Intel
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Datasheet Volume One of Two
10.3 Fan Power Supply [STS200C]........ ................................... .. ................. ..............230
10.3.1 Boxed Processor Cooling Requirements....................................................231
10.4 Boxed Processor Contents.................................................................................234
Figures
1-1 Intel® Xeon® Processor E5-1600 v2 Product Family on the 1 Socket
Platform ...........................................................................................................13
1-2 Intel Xeon Processor E5-2600 v2 Product Family on the 2 Socket
Platform ...................... .. .. ............. .. .. ............. .. .. ............ ... .. ............ .. ... ............14
1-3 Intel Xeon Processor E5-4600 v2 Product Family on the 4 Socket
Platform ...................... .. .. ............. .. .. ............. .. .. ............ ... .. ............ .. ... ............14
1-4 PCI Express* Lane Partitioning and Direct Media Interface Gen 2 (DMI2) ................... 18
2-1 PCI Express* Layering Diagram...........................................................................26
2-2 Packet Flow through the Layers ...........................................................................27
2-3 Ping() ..............................................................................................................31
2-4 Ping() Example..................................................................................................31
2-5 GetDIB() ..........................................................................................................32
2-6 Device Info Field Definition .................................................................................32
2-7 Revision Number Definition .................................................................................33
2-8 GetTemp()........................................................................................................34
2-9 GetTemp() Exam ple............................ .. .. ......................... ... .. ............ .. ... ............34
2-10 RdPkgConfig()...................................................................................................35
2-11 WrPkgConfig()...................................................................................................37
2-12 DRAM Thermal Estimation Configuration Data........................................................40
2-13 DRAM Rank Temperature Write Data .................................................................... 41
2-14 The Processor DIMM Temperature Read / Write .....................................................42
2-15 Ambient Temperature Reference Data ..................................................................42
2-16 Processor DRAM Channel Temperature .................................................................43
2-17 Accumulated DRAM Energy Data..........................................................................43
2-18 DRAM Power Info Read Data ............................................................................... 44
2-19 DRAM Power Limit Data............... .. ............ .. .. ... ............ .. .. ... ............ .. .. ... ............45
2-20 DRAM Pow er Limit Pe rform a nce Data............................ ............... .. ............... ........45
2-21 CPUID Data .......................... .. ... ......................... .. .. ......................... .. ... ............49
2-22 Platform ID Data ...............................................................................................50
2-23 PCU Device ID...................................................................................................50
2-24 Maximum Thread ID...........................................................................................50
2-25 Processor Microcode Revision ..............................................................................50
2-26 Machine Check Status ........................................................................................51
2-27 Package Power SKU Unit Data .............................................................................51
2-28 Package Power SKU Data....................................................................................52
2-29 Package Temperature Read Data .........................................................................53
2-30 Temperature Target Read ...................................................................................54
2-31 Thermal Status Word ........................ .. ........................... ............................ ........54
2-32 Thermal Averaging Constant Write / Read.............................................................55
2-33 Current Config Limit Read Data ...........................................................................55
2-34 Accumulated Energy Read Data ...........................................................................56
2-35 Pow er Lim it Data for VCC Power Plane........................ ........................... ...............57
2-36 Package Turbo Power Limit Data..........................................................................58
2-37 Package Power Limit Performance Data ................................................................58
2-38 Efficient Performance Indicator Read ....................................................................58
2-39 ACPI P-T Notify Data..........................................................................................59
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 7
Datasheet Volume One of Two
2-40 Caching Agent TOR Read Data ............................................................................60
2-41 DTS Thermal Margin Read ..................................................................................60
2-42 Processor ID Construction Example......................................................................61
2-43 RdIAMSR()....................................................................................................... 62
2-44 PCI Configuration Address..................................................................................64
2-45 RdPCIConfig()................................................................................................... 65
2-46 PCI Configuration Address for local accesses.........................................................66
2-47 RdPCIConfigLocal()............................................................................................66
2-48 WrPCIConfigLocal() ........................................................................................... 68
2-49 The Processor PECI Power-up Timeline() ..............................................................70
2-50 Temperature Sensor Data Format........................................................................ 76
4-1 Idle Power Management Breakdown of the Processor Cores.....................................91
4-2 Thread and Core C-State Entry and Exit ...............................................................91
4-3 Package C-State Entry and Exit.................. ............... ............................ ..............95
5-1 TCase Temperatur e The rmal Profile ................. .. .. .. ............... .............. ... ............ 106
5-2 Digital Thermal Sensor DTS Thermal Profile ........................................................ 108
5-3 Embedded Case Temperature Thermal Profile...................................................... 110
5-4 Embedded DTS Thermal Profile ......................................................................... 111
5-5 Case Temperature (TCA SE) Me asure me nt Location................. .. .. .. .. ............... .. .. .. 112
5-6 Frequency and Voltage Ordering........................................................................ 115
7-1 Input Device Hysteresis ................................................................................... 130
7-2 VR Power-State Transitions............................................................................... 134
7-3 Processor VCC Static and Transient Tolerance Loadlines ....................................... 147
7-4 Load Current Versus Time ................... .. .. ......................................................... 148
7-5 VCC Overshoot Example Waveform.................................................................... 149
7-6 BCLK{0/1} Differential Clock Crosspoint Specification .......................................... 155
7-7 BCLK{0/1} Differential Clock Measurement Point for Ringback .............................. 155
7-8 BCLK{0/1} Sing le Ended Clock Measurement Points for Absolute Cross Point
and Swing...................................................................................................... 155
7-9 Maximum Acceptable Overshoot/Undershoot Waveform........................................ 159
9-1 Processor Package Assembly Sketch .................................................................. 211
9-2 Processor PMD Package A (52.5 x 45 mm) Sheet 1 of 2........................................ 213
9-3 Processor PMD Package A (52.5 x 45 mm) Sheet 2 of 2........................................ 214
9-4 Processor PMD Package B (52.5 x 51 mm) Sheet 1 of 2........................................ 215
9-5 Processor PMD Package B (52.5 x 51 mm) Sheet 2 of 2........................................ 216
9-6 Processor Top-Side Markings ........................................................................... 218
10-1 STS200C Passive/Active Combination Heat Sink (with Removable Fan)....... ............ 220
10-2 STS200C Passive/Active Combination Heat Sink (with Fan Removed) ..................... 220
10-3 STS200P and STS200PNRW 25.5 mm Tall Passive Heat Sinks................................ 221
10-4 Boxed Processor Motherboard Keepout Zones (1 of 4).......................................... 222
10-5 Boxed Processor Motherboard Keepout Zones (2 of 4).......................................... 223
10-6 Boxed Processor Motherboard Keepout Zones (3 of 4).......................................... 224
10-7 Boxed Processor Motherboard Keepout Zones (4 of 4).......................................... 225
10-8 Boxed Processor Heat Sink Volumetric (1 of 2).................................................... 226
10-9 Boxed Processor Heat Sink Volumetric (2 of 2).................................................... 227
10-10 4-Pin Fan Cable Connector (For Active Heat Sink)................................................ 228
10-11 4-Pin Base Baseboard Fan Header (For Active Heat Sink)...................................... 229
10-12 Fan Cable Connector Pin Out For 4-Pin Active Thermal Solution ............................. 231
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Tables
1-1 HCC, MCC, and LCC SKU Table Summary..............................................................11
1-2 Volume Structure and Scope ...............................................................................13
1-3 Reference d Documents....... ............. .. .. ......................... .. .. ............. .. .. .................24
2-1 Summary of Processor-specific PECI Commands ....................................................30
2-2 Minor Revision Number Meaning ..........................................................................33
2-3 GetTemp() Response Def i nition ............ .. .. .. ............... ............... .. ............... ..........34
2-4 RdPkgConf ig() Re sp onse Def in i tion............ ............... ........................... ............... ..35
2-5 WrPkgConfig() Response Definition ......................................................................38
2-6 RdPkgConfig() & WrPkgConfig() DRAM Thermal and Power Optimization
Services Summary.............................................................................................39
2-7 Channel & DIMM Index Decoding .........................................................................41
2-8 RdPkgConfig() & WrPkgConfig() CPU Thermal and Power Optimization
Services Summary.............................................................................................46
2-9 Power Control Register Unit Calculations...............................................................51
2-10 RdIAMSR() Response Definition ...........................................................................62
2-11 RdIAMSR() Services Summary12 ......................................................................... 63
2-12 RdPCIConfig() Response Definition.......................................................................65
2-13 RdPCIConfigLocal() Response Definition........... .....................................................67
2-14 WrPCIConfigLocal() Response Definition................................................................68
2-15 WrPCIConfigLocal() Memory Controller and IIO Device/Function Support...................69
2-16 PECI Client Response During Power-Up.................................................................70
2-17 SOCKET ID Strapping.........................................................................................71
2-18 Power Impact of PECI Commands vs. C-states.......................................................71
2-19 Domain ID Definition.............................................. ............................................74
2-20 Multi-Domain Command Code Reference...............................................................74
2-21 Completion Code Pass/Fail Mask..........................................................................75
2-22 Device Specific Completion Code (CC) Definition....................................................75
2-23 Originator Resp onse Guidelines............... .. ............... .. ............... .. ............... .. ........76
2-24 Error Codes and Descriptions...............................................................................77
4-1 System States.......................................... .. .. ............. .. .. .......................... .. .. ......87
4-2 Package C-State Support....................................................................................87
4-3 Core C-State Support.........................................................................................88
4-4 System Memory Power States .............................................................................88
4-5 DMI2/PCI Expr e ss* Link St ate s..................................................... .. .. .. ............. .. ..89
4-6 Intel® QPI States...... ......................... .. .. ......................... ... .. ............ .. ... ............89
4-7 G, S and C State Combinations............................................................................89
4-8 P_LVLx to MWAIT Conversion..............................................................................92
4-9 Coordination of Core Power States at the Package Level..........................................94
4-10 Package C-State Power Specifications...................................................................97
4-11 Processor Package Power Pmax ...........................................................................97
5-1 TCase Temperature Thermal Specifications..........................................................105
5-2 Digital Thermal Sensor (DTS) Sp e cification Summary .............. .............................106
5-3 Embedded TCase Temperature Thermal Specifications..........................................109
5-4 Embedde d DT S The rmal Sp e c ifications .......... .. ............................ .......................111
6-1 Memory Channel DDR0, DDR1, DDR2, DDR3.......................................................119
6-2 Memory Channel Miscellaneous..........................................................................120
6-3 PCI Express* Port 1 Signals ..............................................................................120
6-4 PCI Express* Port 2 Signals ..............................................................................120
6-5 PCI Express* Port 3 Signals ..............................................................................121
6-6 PCI Express* Miscellaneous Signals....................................................................121
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6-7 DMI2 and PCI Express Port 0 Signals ................................................................. 122
6-8 Intel QPI Port 0 and 1 Signals........................................................................... 122
6-9 Intel QPI Miscellaneous Signals ......................................................................... 122
6-10 PECI Signals................................................................................................... 123
6-11 System Reference Clock (BCLK{0/1}) Signals ..................................................... 123
6-12 JTAG and TA P Sig nals .......... .. ... .. ......................... .. .. .. ............. .. .. .. ............. .. .. .. 123
6-13 SVID Signals .................................................................................................. 124
6-14 Processor Asynchronous Sideband Signals .......................................................... 124
6-15 Miscellan eous Signals ............... .. ............ .. .. ... ............ .. .. ... ............ .. .. ... ............ 127
6-16 Power and Ground Signals................................................................................ 127
7-1 Power and Ground Lands.................................................................................. 131
7-2 SVID Address Usage........................................................................................ 135
7-3 VR12.0 Reference Code Voltage Identification (VID) Table ............... .. .. ................. 135
7-4 Signal Description Buffer Types......................................................................... 136
7-5 Signal Groups............. .. ......................... .. .. ............. .. .. .......................... .. .. ...... 137
7-6 Signals with On-Die Termination ........ .. .. .. ............... .. .. .. ............... .. ............... .. .. 139
7-7 Power-On Configuration Option Lands ................................................................ 140
7-8 Fault Resilient Booting (Output Tri-State) Signals ................................................ 141
7-9 Processor Absolute Minimum and Maximum Ratings............................................. 142
7-10 Storage Condition Ratings ................................................................................ 143
7-11 Voltage Specification........................................................................................ 143
7-12 Processor Current Specifications........................................................................ 145
7-13 Processor VCC Static and Transient Tolerance ..................................................... 146
7-14 VCC Overshoot Specifications............................................................................ 149
7-15 DDR3 and DDR3L Signal DC Specifications.......................................................... 149
7-16 PECI DC Specifications..................................................................................... 151
7-17 System Reference Clock (BCLK{0/1}) DC Specifications ....................................... 151
7-18 SMBus DC Specifications .................................................................................. 152
7-19 JTAG and TAP Signals DC Specifications ............................................................. 152
7-20 Serial VID Interface (SVID) DC Specifications...................................................... 152
7-21 Processor Asynchronous Sideband DC Specifications ............................................ 153
7-22 Miscellaneous Signals DC Specifications.............................................................. 154
7-23 Processor I/O Overshoot/Undershoot Specifications ............................................. 157
7-24 Processor Sideband Signal Group Overshoot/U ndershoot Tolerance........................ 159
8-1 Land Name..................................................................................................... 161
8-2 Land Number.................................................................................................. 185
9-1 Processor Package Sizes................................................................................... 212
9-2 Processor Loading Specifications ....................................................................... 217
9-3 Package Handling Guidelin es.............. .. ............... ............... ........................... .... 217
9-4 Processor Materials.......................................................................................... 218
10-1 PWM Fan Frequency Specifications For 4-Pin Active Thermal Solution ..................... 230
10-2 PWM Fan Characteristics for Active Thermal Solution............................................ 230
10-3 PWM Fan Connector Pin and Wire Description...................................................... 231
10-4 Server Thermal Solution Boundary Conditions ..................................................... 232
10 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Revision History
§
Revision
Number Description Revision Date
001 Initial Release September 2013
002
Added Intel® Xeon® Processor E5-4600 Product Family
Updated Section 1.1.1
Updated Table 1-2 - HCC, MCC, and LCC SKU Table Summary
Updated Section 1.6
Updated Table 4-10 -Package C-State Power Specifications
Updated Table 5-1 - Tcase Temperature Thermal Specifications
Updated Table 5-2 - DTS Specifications Summary
Updated Table 5-3 & 5-4 - Embedded TCase Temperature
Thermal Specifications
Updated Table 9-1 - Processor Package Sizes
March 2014
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 11
Datasheet Volume One of Two
1Overview
1.1 Introduction
The Intel® Xeon® processor E5-1600 v2/E5-2600 v2/E5-4600 v2 product families
datasheet- Volume One provides DC electrical specifications, signal integrity,
differential signaling specifications, land and signal definitions, and an overview of
additional processor feature interfaces.This document is intended to be distributed as a
part of the complete document which consists of two v olumes. The structure and scope
of the two volumes are provided in Table 1-2.
The Intel® Xeon® processor E5-1600 v2/E5-2600 v2/E5-4600 v2 product families are
the next generation of 64-bit, multi-core enterprise processors built on 22-nanometer
process technology. Throughout this document, the Intel® Xeon® processor E5-1600
v2/E5-2600 v2/E5-4600 v2 product families may be referred to as simply the
processor. Where information differs between the EP SKUs, this document uses specific
Intel® Xeon® processor E5-1600 v2 product family and Intel® Xe on® processor E5-
2600 v2 product family notation. Based on the low-power/high performance 3rd
Generation Intel® Core™ Processor F amily microarchitecture, the processor is designed
for a two-chip platform as opposed to the traditional three-chip platforms (processor,
MCH, and ICH). The two-chip platform consists of a processor and the Platform
Controller Hub (PCH) and enables higher performance, easier validation, and improved
x-y footprint.
This generation of processor introduces the High-Core count (HCC), Mid-Core count
(MCC), and Low-Core count (LCC) die size terminology to the SKU models. The table
below summarizes the die size associated with the processor TDP, Model Number, and
Core Count.
Table 1-1. HCC, MCC, and LCC SKU Table S ummary (Sheet 1 of 2)
Die Size TDP (W) Model Number Core Count
High-Core Count 130W 1U E5-2697 v2 12
115W 1U E5-2695 v2
E5-4657L v2 12
95W 1U E5-4610 v2 8
Mid-Core Count 150W WS E5-2687W v2 8
130W 1U E5-2690 v2 10
130W 1U E5-4627 v2 8
130W 2U E5-2667 v2 8
130W 2U E5-2643 v2 6
115W 1U E5-2680 v2
E5-2670 v2 10
95W 1U E5-2660 v2
E5-4650 v2
E5-4640 v2 10
95W 1U E5-2650L v2
E5-2640 v2
E5-4620 v2 8
70W 1U E5-2650L v2 10
Overview
12 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Some processor features are not available on all platforms. Refer to the Intel® Xeon®
Processor E5 v2 Product Family Specification Update for details of each processor SKU.
The Intel® Xeon® processor E5-1600 v2/E5-260 0 v2/E5-4600 v2 product families
support these segments.
•The Intel
® Xe on® processor E5-1600 v2 product family is designed for single
processor Workstation platforms only.
•The Intel
® Xe on® processor E5-2600 v2 product family is designed for dual
processor Workstation, Efficient Performance server and HPC platforms.
•The Inte
Xeon® processor E5-4600 v2 product family processor supports scalable
server and HPC platforms of two or more processors, including “glueless” 4-way
platforms.
These processors feature per socket, two Intel® QuickPath Interconnect point-to-point
links capable of up to 8.0 GT/s, up to 40 lanes of PCI Express* 3.0 links capable of
8.0 GT/s, and 4 lanes of DMI2/PCI Express* 2.0 interface with a peak transfer rate of
5.0 GT/s. The processor supports up to 46 bits of physical address space and 48-bit of
virtual address space.
Included in this family of processors is an integrated memory controller (IMC) and
integrated I/O (IIO) (such as PCI Express* and DMI2) on a single silicon die. This single
die solution is known as a monolithic processor.
Figure 1-1 and Figure 1-2, shows the processor 2-socket and 4-socket platform
configuration. Th e “Legacy CPU” is the boot processor that is connected to the PCH
component, this socket is set to NodeID[0]. In the 4-socket configur ation, the “Remote
CPU” is the processor which is not connected to the Legacy CPU.
Low-Core Count 130W 2U E5-2637 v2 4
130W 1S E5-1660 v2
E5-1650 v2 6
130W 1S E5-1620 v2 4
95W 1U E5-4607 v2 6
95W 1U E5-4603 v2 4
80W 1U E5-2630 v2
E5-2620 v2 6
80W 1U E5-2609 v2
E5-2603 v2 4
60W 1U E5-2630L v2 6
LV50W Embedded E5-2618L v2 6
LV95W Embe dded E5-2658 v2
E5-2648L v2
E5-4624L v2 10
LV70W Embe dded E5-2658 v2
E5-2648L v2
E5-4624L v2
LV70W Embedded E5-2628L v2 8
Table 1-1. HCC, MCC, and LCC SKU Table Summary (Sheet 2 of 2)
Die Size TDP (W) Model Number Core Count
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 13
Datasheet Volume One of Two
Table 1-2. Volume Structure and Scope
Volume 1: Electrical, Mechanical and Thermal Specification
•Overview
•Interfaces
Technologies
Power Management
Thermal Management Specifications
Signal Descriptions
Electrical Specifications
Processor Land Listing
Package Mechanical Specifications
Boxed Processor Specifications
Volume 2: Register Information
Configuration Process and Registers
Processor Integrated I/O (IIO) Configuration Registers
Processor Uncore Configuration Registers
Figure 1-1. Intel® Xeon® Processor E5-1600 v2 Product Family on the 1 Socket
Platform
x8
Processor
“Legacy”
DDR3
DDR3
DDR3
DDR3
PCH DMI2
PCIe
PCIe
.
.
.
SATA
ethernet
B
I
O
S
x4
x1
PCIe
x16
PCIe
x16
PCIe
Overview
14 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 1-2. Intel Xeon Processor E5-2600 v2 Product Family on the 2 Socket
Platform
Figure 1-3. Intel Xeon Processor E5-4600 v2 Product Family on the 4 Socket
Platform
x8
Processor
“Legacy”
DDR3
DDR3
DDR3
DDR3
Intel
QPI
Intel
QPI
PCH DMI2
PCIe*
PCIe
.
.
.
SATA
ethernet
B
I
O
S
x4
x1
Processor
“Peer”
DDR3
DDR3
DDR3
DDR3
PCIe
x16
PCIe
x16
PCIe
x16
DMI2/PCIe
x4
PCIe
x8
PCIe
x16
PCIe
Processor
Legacy”
DDR3
DDR3
DDR3
DDR3
QPI
QPI
PCH DMI2
PCIe
PCIe
.
.
.
SATA
ethernet B
I
O
S
x4x4
Processor
Peer
DDR3
DDR3
DDR3
DDR3
Processor
“Peer”
DDR3
DDR3
DDR3
DDR3
QPI
QPI
Processor
Remote”
DDR3
DDR3
DDR3
DDR3
PCIe
x16
DMI2/PCIe
x4
PCIe
x8
PCIe
x16
PCIe
x16
PCIe
x8
PCIe
x16
PCIe
x16
DMI2/PCIe
x4
PCIe
x8
PCIe
x16
PCIe
x16
DMI2/PCIe
x4
PCIe
x8
PCIe
x16
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 15
Datasheet Volume One of Two
1.1.1 Processor Feature Details
Up to 12 execution cores
Each core supports two threads (Intel® Hyper-Threading Technology), up to 24
threads per socket
46-bit physical addressing and 48-bit virtual addressing
1 GB large page support for server applications
A 32-KB instruction and 32-KB data firs t-level cache (L1) for each core
A 256-KB shared instruction/data mid-level (L2) cache for each core
•Up to 30 MB last level cache (LLC): up to 2.5 MB per core instruction/data last level
cache (LLC), shared among all cores
The Intel® Xeon® processor E5-2600 v2 and E5-4600 v2 product families supports
Directory Mode, Route Through, and Node IDs to reduce unnecessary Intel®
QuickPath Interconnect traffic by tracking cache lines present in remote sockets.
Protected Processor Inventory Number (PPIN): A solution for inventory
management available on Intel Xeon processor E5 v2 product families for use in
server platforms.
1.1.2 Supported Technologies
•Intel
® Virtualization Technology (Intel® VT)
•Intel
® Virtualization Technology for Directed I/O (Intel® VT-d)
APIC Virtualization (APICv)
•Intel
® Virtualization Technology Processor Extensions
•Intel
® Trusted Execution Technology (Intel® TXT)
•Intel
® 64 Architecture
•Intel
® Streaming SIMD Extensions 4.1 (Intel® SSE4.1)
•Intel
® Streaming SIMD Extensions 4.2 (Intel® SSE4.2)
•Intel
® Advanced Vector Extensions (Intel® AVX)
•Intel
® AVX Floating Point Bit Depth Conversion (Float 16)
•Intel
® Hyper-Threading Technology
Execute Disable Bit
•Intel
® Turbo Boost Technology
•Intel
® Intelligent Power Technology
Enhanced Intel SpeedStep® Technology
•Intel
® Dynamic Power Technology (Memory Power Management)
•Intel
® Secure Key, formerly known as Digital Random Number Generator (DRNG)
•Intel
® OS Guard, formerly known as Supervisor Mode Execution Protection
Bit (SMEP)
Overview
16 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
1.2 Interfaces
1.2.1 System Memory Support
•Intel
® Xe on® processor E5-160 0 v2/E5-2600 v2/E5-4600 v2 product families
supports 4 DDR3 channels
Unbuffered DDR3 and registered DDR3 DIMMs
LR DIMM (Load Reduced DIMM) for buffered memory solutions demanding higher
capacity memory subsystems
Independent channel mode or lockstep mode
Data burst length of eight cycles for all memory organization modes
Memory DDR3 data transfer rates of 800, 1066, 1333, 1600, and 1866 MT/s
64-bit wide channels plus 8-bits of ECC support for each channel
DDR3 standard I/O Voltage of 1.5 V and DDR3 Low Voltage of 1.35 V
1-GB, 2-GB, and 4-GB DDR3 DRAM technologies supported for these devices:
UDIMMs x8, x16
RDIMMs x4, x8
LRDIMM x4, x8 (2-Gb and 4-Gb only) LR-DIMMs are supported only on server
specific SKUs (Intel® Xeon® processor E5-1600 v2/E5-2600 v2/E5-4600 v2
product families). LR-DIMMs are not supported in workstation specific SKUs
such as the Intel® Xeon® processor E5-1600 v2 product family.
Up to 8 ranks supported per memory channel: 1, 2 or 4 ranks per DIMM
Open with adaptive idle page close timer or closed page policy
Per channel memory test and initialization, engine can initialize DRAM to all logical
zeros with valid ECC (with or without data scrambler) or a predefined test pattern.
Isochronous access support is not available on an y CPU model containing two home
agents.
Minimum memory configuration: independent channel support with
1 DIMM populated.
Integrated dual SMBus master controllers
Command launch modes of 1n/2n
RAS Support (including and not limited to):
Note: RAS support depends on processor SKU. For example, Workstation SKUs do
not support sparing or tagging, lockstep mode, mirroring mode, channel
mirroring mode within a socket, error containment.
Rank Level Sparing and Device Tagging
Demand and Patrol Scrubbing
DRAM Single Device Data Corre ction (S DDC) for any single x4 or x8 DRAM
device failure. Independent channel mode supports x4 SDDC. x8 SDDC
requires lockstep mode
Lockstep mode where channels 0 & 1 and channels 2 & 3 are operated in
lockstep mode
The combination of memory channel pair lockstep and memory mirroring is
not supported
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 17
Datasheet Volume One of Two
Data scrambling with address to ease detection of write errors to an
incorrect address.
Error reporting via Machine Check Architecture
Read Retry during CRC error handling checks by iMC
Channel mirroring within a socket
Channel Mirroring mode is supported on memory channels 0 & 1 and
channels 2 & 3
Error Containment Recovery
Improved Thermal Throttling with dynamic Closed Loop Thermal Throttling (CLTT)
Memory thermal monitoring support for DIMM temperature via two memory
signals, MEM_HOT_C{01/23}_N
1.2.2 PCI Express*
The PCI Express* port(s) are fully-compliant to the PCI Express* Base
Specification, Revision 3.0 (PCIe 3.0)
Support for PCI Express* 3.0 (8.0 GT/s), 2.0 (5.0 GT/s), and 1.0 (2.5 GT/s)
Up to 40 lanes of PCI Express* interconnect for general purpose PCI Express*
devices at PCIe* 3.0 speeds that are configurable for up to 10 independent ports
4 lanes of PCI Express* at PCIe* 2.0 speeds when not using DMI2 port (Port 0),
also can be downgraded to x2 or x1
Negotiating down to narrower widths is supported, see Figure 1-4:
x16 port (Port 2 & Port 3) may negotiate down to x8, x4, x2, or x1.
x8 port (Port 1) may negotiate down to x4, x2, or x1.
x4 port (Port 0) may negotiate down to x2, or x1.
When negotiating down to narrower widths, there are caveats as to how lane
reversal is supported.
Non-Transparent Bridge (NTB) is supported by PCIe Port3a/IOU1. For more details
on NTB mode operation refer to PCI Express Base Specification - Revision 3.0:
x4, x8 or x16 widths and at PCIe* 1.0, 2.0, 3.0 speeds
Two usage models; NTB attached to a Root Port or NTB attached to
another NTB
Supports three 64-bit BARs
Supports posted writes and non-posted memory read transactions across
the NTB
Supports INTx, MSI and MSI-X mechanisms for interrupts on both side of NTB
in upstream direction only
Address Translation Services (ATS) 1.0 support
Hierarchical PCI-compliant configuration mechanism for downstream devices.
Traditional PCI style traffic (asynchronous snooped, PCI ordering).
PCI Express* extended configuration space. The first 256 bytes of configuration
space aliases directly to the PCI compatibility configur ation space. The remaining
portion of the fixed 4-KB block of memory-mapped space above that (starting at
100h) is known as extended configuration space.
PCI Express* Enhanced Access Mechanism. Accessing the device configuration
space in a flat memory mapped fashion.
Overview
18 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Automatic discovery, negotiation, and training of link out of reset.
Supports receiving and decoding 64 bits of address from PCI Express*.
Memory transactions received from PCI Express* that go above the top of
physical address space (when Intel VT-d is enabled, the check would be against
the translated HPA (Host Physical Address) address) are reported as errors by
the processor.
Outbound access to PCI Express* will always have address bits 63 to
46 cleared.
Re-issues Configuration cycles that have been previously completed with the
Configuration Retry status.
Power Management Event (PME) functions.
Message Signaled Interrupt (MSI and MSI-X) messages
Degraded Mode support and Lane Reversal support
Static lane numbering reversal and polarity inversion support
Support for PCIe* 3.0 atomic operation, PCIe 3.0 optional extension on atomic
read-modify-write mechanism
Additional read buffers for point-point transfers. This increases the number of
outstanding transactions in point- point transfers across same processor sockets,
from previous generation of 16 to 64 in this generation.
Figure 1-4. PCI Express* Lane Partitioning and Direct Media Interface Gen 2 (DMI2)
Transaction
Link
Physical
0…3
X4
DMI
Port 0
D M I / P C Ie
4…7
X4
Port 1b
Transaction
Link
Physical
0…3
X4
Port 1a
Port 1
(IOU2)
PCIe
X8
Port 1a
8…11
Transaction
Link
Physical
0…3
Port 2
(IOU0)
PCIe
X4
Port 2b
X4
Port 2a
X8
Port 2a
X4
Port 2d
X4
Port 2c
X8
Port 2c
X16
Port 2a
12..154…7 8…11
Transaction
Link
Physical
0…3
Port 3
(IOU1)
PCIe
X4
Port 3b
X4
Port 3a
X8
Port 3a
X4
Port 3d
X4
Port 3c
X8
Port 3c
X16
Port 3a
12..154…7
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 19
Datasheet Volume One of Two
1.2.3 Direct Media Interface Gen 2 (DMI2)
Serves as the chip-to-chip interface to the Intel® C600 Chipset
The DMI2 port supports x4 link width and only operates in a x4 mo de when in DMI2
Operates at PCI Express* 1.0 or 2.0 speeds
Transparent to software
Processor and peer-to-peer writes and reads with 64-bit address support
APIC and Message Signaled Interrupt (MSI) support. Will send Intel-defined “End of
Interrupt” broadcast message when initiated by the processor.
Downstream System Management Interrupt (SMI), SCI, and SERR error indication
Static lane numbering reversal support
Supports DMI2 virtual channels VC0, VC1, VCm, and VCp
1.2.4 Intel® QuickPath Interconnect (Intel® QPI)
Compliant with Intel QuickPath Interconnect (Intel® QPI) v1.1 standard
packet formats
Implements two full width Intel QPI ports
Full width port includes 20 data lanes and 1 clock lane
64 byte cache-lines
Isochronous access support is not available on any CPU model containing two
home agents.
Note: RAS support depends on processor SKU. For example, Workstation SKUs do
not support sparing or tagging, lockstep mode, mirroring mode, channel
mirroring mode within a socket, error containment.
Home snoop based coherency
•4-bit Node ID
46-bit physical addressing support
No Intel QuickPath Interconnect bifurcation support
Differential signaling
Forwarded clocking
Up to 8.0 GT/s data rate (up to 16 GB/s direction peak bandwidth per port)
All ports run at same operational frequency
R eference Clock is 100 MHz
Slow boot speed initialization at 50 MT/s
Common reference clocking (same clock generator for both sender and receiver)
•Intel
® Interconnect Built-In- Self-Test (Intel® IBIST) for high-speed testability
Polarity Inversion and Lane reversal (Rx side only)
1.2.5 Platform Environment Control Interface (PECI)
The PECI is a one-wire interface that provides a communication channel between a
PECI client (the processor) and a PECI master (the PCH).
Overview
20 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Supports operation at up to 2 Mbps data transfers
Link layer improvements to support additional services and higher efficiency over
PECI 2.0 generation
Services include CPU thermal and estimated power information, control functions
for power limiting, P-state and T-state control, and access for Machine Check
Architecture registers and PCI configuration space (both within the processor
package and downstream devices)
PECI addres s determined by SOCKET_ID configuration
Single domain (Domain 0) is supported
1.3 Power Management Support
1.3.1 Processor Package and Core States
ACPI C-st ates as i mp l emented by the following processor C-states:
Package: PC0, PC1/PC1e, PC2, PC3, PC6 (Package C7 is not supported)
Core: CC0, CC1, CC1E, CC3, CC6 (Processor Core C7 is not supported)
Enhanced Intel SpeedStep® Technology
1.3.2 System States Support
S0, S1, S3, S4, S5
1.3.3 Memory Controller
Multiple CKE power down modes
•Multiple self-refresh modes
Memory thermal monitoring via MEM_HOT_C01_N and MEM_HOT_C23_N Signals
1.3.4 PCI Express*
L0s is not supported
L1 ASPM power management capability
1.3.5 Intel® QPI
L0s is not supported
L0p and L1 power management capabilities
1.4 Thermal Management Support
Digital Thermal Sensor with multiple on-die temperature zones
Adaptive Thermal Monitor
THERMTRIP_N and PROCHOT_N signal support
On-Demand mode clock modulation
Open and Closed Loop Thermal Throttling (OLT T/CLTT) support for system memory
in addition to Hybrid OLTT/CLTT mode
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 21
Datasheet Volume One of Two
Fan speed control with DTS
Two integrated SMBus masters for accessing thermal data from DIMMs
New Memory Thermal Throttling fe atures via MEM_HOT_C{01/23}_N signals
Running Average Power Limit (RAPL), Processor and DRAM Thermal and Power
Optimization Capabilities
1.5 Package Summary
The processor socket type is 52.5 x 45 mm or 52.5 x 51 mm FCLGA12 package
(LGA2011-0).
1.6 Terminology
Term Description
ASPM Active State Power Management
BMC Baseboard Management Controllers
Cbo Cache and Core Box. It is a term used for internal logic prov iding ring interface to
LLC and Core.
DDR3 Third generation Double Data Rate SDRAM memory technology that is the
successor to DDR2 SDRAM
DMA Direct Memory Access
DMI Direct Media Interface
DMI2 Direct Media Interface Gen 2
DTS Digital Thermal Sensor
ECC Error Correction Code
Enhanced Intel
SpeedStep® Technology Allows the operating system to reduce power consumption when performance is
not needed.
Execute Disable Bit The Execute Disable bit allows memory to be marked as executable or non-
executable, when combined with a supporting operating system. 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 Intel® 64 and IA-32 Architectures Software
Developer's Manuals for more detailed information.
Flit Flow Control Unit. The Intel QPI Link layer’s unit of transfer; 1 Flit = 80-bits.
Functional Operation Refers to the normal operating conditions in which all processor specifications,
including DC, system bus, signal quality, mechanical, and thermal, are satisfied.
IMC The Integrated Memory Controller. A Memory Controller that is integrated in the
processor die.
IIO The Integrated I/O Controller. An I/O controller that is integrated in the
processor die.
Intel® ME Intel® Management Engine (Intel® ME)
Intel® QuickData
Technology Intel QuickData Technology is a platform solution designed to maximize the
throughput of server data traffic across a broader range of configurations and
server environments to achieve faster, scalable, and more reliable I/O.
Intel® QuickPath
Interconnect (Intel® QPI) A cache-coherent, link-based Interconnect specification for Intel processors,
chipsets, and I/O bridge components.
Intel® 64 Technology 64-bit memory extensions to the IA-32 architecture. Further details on Intel 64
architecture and programming model can be found at
http://developer.intel.com/technology/intel64/.
Overview
22 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Intel® Turbo Boost
Technology Intel® Turbo Boost Technology is a way to automatically run the processor
core faster than the marked frequency if the part is operating under power,
temperature, and current specifications limits of the Thermal Design
Power (TDP). This results in increased performance of both single and multi-
threaded applications.
Intel® TXT Intel® Trusted Execution Technology
Intel® Virtualization
Technology (Intel® VT) Processor virtualization which when used in conjunction with Virtual Machine
Monitor software enables multiple, robust independent software environments
inside a single platform.
Intel® VT-d Intel® Virtualization Technology (Intel® VT) for Directed I/O. Intel VT-d is a
hardware assist, under system software (Virtual Machine Manager or OS)
control, for enabling I/O device virtualization. Intel VT-d also brings robust
security by providing protection from errant DMAs by using DMA remapping, a
key feature of Intel VT-d.
Intel® Xe on® processor
E5-1600 v2 product family Intel’s 22-nm processor design, is the follow-on to the 3rd Generation Intel®
Core™ Processor Family design. It is the next generation processor for use in
Intel® Xeon® processor E5-1600 v2/E5-2600 v2 product families-based
platforms. Intel® Xeo n® processor E5-1600 v2 product family supports
workstation platforms only.
Intel® Xe on® processor
E5-2600 v2 product family Intel’s 22-nm processor design, is the follow-on to the 3rd Generation Intel®
Core™ Processor Family design. It is the next generation processor for use in
Intel® Xeon® processor E5-1600 v2/E5-2600 v2 product families-based
platforms. Intel® Xeo n® processor E5-2600 v2 product family supports
workstation, Efficient Performance server, and HPC platforms.
Inte Xeo n® pr ocessor
E5-4600 v2 product family Intel’s 22-nm processor design, is the follow-on to the 3rd Generation Intel®
Core™ Processor Family design. It is the next generation processor for use in
Inte Xeon® processor E5-4600 v2 product family platforms. Inte Xeo n®
processor E5-4600 v2 product family supports scalable serv er and HPC platforms
for two or more processors, including glueless four-way platforms.
Integrated Heat Spreader
(IHS) A component of the processor packag e used to enhance the thermal
performance of the package. Component thermal solutions interface with the
processor at the IHS surface.
Jitter Any timing variation of a transition edge or edges from the defined Unit
Interval (UI).
IOV I/O Virtualization
LGA2011-0 Socket The LGA2011-0 land FCLGA12 package mates with the system board through
this surface mount, LGA2011-0 contact socket.
LLC Last Level Cache
LRDIMM Load Reduced Dual In-line Memory Module
NCTF Non-Critical to Function: NCTF locations are typically redundant ground or non-
critical reserved , so the loss of the solder jo int continuity at end of life conditi ons
will not affect the overall product functionality.
NEBS Network Equipment Building System. NEBS is the most common set of
environmental de sign guidelines applied to telecommunications equipme nt in the
United States.
PCH Platform Controller Hub. The next generation chipset with centralized platform
capabilities including the main I/O interfaces along with display connectivity,
audio features, power management, manageability, security and storage
features.
PCU Power Control Unit
PCI Express* 3.0 The third generati on PC I Expr es s* spe cificati on that ope rates at twice the speed
of PCI Express* 2.0 (8 Gb/s); however, PCI Express* 3.0 is completely backward
compatible with PCI Express* 1.0 and 2.0.
PCI Express 3 PCI Express* Generation 3.0
PCI Express 2 PCI Express* Generation 2.0
PCI Express PCI Express* Generation 2.0/3.0
PECI Platform Environment Control Interface
Term Description
Overview
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 23
Datasheet Volume One of Two
Phit Physical Unit. An Intel QPI terminology defining units of transf er at the
physical layer. 1 Phit is equal to 20 bits in ‘full width mode’ and 10 bits in ‘half
width mode’
Processor The 64-bit, single-core or multi-core component (package)
Processor Core The term “processor core” refers to silicon die itself which can contain multiple
executio n cores. Each execution co re has an instruction cac he, data cache, and
256-KB L2 cache. All execution cores share the L3 cache. All DC and signal
integrity specifications are measured at the processor die (pads), unless
otherwise noted.
Protected Processor
Inventory Number (PPIN) A solution for inventory management available on Intel Xeon processor E5 v2
product families for use in server platforms. PPIN defaults to disabled and
follows an 'opt-in' model to enable it. Once PPIN is enabled, a reboot is necessary
to make it available to privileged software, such as the OS or VMM and other ring
0 applications.
RDIMM Registered Dual In-line Module
Rank A unit of DRAM corresponding four to eight devices in parallel, ignoring ECC.
These devices are usually, but not always, mounted on a single side of a
DDR3 DIMM.
SCI System Control Interrupt. Used in ACPI protocol.
SSE Intel® Streaming SIMD Extensions (Intel® SSE)
SKU A processor Stock Keeping Unit (SKU) to be installed in either server or
workstation platforms. Electrical, power and thermal specifications for these
SKU’s are based on specific use condition assumptions. Server processors may
be further categorized as Efficient Performance server, workstation and HPC
SKUs. For further d etails on use condi tion assump tions, ple ase refer to the latest
Product Release Qualification (PRQ) Report available via your Customer Quality
Engineer (CQE) contact.
SMBus System Management Bus. A two-wire interface through which simple system and
power management related devices can communicate with the rest of the
system. It is based on the principals of the operation of the I2C* two-wire serial
bus from Philips Semiconductor.
Storage Conditions 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 landings should not be connected to any supply
voltages, hav e any I/Os biased or receive any clocks . Upon exposure to “free air”
(that is, unsealed packaging or a device removed from packaging material) the
processor must be handled in accordance with moisture sensitivity labeling
(MSL) as indicated on the packaging material.
TAC Thermal Averaging Constant
TDP Thermal Design Power
TSOD Thermal Sensor on DIMM
UDIMM Unbuffered Dual In-line Module
Uncore The portion of the processor comprising the shared cache, IMC, HA, PCU, UBox,
and Intel QPI link interface.
Unit Interval Signaling convention that is binary and unidirectional. In this binary signaling,
one bit is sent for e v ery edge of the forwarded clock, whether it be a rising e dge
or a falling edge. If a number of edges are collected at instances t1, t2, tn,...., tk
then the UI at instance “n” is defined as :
UI n = t n - t n - 1
VCC Processor core power supply
VSS Processor ground
VCCD_01, VCCD_23 Variable power supply for the processor system memory interface. VCCD is the
generic term for VCCD_01, VCCD_23.
x1 Refers to a Link or Port with one Physical Lane
Term Description
Overview
24 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
1.7 Related Documents
Refer to the following documents for additional information.
1.8 Statement of Volatility (SOV)
Intel® Xe on® processor E5-160 0 v2/E5-2600 v2/E5-4600 v2 product families do not
retain any end-user data when powered down and/or the processor is physically
removed from the socket.
1.9 State of Data
The data contained within this document is the most accurate information available by
the publication date of this document.
§
x4 Refers to a Link or Port with four Physical Lanes
x8 Refers to a Link or Port with eight Physical Lanes
x16 Refers to a Link or Port with sixteen Physical Lanes
Term Description
Table 1-3. Referenced Documents
Document Document Number/ Locatio n
Intel® Xeon® Processor E5 v2 Product Family Processor Datasheet,
Volume Two: Registers http://www.intel.com
Intel® Xeon® Processor E5-1600/2600/4600 v1 and v2 Product
Families Thermal / Mechanical Design Guide http://www.intel.com
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product
Families – Boundary Scan Description Language (BSDL) File http://www.intel.com
Intel® C600 Series Chipset Datasheet http://www.intel.com
Advanced Configuration and Power Interface Specification 3.0 http://www.acpi.info
PCI Local Bus Specification 3.0 http://www.pcisig.com/specifications
PCI Express Base Specification - Revision 2.1 and 1.1
PCI Express Base Specification - Revision 3.0 http://www.pcisig.com
System Management Bus (SMBus) Specification http://smbus.org/
DDR3 SDRAM Specification http://www.jedec.org
Low (JESD22-A119) and High (JESD-A103) Temperature Storage
Life Specifications http://www.jedec.org
Intel® 64 and IA-32 Architectures Software Developer's Manuals
Volume 1: Basic Architecture
Volume 2A: Instruction Set Reference, A-M
Volume 2B: Instruction Set Reference, N-Z
Volume 3A: System Programming Guide
Volume 3B: System Programming Guide
Intel® 64 and IA-32 Architectures Optimization Reference Manual
http://www.intel.com/products/processor/manu
als/index.htm
Intel® Virtualization Technology Specification for Directed I/O
Architecture Specification http://download.intel.com/technology/computin
g/vptech/Intel(r)_VT_for_Direct_IO.pdf
Intel® Trusted Execution Technology Software Development Guide http://www.intel.com/technology/security/
National Institute of Standards and Technology NIST SP800-90 http://csrc.nist.gov/publications/PubsSPs.html
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 25
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Interfaces
2Interfaces
This chapter describes the interfaces supported by the processor.
2.1 System Memory Interface
2.1.1 System Memory Technology Support
The Integrated Memory Controller (IMC) supports DDR3 protocols with four
independent 64-bit memory channels with 8 bits of ECC for each channel (total of
72-bits) and supports 1 to 3 DIMMs per channel depending on the type of memory
installed. The type of memory supported by the processor is dependent on the target
platform:
Intel® Xeon® processor E5-1600 v2/E5-2600 v2 product families
platforms support:
ECC registered DIMMs: with a maximum of three DIMMs per channel allowing
up to eight device ranks per channel.
ECC and non-ECC unbuffered DIMMs: with a maximum of two DIMMs per
channel thus allowing up to four device ranks per channel. Support for mixed
non-ECC with ECC un-buffered DIMM configurations.
2.1.2 System Memory Timing Support
The IMC supports the following DDR3 Speed Bin, CAS Write Latency (CWL), and
command signal mode timings on the main memory interface:
tCL = CAS Latency
tRCD = Activate Command to READ or WRITE Command delay
tRP = PRECHARGE Command Period
CWL = CAS Write Latency
Command Signal modes = 1n indicates a new command may be issued every clock
and 2n indicates a new command may be issued every 2 clocks. Command launch
mode programming depends on the transfer rate and memory configuration.
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26 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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2.2 PCI Express* Interface
This section describes the PCI Express* 3.0 interface capabilities of the processor. See
the PCI Express* Base Specific ation for details of PCI Express* 3.0.
2.2.1 PCI Express* Architecture
Compatibility with the PCI addressing model is maintained to ensure that all existing
applications and drivers operate unchanged. The PCI Express* configuration uses
standard mechanisms as defined in the PCI Plug-and-Play specification.
The PCI Express* architecture is specified in three layers: Transaction Layer, Data Link
Layer, and Physical Layer. The partitioning in the component is not necessarily along
these same boundaries. Refer to Figure 2-1 for the PCI Express* Layering Diagram.
PCI Express* uses packets to communicate information between components. Packets
are formed in the Transaction and Data Link Layers to carry the information from the
transmitting component to the receiving component. As the transmitted packets flow
through the other layers, they are extended with additional information necessary to
handle packets at those layers. At the receiving side, the reverse process occurs and
packets get transformed from their Physical Layer representation to the Data Link
Layer representation and finally (for Transaction Layer P ackets) to the form th at can be
processed by the Transaction Layer of the receiving device.
Figure 2-1. PCI Express* Layering Diagram
Transaction
Data Link
Physical
Logical Sub-Block
Electrical Sub-Block
RX TX
Transaction
Data Link
Physical
Logical Sub-Block
Electrical Sub- Block
RX TX
Transaction
Data Link
Physical
Logical Sub-Block
Electrical Sub-Block
RX TX
Transaction
Data Link
Physical
Logical Sub-Block
Electrical Sub- Block
RX TX
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2.2.1.1 Transaction Layer
The upper layer of the PCI Express* architecture is the Transaction Layer. The
Transaction Layer's primary responsibility is the assembly and disassembly of
Transaction Layer Packets (TLPs). TLPs are used to communicate transactions, such as
read and write, as well as certain types of events. The Transaction Lay er also manages
flow control of TLPs.
2.2.1.2 Data Link Layer
The middle layer in the PCI Express* stack, the Data Link Layer, serves as an
intermediate stage between the Transaction Layer and the Physical Layer.
Responsibilities of Data Link Layer include link management, error detection, and
error correction.
The transmission side of the Data Link Layer accepts TLPs assembled by the
Transaction Layer, calculates and applies data protection code and TLP sequence
number, and submits them to Physical Layer for transmission across the Link. The
receiving Data Link Layer is responsible for checking the integrity of received TLPs and
for submitting them to the Transaction Lay er for further processing. On detection of TLP
error(s), this layer is responsible for requesting retransmission of TLPs until information
is correctly received, or the Link is determined to have failed. The Data Link Layer also
generates and consumes packets which are used for Link management functions.
2.2.1.3 Physical Layer
The Physical Layer includes all circuitry for interface operation, including driver and
input buffers, parallel-to-serial and serial-to-parallel con version, PLL(s), and impedance
matching circuitry . It also includes logical functions related to interface initialization and
maintenance. The Physical Layer exchanges data with the Data Link Layer in an
implementation-specific format, and is responsible for converting this to an appropriate
serialized format and transmitting it across the PCI Express* Link at a frequency and
width compatible with the remote device.
2.2.2 PCI Express* Configuration Mechanism
The PCI Express* link is mapped through a PCI-to-PCI bridge structure.
Figure 2-2. Packet Flow through the Layers
Framing Sequence
Number Header Date LCRCECRC Framing
Data Link Layer
Transaction La yer
Physical Layer
Framing Sequence
Number Header Date LCRCECRC Framing
Data Link Layer
Transaction La yer
Physical Layer
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28 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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PCI Express* extends the configuration space to 4096 bytes per-device/function, as
compared to 256 bytes allowed by the Conventional PCI Specification. PCI Express*
configuration space is divided into a PCI-compatible region (which consists of the first
256 bytes of a logical device's configuration space) and an extended PCI Express*
region (which consists of the remaining configuration space). The PCI-compatible
region can be accessed using either the mechanisms defined in the PCI specification or
using the enhanced PCI Express* configurat ion access mechanism described in the PCI
Express* Enhanced Configuration Mechanism section.
The PCI Express* Host Bridge is required to translate the memory-mapped PCI
Express* configuration space accesses from the host processor to PCI Express*
configuration cycles. To maintain compatibility with PCI configuration addressing
mechanisms, it is recommended that system software access the enhanced
configuration space using 32-bit operations (32-bit aligned) only.
See the PCI Express* Base Specification for details of both the PCI-compatible and PCI
Express* Enhanced configuration mechanisms and transaction rules.
2.3 DMI2/PCI Express* Interface
Direct Media Interface 2 (DMI2) connects the processor to the Platform Controller Hub
(PCH). DMI2 is similar to a four-lane PCI Express* supporting a speed of 5 GT/s per
lane. This interface can be configured at power-on to serve as a x4 PCI Express* link
based on the setting of the SOCKET_ID[1:0] and FRMAGENT signal for processors not
connected to a PCH.
Note: Only DMI2 x4 configuration is supported.
2.3.1 DMI2 Error Flow
DMI2 can only generate SERR in response to errors, never SCI, SMI, MSI, PCI INT, or
GPE. Any DMI2 related SERR activity is associated with Device 0.
2.3.2 Processor/PCH Compatibility Assumptions
The processor is compatible with the PCH and is not compatible with any previous MCH
or ICH products.
2.3.3 DMI2 Link Down
The DMI2 link going down is a fatal, unrecoverable error. If the DMI2 data link goes to
data link down, after the link was up, then the DMI2 link hangs the system by not
allowing the link to retrain to prevent data corruption. This is controlled by the PCH.
Downstream transactions that had been successfully transmitted across the link
prior to the link going down may be processed as normal. No completions from
downstream, non-posted transactions are returned upstream over the DMI2 link after a
link down event.
2.4 Intel® QuickPath Interconnect (Intel® QPI)
The Intel QuickPath Interconnect is a high speed, packetized, point-to-point
interconnect used in the 3rd Generation Intel® Core™ Processor Family. The narrow
high-speed links stitch together processors in distributed shared memory and
integrated I/O platform architecture. It offers much higher bandwidth with lo w latency.
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 29
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The Intel QuickPath Interconnect has an efficient architecture allowing more
interconnect performance to be achieved in real systems. It has a snoop protocol
optimized for low latency and high scalability, as well as packet and lane structures
enabling quick completions of transactions. Reliability, availability, and servicea bility
features (RAS) are built into the architecture.
The physical connectivity of each interconnect link is made up of twenty differential
signal pairs plus a differential forwarded clock. Each port supports a link pair consisting
of two uni-directional links to complete the connection between two components. This
supports traffic in both directions simultaneously. To facilitate flexibility and longevity,
the interconnect is defined as having five layers: Physical, Link, Routing, Transport,
and Protocol.
The Physical layer consists of the actual wires carrying the signals, as well as
circuitry and logic to support ancillary features required in the transmission and
receipt of the 1s and 0s. The unit of transfer at the Physical layer is 20-bits, which
is called a Phit (for Physical unit).
The Link layer is responsible for reliable transmission and flow control. The Link
layer’s unit of transfer is 80-bits, which is called a Flit (for Flow control unit).
The Routing layer provides the framework for directing packets through
the fabric.
The Transport layer is an architecturally defined layer (not implemented in
the initial products) providing advanced routing capability for reliable
end-to-end transmission.
The Protocol layer is the high-level set of rules for exchanging packets of data
between devices. A packet is comprised of an integral number of Flits.
The Intel® QuickPath Interconnect includes a cache coherency protocol to keep the
distributed memory and caching structures coherent during system operation. It
supports both low-latency source snooping and a scalable home snoop behavior. The
coherency protocol provides for direct cache-to-cache transfers for optimal latency.
2.5 Platform Environment Control Interface (PECI)
The Platform Environment Control Interface (PECI) uses a single wire for self-clocking
and data transfer. The bus requires no additional control lines. The physical layer is a
self-clocked one-wire bus that begins each bit with a driven, rising edge from an idle
level near zero volts. The duration of the signal driven high depends on whether the
bit value is a logic ‘0’ or logic ‘1’. PECI also includes variable data transfer rate
established with every message. In this way, it is highly flexible even though underlying
logic is simple.
The interface design was optimized for interfacing to Intel processor and chipset
components in both single processor and multiple processor environments. The single
wire interface provides low board routing overhead for the multiple load connections in
the congested routing area near the processor and chipset components. Bus speed,
error checking, and low protocol overhead provides adequate link bandwidth and
reliability to transfer critical device operating conditions and configuration information.
The PECI bus offers:
A wide speed range from 2 Kbps to 2 Mbps
CRC check byte used to efficiently and atomically confirm accurate data delivery
Synchronization at the beginning of every message minimizes device timing
accuracy requirements
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30 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Generic PECI specification details are out of the scope of this document. What follows is
a processor-specific PECI client definition, and is largely an addendum to the PECI
Network Layer and Design Recommendations sections for the PECI specification.
Note: The PECI commands described in this document apply primarily to the Intel® Xeon®
processor E5-1600 v2/E5-2600 v2 product families. The processors utilizes the
capabilities described in this document to indicate support for four memory channels.
Refer to Table 2-1 for the list of PECI commands supported by the processors.
2.5.1 PECI Client Capabilities
The processor PECI client is designed to support the following sideband functions:
Processor and DRAM thermal management
Platform manageability func tions including thermal, power, and error monitoring
The platform ‘power’ management includes monitoring and control for both the
processor and DRAM subsystem to assist with data center power limiting.
2.5.1.1 Thermal Management
Processor fan speed control is managed by comparing Digital Thermal Sensor (DTS)
thermal readings acquired via PECI against the processor-specific fan speed control
reference point, or TCONTROL. Both TCONTROL and DTS thermal readings are accessible
via the processor PECI client. These variables are referenced to a common
temperature, the TCC activation point, and are both defined as negative offsets from
that reference.
PECI-based access to the processor package configuration space provides a means for
Baseboard Management Controllers (BMCs) or other platform management devices to
actively manage the processor and memory power and thermal features. Details on the
list of available power and thermal optimization services can be found in
Section 2.5.2.6.
2.5.1.2 Platform Manageability
PECI allows read access to certain error registers in the processor MSR space and
status monitoring registers in the PCI configuration space within the processor and
downstream devices. Details are covered in subsequent sections.
Table 2-1. Summary of Processor-specific PECI Commands
Command Supported on the Processor
Ping() Yes
GetDIB() Yes
GetTemp() Yes
RdPkgConfig() Yes
WrPkgConfig() Yes
RdIAMSR() Yes
WrIAMSR() No
RdPCIConfig() Yes
WrPCIConfig() No
RdPCIConfigLocal() Yes
WrPCIConfigLocal() Yes
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PECI permits writes to certain Memory Controller RA S-related registers in the processor
PCI configuration space. Details are covered in Section 2.5.2.10.
2.5.2 Client Command Suite
PECI command requires at least one frame check sequence (FCS) byte to ensure
reliable data exchange between originator and client. The PECI message protocol
defines two FCS bytes that are returned by the client to the message originator. The
first FCS byte covers the client address byte, the Read and Write Length bytes, and all
bytes in the write data block. The second FCS byte covers the read response data
returned by the PECI client. The FCS byte is the result of a cyclic redundancy check
(CRC) of each data block.
2.5.2.1 Ping()
Ping() is a required message for all PECI devices. This message is used to enumerate
devices or determine if a device has been removed, been powered-off, and so forth. A
Ping() sent to a device address always returns a non-zero W rite FCS if the device at the
targeted address is able to respond.
2.5.2.1.1 Command Format
The Ping() format is as follows:
Write Length: 0x00
Read Length: 0x00
An example Ping() command to PECI device address 0x30 is shown below.
2.5.2.2 GetDIB()
The processor PECI client implementation of GetDIB() includes an 8-byte response and
provides information regarding client revision number and the number of supported
domains. All processor PECI clients support the GetDIB() command.
2.5.2.2.1 Command Format
The GetDIB() format is as follows:
Write Length: 0x01
Figure 2-3. Ping()
Byte #
Byte
Definition
0
Client Address
1
Write Length
0x00
2
Read Length
0x00
3
FCS
Figure 2-4. Ping() Example
Byte #
Byte
Definition
0
0x30
1
0x00
2
0x00
3
0xe1
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Read Length: 0x08
Command: 0xf7
2.5.2.2.2 Device Info
The Device Info byte gives details regarding the PECI client configuration. At a
minimum, all clients supporting GetDIB will return the number of domains inside the
package via this field. With any client, at least one domain (Domain 0) must exist.
Therefore, the Number of Domains reported is defined as the number of domains in
addition to Domain 0. For example, if bit 2 of the Device Info byte returns a ‘1’, that
would indicate that the PECI client supports two domains.
2.5.2.2.3 Revision Number
All clients that support the GetDIB command also support Revision Number reporting.
The revision number ma y be used by a host or originator to manage different command
suites or response codes from the client. Revision Number is always reported in the
second byte of the GetDIB() response. The ‘Major Revision’ number in Figure 2-7
always maps to the revision number of the PECI specification that the PECI client
processor is designed to. The ‘Minor Revision’ number value depends on the exact
command suite supported by the PECI client as defined in Table 2-2.
Figure 2-5. GetDIB()
Figure 2-6. Device Info Field Definition
Reserved
# of Domains
Reserved
76543210
Byte# 5
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For the processor PECI client, the Revision Number it returns will be ‘0011 0100b’.
2.5.2.3 GetTemp()
The GetTemp() command is used to retrieve the die temperature from a target PECI
address. The temperature is used by the external thermal management system to
regulate the temperature on the die. The data is returned as a negative value
representing the number of degrees Celsius below the processor DTS temperature
(TProchot) at which PROCHOT_N asserts. The PECI temperature value of zero
corresponds to TProchot. This also represents the minimum temperature at which the
processor Thermal Control Circuit activates. The actual value that the thermal
management system uses as a control set point (TCONTROL) is also defined as a
negative number below TProchot. TCONTROL may be extracted from the processor by
issuing a PECI RdPkgConfig() command as described in Section 2.5.2.4 or using a
RDMSR instruction. TCONTROL application to fan speed control management is defined in
the Intel® Xeon® Processor E5-1600/2600/4600 v1 and v2 Product Families Thermal /
Mechanical Design Guide.
Please refer to Section 2.5.7 for details regarding PECI temperature data formatting.
2.5.2.3.1 Command Format
The GetTemp() format is as follows:
Write Length: 0x01
Read Length: 0x02
Figure 2-7. Revision Number Definition
Table 2-2. Minor Revision Number Meaning
Minor Revision Supported Command Suite
0 Ping(), GetDIB(), GetTemp()
1 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig()
2 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig(), RdIAMSR()
3 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig(), RdIAMSR(),
RdPCIConfigLocal(), WrPCIConfigLocal()
4 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig(), RdIAMSR(),
RdPCIConfigLocal(), WrPCIConfigLocal(), RdPCIConfig()
5 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig(), RdIAMSR(),
RdPCIConfigLocal(), WrPCIConfigLocal(), RdPCIConfig(), WrPCIConfig()
6 Ping(), GetDIB(), GetTemp(), WrPkgConfig(), RdPkgConfig(), RdIAMSR(),
RdPCIConfigLocal(), WrPCIConfigLocal(), RdPCIConfig(), WrPCIConfig(), WrIAMSR()
0
3
4
7
Major Revision#
Minor Revision#
Byte# 6
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34 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Command: 0x01
Description: Returns the highest die temperature for addressed processor PECI client.
Example bus transaction for a thermal sensor device located at address 0x30 returning
a value of negative 10 counts is show in Figure 2-9.
2.5.2.3.2 S upp o rte d Response s
The typical client response is a passing FCS and valid thermal data. Under some
conditions, the client’s response will indicate a failure. GetTemp() response definitions
are listed in Table 2-3. Refer to Section 2.5.7.4 for more details on sensor errors.
Notes:
1. This response will be reflected in Bytes 5 & 6 in Figure 2-9.
2.5.2.4 RdPkgConfig()
The RdPkgConfig() command provides read access to the package configuration space
(PCS) within the processor, including various power and thermal management
functions. Typical PCS read services supported by the processor may include access to
temperature data, energy status, run time inform ation, DIMM temperatures and so on.
Refer to Section 2.5.2.6 for more details on processor-specific services supported
through this command.
Figure 2-8. GetTemp()
Byte #
Byte
Definition
0
Client A ddres s
1
Write Length
0x01
2
Read Length
0x02
4
FCS
5
Temp[7:0]
6
Temp[15:8]
7
FCS
3
Cmd Code
0x01
Figure 2-9. GetTemp() Example
Byte #
Byte
Definition
0
0x30
1
0x01
2
0x02
4
0xef
5
0x80
6
0xfd
7
0x4b
3
0x01
Table 2-3. GetTemp() Response Definition
Response Meaning
General Sensor Error (GSE)1Thermal scan did not complete in time. Retry is appropriate.
Bad Write FCS Electrical error
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
0x00001Processor is running at its maximum temperature or is currently being reset.
All other data Valid temperature reading, reported as a negative offset from TProchot.
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 35
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2.5.2.4.1 Command Format
The RdPkgConfig() format is as follows:
Write Length: 0x05
Read Length: 0x05 (dword)
Command: 0xa1
Description: Returns the data maintained in the processor package configuration
space for the PCS entry as specified by the ‘index’ and ‘parameter’ fie l ds. The ‘index’
field contains the encoding for the requested service and is used in conjunction with the
‘parameter’ field to specify the exact data being requested. The Read Length dictates
the desired data return size. This command supports only dword responses on the
processor PECI clients. All command responses are prepended with a completion code
that contains additional pass/fail status information. Refer to Section 2.5.5.2 for details
regarding completion codes.
Note: The 2-byte parameter field and 4-byte r ead data field defined in Figure 2-10 are sent in standard PECI ordering with LSB
first and MSB last.
2.5.2.4.2 Supported Responses
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
Figure 2-10. RdPkgConfig()
Table 2-4. RdPkgConfig() Response Definition
Response Meaning
Bad Write FCS Electrical error
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The pro cessor is not able to g enerate the require d response i n a timely
fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able to allocate resources for servicing this
command at this time. Retry is appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
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36 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.5 WrPkgConfig()
The W rPkgConfig() command provides write access to the package con figuration space
(PCS) within the processor, including various power and thermal management
functions. Typical PCS write services supported by the processor may include power
limiting, thermal averaging constant programming and so on. Refer to Section 2.5.2.6
for more details on processor-specific services supported through this command.
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to
process the requ est.
CC: 0x93 Pcode MCA - PECI access allowed, but PECI access cannot be completed.
CC: 0x94 Pcode MCA - PECI access allowed and access completes. Will respond with the data along
with the response code.
Table 2-4. RdPkgConfig() Response Definition
Response Meaning
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 37
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2.5.2.5.1 Command Format
The WrPkgConfig() format is as follows:
Write Length: 0x0a(dword)
Read Length: 0x01
Command: 0xa5
AW FCS Support: Yes
Description: Writes data to the processor PCS entry as specified by the ‘index’ and
‘parameter’ fields. This command supports only dword data writes on the processor
PECI clients. All command responses include a completion code that provides
additional pass/fail status information. Refer to Section 2.5.5.2 for details regarding
completion codes.
The Assured Write FCS (AW FCS) support provides the processor client a high degree
of confidence that the data it received from the host is correct. This is especially
critical where the consumption of bad data might result in improper or non-recover able
operation.
Note: The 2-byte parameter field and 4-byte write data field defined in Figure 2-11 are sent in standard PECI
ordering with LSB first and MS B last.
Figure 2-11. WrPkgConfig()
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38 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.5.2 S upp o rte d Response s
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
2.5.2.6 Package Configuration Capabilities
Table 2-6 combines both read and write services. Any service listed as a “read” would
use the RdPkgConfig() command and a service listed as a “write” would use the
WrPkgConfig() command. PECI requests for memory temperature or other data
generated outside the processor package do not trigger special polling cycles on the
processor memory or SMBus interfaces to procure the required information.
2.5.2.6.1 DRAM Thermal and Power Optimization Capabilities
DRAM thermal and power optimization (also known as RAPL or “Running Av erage Power
Limit”) services provide a way for platform thermal management solutions to program
and access DRAM power, energy and temperature parameters. Memory temperature
information is typically used to regulate fan speeds, tune refresh rates and throttle the
memory subsystem as appropriate. Memory temperature data may be derived from a
variety of sources including on-die or on-board DIMM sensors, DRAM activity
information or a combination of the two. Though memory temperature data is a byte
long, range of actual temperature values are determined by the DIMM specifications
and operating range.
Note: DRAM related PECI services described in this section apply only to the memory
connected to the specific processor PECI client in question and not the ov er all platform
memory in general. For estim ating DRAM thermal information in closed loop throttling
mode, a dedicated SMBus is required between the CPU and the DIMMs. The proce ssor
PCU requires access to the VR12 voltage regulator for reading average output current
information through the SVID bus for initial DRAM RAPL related power tuning.
Table 2-6 provides a summary of the DRAM power and thermal optimization capabilities
that can be accessed over PECI on the processor. The Index values referenced in
Table 2-6 are in decimal f ormat.
Table 2-6 also provides information on alternate inband mechanisms to access similar
or equivalent inf ormation through register reads and writes where applicable. The user
should consult the Intel® Xeon® Processor E5 v2 Product Family Processor Datasheet,
Volume Two: Registers for exact details on MSR or CSR register content.
Table 2-5. WrPkgConfig() Response Definition
Response Meaning
Bad Write FCS Electrical error or AW FCS failure
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The processor was not able to generate the required response in a
timely fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able to allocate resources for servicing this
command at this time. Retry is appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to
process the request.
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 39
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Interfaces
Table 2-6. RdPkgConfig() & WrPkgConfig() DRAM Thermal and Power Optimization
Services Summary (Sheet 1 of 2)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig()
Data
(dword) Description
Alternate
Inband
MSR or CSR
Access
DRAM
Thermal
Estimation
Configuration
Data
Read/Write
15 0x0000
DRAM Thermal
Estimation
Configuration Data
N/A Read the DRAM
Thermal
Estimation
configuration
parameters.
CSR:
MEM_TRML_ESTIMATION_
CONFIG
DRAM
Thermal
Estimation
Configuration
Data
Read/Write
15 0x0000
N/A DRAM Thermal
Estimation
Configuration
Data
Configure the
DRAM Thermal
Estimation
parameters.
CSR:
MEM_TRML_ESTIMATION_
CONFIG
DRAM Rank
Temperature
Write 18 Channel
Index &
DIMM Index
N/A Absolute
temperature in
Degrees Celsius
for ranks 0, 1, 2
& 3
Write
temperature
for each rank
within a single
DIMM.
N/A
DIMM
Temperature
Read 14 Channel
Index
Absolute
temperature in
Degrees Celsius for
DIMMs 0, 1, & 2
N/A Read
temper ature of
each DIMM
within a
channel.
CSR: DIMMTEMPSTAT_[0:2]
DIMM
Ambient
Temperature
Write / Read 19 0x0000
N/A Absolute
temperature in
Degrees C to be
used as ambient
temperature
reference
Wr ite ambient
temperature
reference for
activity-based
rank
temperature
estimation.
N/A
DIMM
Ambient
Temperature
Write / Read 19 0x0000
Absolute
temperature in
Degrees C to be
used as ambient
temperature
reference
N/A Read ambient
temperature
reference for
activity-based
rank
temperature
estimation.
N/A
DRAM
Channel
Temperature
Read 22 0x0000
Maximum of all
rank temperatures
for each channel in
Degrees Celsius
N/A Read the
maximum
DRAM channel
temperature.
N/A
Accumulated
DRAM Energy
Read
04 Channel
Index
0x00FF - All
Channels
DRAM energy
consumed by the
DIMMs
N/A Read the DRAM
energy
consumed by
all the DIMMs
in all the
channels or all
the DIMMs
within a
specified
channel.
MSR 619h:
DRAM_ENERGY_STATUS
CSR: DRAM_ENERGY_STATUS
CSR:
DRAM_ENERGY_STATUS_CH[
0:3] 1
DRAM Power
Info Read 35 0x0000
Typical and
minimum DRAM
power settings
N/A Read DRAM
power settings
info to be used
by power
limiting entity.
MSR 61Ch:
DRAM_POWER_INFO
CSR: DRAM_POWER_INFO
DRAM Power
Info Read 36 0x0000
Maximum DRAM
power settings &
maximum time
window
N/A Read DRAM
power settings
info to be used
by power
limiting entity
MSR 61Ch:
DRAM_POWER_INFO
CSR: DRAM_POWER_INFO
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40 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Notes:
1. Time, energy and power units should be assumed, where applicable, to be based on values retu rned by a read of the
PACKAGE_POWER_SKU_UNIT MSR or through the Package Power SKU Unit PCS read service.
2.5.2.6.2 DRAM Thermal Estimation Configuration Data Read/Write
This feature is relevant only when activity-based DRAM temperature estimation
methods are being utilized and would apply to all the DIMMs on all the memory
channels. The write allows the PECI host to configure the ‘β’ and ‘θ’ variables in
Figure 2-12 for DRAM channel temperature filtering as per the equation below:
TN = β TN-1 + θ ∗ ΔEnergy
TN and TN-1 are the current and previous DRAM temperature estimates respectively in
degrees Celsius, ‘β’ is the DRAM temperature decay factor, ‘ΔEnergy’ is the energy
difference between the current and previous memory transactions as determined by
the processor power control unit and ‘θ’ is the DRAM energy -to-temperature translation
coefficient. The default value of ‘β’ is 0x3FF. ‘θ’ is defined by the equation:
θ = (1 - β) ∗ (Thermal Resistance) ∗ (Scaling Factor)
The ‘Thermal Resistance’ serves as a multiplier for translation of DRAM energy changes
to corresponding temperature changes and may be derived from actual platform
characterization data. The ‘Scaling Factor’ is used to convert memory transaction
information to energy units in Joules and can be derived from system/memory
configuration information. Refer to the Intel® 64 and IA-32 Architectures Software
Developer’s Manual for methods to program and access ‘Scaling Factor’ information.
DRAM Power
Limit Data
Write / Read 34 0x0000
N/A DRAM Plane
Power Limit Data Write DR AM
Power Limit
Data
MSR 618h:
DRAM_POWER_LIMIT
CSR:
DRAM_PLANE_POWER_LIMIT
DRAM Power
Limit Data
Write / Read 34 0x0000
DRAM Plane P ower
Limit Data N/A Read DRAM
Power Limit
Data
MSR 618h:
DRAM_POWER_LIMIT
CSR:
DRAM_PLANE_POWER_LIMIT
DRAM Power
Limit
Performance
Status Read 38 0x0000
Accumulated DRAM
throttle time N/A Read sum of all
time durations
for which each
DIMM has been
throttled
CSR:
DRAM_RAPL_PERF_STATUS
Table 2-6. RdPkgConfig() & WrPkgConfig() DRAM Thermal and Power Optimization
Services Summary (Sheet 2 of 2)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig()
Data
(dword) Description
Alternate
Inband
MSR or CSR
Access
Figure 2-12. DRAM Thermal Estimation Configuration Data
Memory Thermal Estimation Configuration Data
RESERVED
1031
BETA VARIA BLE
9 0
THETA VARIABLE
1920
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 41
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2.5.2.6.3 DRAM Rank Temperature Write
This feature allows the PECI host to program into the processor, the temperature for all
the ranks within a DIMM up to a maximum of four ranks as shown in Figure 2-13. The
DIMM index and Channel index are specified through the parameter field as shown in
Table 2-7. This write is relevant in platforms that do not hav e on-die or on-board DIMM
thermal sensors to provide memory temperature information or if the processor
does not have direct access to the DIMM thermal sensors. This temperature
information is used by the processor in conjunction with the activity-based DRAM
temperature estimations.
2.5.2.6.4 DIMM Temperature Read
This feature allows the PECI host to read the temperature of all the DIMMs within a
channel up to a maximum of th ree DIMMs. This read is not limited to platforms using a
particular memory temperature source or temperature estimation method. For
platforms using DRAM thermal estimation, the PCU will provide the estimated
temperatures. Otherwise, the data represents the latest DIMM temperature provided
by the TSOD or on-board DIMM sensor and requires that CLTT (closed loop throttling
mode) be enabled and OL T T (open loop throttling mode) be disabled. Refer to Table 2-7
for channel index encodings.
Table 2-7. Channel & DIMM Index Decoding
Index Encoding Physical Channel# Physical DIMM#
000 0 0
001 1 1
010 2 2
011 3 Reserved
Figure 2-13. DRAM Rank Temperature Write Data
15 7 0
Rank Temperature Data
Rank# 3
Absolute Temp
(in Degrees C)
Rank# 2
Absolute Temp
(in Degrees C)
Rank# 1
Absolute Temp
(in Degrees C)
Rank# 0
Absolute Temp
(in Degrees C)
816232431
15 2
Paramet er format
Reserved DIMM Index
6
Channel Index
5 3 0
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42 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.6.5 DIMM Ambient Temperature Write / Read
This feature allows the PECI host to provide an ambient temperature reference to be
used by the processor for activity-based DRAM temperature estimation. This write is
used only when no DIMM temperature information is available from on-board or on-die
DIMM thermal sensors. It is also possible for the PECI host controller to read back the
DIMM ambient reference temperature.
Since the ambient temper ature may vary ov er time within a system, it is recommended
that systems monitoring and updating the ambient temperature at a fast rate use the
‘maximum’ temperature value while those updating the ambient temper ature at a slow
rate use an ‘average’ value. The ambient temperature assumes a single value for all
memory channel/DIMM locations and does not account for possible temperature
variations based on DIMM location.
2.5.2.6.6 DRAM Channel Temperature Read
This feature enables a PECI host read of the maximum temperature of each channel.
This would include all the DIMMs within the channel and all the ranks within each of the
DIMMs. Channels that are not populated will return the ‘ambient temperature’ on
systems using activity-based temperature estimations or alternatively return a ‘zero’
for systems using sensor-based temperatures.
Figure 2-14. The Processor DIMM Temperature Read / Write
15 7 0
DIMM Temperature Data
Reserved DIMM# 2
Absolute Temp
(in Degrees C)
DIMM# 1
Absolute Temp
(in Degre es C)
DIMM# 0
Absolute Temp
(in Degrees C)
816232431
15 2
Parameter format
Reserved Channel Index
3 0
Figure 2-15. Ambient Temperature Reference Data
7 0
Ambient Temperature Reference Data
Reserved Ambient
Temperature
(in Deg r e es C)
831
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 43
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2.5.2.6.7 Accumulated DRAM Energy Read
This feature allows the PECI host to read the DRAM energy consumed by all the DIMMs
within all the channels or all the DIMMs within just a specified channel. The parameter
field is used to specify the channel index. Units used are defined as per the Package
Power SKU Unit read described in Section 2.5.2.6.11. This information is tracked by a
32-bit counter that wraps around. The channel index in Figure 2-17 is specified as per
the index encoding described in Ta ble 2-7. A channel in dex of 0x00 FF is used to specify
the “all channels” case. While Intel requires reading the accumulated energy data at
least once every 16 seconds to ensure functional correctness, a more realistic polling
rate recommendation is once every 100 mS for better accuracy. This feature assumes a
200W memory capacity. In general, as the power capability decreases, so will the
minimum polling rate requirement.
When determining energy changes by subtracting energy values between successive
reads, Intel advocates using the 2’s complement method to account for counter wrap-
arounds. Alternatively, adding all ‘F’s (‘0xFFFFFFFF’) to a negative result from the
subtraction will accomplish the same goal.
2.5.2.6.8 DRAM Power Info Read
This read returns the minimum, typical and maximum DRAM power settings and the
maximum time window over which the power can be sustained for the entire DRAM
domain and is inclusive of all the DIMMs within all the memory channels. Any power
values specified by the power limiting entity that is outside of the range specified
through these settings cannot be guaranteed. Since this data is 64 bits wide, PECI
facilitates access to this register by allowing two requests to read the lower 32 bits and
upper 32 bits separately as shown in Table 2-6. Power and time units for this read are
defined as per the Package Power SKU Unit settings described in Section 2.5.2.6.11.
Figure 2-16. Processor DRAM Channel Temperature
15 7 0
Channel Temperature Data
Channel 3
Maximum
Temperature
(in Degrees C)
Channel 2
Maximum
Temperature
(in Degrees C)
Channel 1
Maximum
Temperature
(in Degrees C)
Channel 0
Maximum
Temperature
(in Degrees C)
816232431
Figure 2-17. Accumulated DRAM En ergy Data
0
Accumulated DRAM Energy Data
Accumulated DRAM Energy
31
15 2
Parameter format
Reserved Channel Index
3 0
Interfaces
44 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
The minimum DRAM power in Figure 2-18 corresponds to a minimum bandwidth
setting of the memory interface. It does ‘not’ correspond to a processor IDLE or
memory self-refresh state. The ‘time window’ in Figure 2-18 is representative of the
rate at which the power control unit (PCU) samples the DRAM energy consumption
information and reactively takes the necessary measures to meet the imposed power
limits. Programming too small a time window may not give the PCU enough time to
sample energy information and enforce the limit while too large a time window runs the
risk of the PCU not being able to monitor and take timely action on energy excursions.
While the DRAM power setting in Figure 2-18 provides a maximum value for the ‘time
window’ (typically a few seconds), the minimum value may be assumed to be
~100 mS.
The PCU programs the DRAM power settings described in Figure 2-18 when DRAM
characterization has been completed by the memory reference code (MRC) du ring boot
as indicated by the setting of the RST_CPL bit of the BIOS_RESET_CPL register. The
DRAM power settings will be programmed during boot independent of the ‘DRAM Power
Limit Enable’ bit setting. Please refer to the In tel® Xeon® Processor E5 v2 Product
Family Processor Datasheet, Volume Two: Registers for information on memory energy
estimation methods and energy tuning options used by BIOS and other utilities for
determining the range specified in the DRAM power settings. In general, any tuning of
the power settings is done by polling the voltage regulators supplying the DIMMs.
2.5.2.6.9 DRAM Power Limit Data Write / Read
This feature allows the PECI host to program the power limit over a specified time or
control window for the entire DRAM domain covering all the DIMMs within all the
memory channels. Actual values are chosen based on DRAM power consumption
characteristics. The units for the DRAM Power Limit and Control Time Window are
determined as per the Package Power SKU Unit settings described in
Section 2.5.2.6.11. The DRAM Power Limit Enable bit in Figure 2-19 should be set to
activate this feature. Exact DRAM power limit v alues are largely determined by platform
memory configuration. As such, this feature is disabled by default and the re are no
defaults associated with the DRAM power limit values. The PECI host may be used to
enable and initialize the power limit fields for the purposes of DRAM power budgeting.
Alternatively, this can also be accomplished through inband writes to the appropriate
registers. Both power limit enabling and initialization of power limit values can be done
in the same command cycle. All RAPL parameter v alues including the power limit value,
control time window , and enable bit will have to be specified correctly ev en if the intent
is to change just one parameter value when programming over PECI.
Figure 2-18. DRAM Power Info Read Data
DRAM_POWER_INFO (lower bits)
Reserved
14
Minimum DRAM Power
16
TDP DR AM Pow e r
(Typical Value)
30 015
Reserved
31
DRAM_POWER_INFO (upper bits)
Maximum DRAM Power
3246
Reserved
47
Maximum Time
Window
4854
Reserved
5563
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 45
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The following conversion formula should be used for encoding or programming the
‘Control Time Window’ in bits [23:17].
Control Time Window (in seconds) = ([1 + 0.25 * ‘x’] * 2‘y’) * ‘z’ where
‘x’ = integer value of bits[23:22]
‘y’ = integer value of bits[21:17]
‘z’ = Package Power SKU Time Unit[19:16] (see Section 2.5.2.6.13 for details on
Pa ckage Power SKU Unit)
For example, using this formula, a control time value of 0x0A will correspond to a
‘1-second’ time window. A valid range for the value of the ‘Control Time Window’ in
Figure 2-19 that can be programmed into bits [23:17] is 250 mS - 40 seconds.
From a DRAM power management standpoint, all post-boot DRAM power management
activities (also referred to as ‘DRAM RAPL’ or ‘DRAM Running Average Power Limit’)
should be managed exclusively through a single interface like PECI or alternatively an
inband mechanism. If PECI is being used to manage DRAM power budgeting activities,
BIOS should lock out all subsequent inband DRAM power limiting accesses by setting
bit 31 of the DRAM_POWER_LIMIT MSR or DRAM_PLANE_POWER_LIMIT CSR to ‘1’.
2.5.2.6.10 DRAM Power Limit Performance Status Read
This service allows the PECI host to assess the performance impact of the currently
active DRAM power limiting modes. The read return data contains the sum of all the
time durations for which each of the DIMMs has been operating in a low power state.
This information is tracked by a 32-bit counter that wraps around. The unit for time is
determined as per the Package Power SKU Unit settings described in
Section 2.5.2.6.11. The DRAM performance data does not account for stalls on the
memory interface.
In general, for the purposes of DRAM RAPL, the DRAM power management entity
should use PECI accesses to DRAM energy and performance status in conjunction with
the power limiting feature to budget power between the various memory sub-systems
in the server system.
Figure 2-19. DRAM Powe r Limit Data
DRAM _POW ER_LIM IT Data
DRAM
Power Lim it
Enable
1523
DRAM Power Lim it
14 0
RESERVED
16
Control Tim e
Window
1731
RESERVED
24
Figure 2-20. DRAM Power Limit Performance Data
DRAM Power Limit Perfor mance
Accumulated DRA M Thr ottle Tim e
0
31
Interfaces
46 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.6.11 CPU Thermal and Power Optimization Capabilities
Table 2-8 provides a summary of the processor power and thermal optimization
capabilities that can be accessed over PECI.
Note: The Index values referenced in Table 2-8 are in decimal format.
Table 2-8 also provides information on alternate inband mechanisms to access similar
or equivalent information for register reads and writes where applicable. The user
should consult the appropriate Intel® Xeon® Processor E5 v2 Product Family Processor
Datasheet, Volume Two: Registers for exact details on MSR or CSR register content.
Table 2-8. RdPkgConfig() & WrPkgConfig() CPU Thermal and Power Optimization
Services Summary (Sheet 1 of 4)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig
()
Data
(dword)
Description
Alternate
Inband
MSR or CSR
Access
Package
Identifier Read 00 0x0000 CPUID
Information Returns processor-
specific information
including CPU family ,
model and stepping
information.
Execute CPUID instruction to get
processor signature
0x0001 Platform ID Used to ensure
microcode update
compatibility with
processor.
MSR 17h: IA32_PLATFORM_ID
0x0002 PCU Device ID Returns the Device
ID information for
the processor Power
Control Unit.
CSR: DID
0x0003 Max Thread ID Returns the
maximum ‘Thread
ID’ value supported
by the processor.
MSR: RESOLVED_CORES_MASK
CSR: RESOLVED_CORES_MASK
0x0004 CPU Microcode
Update Revision Returns processor
microcode and PCU
firmware revision
information.
MSR 8Bh: IA32_BIOS_SIGN_ID
0x0005 MCA Error
Source Log Returns the MCA
Error Source Log CSR: MCA_ERR_SRC_LOG
Package Power
SKU Unit Read 30 0x0000 Time, Energy
and Power Units N/A Read units for power,
energy and time
used in powe r
control registers.
MSR 606h:
PACKAGE_POWER_SKU_UNIT
CSR:
PACKAGE_POWER_SKU_UNIT
Package Power
SKU Read 28 0x0000 Package Power
SKU[31:0] N/A Returns Thermal
Design Power an d
minimum package
power values for the
processo r SKU.
MSR 614h:
PACKAGE_POWER_SKU
CSR: PACKAGE_POWER_SKU
Package Power
SKU Read 29 0x0000 Package Power
SKU[64:32] N/A Returns the
maximum package
power value for the
processor SKU and
the maximum time
interval for which it
can be s ustaine d.
MSR 614h:
PACKAGE_POWER_SKU
CSR: PACKAGE_POWER_SKU
“W ak e on PECI”
Mode bit W rite /
Read
05 0x0001 - Set
0x0000 -
Reset
N/A “Wake on PECI”
mode bit Enables package
pop-up to C2 to
service PECI
PCIConfig() accesses
if appropriate.
N/A
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 47
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Interfaces
“W ake on PECI”
Mode bit Write /
Read
05 0x0000 “W ake on PECI”
mode bit N/A Read status of
“Wake on PECI
mode bit
N/A
Accumulated
Run Time Rea d 31 0x0000 Total reference
time N/A R eturns the total run
time. MSR 10h:
IA32_TIME_STAMP_COUNTER
Package
Temperature
Read
02 0x00FF Processor
package
Temperature
N/A Returns the
maximum processor
die temperature in
PECI format.
MSR 1B1h:
IA32_PACKAGE_THERM_STATUS
Per Core DTS
Temperature
Read
09 0x0000-
0x0007
(cores 0-7)
0x00FF -
System
Agent
Per core DTS
maximum
temperature
N/A Read the maximum
DTS temperature of
a particular core or
the System Agent
within the processor
die in relative PECI
temperature format
MSR 19Ch: IA32_THERM_ST A TUS
Temperature
Target Read 16 0x0000 Processor
TProchot and
TCONTROL
N/A Returns the
PROCHOT_N
assertion
temperature and
processo r TCONTROL.
MSR 1A2h:
TEMPERATURE_TARGET
CSR: TEMPERATURE_TARGET
Package
Thermal Status
Read / Clear
20 0x0000 Thermal Status
Register N/A Read the thermal
status register and
optionally clear any
log bits. The regis ter
includes status and
log bits for TCC
activation,
PROCHOT_N
assertion and Critical
Temperature.
MSR 1B1h:
IA32_PACKAGE_THERM_STATUS
Thermal
Averaging
Constant Write /
Read
21 0x0000 Thermal
Averaging
Constant
N/A Reads the Thermal
Averaging Constant N/A
Thermal
Averaging
Constant Write /
Read
21 0x0000 N/A Thermal
Averaging
Constant
Writes the Thermal
Averaging Constant N/A
Thermally
Constrained
Time Read
32 0x0000 Thermally
Constrained
Time
N/A Read the time for
which the proc essor
has been op erating
in a lowered power
state due to internal
TCC activation.
N/A
Current Limit
Read 17 0x0000 Current Limit
per power plane N/A Reads the current
limit on the VCC
power plane
CSR:
PRIMARY_PLANE_CURRENT_
CONFIG_CONTROL
Accumulated
Energy Sta tus
Read
03 0x0000 -
VCC
0x00FF - CPU
package
Accumulated
CPU energy N/A Returns the value of
the energy
consumed by just
the VCC power plane
or entire CPU
package.
MSR 639h: PP0_ENERGY_
STATUS
CSR: PP0_ENERGY_STATUS
MSR 611h:
PACKAGE_ENERGY_STATUS
CSR: PACKAG_ENERGY_STATUS
Table 2-8. RdPkgConfig() & WrPkgConfig() CPU Thermal and Power Optimization
Services Summary (Sheet 2 of 4)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig
()
Data
(dword)
Description
Alternate
Inband
MSR or CSR
Access
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48 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Power Limit for
the VCC Power
Plane Write /
Read
25 0x0000 N/A Power Limit Data Program power limit
for VCC power plane MSR 638h: PP0_POWER_LIMIT
CSR: PP0_POWER_LIMIT
Power Limit for
the VCC Power
Plane Write /
Read
25 0x0000 Power Limit
Data N/A Read power limit
data fo r VCC power
plane
MSR 638h: PP0_POWER_LIMIT
CSR: PP0_POWER_LIMIT
Package Power
Limits For
Multiple Turbo
Modes
26 0x0000 N/A Power Limit 1
Data Write power limit
data 1 in multiple
turbo mode.
MSR 610h:
PACKAGE_POWER_LIMIT
CSR: PACKAGE_POWER_LIMIT
Package Power
Limits For
Multiple Turbo
Modes
27 0x0000 N/A Power Limit 2
Data Write power limit
data 2 in multiple
turbo mode.
MSR 610h:
PACKAGE_POWER_LIMIT
CSR: PACKAGE_POWER_LIMIT
Package Power
Limits For
Multiple Turbo
Modes
26 0x0000 Power Limit 1
Data N/A Read power limit 1
data in multiple
turbo mode.
MSR 610h:
PACKAGE_POWER_LIMIT
CSR: PACKAGE_POWER_LIMIT
Package Power
Limits For
Multiple Turbo
Modes
27 0x0000 Power Limit 2
Data N/A Read power limit 2
data in multiple
turbo mode.
MSR 610h:
PACKAGE_POWER_LIMIT
CSR: PACKAGE_POWER_LIMIT
Package Power
Limit
Performance
Status Read
08 0x00FF - CPU
package Accumulated
CPU throttle
time
N/A Read the total time
for which the
processor packa ge
was throttled due to
power limiting.
CSR:
PACKAGE_RAPL_PERF_STATUS
Efficient
Performance
Indicator Read
06 0x0000 Number of
productive
processor cycles
N/A Read number of
productive cycles for
power budgeting
purposes.
N/A
ACPI P-T Notify
Write & Rea d 33 0x0000 N/A New p-state
equivalen t of P1
used in
conjunction with
package power
limiting
Notify the processor
PCU of the new p-
state that is one
state below the
turbo frequency as
specified through the
last ACPI Notify
N/A
Table 2-8. RdPkgConfig() & WrPkgConfig() CPU Thermal and Power Optimization
Services Summary (Sheet 3 of 4)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig
()
Data
(dword)
Description
Alternate
Inband
MSR or CSR
Access
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 49
Datasheet Volume One of Two
Interfaces
2.5.2.6.12 Package Identifier Read
This feature enables the PECI host to uniquely identify the PECI client processor. The
parameter field encodings shown in Table 2-8 allow the PECI host to access the
relevant processor information as described below.
CPUID data: This is the equivalent of data that can be accessed through the
CPUID instruction execution. It contains processor type, stepping, model and
family ID information as shown in Figure 2-21.
Platform ID data: The Platform ID data can be used to ensure processor
microcode updates are compatible with the processor. The value of the Platform ID
or Processor Flag[2:0] as shown in Figure 2-22 is typically unique to the platform
type and processor stepping. Refer to the Intel® 64 and IA-32 Architectures
Software Developer’s Manual for more information.
ACPI P-T Notify
Write & Read 33 0x0000 New p-state
equivalent o f P1
used in
conjunction with
package power
limiting
N/A Read the processor
PCU to determine
the p-state that is
one state below the
turbo frequency as
specified through the
last ACPI Notify
N/A
Caching Agent
TOR Read 39 Cbo Index,
TOR Index,
Bank#;
Read Mode
Caching Agent
(Cbo) Table of
Requ ests (TOR)
data;
Core ID &
associated v alid
bit
N/A Read the Cbo TOR
data for all enabled
cores in the event of
a 3-strike timeout.
Can alternatively be
used to read ‘Core
ID’ data to confirm
that IERR was
caused by a core
timeout
N/A
Thermal Margin
Read 10 0x0000 Thermal margin
to processor
thermal profile
or load line
N/A Read margin to
processor thermal
load line
N/A
Table 2-8. RdPkgConfig() & WrPkgConfig() CPU Thermal and Power Optimization
Services Summary (Sheet 4 of 4)
Service Index
Value
(decimal)
Parameter
Value
(word)
RdPkgConfig()
Data
(dword)
WrPkgConfig
()
Data
(dword)
Description
Alternate
Inband
MSR or CSR
Access
Figure 2-21. CPUID Data
CPU ID Data
Model
4
20
Stepping ID
3 0
Family ID
16
Processor
Type
1931
RESERVED
27
Extended
Model
Extended
Family ID
78111228
RESERVED
1315 14
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50 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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PCU Device ID: This information can be used to uniquely identify the processor
power control unit (PCU) device when combined with the Vendor Identification
register content and remains constant across all SKUs. Refer to the appropriate
register description for the exact processor PCU Device ID value.
Max Thread ID: The maximum Thread ID data provides the number of supported
processor threads. This value is dependent on the number of cores within the
processor as determined by the processor SKU and is independent of whether
certain cores or corresponding threads are enabled or disabled.
CPU Microcode Update Revision: R eflects the revision number for the microcode
update and power control unit firmware updates on the processor sample. The
revision data is a unique 32-bit identifier that reflects a combination of specific
versions of the processor microcode and PCU control firmware.
Machine Check Status: Returns error information as logged by the MCA Error
Source Log register. See Figure 2-26 for details. The power control unit will assert
the relevant bit when the error condition represented by the bit occurs. For
example, bit 29 will be set if the package asserted MCERR, bit 30 is set if the
package asserted IERR and bit 31 is set if the package asserted CAT_ERR_N. The
CAT_ERR_N may be used to signal the occurrence of a MCERR or IERR.
Figure 2-22. Platform ID Data
Platform ID Data
Processor
Flag
Reserved
2
31 0
3
Figure 2-23. PCU Device ID
PCU Device ID Data
RESERVED
031
PCU Device ID
1516
Figure 2-24. Maximum Thread ID
Maximum Thread ID Data
Max Thread
ID
Reserved
3
31 0
4
Figure 2-25. Processor Microcode Revision
CPU microcode and PCU firmware revision
31 0
CPU code patch revision
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 51
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2.5.2.6.13 Package Power SKU Unit Read
This feature enables the PECI host to read the units of time, energy and power used in
the processor and DRAM power control registers for calculating power and timing
parameters. In Figure 2-27, the default value of the power unit field [3:0] is 0011b,
energy unit [12:8] is 10000b and the time unit [19:16] is 1010b. Actual unit values are
calculated as shown in Table 2-9.
2.5.2.6.14 Package Power SKU Read
This read allows the PECI host to access the minimum, Thermal Design Power and
maximum power settings for the processor package SKU. It also returns the maximum
time interval or window over which the power can be sustained. If the power limiting
entity specifies a power limit value outside of the range specified through these
settings, power regulation cannot be guaranteed. Since this data is 64 bits wide, PECI
facilitates access to this register by allowing two requests to read the lower 32 bits and
upper 32 bits separately as shown in Table 2-8. Power units for this read are
determined as per the Package Power SKU Unit settings described in
Section 2.5.2.6.13.
‘Pack age Power SKU data’ is prog r amm ed by the PCU f irm w are during boot time b ased
on SKU dependent power-on default values set during manufacturing. The TDP
package power specified through bits [14:0] in Figure 2-28 is the maximum value of
the ‘P ower Limit1’ fie ld in Section 2.5.2.6.26 while the maximum package power in bits
[46:32] is the maximum value of the ‘Power Limit2’ field.
The minimum package power in bits [30:16] is applicable to both the ‘Power Limit1’ &
‘Po wer Limit2’ fields and corresponds to a mode when all the cores are operational and
in their lowest frequency mode. Attempts to program the power limit below the
minimum power value may not be effective since BIOS/OS, and not the PCU, controls
disabling of cores and core activity.
Figure 2-26. Machine Check Status
MCA Error Source Log
Reserved
28 0
MCERRIERRCATERR
293031
Figure 2-27. Package Power SKU Unit Dat a
Table 2-9. Power Control Register Unit Calculations
Unit Field V alue Calculation Default Value
Time 1s / 2TIME UNIT 1s / 210 = 976 µs
Energy 1J / 2ENERGY UNIT 1J / 216 = 15.3 µJ
Pow e r 1W / 2POWER UNIT 1W / 23 = 1/8 W
Reserved
2031
Time Unit
19
Reserved
16 15
Energy U n it
12 8
Reserved Power U n it
13 7 4 3 0
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52 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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The ‘maximum time window’ in bits [54:48] is representative of the maximum rate at
which the power control unit (PCU) can sample the package energy consumption and
reactively take the necessary measures to meet the imposed power limits.
Programming too large a time window runs the risk of the PCU not being able to
monitor and take timely action on package energy excursions. On the other hand,
programming too small a time window may not give the PCU enough time to sample
energy information and enforce the limit. The minimum value of the ‘time window’ can
be obtained by reading bits [21:15] of the PWR_LIMIT_MISC_INFO CSR using the PECI
RdPCIConfigLocal() command.
2.5.2.6.15 “Wake on PECI” Mode bit Write / Read
Setting the “Wake on PECI” mode bit enables successful completion of the
WrPCIConfigLocal(), RdPCIConfigLocal(), WrPCIConfig() and RdPCIConfig() PECI
commands by forcing a package ‘pop-up’ to the C2 state to service these commands if
the processor is in a low-power state. The exact power impact of such a ‘pop-up’ is
determined by the product SKU, the C-state from which the pop-up is initiated and the
negotiated PECI bit rate. A ‘reset’ or ‘clearof this bit or simply not setting the “Wake
on PECI” mode bit could result in a “timeout” response (completion code of 0x82) from
the processor indicating that the resources required to service the command are in a
low power state.
Alternatively, this mode bit can also be read to determine PECI behavior in package
states C3 or deeper.
2.5.2.6.16 Accumulated Run Time Read
This read returns the total time for which the processor has been executing with a
resolution of 1mS per count. This is tracked by a 32-bit counter that rolls over on
reaching the maximum value. This counter activates and starts counting for the first
time at RESET_N de-assertion.
Figure 2-28. Package Power SKU Data
Package Power SKU (lower bits)
Reserved
14
Minimum Package Power
16
TDP Package Power
30 015
Reserved
31
Package Po wer SKU (upper bits)
Maximum Package Power
3246
Reserved
47
Maximum Time
Window
4854
Reserved
5563
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 53
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2.5.2.6.17 Package Temp erature Read
This read returns the maximum processor die temperature in 16-bit PECI format. The
upper 16 bits of the response data are reserved. The PECI temperature data returned
by this read is an exponential moving average of the maximum sensor temperature
(max(core and uncore sensors)), updated once every ms. The equation for the update
is:
Where: Tn is the current average value
Tn-1 is the last average value
tn is the current maximum sensor temperature
Note: This value is not the value as returned by the PECI GetTemp() described in
Section 2.5.2.3.
2.5.2.6.18 Per Core DTS Temperature Read
This feature enables the PECI host to read the maximum v alue of the D TS temper ature
for any specific core within the processor. Alternatively, this service can be used to read
the System Agent temperature. Temperature is returned in the same format as the
P ackage Temperature Re ad described in Section 2.5.2.6.17. Data is returned in relative
PECI temperature format.
Reads to a parameter value outside the supported range will return an error as
indicated by a completion code of 0x90. The supported range of parameter values can
vary depending on the number of cores within the processor. The temperature data
returned through this feature is the instantaneous value and not an averaged value. It
is updated once every 1 mS.
2.5.2.6.19 Temperature Target Read
The Temperature Target Read allows the PECI host to obtain the target DTS
temperature (TProchot) for PROCHOT_N assertion in degrees Celsius. This is the
minimum temperature at which the processor thermal control circuit (TCC) activates.
The actual temperature of TCC activation may vary slightly between processor units
due to manufacturing process variations. The Temperature Target read also returns the
processor TCONTROL value. TCONTROL is returned in standard PECI temperature format
and represents the threshold temperature used by the thermal management system
for fan speed control.
TnTn1255
256
------tn
256
------
+


×=
Figure 2-29. Package Temperature Read Data
Sign
Bit
14
RESERVED
16
PECI Temperature
(Integer Valu e)
61531
PECI Tem pe rature
(F ra c tio n a l V a lu e)
5 0
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54 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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2.5.2.6.20 Package Thermal Status Read / Clear
The Thermal Status Read provides information on package level thermal status. Data
includes:
Thermal Control Circuit (TCC) activation
Bidirectional PROCHOT_N signal assertion
•Critical Temperature
Both status and sticky log bits are managed in this status word. All sticky log bits are
set upon a rising edge of the associated status bit and the log bits are cleared only by
Thermal Status reads or a processor reset. A read of the Thermal Status word always
includes a log bit clear mask that allows the host to clear any or all of the log bits that
it is interested in tracking.
A bit set to ‘0’ in the log bit clear mask will result in clearing the associated log bit. If a
mask bit is set to ‘0’ and that bit is not a legal mask, a failing completion code will be
returned. A bit set to ‘1’ is ignored and results in no change to any sticky log bits. For
example, to clear the TCC Activation Log bit and retain all other log bits, the Thermal
Status Read should send a mask of 0xFFFFFFFD.
2.5.2.6.21 Thermal Averaging Constant Write / Read
This feature allows the PECI host to control the window over which the estimated
processor PECI temperature is filtered. The host may configure this window as a power
of two. F or example, programming a value of 5 results in a filtering window of 25 or 32
samples. The maximum programmable value is 8 or 256 samples. Programming a
value of zero would disable the PECI temperature averaging feature. The default value
of the thermal aver aging constant is 4 which tr anslates to an av eraging window size of
24 or 16 samples. More details on the PECI temperature filtering function can be found
in Section 2.5.7.3.
Figure 2-30. Temperature Target Read
Figure 2-31. Thermal Status Word
Critical Temperature Log
Critical Temperature Status
Bidirectional PROCHOT# Log
Bidirectional PROCHOT#
Status
TCC Activation Log
TCC Activation Status
31 6543210
Reserved
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 55
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Interfaces
2.5.2.6.22 Thermally Constrained Time Read
This features allows the PECI host to access the total time for which the processor has
been operating in a lowered power state due to TCC activation. The returned data
includes the time required to ramp back up to the original P-state target after TCC
activation expires. Th is timer does not include T CC activation as a result of an external
assertion of PROCHOT_N. This is tracked by a 32-bit counter with a resolution of 1mS
per count that rolls over or wr aps arou nd. On the processor PECI clients, the only logic
that can be thermally constrained is that supplied by VCC.
2.5.2.6.23 Current Limit Read
This read returns the current limit for the processor VCC power plane in 1/8A
increments. Actual current limit data is contained only in the lower 13 bits of the
response data. The default return value of 0x438 corresponds to a current limit value
of 135A.
2.5.2.6.24 Accumulated Energy Status Read
This service can return the value of the total energy consumed by the entire processor
package or just the logic supplied by the VCC power plane as specified through the
parameter field in Table 2-8. This information is tracked by a 32-bit counter that wraps
around and continues counting on reaching its limit. Energy units for this read are
determined as per the Package Power SKU Unit settings described in
Section 2.5.2.6.13.
While Intel requires reading the accumulated energy data at least onc e ev e ry 16
seconds to ensure functional correctness, a more realistic polling rate
recommendation is once every 100mS for better accuracy. This feature assumes a
150W processor. In general, as the power capability decreases, so will the minimum
polling rate requirement.
When determining energy changes by subtracting energy values between successive
reads, Intel advocates using the 2’s complement method to account for counter wrap-
arounds. Alternatively, adding all ‘F’s (‘0xFFFFFFFF’) to a negative result from the
subtraction will accomplish the same goal.
Figure 2-32. Thermal Averaging Constant Write / Read
Thermal Averaging Constant
RESERVED
431 PECI Temperature
Averaging Constant
3 0
Figure 2-33. Current Config Limit Read D a ta
Current Config Limit Data
RESERVED
1331
Current Limi t fo r p rocesso r VCC
12 0
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56 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.6.25 Power Limit for the VCC Power Plane Write / Read
This feature allows the PECI host to program the power limit over a specified time or
control window for the processor logic supplied by the VCC power plane. This typically
includes all the cores, home agent and last level cache. The processor does not support
power limiting on a per-core basis. Actual power limit values are chosen based on the
external VR (voltage regulator) capabilities. The units for the Power Limit and Control
Time Window are determined as per the Package Power SKU Unit settings described in
Section 2.5.2.6.13.
Since the exact VCC plane power limit value is a function of the platform VR, this
feature is not enabled by default and there are no default values associated with the
power limit value or the control time window. The Power Limit Enable bit in Figure 2-35
should be set to activate this feature. The Clamp Mode bit is also required to be set to
allow the cores to go into power states below what the operating system originally
requested. In general, this feature provides an improved mechanism for VR protection
compared to the input PROCHOT_N signal assertion method. Both power limit enabling
and initialization of power limit values can be done in the same command cycle. Setting
a power limit for the VCC plane enables turbo modes for associated logic. External VR
protection is guaranteed during boot through operation at safe voltage and frequency.
All RAPL parameter values including the power limit value, control time window, clamp
mode and enable bit will have to be specified correctly even if the intent is to change
just one parameter value when programming over PECI.
The usefulness of the VCC power plane RAPL may be somewhat limited if the platform
has a fully compliant external voltage regulator. However, platforms using lower cost
voltage regulators may find this feature useful. The VCC RAPL value is generally
expected to be a static value after initialization and there may not be any use cases for
dynamic control of VCC plane power limit values during run time. BIOS may be ideally
used to read the VR (and associated heat sink) capabilities and program the PCU with
the power limit information during boot. No matter what the method is, Intel
recommends exclusive use of just one entity or interface, PECI for instance, to manage
VCC plane power limiting needs. If PECI is being used to manage VCC plane power
limiting activities, BIOS should lock out all subsequent inband VCC plane power limiting
accesses by setting bit 31 of the PP0_POWER_LIMIT MSR and CSR to ‘1’.
The same conversion formula used for DRAM Power Limiting (see Section 2.5.2.6.9)
should be applied for encoding or programming the ‘Control Time Window’ in bits
[23:17].
Figure 2-34. Accumulated Energy Read Data
Accumulated Energy Status
Accumulated CPU Energy
0
31
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 57
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2.5.2.6.26 Package Power Limits For Multiple Turbo Modes
This feature allows the PECI host to progr am two power limit values to support multiple
turbo modes. The operating systems and drivers can balance the power budget using
these two limits. Two separate PECI requests are available to program the lower and
upper 32 bits of the power limit data shown in Figure 2-36. The units for the Power
Limit and Control Time Window are determined as per the Package Po wer SKU Unit
settings described in Section 2.5.2.6.13 while the valid range for power limit v alues are
determined by the Package Power SKU settings described in Section 2.5.2.6.14. Setting
the Clamp Mode bits is required to allow the cores to go into power states below what
the operating system originally requested. The P ower Limit Enable bits should be set to
enable the power limiting function. Power limit v alues, enable and clamp mode bits can
all be set in the same command cycle. All RAPL parameter values including the power
limit value, control time window, clamp mode and enable bit will have to be specified
correctly even if the intent is to change just one par ameter value when programming
over PECI.
Intel recommends exclusive use of just one entity or interface, PECI for instance, to
manage all processor package power limiting and budgeting needs. If PECI is being
used to manage package power limiting activities, BIOS should lock out all subsequent
inband package power limiting accesses by setting bit 31 of the
PACKAGE_POWER_LIMIT MSR and CSR to ‘1’. The ‘power limit 1’ is intended to limit
processor power consumption to any reasonable value below TDP and defaults to TDP.
‘Power Limit 1’ values may be impacted by the processor heat sinks and system air
flow . Processor ‘power limit 2’ can be used as appropriate to limit th e current dr awn by
the processor to prevent any external power supply unit issues. The ‘Power Limit 2’
should always be programmed to a value (typically 20%) higher than ‘Power Limit 1’
and has no default value associated with it.
Though this feature is disabled by default and external programming is required to
enable, initialize and control package power limit values and time windows, the
processor package will still turbo to TDP if ‘Power Limit 1’ is not enabled or initialized.
‘Control Time Window#1’ (Power_Limit_1_Time also known as Tau) values may be
programmed to be within a range of 250 mS-40 seconds. ‘Control Time Window#2’
(Power_Limit_2_Time) values should be in the range 3 mS-10 mS.
The same conversion formula used for the DRAM Power Limiting feature (see
Section 2.5.2.6.9) should be applied when programming the ‘Co ntrol Time Window’ bits
[23:17] for ‘power limit 1’ in Figure 2-36. The ‘Control Time Window’ for ‘power limit 2’
can be directly programmed into bits [55:49] in units of mS without the aid of any
conversion formulas.
Figure 2-35. Power Limit D a ta for VCC Power Plane
VCC Power Plane Power Limit Data
Power Limit
Enable
1523
VCC Plane Power Limit
14 0
Clamp
Mode
16
Control Time
Window
1731
RESERVED
24
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58 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
2.5.2.6.27 Package Power Limit Performance Status Read
This service allows the PECI host to assess the performance impact of the currently
active power limiting modes. The read return data contains the total amou nt of time for
which the entire processor package has been operating in a power state that is lower
than what the operating system originally requested. This information is tracked by a
32-bit counter that wraps around. The unit for time is determined as per the Package
Power SKU Unit settings described in Section 2.5.2.6.13.
2.5.2.6.28 Efficient Performance Indicator Read
The Efficient Performance Indicator (EPI) Read provides an indication of the total
number of productive cycles. Specifically, these are the cycles when the processor is
engaged in any activity to retire instructions and as a result, consuming energy. Any
power management entity monitoring this indicator should sample it at least once
every 4 seconds to enable detection of wraparounds. Refer to th e Intel® 64 and IA-32
Architectures Software Developer’s Manual, for details on programming the
IA32_ENERGY_PERFORMANCE_BIAS register to set the ‘Energy Efficiency’ policy of the
processor.
Figure 2-36. Package Turbo Power Limit Data
Package Power Limit 1
Power Limit
Enable #1
1523
Power Limit # 1
14 0
Clamp
Mode #1
16
Control Time
Window #1
1731
RESERVED
24
Package Power Limit 2
Power Limit
Enable #2
4755
Power Limit # 2
46 32
Clamp
Mode #2
48
Contro l Time
Window #2
4963
RESERVED
56
Figure 2-37. Package Power Limit Performance Data
Accum ulated CPU T hrottle Time
Accumulated CPU Throttle Time
0
31
Figure 2-38. Efficient Performance Indicator Read
Effic ien t P e rfo rman ce In dic ato r D a ta
Efficient Performance Cycles
0
31
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2.5.2.6.29 ACPI P-T Notify Write & Read
This feature enables the processor turbo capability when used in conjunction with the
PECI package RAPL or power limit. When the BMC sets the package power limit to a
value below TDP, it also determines a new corresponding turbo frequency and notifies
the OS using the ‘ACPI Notify’ mechanism as supported by the _PPC or performance
present capabilities object. The BMC then notifies the processor PCU using the PECI
ACPI P-T Notify’ service by programming a new state that is one p-state below the
turbo frequency sent to the OS via the _PPC method.
When the OS requests a p-state higher than what is specified in bits [7:0] of the PECI
ACPI P-T Notify data field, the CPU will treat it as request for P0 or turbo. The PCU will
use the IA32_E NER G Y _P ER F OR M AN C E_ B IA S register settings to determine the exact
extent of turbo. Any OS p-state request that is equal to or below what is specified in
the PECI ACPI P-T Notify will be granted as long as the RAPL power limit does not
impose a lower p-state. However, turbo will not be enabled in this instance even if there
is headroom between the processor energy consumption and the RAPL power limit.
This feature does not affect the Thermal Monitor behavior of the processor nor is it
impacted by the setting of the power limit clamp mode bit.
2.5.2.6.30 Caching Agent TOR Read
This feature allows the PECI host to read the Caching Agent (Cbo) Table of Requests
(TOR). This information is useful for debug in the event of a 3-strike timeout that
results in a processor IERR assertion. The 16-bit parameter field is used to specify the
Cbo index, TOR array index and bank number according to the following bit
assignments.
Bits [1:0] - Bank Number - legal values from 0 to 2
Bits [6:2] - TOR Array Index - legal values from 0 to 19
Bits [10:7] - Cbo Index - legal values from 0 to 7
Bit [11] - Read Mode - should be set to ‘0’ for TOR reads, ‘1’ for Core ID reads
Bits [15:12] - Reserved
Bit[11] is the Read Mode bit and should be set to ‘0’ for TOR reads. The Read Mode bit
can alternatively be set to ‘1’ to read the ‘Core ID’ (with associated valid bit as shown in
Figure 2-40) that points to the first core that asserted the IERR. In this case bits [10:0]
of the parameter field are ignored. The ‘Core ID’ read may not return v alid data until at
least 1 mS after the IERR assertion.
Figure 2-39. ACPI P-T Notify Data
ACPI P-T Notify Data
New P1 stateReserved
7
31 0
8
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60 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Note: Reads to caching agents that are not enabled will return all zeroes. Refer to the debug handbook for
details on methods to interpret the crash dump results using the Cbo TOR data shown in Figure 2-40.
2.5.2.6.31 Thermal Margin Read
This service allows the PECI host to read the margin to the processor thermal profile or
load line. Thermal margin data is returned in the format shown in Figure 2-41 with a
sign bit, an integer part and a fractional part. A negative thermal margin value implies
that the processor is operating in violation of its thermal load line and may be indicative
of a need for more aggressive cooling mechanisms through a fan speed increase or
other means. This PECI service will continue to return valid margin values even when
the processor die temperature exceeds TProchot.
2.5.2.7 RdIAMSR()
The RdIAMSR() PECI command provides read access to Model Specific Registers
(MSRs) defined in the processor’s Intel® Architecture (IA). MSR definitions may be
found in the Intel® Xeon® Processor E5 v2 Product Family Processor Datasheet,
Volume Two: Registers. Refer to Table 2-11 for the exact listing of processor registers
accessible through this command.
2.5.2.7.1 Command Format
The RdIAMSR() format is as follows:
Write Length: 0x05
Read Length: 0x09 (qword)
Command: 0xb1
Description: Returns the data maintained in the processor IA MSR space as specified
by the ‘Processor ID’ and ‘MSR Address’ fields. The Read Length dictates the desired
data return size. This command supports only qword responses. All command
responses are prepended with a completion code that contains additional pass/fail
Figure 2-40. Caching Agent TOR Read Data
Read Mode (bit 11) = ‘0’ (within the Param enter)
031
Cbo TOR Data
Read Mode (bit 11) = ‘1’ (within the Parameter)
RESERVED
031
Core ID
35
Valid
4
Figure 2-41. DTS Thermal Margin Read
Sign
Bit
14
RESERVED
16
Thermal Margin
(Integer Value)
61531
The r mal Ma rg in
(F r a c t io n al V alue)
5 0
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status information. Refer to Section 2.5.5.2 for details regarding completion codes.
2.5.2.7.2 Processor ID Enumeration
The ‘Processor ID’ field that is used to address the IA MSR space refers to a specific
logical processor within the CPU. The ‘Processor ID’ always refers to the same ph ysical
location in the processor silicon regardless of configuration as shown in the example in
Figure 2-42. For example, if certain logical processors are disabled by BIOS, the
Processor ID mapping will not change. The total number of Processor IDs on a CPU is
product-specific.
‘Processor ID’ enumeration involves discovering the logical processors enabled within
the CPU package. This can be accomplished by reading the ‘Max Thread ID’ value
through the RdPkgConfig() command (Index 0, Parameter 3) described in
Section 2.5.2.6.12 and subsequently querying each of the supported processor
threads. Unavailable processor threads will return a completion code of 0x90.
Alternatively, this information may be obtained from the RESOLVED_CORES_MASK
register readable through the RdPCIConfigLocal() PECI command described in
Section 2.5.2.9 or other means. Bits [7:0] and [9:8] of this register contain the ‘Core
Mask’ and ‘Thread Mask’ information respectively. The ‘Thread Mask’ applies to all the
enabled cores within the processor package as indicated by the ‘Core Mask’. For
the processor PECI clients, the ‘Processor ID’ may take on values in the range 0
through 23.
Figure 2-42. Processor ID Construction Example
T0T1T0T1T0T1T0T1T0T1T0T1T0T1T0T1
C0C1C2C3…………………C10C11C12
0123456………………181920212223
Processor
ID (0...23)
Cores 0,1,2...12
Thread (0,1) Mask f or Core10
7
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Note: The 2-byte MSR Address field and read data field defined in Figure 2-43 are sent in standard PECI
ordering with LSB first and MSB last.
2.5.2.7.3 S upp o rte d Response s
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
2.5.2.7.4 RdIAMSR() Capabilities
The processor PECI client allows PECI RdIAMSR() access to the registers listed in
Table 2-11. These registers pertain to the processor core and uncore error banks
(machine check banks 0 through 19). Information on the exact number of accessible
banks for the processor device may be obtained by reading the IA32_MCG_CAP[7:0]
MSR (0x0179). This register may be alternatively read using a RDMSR RBIOS
instruction. Please consult the Intel® Xeon® Processor E5 v2 Prodcut Family
Specification Update for more information on the exact number of cores supported by a
particular processor SKU. Any attempt to read processor MSRs that are not accessible
over PECI or simply not implemented will result in a completion code of 0x90.
Figure 2-43. RdIAMSR()
Table 2-10. RdIAMSR() Response Definition
Response Meaning
Bad FCS Electrical error
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The processor was not able to generate the required response in a timely
fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able to allocate resources for servicing this command
at this time. Retry is appropriate.
CC: 0x82 The processor hard ware resources required to se rvic e th is co mmand are in a lo w p ower state .
Retry may be appropriate after modification of PECI wake mode behavior if appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to process
the request.
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PECI access to these registers is expected only when in-band access mechanisms are
not available.
Notes:
1. The IA32_MC0_MISC register details will be available upon implementation in a future processor stepping.
2. The MCi_ADDR and MCi_ MISC re gis ters f or mac hine check banks 2 & 4 are n ot im plem ented on t he pro cesso rs. The MCi_ CTL
register for machine check bank 2 is also not implemented.
Table 2-11. RdIAMSR() Services Summary12
Processor
ID (byte)
MSR
Address
(dword) Meaning Processor
ID (byte)
MSR
Address
(dword) Meaning Processor
ID (byte)
MSR
Address
(dword) Meaning
0x0-0xF 0x0400 IA32_MC0_CTL 0x0-0xF 0x041B IA32_MC6_MISC 0x0-0xF 0x0436 IA32_MC13_ADDR
0x0-0xF 0x0280 IA32_MC0_CTL2 0x0-0xF 0x041C IA32_MC7_CTL 0x0-0xF 0x0437 IA32_MC13_MISC
0x0-0xF 0x0401 IA32_MC0_STATUS 0x0-0xF 0x0287 IA32_MC7_CTL2 0x0-0xF 0x0438 IA32_MC14_CTL
0x0-0xF 0x0402 IA32_MC0_ADDR 0x0-0xF 0x041D IA32_MC7_STATUS 0x0-0xF 0x028E IA32_MC14_CTL2
0x0-0xF 0x0403 IA32_MC0_MISC10x0-0xF 0x041E IA32_MC7_ADDR 0x0-0xF 0x0439 IA32_MC14_STATUS
0x0-0xF 0x0404 IA32_MC1_CTL 0x0-0xF 0x041F IA32_MC7_MISC 0x0-0xF 0x043A IA32_MC14_ADDR
0x0-0xF 0x0281 IA32_MC1_CTL2 0x0-0xF 0x0420 IA32_MC8_CTL 0x0-0xF 0x043B IA32_MC14_MISC
0x0-0xF 0x0405 IA32_MC1_STATUS 0x0-0xF 0x0288 IA32_MC8_CTL2 0x0-0xF 0x043C IA32_MC15_CTL
0x0-0xF 0x0406 IA32_MC1_ADDR 0x0-0xF 0x0421 IA32_MC8_STATUS 0x0-0xF 0x028F IA32_MC15_CTL2
0x0-0xF 0x0407 IA32_MC1_MISC 0x0-0xF 0x0422 IA32_MC8_ADDR 0x0-0xF 0x043D IA32_MC15_STATUS
0x0-0xF 0x0408 IA32_MC2_CTL20x0-0xF 0x0423 IA32_MC8_MISC 0x0-0xF 0x043E IA32_MC15_ADDR
0x0-0xF 0x0282 IA32_MC2_CTL2 0x0-0xF 0x0424 IA32_MC9_CTL 0x0-0xF 0x043F IA32_MC15_MISC
0x0-0xF 0x0409 IA32_MC2_STATUS 0x0-0xF 0x0289 IA32_MC9_CTL2 0x0-0xF 0x0440 IA32_MC16_CTL
0x0-0xF 0x040A IA32_MC2_ADDR20x0-0xF 0x0425 IA32_MC9_STATUS 0x0-0xF 0x0290 IA32_MC16_CTL2
0x0-0xF 0x040B IA32_MC2_MISC20x0-0xF 0x0426 IA32_MC9_ADDR 0x0-0xF 0x0441 IA32_MC16_STATUS
0x0-0xF 0x040C IA32_MC3_CTL 0x0-0xF 0x0427 IA32_MC9_MISC 0x0-0xF 0x0442 IA32_MC16_ADDR
0x0-0xF 0x0283 IA32_MC3_CTL2 0x0-0xF 0x0428 IA32_MC10_CTL 0x0-0xF 0x0443 IA32_MC16_MISC
0x0-0xF 0x040D IA32_MC3_STATUS 0x0-0xF 0x028A IA32_MC10_CTL2 0x0-0xF 0x0444 IA32_MC17_CTL
0x0-0xF 0x040E IA32_MC3_ADDR 0x0-0xF 0x0429 IA32_MC10_STATUS 0x0-0xF 0x0291 IA32_MC17_CTL2
0x0-0xF 0x040F IA32_MC3_MISC 0x0-0xF 0x042A IA32_MC10_ADDR 0x0-0xF 0x0445 IA32_MC17_STATUS
0x0-0xF 0x0410 IA32_MC4_CTL 0x0-0xF 0x042B IA32_MC10_MISC 0x0-0xF 0x0446 IA32_MC17_ADDR
0x0-0xF 0x0284 IA32_MC4_CTL2 0x0-0xF 0x042C IA32_MC11_CTL 0x0-0xF 0x0447 IA32_MC17_MISC
0x0-0xF 0x0411 IA32_MC4_STATUS 0x0-0xF 0x028B IA32_MC11_CTL2 0x0-0xF 0x0448 IA32_MC18_CTL
0x0-0xF 0x0412 IA32_MC4_ADDR20x0-0xF 0x042D IA32_MC11_STATUS 0x0-0xF 0x0292 IA32_MC18_CTL2
0x0-0xF 0x0413 IA32_MC4_MISC20x0-0xF 0x042E IA32_MC11_ADDR 0x0-0xF 0x0449 IA32_MC18_STATUS
0x0-0xF 0x0414 IA32_MC5_CTL 0x0-0xF 0x042F IA32_MC11_MISC 0x0-0xF 0x044A IA32_MC18_ADDR
0x0-0xF 0x0285 IA32_MC5_CTL2 0x0-0xF 0x0430 IA32_MC12_CTL 0x0-0xF 0x044B IA32_MC18_MISC
0x0-0xF 0x0415 IA32_MC5_STATUS 0x0-0xF 0x028C IA32_MC12_CTL2 0x0-0xF 0x044C IA32_MC19_CTL
0x0-0xF 0x0416 IA32_MC5_ADDR 0x0-0xF 0x0431 IA32_MC12_STATUS 0x0-0xF 0x0293 IA32_MC19_CTL2
0x0-0xF 0x0417 IA32_MC5_MISC 0x0-0xF 0x0432 IA32_MC12_ADDR 0x0-0xF 0x044D IA32_MC19_STATUS
0x0-0xF 0x0418 IA32_MC6_CTL 0x0-0xF 0x0433 IA32_MC12_MISC 0x0-0xF 0x044E IA32_MC19_ADDR
0x0-0xF 0x0286 IA32_MC6_CTL2 0x0-0xF 0x0434 IA32_MC13_CTL 0x0-0xF 0x0179 IA32_MCG_CAP
0x0-0xF 0x0419 IA32_MC6_STATUS 0x0-0xF 0x028D IA32_MC13_CTL2 0x0-0xF 0x017A IA32_MCG_STATUS
0x0-0xF 0x041A IA32_MC6_ADDR 0x0-0xF 0x0435 IA32_MC13_STATUS 0x0-0xF 0x0178 IA32_MCG_CONTAIN
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64 Int el® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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3. The PECI host must determine the total number of machine check banks and the validity of the MCi_ADDR and MCi_MISC
register contents prior to issuing a read to the machine check bank similar to standard ma chine check archi tecture
enumeration and accesses.
4. The inform ation prese nted in Table 2-11 is applicable to the processor only. No association between bank numb ers and logical
functions should be assume d fo r any other processor devic es (past, present or future) based on the information presented in
Table 2-11.
5. The processor machine check banks 4 through 19 reside in the processor uncore and hence will return the same value
independent of the processor ID used to access these banks.
6. The IA32_MCG_STATUS, IA32_MCG_CONTAIN and IA32_MCG_CAP are located in the uncore and will return the same value
independent of the processor ID used to access them.
7. The processor machine check banks 0 through 3 are core-specific. Since the processor ID is thread-specific and not core-
specific, machine check banks 0 through 3 will return the same value for a particular core independent of the thread
referenced by the processor ID.
8. PECI accesses to the machi ne check b anks may no t be possible in the event of a core hang. A warm reset of the processor
may be required to read any sticky machine check banks.
9. Valid processor ID values may be obtained by using the enumeration methods described in Section 2.5.2.7.2.
10. Reads to a machine check bank within a core or thread that is disabled will return all zeroes with a completion code of 0x90.
11. For SKUs where Intel QPI is disabled or absent, reads to the corresponding machine check banks will return all zeros with a
completion code of 0x40.
12. Greye d o ut services are reserved: MC6, MC8, MC13, MC14, MC15, MC16
2.5.2.8 RdPCIConfig()
The RdPCIConfig() command provides sideband read access to the PCI configuration
space maintained in downstream devices external to the processor. PECI originators
may conduct a device/function/register enumeration sweep of this space by issuing
reads in the same manner that the BIOS would. A response of all 1’s may indicate that
the device/function/register is unimplemented even with a ‘passing’ completion code.
Alternatively, reads to unimplemented registers may return a completion code of 0x90
indicating an invalid request. Responses will follow normal PCI protocol.
PCI configuration addresses are constructed as shown in Figure 2-44. Under normal in-
band procedures, the Bus number would be used to direct a read or write to the proper
device. Actual PC I bus numbers for all PCI devices including the PCH are programmable
by BIOS. The bus number for PCH devices may be obtained by reading the CPUBUSNO
CSR. Refer to the Intel® Xeon® Processor E5 v2 Product Family Processor Datasheet,
Volume Two: Registers document for details on this register.
PCI configuration reads may be issued in byte, word or dword granularities.
2.5.2.8.1 Command Format
The RdPCIConfig() format is as follows:
Write Length: 0x06
Read Length: 0x05 (dword)
Command: 0x61
Description: Returns the data maintained in the PCI configuration space at the
requested PCI config ur ation ad dress. The Read Length dictates the desired data return
size. This command supports only dword responses with a completion code on the
processor PECI clients. All command responses are prepended with a completion code
that includes additional pass/fail status information. Refer to Section 2.5.5.2 for details
regarding completion codes.
Figure 2-44. PCI Configuration Address
31
Reserved
2728 20 19 15 1114 12 0
FunctionDevice
Bus Register
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Note: The 4-byte PCI configuration address and read data field defined in Figure 2-45 are sent in standard
PECI ordering with LSB first and MSB last.
2.5.2.8.2 Supported Responses
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
The PECI client response can also vary depending on the address and data. It will
respond with a passing completion code if it successfully submits the request to the
appropriate location and gets a response. Exactly what the receiving agent does with
the data or how it responds is up to that agent and is outside the scope of PECI 3.0.
2.5.2.9 RdPCIConfigLocal()
The RdPCIConfigLocal() command provides sideband read access to the PCI
configuration space that resides within the processor. This includes all processor IIO
and uncore registers within the PCI configuration space as described in the Intel®
Xeon® Processor E5 v2 Product Family Processor Datasheet, Volume Two: Registers
document.
PECI originators may conduct a device/function enumeration sweep of this space by
issuing reads in the same manner that the BIOS would. A response of all 1’s may
indicate that the device/function/register is unimplemented even with a ‘passing’
Figure 2-45. RdPCIConfig()
Table 2-12. RdPCIConfig() Response Definition
Response Meaning
Bad FCS Electrical error
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The processor was not able to generate the required response in a
timely fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able to allocate resources for servicing this
command at this time. Retry is appropriate.
CC: 0x82 The processor hardware resources required to service this command are in a low power
state. Retry may be appropriate after modification of PECI wake mode behavior if
appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to
process the request.
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completion code. Alternatively, reads to unimplemented or hidden registers may return
a completion code of 0x90 indicating an invalid request. It is also possible that reads to
function 0 of non-existent IIO devices issued prior to BIOS POST may return all ‘0’s
with a passing completion code. PECI originators can access this space even prior to
BIOS enumeration of the system buses. There is no read restriction on accesses to
locked registers.
PCI configuration addresses are constructed as shown in Figure 2-46. Under normal in-
band procedures, the Bus number would be used to direct a read or write to the proper
device. PECI reads to the processor IIO devices should specify a bus number of ‘0000’
and reads to the rest of the processor uncore should specify a bus number of ‘0001’ for
bits [23:20] in Figure 2-4 6. Any request made with a bad Bus number is ignored and
the client will respond with all ‘0’s and a ‘passing’ completion code.
2.5.2.9.1 Command Format
The RdPCIConfigLocal() format is as follows:
Write Length: 0x05
Read Length: 0x02 (byte), 0x03 (word), 0x05 (dword)
Command: 0xe1
Description: Returns the data maintained in the PCI configuration space within the
processor at the requested PCI configuration address. The Read Length dictates the
desired data return size. This command supports byte, word and dword responses as
well as a completion code. All command responses are prepended with a completion
code that includes additional pass/fail status information. Refer to Section 2.5.5.2 for
details regarding completion codes.
Note: The 3-byte PCI configuration address and read data field defined in Figure 2-47 are sent in standard
PECI ordering with LSB first and MSB last.
Figure 2-46. PCI Configuration Address for local accesses
20 19 15 1114 12 0
23
DeviceBus Function Register
Figure 2-47. RdPCIConfigLocal()
01 2 3
Byte #
FCS
12
7
9
Completion
Code
LSB PCI Configuration Address MSB
10
Write Length
0x05
LSB Data (1, 2 or 4 bytes) MSB
5
Cmd Code
0xe1
14
Read Length
{0x02,0x03,0x05}
68
Host ID[7:1] &
Retry[0]
Client Address
13
4
11
FCS
Byte
Definition
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2.5.2.9.2 Supported Responses
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
The PECI client response can also vary depending on the address and data. It will
respond with a passing completion code if it successfully submits the request to the
appropriate location and gets a response. Exactly what the receiving agent does with
the data or how it responds is up to that agent and is outside the scope of PECI 3.0.
2.5.2.10 WrPCIConfigLocal()
The WrPCIConfigLocal() command provides sideband write access to the PCI
configuration space that resides within the processor. PECI originators can access this
space even before BIOS enumeration of the system buses. The exact listing of
supported devices and functions for writes using this command on the processor is
defined in Table 2-19. The write accesses to registers that are locked will not take effect
but will still return a completion code of 0x40. However, write accesses to registers that
are hidden will return a completion code of 0x90.
Because a WrPCIConfigLocal() command results in an update to potentially critical
registers inside the processor, it includes an Assured Write FCS (AW FCS) byte as part
of the write data payload. In the event that the AW FCS mismatches with the client-
calculated FCS, the client will abort the write and will always respond with a bad
write FCS.
PCI Configuration addresses are constructed as shown in Figure 2-46. The write
command is subject to the same address configuration rules as defined in
Section 2.5.2.9. PCI configuration writes may be issued in byte, word or dword
granularity.
2.5.2.10.1 Command Format
The WrPCIConfigLocal() format is as follows:
Write Length: 0x07 (byte), 0x08 (word), 0x0a (dword)
Read Length: 0x01
Command: 0xe5
Table 2-13. RdPCIConfigLocal() Response Definition
Response Meaning
Bad FCS Electrical error
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The processor was not able to generate the required response in a
timely fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able to allocate resources for servicing this
command at this time. Retry is appropriate.
CC: 0x82 The processor hardware resources required to service this command are in a low power
state. Retry may be appropriate after modification of PECI wake mode behavior if
appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to
process the req uest.
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AW FCS Support: Yes
Description: Writes the data sent to the requested register address. Write Length
dictates the desired write granularity. The command always returns a completion code
indicating pass/fail status. Refer to Section 2.5.5.2 for details on completion codes.
Note: The 3-byte PCI configuration address and write data field defined in Figure 2-48 are sent in standard
PECI ordering with LSB first and MSB last.
2.5.2.10.2 Supported Responses
The typical client response is a passing FCS, a passing Completion Code and valid data.
Under some conditions, the client’s response will indicate a failure.
The PECI client response can also vary depending on the address and data. It will
respond with a passing completion code if it successfully submits the request to the
appropriate location and gets a response. Exactly what the receiving agent does with
the data or how it responds is up to that agent and is outside the scope of PECI 3.0.
Figure 2-48. WrPCIConfigLocal()
Byte
Definition
01 2
FCS
3
Completion
Code
AW FCS
12
Byte #
FCS
13 14 15
Write Length
{0x07, 0x08, 0x0a}
Host ID[7 :1 ] &
Retry[0]
4
8
Read Length
0x01
56
Cmd Code
0xe5
10 11
Client Addre ss
9
LSB PCI Configuration Address MSB
LSB Data (1, 2 or 4 bytes) MSB
7
Table 2-14. Wr PCIConfigLocal() Response Definition (Sheet 1 of 2)
Response Meaning
Bad FCS Electrical error or AW FCS failure
Abort FCS Illegal command formatting (mismatched RL/WL/Command Code)
CC: 0x40 Command passed, data is valid.
CC: 0x80 Response timeout. The proce ssor w as not able to generate the required response i n a timely
fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor is not able t o allocate resources for servicing this command
at this time. Retry is appropriate.
CC: 0x82 The processor hardware resources required to service this command are in a low power
state. Retry may be appropriate after modification of PECI wake mode behavior if
appropriate.
CC: 0x90 Unknown/Invalid/Illegal Request
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2.5.2.10.3 WrPCIConfigLocal() Capabilities
On the processor PECI clients, the PECI WrPCIConfigLocal() command provides a
method for programming certain integrated memory controller and IIO functions as
described in Tab le 2-15. Refer to the Intel® Xeon® Processor E5 v2 Product Family
Processor Datasheet, Volume Two: Registers for more details on specific register
definitions. It also enables writing to processor REUT (Robust Electrical Unified Test)
registers associated with the Intel® QPI, PCIe* and DDR3 functions.
2.5.3 Client Management
2.5.3.1 Power-up Sequencing
The PECI client will not be available when the PWRGOOD signal is de-asserted. Any
transactions on the bus during this time will be completely ignored, and the host will
read the response from the client as all zeroes. PECI client initialization is completed
approximately 100 µS after the PWRGOOD assertion. This is represented by the start of
the PECI Client “Data Not Ready” (DNR) phase in Figure 2-49. While in this phase, the
PECI client will respond normally to the Ping() and GetDIB() commands and return the
highest processor die temperature of 0x0000 to the GetTemp() command. All other
commands will get a ‘Response Timeout’ completion in the DNR phase as shown in
Table 2-16. All PECI services with the exception of core MSR space accesses become
available ~500 µS after RESET_N de-assertion as shown in Figure 2-49. PECI will be
fully functional with all services including core accesses being available when the core
comes out of reset upon completion of the RESET microcode execution.
In the event of the occurrence of a fatal or catastrophic error, all PECI services with the
exception of core MSR space accesses will be available during the DNR phase to
facilitate debug through configuration space accesses.
CC: 0x91 PECI control hardware, firmware or associated logic error. The processor is unable to p rocess
the request.
Table 2-14. WrPCIConfigLocal() Response Definition (Sheet 2 of 2)
Response Meaning
Table 2-15. WrPCIConfigLocal() Memory Controller and IIO Device/Function Support
Bus Device Function Offset Range Description
0000 0-5 0-7 000-FFFh Integrated I/O (IIO) Configuration Registers
0001 15 0 104h-127h Integrated Memory Controller 0 MEM_HOT_N Registers
0001 15 0 180h-1AFh Integrated Memory Controller 0 SMBus Registers
0001 15 1 080h-0CFh Integrated Memory Controller 0 RAS Registers
(Scrub/Spare)
0001 16 0, 1, 4, 5 104h-18Bh
1F4h-1FFh Integrated Memory Controller 0 Thermal Control Registers
0001 16 2, 3, 6, 7 104h-147h Integrated Memory Controller 0 Error Registers
0001 29 0 104h-127h Integrated Memory Controller 1 MEM_HOT_N Registers
0001 29 0 180h-1AFh Integrated Memory Controller 1 SMBus Registers
0001 29 1 080h-0CFh Integrated Memory Controller 1 RAS Registers
(Scrub/Spare)
0001 30 0, 1, 4, 5 104h-18Bh
1F4h-1FFh Integrated Memory Controller 1 Thermal Control Registers
0001 30 2, 3, 6, 7 104h-147h Integrated Memory Controller 1 Error Registers
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In the event that the processor is tri-stated using power -on-configuration controls, the
PECI client will also be tri-stated. Processor tri-state controls are described in
Section 7.3, “Power-On Configuration (POC) Options”.
2.5.3.2 Device Discovery
The PECI client is av ailable on all processors. The presence of a PECI enabled processor
in a CPU socket can be confirmed by using the Ping() command described in
Section 2.5.2.1. Positive identification of the PECI revision number can be achieved by
issuing the GetDIB() command. The revision number acts as a reference to the PECI
specification document applicable to the processor client definition. Please refer to
Section 2.5.2.2 for details on GetDIB response formatting.
2.5.3.3 Client Addressing
The PECI client assumes a default address of 0x30. The PECI client address for the
processor is configured through the settings of the SOCKET_ID[1:0] signals. Each
processor socket in the system requires that the two SOCKET_ID signals be configured
Table 2-16. PECI Client Response During Power-Up
Command Response During
‘Data Not Ready’ Response During
‘Available Except Core Services’
Ping() Fully functional Fully functional
GetDIB() Fully functional Fully functional
GetTemp() Client responds with a ‘hot’ reading or 0x0000 Fu lly functional
RdPkgConfig() Client responds with a timeout completion
code of 0x81 Fully functional
WrPkgConfig() Client responds with a timeout completion
code of 0x81 Fully functional
RdIAMSR() Client responds with a timeout completion
code of 0x81 Client responds with a timeout
completion code of 0x81
RdPCIConfigLocal() Client responds with a timeout completion
code of 0x81 Fully functional
WrPCIConfigLocal() Client responds with a timeout completion
code of 0x81 Fully functional
RdPCIConfig() Client responds with a timeout completion
code of 0x81 Fully functional
Figure 2-49. The Processor PECI Power-up Timeline()
PWRGOOD
RESET_N
Core e xe cu tio n idle running
Reset uCode Boot BIOS
PECI Client
Status Data Not Ready Available except core
services
SOCKET_ID[1:0] XSOCKET ID Valid
In R eset
Fully Ope ra tio n al
In Reset
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to a different PECI addresses. Strapping the SOCKET_ID[1:0] pins results in
the client addresses shown in Table 2-17. These package strap(s) are evaluated
at the assertion of PWRGOOD (as depicted in Figure 2-49).
The client address may not be changed after PWRGOOD assertion, until the next power
cycle on the processor. Remov al of a processor from its socket or tri-stating a processor
will have no impact to the remaining non-tri-stated PECI client addresses. Since each
socket in the system should have a unique PECI address, the SOCKET_ID strapping is
required to be unique for each socket.
2.5.3.4 C-states
The processor PECI client may be fully functional in most core and package C-states.
The Ping(), GetDIB(), GetTemp(), RdPkgConfig() and WrPkgConfig() commands
have no measurable impact on CPU power in any of the core or package C-states.
The RdIAMSR() command will complete normally u nless the targeted core is in a C -
state that is C3 or deeper. The PECI client will respond with a completion code of
0x82 (see Table 2-22 for definition) for RdIAMSR() accesses in core C-states that
are C3 or deeper.
The RdPCIConfigLocal(), WrPCIConfigLocal(), and RdPCIConfig() commands will
not impact the core C-states but may have a measur able impact on the package C-
state. The PECI client will successfully return data without impacting package C-
state if the resources needed to service the command are not in a low pow er state.
If the resources required to service the command are in a low power state, the
PECI client will respond with a completion code of 0x82 (see Table 2-22 for
definition). If this is the case, setting the “W ake on PECI” mode bit as described
in Section 2.5.2.6 can cause a package ‘pop-up’ to the C2 state and enable
successful completion of the command. Th e exact power impact of a pop-up to
C2 will v ary by product SKU, the C-state from w hich the pop-up is initiated and
the negotiated PECI bit rate.
Table 2-17. SOCKET ID Strapping
SOCKET_ID[1] Str ap SOCKET_ID[0] Strap PECI Client Address
Ground Ground 0x30
Ground VTT 0x31
VTT Ground 0x32
VTT VTT 0x33
Table 2-18. Power Impact of PECI Commands vs. C-states
Command Power Impact
Ping() Not measurable
GetDIB() Not measurable
GetTemp() Not measurable
RdPkgConfig() Not measurable
WrPkgConfig() Not measurable
RdIAMSR() Not measurable. PECI client will not return valid data in core C-state that is C3 or
deeper
RdPCIConfigLocal() May require package ‘pop-up’ to C2 state
WrPCIConfigLocal() May require package ‘pop-up’ to C2 state
RdPCIConfig() May require package ‘pop-up’ to C2 state
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2.5.3.5 S-states
The processor PECI client is alwa ys guaranteed to be operational in the S0 sleep state.
The Ping(), GetDIB(), GetTemp(), RdPkgConfig(), WrPkgConfig(),
RdPCIConfigLocal() and WrPCIConfigLocal() will be fully operational in S0 and S1.
Responses in S3 or deeper states are dependent on POWERGOOD assertion status.
The RdPCIConfig() and RdIAMSR() responses are guaranteed in S0 only. Behavior
in S1 or deeper states is indeterminate.
PECI behavior is indeterminate in the S3, S4 and S5 states and responses to PECI
originator requests when the PECI client is in these states cannot be guaranteed.
2.5.3.6 Processor Reset
The processor PECI client is fully reset on all RESET_N assertions. Upon deassertion of
RESET_N where power is maintained to the processor (otherwise known as a ‘warm
reset’), the following are true:
The PECI client assumes a bus Idle state.
The Thermal Filtering Constant is retained.
PECI SOCKET_ID is retained.
GetTemp() reading resets to 0x0000.
Any transaction in progress is aborted by the client (as measured by the client no
longer participating in the response).
The processor client is otherwise reset to a default configuration.
PECI commands that utilize processor resources being reset will receive a ‘resource
unavailable’ response till the reset sequence is completed.
2.5.3.7 System Service Processor (SSP) Mode Support
Sockets in SSP mode have limited PECI command support. Only the following PECI
commands will be supported while in SSP mode. Other PECI commands are not
guaranteed to complete in this mode.
•Ping
RdPCIConfigLocal
WrPCIConfigLocal (all uncore and IIO CSRs within the processor PCI configuration
space will be accessible)
RdPkgConfig (Index 0 only)
Sockets remain in S SP mode until the “Go” handshak e is receiv ed. This is applicable to
the following SSP modes.
2.5.3.7.1 BMC INIT Mode
The BMC INIT boot mode is used to provide a quick and efficient means to transfer
responsibility for uncore configuration to a service processor like the BMC. In this
mode, the socket performs a minimal amount of internal configuration and then waits
for the BMC or service processor to complete the initialization.
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2.5.3.7.2 Link Init Mode
In cases where the socket is not one QPI hop awa y from the Firmware Agent socket, or
a working link to the Firmware Agent socket cannot be resolved, the sock et is placed in
Link Init mode. The socket performs a minimal amount of internal configuration and
waits for complete configuration by BIOS.
2.5.3.8 Processor Error Handling
Availability of PECI services may be affected by the processor PECI client error status.
Server manageability requirements place a st rong emphasis on continued availability of
PECI services to facilitate logging and debug of the error condition.
Most processor PECI client services are available in the event of a CAT_ERR_N
assertion though they cannot be guaranteed.
The Ping(), GetDIB(), GetT emp(), RdPkgConfig() and W rPkgConfig() commands will
be serviced if the source of the CAT_ERR_N assertion is not in the processor power
control unit hardware, firmware or associated register logic. Additionally, the
RdPCIConfigLocal() and W rPCIConfigLocal() commands may also be serviced in this
case.
It is recommended that the PECI originator read Index 0/Parameter 5 using the
RdPkgConfig() command to debug the CAT_ERR_N assertion.
The PECI client will return the 0x91 completion code if the CAT_ERR_N
assertion is caused by the PCU hardware, firmware or associated logic errors.
In such an event, only the Ping(), GetTemp() and GetDIB() PECI commands
may be serviced. All other processor PECI services will be unava ilable and
further debug of the processor error status will not be possible.
If the PECI client returns a passing completion code, the originator should use
the response data to determine the cause of the CA T_ERR_N assertion. In such
an event, it is also recommended that the PECI originator determine the exact
suite of available PECI client services by issuing each of the PECI commands.
The processor will issue ‘timeout’ responses for those services that ma y no t be
available.
If the PECI client continues to return the 0x81 completion code in response to
multiple retries of the RdPkgConfig() command, no PECI services, with the
exception of the Ping(), GetTemp() and GetDIB(), will be guaranteed.
The RdIAMSR() command may be serviced during a CA T_ERR_N assertion though it
cannot be guaranteed.
2.5.3.9 Originator Retry and Timeout Policy
The PECI originator may need to retry a command if the processor PECI client responds
with a ‘response timeout’ completion code or a bad Read FCS. In each instance, the
processor PECI client may have started the operation but not completed it yet. When
the 'retry' bit is set, the PECI client will ignore a new request if it exactly matches a
previous valid request.
The processor PECI client will not clear the semaphore that was acquired to service the
request until the originator sends the ‘retry’ request in a timely fashion to successfully
retrieve the response data. In the absence of any automatic timeouts, this could tie up
shared resources and result in artificial bandwidth conflicts.
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2.5.3.10 Enumerating PECI Client Capabilities
The PECI host originator should be designed to support all optional but desirable
features from all processors of interest. Each feature has a discovery method and
response code that indicates availability on the destination PECI client.
The first step in the enumeration process would be for the PECI host to confirm the
Revision Number through the use of the GetDIB() command. The revision number
returned by the PECI client processor always maps to the revision number of the PECI
specification that it is designed to. The Minor R evision Number as described in Table 2-2
may be used to identify the subset of PECI commands that the processor in question
supports for any major PECI revision.
The next step in the enumeration process is to utilize the desired command suite in a
real execution context. If the Write FCS response is an Abort FCS or if the data
returned includes an “Unknown/Invalid/Illegal Request” completion code (0x90), then
the command is unsupported.
Enumerating known commands without real, execution context data, or attempting
undefined commands, is dangerous because a write command could result in
unexpected behavior if the data is not properly formatted. Methods for enumerating
write commands using carefully constructed and innocuous data are possible, but are
not guaranteed by the PECI client definition.
This enumeration procedure is not robust enough to detect differences in bit definitions
or data interpretation in the message payload or client response. Instead, it is only
designed to enumerate discrete features.
2.5.4 Multi-Domain Commands
The processor does not support multiple domains, but it is possible that future products
will, and the following tables are included as a reference for domain-specific definitions.
Table 2-19. Domain ID Definition
Domain ID Domain Number
0b01 0
0b10 1
Table 2-20. Multi-Domain Command Code Reference
Command Name Domain 0
Code Domain 1
Code
GetTemp() 0x01 0x02
RdPkgConfig() 0xa1 0xa2
WrPkgConfig() 0xa5 0xa6
RdIAMSR() 0xb1 0xb2
RdPCIConfig() 0x61 0x62
RdPCIConfigLocal() 0xe1 0xe2
WrPCIConfigLocal() 0xe5 0xe6
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2.5.5 Client Responses
2.5.5.1 Abort FCS
The Client responds with an Abort FCS under the following conditions:
The decoded command is not understood or not supported on this processor (this
includes good command codes with bad Read Length or Write Length bytes).
Assured Write FCS (AW FCS) failure. Under most circumstances, an Assured Write
failure will appear as a bad FCS. However, when an originator issues a poorly
formatted command with a miscalculated A W FCS, the client will intentionally abort
the FCS in order to guarantee originator notification.
2.5.5.2 Completion Codes
Some PECI commands respond with a completion code byte. These codes are designed
to communicate the pass/fail status of the command and may also provide more
detailed information regarding the class of pass or fail. For all commands listed in
Section 2.5.2 that support completion codes, the definition in the following table
applies. Throughout this document, a completion code reference may be abbreviated
with ‘CC’.
An originator that is decoding these commands can apply a simple mask as shown in
Table 2-21 to determine a pass or fail. Bit 7 is always set on a command that did not
complete successfully and is cleared on a passing command.
Note: The codes explicitly defined in Table 2-22 may be useful in PECI originator response
algorithms. Reserved or undefined codes may also be generated by a PECI client
device, and the originating agent must be cap able of toler ating any code. The Pass/Fail
mask defined in Table 2-21 applies to all codes, and general response policies may be
based on this information. Refer to Section 2.5.6 for originator response policies and
recommendations.
Table 2-21. Completion Code Pass/Fail Mask
0xxx xxxxb Command passed
1xxx xxxxb Command failed
Table 2-22. Device Specific Completion Code (CC) Definition
Completion
Code Description
0x40 Command Passed
CC: 0x80 Response timeou t. The processor w as not able to gener ate the required response in a timely
fashion. Retry is appropriate.
CC: 0x81 Response timeout. The processor was not able to allocate resources for servicing this
command. Retry is appropriate.
CC: 0x82 The processor hardware resources required to service this command are in a low power
state. Retry may be appropriate after modification of PECI wake mode behavior if
appropriate.
CC: 0x83-8F Reserved
CC: 0x90 Unknown/Invalid/Illegal Request
CC: 0x91 PECI control hardware, firmw are or associated logic error. The processor is unable to pro cess
the request.
CC: 0x92-9F Reserved
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2.5.6 Originator Responses
The simplest policy that an originator may employ in response to receipt of a failing
completion code is to retry the request. However, certain completion codes or FCS
responses are indicative of an error in command encoding and a retry will not result in
a different response from the client. Furthermore, the message originator must have a
response policy in the event of successive failure responses. Refer to Table 2-22 for
originator response guidelines.
Refer to the definition of each command in Section 2.5.2 for a specific definition of
possible command codes or FCS responses for a given command. The following
response policy definition is generic, and more advanced response policies may be
employed at the discretion of the originator developer.
2.5.7 DTS Temperature Data
2.5.7.1 Format
The temperature is formatted in a 16-bit, 2’ s complement value representing a number
of 1/64 degrees Celsius. This format allows temperatures in a range of ±512°C to be
reported to approximately a 0.016°C resolution.
2.5.7.2 Interpretation
The resolution of the processor’s Digital Thermal Sensor (DTS) is approximately 1°C,
which can be confirmed by a RDMSR from the IA32_THERM_STATUS MSR where it is
architecturally defined. The MSR read will return only bits [13:6] of the PECI
temperature sensor data defined in Figure 2-50. PECI temperatures are sent through a
configurable low-pass filter prior to delivery in the GetTemp() response data. The
output of this filter produces temperatures at the full 1/64°C resolution even though
the DTS itself is not this accurate.
Table 2-23. Originator Response Guidelines
Response After 1 Attempt After 3 Attempts
Bad FCS Retry Fail with PECI client device error.
Abort FCS Retry Fail with PECI client device error if command was not illegal or
malformed.
CC: 0x8x Retry The PECI client has failed in its attempts to generate a response.
Notify application layer.
CC: 0x9x Abandon any further
attempts and notify
application layer
n/a
None (all 0’s) Force bus idle (drive
low) for 1 mS and retry Fail with PECI client device error. Client may not be alive or may be
otherwise unresponsive (for example, it could be in RESET).
CC: 0x4x Pass n/a
Good FCS Pass n/a
Figure 2-50. Temperature Sensor Data Format
MSB
Upper nibble MSB
Lower nibble LSB
Upper nibble LSB
Lower nibble
S x x x x x x x x x x x x x x x
Sign Integer Value (0-511) Fractional Value (~0.016)
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Temperature readings from the processor are always negative in a 2’s complement
format, and imply an offset from the processor TProchot (PECI = 0). For example, if the
processor TProchot is 100°C, a PECI thermal reading of -10 implies that the processor is
running at approximately 10°C below TProchot or 90°C. PECI temperature readings are
not reliable at temperatures above TProchot since the processor is outside its operating
range and hence, PECI temperature readings are never positive.
The changes in PECI data counts are approximately linear in relation to changes in
temperature in degrees Celsius. A change of ‘1’ in the PECI count represents roughly a
temperature change of 1 degree Celsius. This linearity is approximate and cannot be
guaranteed over the entire range of PECI temperatures, especially as the offset from
the maximum PECI temperature (zero) increases.
2.5.7.3 Temperature Filtering
The processor digital thermal sensor (DT S) pro vides an impro v ed capabilit y to m onitor
device hot spots, which inherently leads to more varying temperature readings over
short time intervals. Coupled with the fact that typical fan speed controllers may only
read temperatures at 4Hz, it is necessary for the thermal readings to reflect thermal
trends and not instantaneous readings. Therefore, PECI supports a configurable low-
pass temperature filtering function that is expressed by the equation:
TN = (1-α) * TN-1 + α * TSAMPLE
where TN and TN-1 are the current and previous averaged PECI temperature values
respectively, TSAMPLE is the current PECI temperature sample value and the variable
α’ = 1/2X, where ‘X’ is the ‘Thermal Averaging Constant’ that is programmable as
described in Section 2.5.2.6.21.
2.5.7.4 Reserved Values
Several values well out of the operational range are reserved to signal temperature
sensor errors. These are summarized in Table 2-24.
§
Table 2-24. Error Codes and Descriptions
Error Code Description
0x8000 General Sensor Error (GSE)
0x8001 Reserved
0x8002 Sensor is operational, but has detected a temperature below its operational range
(underflow)
0x8003-0x81ff Reserved
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Technologies
3Technologies
3.1 Intel® Virtualization Technology (Intel® VT)
Intel® Virtualization Technology (Intel® VT) makes a single system appear as multiple
independent systems to software. This allows multiple, independent oper ating systems
to run simultaneously on a single system. Intel VT comprises technology components
to support virtualization of platforms based on Intel architecture microprocessors and
chipsets.
Intel® Virtualization Technology (Intel® VT) for Intel® 64 and IA-32
Intel® Architecture (Intel® VT-x) adds hardware support in the processor to
improve the virtualization performance and robustness. Intel VT-x specifications
and functional descriptions are included in the Intel® 64 and IA-32 Architectures
Software Developer’s Manual, Volume 3B and is available at
http://www.intel.com/products/processor/manuals/index.htm
Intel® Virtualization Technology (Intel® VT) for Directed I/O
(Intel® VT-d) adds processor and uncore implementations to support and
improve I/O virtualization performance and robustness. The Intel VT-d spec and
other Intel VT documents can be referenced at
http://www.intel.com/technology/virtualization/index.htm
3.1.1 Intel® VT-x Objectives
Intel VT-x provides hardware acceleration for virtualization of IA platforms. Virtual
Machine Monitor (VMM) can use Intel VT-x features to provide improved reliable
virtualized platform. By using Intel VT- x, a VMM is:
Robust: VMMs no longer need to use para- virtualization or binary tr anslation. This
means that they will be able to run off-the-shelf OS’s and applications without any
special steps.
Enhanced: Intel VT enables VMMs to run 64-bit guest oper ating systems on IA x86
processors.
More reliable: Due to the hardware support, VMMs can now be smaller, less
complex, and more efficient. This improves reliability and availability and reduces
the potential for softwa re conflicts.
More secu re: The use of hardware transitions in the VMM strengthens the isolation
of VMs and further prevents corruption of one VM from affecting others on the
same system.
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3.1.2 Intel® VT-x Features
The processor core supports the following Intel VT-x features:
Extended Page Tables (EPT)
hardware assisted page table virtualization
eliminates VM exits from guest OS to the VMM for shadow page-table
maintenance
Virtual Processor IDs (VPID)
Ability to assign a VM ID to tag processor core hardware structures (for
example, TLBs)
This avoids flushes on VM transitions to give a lower-cost VM transition time
and an overall reduction in virtualization overhead.
Guest Preemption Timer
Mechanism for a VMM to preempt the execution of a guest OS after an amount
of time specified by the VMM. The VMM sets a timer value before entering a
guest
The feature aids VMM developers in flexibility and Quality of Service (QoS)
guarantees
Descriptor-Table Exiting
Descriptor-table exiting allows a VMM to protect a guest OS from internal
(malicious software based) attack by preventing relocation of key system data
structures like IDT (interrupt descriptor table), GDT (global descriptor table),
LDT (local descriptor table), and TSS (task segment selector).
A VMM using this feature can intercept (by a VM exit) attempts to
relocate these data structures and prevent them from being tampered by
malicious software.
Pause Loop Exiting (PLE)
PLE aims to improve virtualization performance and enhance the scaling of
virtual machines with multiple virtual processors
PLE attempts to detect lock-holder preemption in a VM and helps the VMM to
make better scheduling decisions
APIC Virtualization (APICv)
APICv adds hardware support in the proc essor to reduce the overhead of virtual
interrupt processing (APIC accesses and interrupt delivery). This benefits
mostly interrupt intensive workloads.
In a virtualized environm ent the virtual machine manager (VMM) must emulate
nearly all guest OS accesses to the advanced programmable interrupt
controller (APIC) registers which requires “VM exits” (time-consuming
transitions to the VMM for emulation and back). These exits are a major source
of overhead in a virtual environment. Intel's Adv anced Programmable Interrupt
Controller virtualization (APICv) reduces the number of exits by redirecting
most guest OS APIC reads/writes to a virtual- APIC page to allow m ost reads to
occur without VM exits.
3.1.3 Intel® VT-d Objectives
The key Intel VT-d objectives are domain-based isolation and hardware-based
virtualization. A domain can be abstractly defined as an isolated environment in a
platform to which a subset of host physical memory is allocated. Virtualization allows
for the creation of one or more partitions on a single system. This could be multiple
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partitions in the same operating system, or there can be multiple operating system
instances running on the same system – offering benefits such as system
consolidation, legacy migration, activity partitioning or security.
3.1.3.1 Intel VT-d Features Supported
The processor supports the following Intel VT-d features:
Root entry, context entry, and default context
Support for 4-K page sizes only
Support for register-based fault recording only (for single entry only) and support
for MSI interrupts for faults
Support for fault collapsing based on Requester ID
Support for both leaf and non-leaf caching
Support for boot protection of default page table
Support for non-caching of invalid page table entries
Support for hardware based flushing of translated but pending writes and pending
reads upon IOTLB invalidation.
Support for page-selective IOTLB invalidation.
Support for ARI (Alternative Requester ID - a PCI SIG ECR for increasing the
function number count in a PCIe device) to support IOV devices.
Improved invalidation architecture
End point caching support (ATS)
Interrupt remapping
3.1.4 Intel® Virtualization Technology Processor Extensions
The processor supports the following Intel VT Processor Extensions features:
Large Intel VT-d Pages
Adds 2 MB and 1 GB page sizes to Intel VT-d implementations
Matches current support for Extended Page Tables (EPT)
Ability to share CPU's EPT page-table (with super-pages) with Intel VT-d
Benefits:
Less memory foot-print for I/O page-tables when using super-pages
Potential for improved performance - Due to shorter page-walks, allows
hardware optimization for IOTLB
Transition latency reductions expected to improve virtualization performance
without the need for VMM enabling. This reduces the VMM overheads further and
increase virtualization performance.
3.2 Security Technologies
3.2.1 Intel® Trusted Execution Technology
Intel TXT defines platform-level enhancements that provide the building blocks for
creating trusted platforms.
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The Intel TXT platform helps to provide the authenticit y o f the controlling en v ironment
such that those wishing to rely on the platform can make an appropriate tru st decision.
The Intel TXT platform determines the identity of the controlling environment by
accurately measuring and verifying the controlling software.
Another aspect of the trust decision is the ability of the platform to resist attempts to
change the controlling environment. The Intel TXT platform will resist attempts by
software processes to change the controlling en viron ment or by pass the boun ds set by
the controlling environment.
Intel TXT is a set of extensions designed to provide a measured and controlled launch
of system software that will then establish a protected environment for itself and any
additional software that it may execute.
These extensions enhance two areas:
The launching of the Measured Launched Environment (MLE).
The protection of the MLE from potential corruption.
The enhanced platform provides these launc h and control interfaces using Safer Mode
Extensions (SMX).
The SMX interface includes the following functions:
Measured/Verified launch of the MLE.
Mechanisms to ensure the above measurement is protected and stored in a secure
location.
Protection mechanisms that allow the MLE to control attempts to modify itself.
For more information refer to the Intel® Trusted Execution Technology Software
Development Guide. Fo r more information on Intel Trusted Execution Technology, see
http://www.intel.com/technology/security/
3.2.2 Intel® Trusted Execution Technology – Server Extensions
Software binary compatible with Intel® Trusted Execution Technology –
Server Extensions
Provides measurement of runtime firmware, including SMM
Enables run-time firmware in trusted session: BIOS and SSP
Covers support for existing and expected future Server RAS features
Only requires portions of BIOS to be trusted, for example, Option ROMs need not
be trusted
Supports S3 State without teardown: Since BIOS is part of the trust chain
3.2.3 AES Instructions
These instructions enable fast and secure data encryption and decryption, using the
Advan ced Encryption Standard (A ES) which is defined by FIPS Publication number 197.
Since AES is the dominant block cipher, and it is deploy ed in vario us protocols, the new
instructions will be valuable for a wide range of applications.
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The architecture consists of six instructions that offer full hardware support for AES.
Fo ur instructions support the AES encryption and decryption, and the other two
instructions support the AES key expansion. Together, they offer a significant increase
in performance compared to pure software implementations.
The AES instructions have the flexibility to support all three standard AES key length s,
all standard modes of operation, and even some nonstandard or future variants.
Beyond improving performance, the AES instructions provide important security
benefits. Since the instructions run in data-independent time and do not use lookup
tables, they help in eliminating the major timing and cache-based attacks that threaten
table-based software implementations of AES . In addition, these instructions make AES
simple to implement, with reduced code size. This helps reducing the risk of
inadverten t introduction of security flaws, such as difficult -to-detect side channel leaks.
3.2.4 Execute Disable Bit
Intel's Execute Disable Bit functionality can help prevent certain classes of malicious
buffer overflow attacks when combined with a supporting operating system.
Allows the processor to classify areas in memory by where application code can
execute and where it cannot.
When a malicious worm attempts to insert code in the buffer, the processor
disables code execution, preventing damage and worm propagation.
3.3 Intel® Secure Key
This was formerly known as Digital Random Number Generator (DRNG).
The processor supports an on-die digital random number generator (DRNG). This
implementation is based on the ANSI X9.82 2007 draft and the NIST SP800-90
specification.
The X9.82 standard describes two components necessary to generate high quality
random numbers: an Entropy Source and a Deterministic Random Bit Generator
(DRBG). The Entropy Source is also referred to as a Non-Deterministic Random Bit
Generator (NRBG).
3.4 Intel® OS Guard
This was formerly known as Supervisor Mode Execution Protection (SMEP)
Supervisor Mode Execution Protection Bit (SMEP) prevents execution and calls to the
operating system by compromised application in the user mode or code pages. This
also allows additional malware protection over existing Intel XD bit technology.
3.5 Intel® Hyper-Threading Technology
The processor supports Intel® Hyper-Threading Technology (Intel® HT Technology),
which allows an execution core to function as two logical processors. While some
execution resources such as caches, execution units, and buses are shared, each
logical processor has its own architectural state with its own set of general-purpose
registers and control registers. This feature must be enabled via the BIOS and requires
operating system support.
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For more information on Intel Hyper-Threading Technology, see
http://www.intel.com/products/ht/hyperthreading_more.htm.
3.6 Intel® Turbo Boost Technology
Intel Turbo Boost Technology is a feature that allows the processor to opportunistically
and automatically run faster than its rated operating frequency if it is operating below
power, temperature, and current limits. The result is increased performance in multi-
threaded and single threaded workloads. It should be enabled in the BIOS for the
processor to operate with maximum performance.
3.6.1 Intel® Turbo Boost Operating Frequency
The processor’s rated frequency assumes that all execution cores are running an
application at the thermal design power (TDP). Howev e r, under typical operation, not
all cores are active. Therefore most applications are consuming less than the TDP at the
rated frequency. T o tak e advantage of the av ailable TDP headroom, the active cores can
increase their operating frequency.
To determine the highest performance frequency amongst active cores, the processor
takes the following into consideration:
The number of cores operating in the C0 state.
The estimated current consumption.
The estimated power consumption.
The die temperature.
Any of these factors can affect the maximum frequency for a given workload. If the
power, current, or thermal limit is reached, the processor w ill automatically reduce th e
frequency to stay with its TDP limit.
Note: Intel Turbo Boost Technology is only active if the operating sy stem is requesting the P0
state. For more information on P-states and C-states refer to Section 4, “Power
Management”.
3.7 Enhanced Intel SpeedStep® Technology
The processor supports Enhanced Intel SpeedStep® Technology as an advanced means
of enabling very high performance while also meeting the power-con servation needs of
the platform.
Enhanced Intel SpeedStep Technology builds upon that architecture using design
strategies that include the following:
Separation between Voltage and Frequency Changes. By stepping voltage up
and down in small increments separ ately from frequency changes, th e processor is
able to reduce periods of system unavailability (which occur during frequency
change). Thus, the system is able to transition between voltage and frequency
states more often, providing improved power/performance balance.
Clock Partitioning and Recovery. The bus clock continues running during state
transition, even when the core clock and Phase-Locked Loop are stopped, which
allows logic to remain active. The core clock is also able to restart more quickly
under Enhanced Intel SpeedStep Technology.
For additional information on Enhanced Intel SpeedStep Technology see Section 4.2.1.
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3.8 Intel® Intelligent Power Technology
Intel® Intelligent P ower Technology conserves power while delivering advanced power-
management capabilities at the rack, group, and data center level. Providing the
highest system-level performance per watt with “Automated Low Power States” and
“Integrated Power Gates”. Improvements to this processor generation are:
Intel Network Power Management Technology
Intel Power Tuning Technology
For more information on Intel Intelligent Power Technology, see this link
http://www.intel.com/technology/intelligentpower/.
3.9 Intel® Advanced Vector Extensions (Intel® AVX)
Intel® Adv anced Vector Extensions (Intel® AV X) is a 256-bit vector SIMD extension of
Intel Architecture that continues with the 3rd Generation Intel® Core™ Pro cessor
Family. Intel AVX accelerates the trend of parallel computation in general purpose
applications like image, video, and audio processing, engineering applications such as
3D modeling and analysis, scientific simulation, and financial analysts.
Intel AVX is a comprehensive ISA extension of the Intel 64 Architecture. The main
elements of Intel AVX are:
Support for wider vector data (up to 256-bit) for floating-point computation.
Efficient instruction encoding scheme that supports 3 operand syntax and
headroom for future extensions.
Flexibility in programming environment, ranging from branch handling to relaxed
memory alignment requirements.
New data manipulation and arithmetic compute primitives, including broadcast,
permute, fused-multiply-add, and so forth.
Floating point bit depth conversion (Float 16)
A group of 4 instructions that accelerate data conversion between 16-bit
floating point format to 32-bit and vice versa.
This benefits image processing and graphical applications allowing
compression of data so less memory and bandwidth is required.
The key advantages of Intel AVX are:
Performance - Intel AVX can accelerate application performance via data
parallelism and scalable hardware infrastructure across existing and new
application domains:
256-bit vector data sets can be processed up to twice the throughput of 128-bit
data sets.
Application performance can scale up with number of hardware threads and
number of cores.
Application domain can scale out with advanced platform interconnect fabrics,
such as Intel QPI.
Power Efficiency - Intel AVX is extremely power efficient. Incremental power is
insignificant when the instructions are unused or scarcely used. Combined with the
high performance that it can deliver, applications that lend themselves heavily to
using Intel AVX can be much more energy efficient and realize a higher
performance-per-watt.
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Extensibility - Intel AVX has built -in extensibility for the future vector extensions:
OS context management for vector-widths beyond 256 bits is streamlined.
Efficient instruction encoding allows unlimited functional enhancements:
Vector width support beyond 256 bits
256-bit Vector Integer processing
Additional computational and/or data manipulation primitives.
Compatibility - Intel AVX is backward compatible with previous ISA extensions
including Intel SSE4:
Existing Intel® SSE applications/library can:
Run unmodified and benefit from processor enhancements
Recompile existing Intel® SSE intrinsic using compilers that generate
Intel AVX code
Inter-operate with library ported to Intel AVX
Applications compiled with Intel AVX can inter-operate with existing Intel SSE
libraries.
3.10 Intel® Dynamic Power Technology
Intel® Dynamic Power technology (Memory Power Management) is a platform feature
with the ability to transition memory components into various low power states based
on workload requirements. The Intel® Xeon® processor E5-1600 v2/E5-2600 v2
product families platform supports Dynamic CKE (hardware assisted) and Memory Self
Refresh (softw are assisted). For further details refer to the ACPI Specifications for
Memory Power Management document.
§
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4Power Management
This chapter provides information on the following power management topics:
•ACPI States
•System States
Processor Core/Package States
Integrated Memory Controller (IMC) and System Memory States
Direct Media Interface Gen 2 (DMI2)/PCI Express* Link States
Intel QuickPath Interconnect States
4.1 ACPI States Supported
The ACPI states supported by the processor are described in this section.
4.1.1 System States
4.1.2 Processor Package and Core States
Table 4-2 lists the package C-state support as: 1) the shallowest core C-state that
allows entry into the package C-state, 2) the additional factors that will restrict the
state from going any deeper, and 3) the actions taken with respect to the Ring Vcc, PLL
state and LLC.
Table 4-3 lists the processor core C-states support.
Table 4-1. System States
State Description
G0/S0 Full On
G1/S3-Cold Suspend-to-RAM (STR). Context saved to memory.
G1/S4 Suspend-to-Disk (STD). All power lost (except wakeup on PCH).
G2/S5 Soft off. All power lost (except wakeup on PCH). Total reboot.
G3 Mechanical off. All power removed from system.
Table 4-2. Package C-State Support (Sheet 1 of 2)
Package
C-State Core
States Limiting Factors Retention and
PLL-Off
LLC
Fully
Flushed Notes1
PC0 -
Active CC0 N/A No No 2
PC2 -
Snoopable
Idle
CC3-CC6 PCIe/PCH and Remote Socket
Snoops
PCIe/PCH and Remote Socket
Accesses
Interrupt response time
requirement
DMI Sidebands
Configuration Constraints
VccMin
Freq = MinFreq
PLL = ON
No 2
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Notes:
1. Processor Core and Package C7 is not supported.
2. All package states are defined to be “E” states - such that they always exit back into the LFM point upon
execution resume
3. The mapping of actions for PC3, and PC6 are suggestions - microcode will dynamically determine which
actions should be taken based on the desired exit latency parameters.
4. CC3/CC6 will all use a voltage below the VccMin operational point; The exact voltage selected will be a
function of the snoo p and in ter rupt resp onse ti me re quire ments mad e by the device s (PC Ie* and DMI) and
the operating system.
5. The processor supports retention voltage during package C3 and package C6.
4.1.3 Integrated Memory Controller States
PC3 - Light
Retention at least
one Core
in C3
•Core C-state
Snoop Response Time
Interrupt Response Time
Non Snoop Response Time
Vcc = retention
PLL = OFF No 2,3,4, 5
PC6 -
Deeper
Retention
CC6- LLC ways open
Snoop Response Time
Non Snoop Response Time
Interrupt Response Time
Vcc = retention
PLL = OFF No 2,3,4, 5
Table 4-2. Package C-State Support (S he et 2 of 2)
Package
C-State Core
States Limiting Factors Retention and
PLL-Off
LLC
Fully
Flushed Notes1
Table 4-3. Core C-State Support
Core C-State Global Clock PLL L1/L2 Cache Core VCC Context
CC0 Running On Coherent Active Maintained
CC1 Stopped On Coherent Active Maintained
CC1E Stopped On Coherent Request LFM Maintained
CC3 Stopped On Flushed to LLC Request Retention Maintained
CC6 Stopped Off Flushed to LLC Power Gate Flushed to LLC
Table 4-4. System Memory Power States (Sheet 1 of 2)
State Description
Power Up/Normal Operation CKE asserted. Active Mode, highest power consumption.
CKE Power Down Opportunistic, per rank control after idle time:
Active Power Down (APD) (default mode)
CKE de-asserted. Power savings in this mode, relative to active idle
state is about 55% of the memory power. Exiting this mode takes 3
– 5 DCLK cycles.
Pre-charge Power Down Fast Exit (PPDF)
CKE de-asserte d. DLL-On. Als o known as Fast CKE. P ower sa vings in
this mode, relative to active idle state is about 60% of the memory
power. Exiting this mode takes 3 – 5 DCLK cycles.
Pre-charge Power Down Slow Exit (PPDS)
CKE de-asserte d. DLL -Off . Also known as Slow CKE. Po wer savings in
this mode, relative to active idle state is about 87% of the memory
power. Exiting this mode takes 3 – 5 DCLK cycles until the first
command is allowed and 16 cycles until first data is allowed.
Register CKE Power Down:
IBT-ON mode: Bo th CKE’s are de-asserted, the Input Buffer
Term inators (IBTs) are left “on”.
IBT-OFF mode: Both CKE’s are de-asserted, the Input Buffer
Terminators (IBTs) are turned “off”.
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4.1.4 DMI2/PCI Express* Link States
Note: L1 is o nly supported when the DM I2/PCI Express* port is operating a s a PCI Express * port.
4.1.5 Intel® QuickPath Interconnect States
4.1.6 G, S, and C State Combinations
Self-Refresh CKE de-asserted. In this mode, no transactions are executed and the system
memory consumes the minimum possible power. Self refresh modes apply to
all memory channels for the processor.
IO-MDLL Off: Option that sets the IO master DLL off when self refresh
occurs.
PLL Off: Option that sets the PLL off when self refresh occurs.
In addition, the register component found on registered DIMMs (RDIMMs) is
complemented with the following power down states:
Clock Stopped Power Down with IBT-On
Clock Stopped Power Down with IBT-Off
Table 4-5. DMI2/PCI Expr ess* Link States
State Description
L0 Full on – Active transfer state.
L1 Lowest Active State Power Management (ASPM) - Longer exit latency.
Table 4-4. System Memory Power States (Sheet 2 of 2)
State Description
Table 4-6. Intel® QPI States
State Description
L0 Link on. This is the power on active working state,
L0p A lower power state from L0 that reduces the link from full width to half width
L1 A low power state with longer latency and lower power than L0s and is
activated in conjunction with package C-states below C0.
Table 4-7. G, S and C State Combinations
Global (G)
State Sleep
(S) State
Processor
Core
(C) State
Processor
State System
Clocks Description
G0 S0 C0 Full On On Full On
G0 S0 C1/C1E Auto-Halt On Auto-Halt
G0 S0 C3 Deep Sleep On Deep Sleep
G0 S0 C6 Deep Power
Down On Deep Power Down
G1 S3 Power off Off, except RTC Suspend to RAM
G1 S4 Power off Off, except RTC Suspend to Disk
G2 S5 Power off Off, except RT C Soft Off
G3 N/A Power off Power off Hard off
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4.2 Processor Core/Package Power Management
While executin g co de, Enhan ced Intel SpeedStep® Technology optimizes the
processor’s frequency and core voltage based on workload. Each frequency and voltage
operating point is defined by ACPI as a P-state. When the processor is not executing
code, it is idle. A low-power idle state is defined by ACPI as a C -state. In general, lower
power C-states have longer entry and exit latencies.
4.2.1 Enhanced Intel SpeedStep® Technology
The following are the k ey feature s of Enhanced Intel SpeedStep® Technology:
Multiple frequency and voltage points for optimal performance and power
efficiency. These operating points are known as P-states.
Frequency selection is software controlled by writing to processor MSRs. The
voltage is optimized based on temperature, leakage, power delivery loadline and
dynamic capacitance.
If the target frequency is higher than the current frequency, VCC is ramped up
to an optimized voltage. This v oltage is signaled by the SVID Bus to the voltage
regulator. Once the voltage is established, the PLL locks on to the target
frequency.
If the target frequency is lower than the current frequency, the PLL locks to the
target frequency, then transitions to a lower voltage by signaling the target
voltage on the SVID Bus.
All active processor cores share the same frequency and voltage. In a multi-
core processor, the highest frequency P-state requested amongst all active
cores is selected.
Software-requested transitions are accepted at any time. The processor has a
new capability from the previous processor generation, it can preempt the
previous transition and complete the new request without waiting for this
request to complete.
The processor controls voltage ramp rates internally to ensure glitch-free
transitions.
Because there is low transition latency between P-states, a significant number of
transitions per second are possible.
4.2.2 Low-Power Idle States
When the processor is idle, low-power idle states (C-states) are used to save power.
More power savings actions are tak en for numerically higher C -states. Howev er, higher
C-states have longer exit and entry latencies. Resolution of C-states occurs at the
thread, processor core, and processor package level. Thread level C-states are
available if Intel H yper-Threading Technology is enabled. Entry and exit of the C- States
at the thread and core level are shown in Figure 4-2.
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While individual threads can request low power C-states, power saving actions only
take place once the core C-state is resolved. Core C-states are automatically resolved
by the processor. For thread and core C-states, a transition to and from C0 is required
before entering any other C-state.
4.2.3 Requesting Low-Power Idle States
The core C-state will be C1E if all actives cores have also resolved a core C1 state or
higher.
The primary software interfaces for requesti ng low power idle states are through the
MWAIT instruction with sub-state hints and the HLT instruction (for C1 and C1E).
However, software may make C-state requests using the legacy method of I/O reads
Figure 4-1. Idle Power Management Breakdown of the Processor Cores
Figure 4-2. Thread and Core C-State Entry and Exit
Processor Package State
Core N State
Thread 1Thread 0
Core 0 State
Thread 1Thread 0
C1 C1E C6C3
MWAIT(C1), HLT
C0
MWAIT(C6),
P_LVL3 I/O Read
MWAIT(C3),
P_LVL2 I/O Read
MWAIT(C1), HLT
(C1E Enabled)
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from the ACPI-defined processor clock control registers, referred to as P_LVLx. This
method of requesting C-states provides legacy support for operating systems that
initiate C-state transitions via I/O reads.
For legacy operating systems, P_LVLx I/O reads are converted within the processor to
the equivalent MW AIT C-state request. Therefore, P_L VLx reads do not directly result in
I/O reads to the system. The feature, known as I/O MWAIT redirection, must be
enabled in the BIOS.
Note: The P_LVLx I/O Monitor address needs to be set up before using the P_LVLx I/O read
interface. Each P-LVLx is mapped to the supported MWAIT(Cx) instruction as follows.
The BIOS can write to the C-state range field of the PMG_IO_CAPTURE MSR to restrict
the range of I/O addresses that are tr apped and emulate MWAIT like functionality. Any
P_L VLx reads outside of this range does not cause an I/O redirection to MW AIT(Cx) like
request. They fall through like a normal I/O instruction.
Note: When P_LVLx I/O instructions are used, MWAIT substates cannot be defined. The
MWAIT substate is always zero if I/O MWAIT redirection is used. By default, P_L VLx I/O
redirections enable the MWAIT 'break on EFLAGS.IF’ feature which triggers a wakeup
on an interrupt even if interrupts are masked by EFLAGS.IF.
4.2.4 Core C-states
The following are general rules for all core C-states, unless specified otherwise:
A core C-State is determined by the lowest numerical thread state (e.g., Thread 0
requests C1E while Thread 1 requests C3, resulting in a core C1E state). See
Table 4-7.
A core transitions to C0 state when:
an interrupt occurs.
there is an access to the monitored address if the state was entered via an
MWAIT instruction.
For core C1/C1E, and core C3, an interrupt directed toward a single thread wakes
only that thread. However, since both threads are no longer at the same core
C-state, the core resolves to C0.
An interrupt only wakes the target thread for both C3 and C6 states. Any interrupt
coming into the processor package may wake any core.
4.2.4.1 Core C0 State
The normal operating state of a core where code is being executed.
4.2.4.2 Core C1/C1E Stat e
C1/C1E is a low power state entered when all threads within a core execute a HLT or
MWAIT(C1/C1E) instruction.
Table 4-8. P_LVLx to MWAIT Conversion
P_LVLx MWAIT(Cx) Notes
P_LVL2 MWAIT(C3) The P_LV L2 base address is define d in the PMG_IO_CAPTURE MSR,
described in the Intel® Xeon® Processor E5 v2 Product Family
Processor Datasheet, Volume Two: Registers.
P_LVL3 MWAIT(C6) C6. No sub-states allowed.
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A System Management Interrupt (SMI) handler returns execution to either Normal
state or the C1/C1E state. See the Intel® 64 and IA-32 Architecture Software
Developer’s Manual, Volume 3A/3B: System Programmer’s Guide for more information.
While a core is in C1/C1E state, it processes bus snoops and snoops from other
threads. F or more information on C1E, see Section 4.2.5.2, “Package C1/C1E”.
To operate within specification, BIOS must enable the C1E feature for all installed
processors. Please refer to the Intel® Xeon® Processor E5 v2 Product Family Processor
Datasheet, Volume Two: Registers for more details.
4.2.4.3 Core C3 State
Individual threads of a core can enter the C3 state by initiating a P_LVL2 I/O read to
the P_BLK or an MWAIT(C3) instruction. A core in C3 state flushes the contents of its
L1 instruction cache, L1 data cache, and L2 cache to the shared L3 cache, while
maintaining its architectura l state. All core clocks are stopped at this point. Because the
core’ s caches are flushed, the processor does not wake an y core that is in the C3 state
when either a snoop is detected or when another core accesses cacheable memory.
4.2.4.4 Core C6 State
Individual threads of a core can enter the C6 state by initiating a P_L V L3 I/O read or an
MWAIT(C6) instruction. Before entering core C6, the core will save its architectural
state to a dedicated SRAM. Once complete, a core will ha ve its voltage reduced to zero
volts. In addition to flushing core caches core architecture state is saved to the uncore.
Once the core state sav e is completed, core voltage is reduced to zero. Du ring exit, the
core is powered on and its architectural state is restored.
4.2.4.5 Delayed Deep C-States
The Delayed Deep C-states (DDCst) feature on this processor replaces the “C -state
auto-demotion” scheme used in the previous processor generation. Deep C-states are
defined as CC3 through CC6 (refer to Table 4-3 for supported deep c-states).
The Delayed Deep C-states are intended to allow a staged entry into deeper C-states
whereby the processor enters a lighter, short exit-latency C-state (core C1) for a period
of time before committing to a long exit-latency deep C-state (core C3 and core C6).
This is intended to allow the processor to get past the cluster of short-duration idles,
providing each of those with a very fast wa ke-up time, but to still get the power benefit
of the deep C-states on the longer idles.
4.2.5 Package C-States
The processor supports C0, C1/C1E, C2, C3, and C6 power states. The following is a
summary of the general rules for package C-state entry. These apply to all package
C -states unless specified otherwise:
A package C-state request is determined by the lowest numerical core C-state
amongst all cores.
A package C-state is automatically resolved by the processor depending on the
core idle power states and the status of the platform components.
Each core can be at a lower idle power state than the package if the platform
does not grant the processor permission to enter a requested package C-state.
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The platform may allow additional power savings to be realized in the
processor.
For package C -states, the processor is not required to enter C0 before entering any
other C-state.
The processor exits a package C-state when a break event is detected. Depending on
the type of break event, the processor does the following:
If a core break event is received, the target core is activated and the break event
message is forwarded to the target core.
If the break event is not masked, the target core enters the core C0 state and
the processor enters package C0.
If the break event is masked, the processor attempts to re-enter its previous
package state.
If the break event was due to a memory access or snoop request.
But the platform did not request to keep the processor in a higher package
C-state, the package returns to its previous C-state.
And the platform requests a higher power C-state, the memo ry access or snoop
request is serviced and the package remains in the higher power C-state.
The package C-states fall into two categories: independent and coordinated.
C0/C1/C1E are independent, while C2/C3/C6 are coordinated.
Package C-states are based on exit latency requirements which are accumulated from
the PCIe* devices, PCH, and software sources. The level of power savings that can be
achieved is a function of the exit latency re quire me nt from the platfo rm. As a result,
there is no fixed relationship between the coordinated C-state of a package, and the
power savings that w ill be obtained from th e state. Coordinated package C-states offer
a range of power savings which is a function of the guaranteed exit latency requirement
from the platform.
There is also a concept of Execution Allowed (EA), when EA status is 0, the cores in a
socket are in C3 or a deeper state, a socket initiates a request to enter a coordinated
package C-state. The coordination is across all sockets and the PCH.
Table 4-9 shows an example of a dual-core processor package C-state resolution.
Figure 4-3 summarizes package C-state transitions with package C2 as the interim
between PC0 and PC1 prior to PC3 and PC6.
Table 4-9. Coordination of Core Power States at the Package Level
Package C-State Core 1
C0 C1 C3 C6
Core 0
C0 C0 C0 C0 C0
C1 C0 C11
1. The package C-state will be C1E if all actives cores have resolved a core C1 state or higher.
C11C11
C3 C0 C11C3 C3
C6 C0 C11C3 C6
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4.2.5.1 Package C0
The normal operating state for the processor. The processor remains in the normal
state when at least one of its cores is in the C0 or C1 state or when the platform has
not granted permission to the processor to go into a low power state. Individual cores
may be in lower power idle states while the package is in C0.
4.2.5.2 Package C1/C1E
No additional power reduction actions are taken in the package C1 state. However, if
the C1E substate is enabled, the processor automatically transitions to the lowest
supported core clock frequency, followed by a reduction in voltage. Autonomous power
reduction actions which are based on idle timers, can trigger depen ding on the activity
in the system.
The package enters the C1 low power state when:
At least one core is in the C1 state.
The other cores are in a C1 or lower power state.
The package enters the C1E state when:
All cores have directly requested C1E via MWAIT(C1) with a C1E sub-state hint.
All cores are in a power state lower that C1/C1E but the package low power state is
limited to C1/C1E via the PMG_CST_CONFIG_CONTROL MSR.
All cores have requested C1 using HLT or MWAIT(C1) and C1E auto-promotion is
enabled in POWER_CTL.
No notification to the system occurs upon entry to C1/C1E.
Figure 4-3. Package C-State Entry and Exit
C2
C0 C1
C6C3
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4.2.5.3 Package C2 State
Package C2 state is an intermediate state which represents the point at which the
system level coordination is in progress. The package cannot reach this state unless all
cores are in at least C3.
The package will remain in C2 when:
it is awaiting for a coordinated response
the coordinated exit latency requirements are too stringent for the package to take
any power saving actions
If the exit latency requirements are high enough the package will tr ansition to C3 or C6
depending on the state of the cores.
4.2.5.4 Package C3 State
A processor enters the package C3 low power state when:
At least one core is in the C3 state.
The other cores are in a C3 or lower power state, and the processor has been
granted perm ission by the platform.
L3 shared cache retains context and becomes inaccessible in this state.
Additional power savings actions, as allowed by the exit latency requirements,
include putting Intel QPI and PCIe* links in L1, the uncore is not available, further
voltage reduction can be taken.
In package C3, the ring will be off and as a result no accesses to the LLC are possible.
The content of the LLC is preserved.
4.2.5.5 Package C6 State
A processor enters the package C6 low power state when:
At least one core is in the C6 state.
The other cores are in a C6 or lower power state, and the processor has been
granted perm ission by the platform.
L3 shared cache retains context and becomes inaccessible in this state.
Additional power savings actions, as allowed by the exit latency requirements,
include putting Intel QPI and PCIe* links in L1, the uncore is not available, further
voltage reduction can be taken.
In package C6 state, all cores have saved their architectural state and have had their
core voltages reduced to zero volts. The LLC retains context, but no accesses can be
made to the LLC in this state, the cores must break out to the internal state package C2
for snoops to occur.
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4.2.6 Package C-State Power Specifications
The table below lists the processor package C-state power specifications for various
processor SKUs. For details on processor SKU information, see Table 1-1, “HCC, MCC,
and LCC SKU Table Summary..
Notes:
1. SKU’s are subject to change. Please contact your Intel Field Representative to obtain the latest SKU
information.
2. Package C1E power specified at Tcase=60oC
3. Package C3/C6 power specified at Tcase = 50oC
4.2.7 Processor Package Power Specifications
Processor package power, Pmax, is defined by the maximum instantaneous power at the
socket and is reported by the PACKAGE_POWER_SKU MSR/CSR Registers. For details
on processor SKU information, see Table 1-1, “HCC, MCC, and LCC SKU Table
Summary..
Table 4-10. Package C-State Power Specifications
TDP SKUs1C1E (W)2C3 (W)3C6 (W)3
150W WS (8cores) 58 27 14
130W 1U (12-cores) 47 22 15
130W 1U (10-cores) 47 22 14
130W 1U and 2U (8cores) 53 35 14
130W 2U (6-cores) 53 28 14
130W 2U (4-cores) 53 28 13
130W 1S WS (6/4-cores) 53 28 13
115W (12-cores) 47 22 15
115W (10-cores) 47 22 14
95W (10cores) 47 22 14
95W (8cores) (E5-4610 v2) 47 22 21
95W (8cores) 48 22 14
18 (E5-2640 v2)
95W (6/4-cores) 47 22 1 3
80W (6/4-cores) 42 30 1 3
21 (E5-2620 v2)
21 (E5-2603 v2)
70W (10cores) 39 20 13
60W (6cores) 38 20 12
LV95W (10cores) 47 22 14
LV70W (10/8-cores) 39 20 13
LV50W (6cores) 21 13 12
Table 4-11. Processor Package Power Pmax
TDP SKUs Pmax (W)
150W WS (8cores) 230
130W 1U (12/10/8-cores) 200
130W 2U (8-cores) 200
130W 2U (6/4-cores) 175
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4.3 System Memory Power Management
The DDR3 power states can be summarized as the following:
Normal operation (highest power consumption).
CKE Power-Down: Opportunistic, per rank control after idle time. There may be
different levels.
—Active Power-Down.
Precharge Power-Down with Fast Exit.
Precharge power Down with Slow Exit.
Self Refresh: In this mode no transaction is executed. The DDR consumes the
minimum possible power.
4.3.1 CKE Power-Down
The CKE input land is used to enter and exit different power-down modes. The memory
controller has a configurable activity timeout for each rank. Whenever no reads are
present to a giv en rank for the configured interval, the memory controller will transition
the rank to power-down mode.
The memory controller transitions the DRAM to power-down by de-asserting CKE and
driving a NOP command. The memory controller will tri-state all DDR interface lands
except CKE (de-asserted) and ODT while in power-down. The memory controller will
transition the DRAM out of power-down state by synchronously asserting CKE and
driving a NOP command.
When CKE is off the internal DDR clock is disabled and the DDR power is significantly
reduced.
The DDR defines three levels of power-down:
Active power-down: This mode is entered if there are open pages when CKE is de-
asserted. In this mode the open pages are retained. Existing this mode is 3 - 5
DCLK cycles.
Precharge power-down fast exit: This mode is entered if all banks in DDR are
precharged when de-asserting CKE. Existing this mode is 3 - 5 DCLK cycles.
Difference from the active power-down mode is that when waking up all page-
buffers are empty.
130W 1S WS (6-cores) 190
130W 1S WS (4-cores) 175
115W (12/10-cores) 180
95W (10/8-cores) 150
95W (6/4-cores) 130
80W (6/4-cores) 110
70W (10-cores) 120
60W (6-cores) 100
LV95W (10-cores) 150
LV70W (10/8-cores) 120
LV50W (6-cores) 75
Table 4-11. Processor Package Power Pmax
TDP SKUs Pmax (W)
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Precharge power-down slow exit: In this mode the data-in DLL s on DDR are off.
Existing this mode is 3 - 5 DCLK cycles until the first command is allowed, but
about 16 cycles until first data is allowed.
4.3.2 Self Refresh
The Power Control Unit (PCU) may request the memory controller to place the DRAMs
in self refresh state. Self refresh per channel is supported. The BIOS can put the
channel in self -refresh if softw are remaps memory to use a subset of all chann els. Also
processor channels can enter self refresh autonomously without PCU instruction when
the package is in a package C0 state.
4.3.2.1 Self Refresh Entry
Self refresh entrance can be either disabled or triggered by an idle counter. Idle counter
always clears with any access to the memory controller and remains clear as long as
the memory controller is not drained. As soon as the memory controller is drained, the
counter starts counting, and when it reaches the idle-count, the memory controller w ill
place the DRAMs in self refresh state.
P ower may be remo ved from th e memory controller core at this point. But V CCD supply
(1.5 V or 1.35 V) to the DDR IO must be maintained.
4.3.2.2 Self Refresh Exit
Self refresh exit can be either a message from an external unit (PCU in most cases, bu t
also possibly from any message-channel master) or as reaction for an incoming
transaction.
Here are the proper actions on self refresh exit:
CK is enabled, and four CK cycles driven.
When proper skew between Address/Command and CK are established, assert
CKE.
Issue NOPs for tXSRD cycles.
Issue ZQCL to each rank.
The global scheduler will be enabled to issue commands.
4.3.2.3 DLL and PLL Shutdown
Self refresh, according to configuration, may be a trigger for master DLL shut-down
and PLL shut-down. The master DLL shut-down is issued by the memory controller
after the DRAMs have entered self refresh.
The PLL shut-down and wake-up is issued by the PCU. The memory controller gets a
signal from PLL indicating that the memory controller can start working again.
4.3.3 DRAM I/O Power Management
Unused signals are tristated to save power. This includes all signals associated with an
unused memory channel.
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The I/O buffer for an unused signal should be tristated (output driver disabled), the
input receiver (differential sense-amp) should be disabled. The input path must be
gated to prevent spurious results due to n oise on the unused signals (t ypically handled
automatically when input receiver is disabled).
4.4 DMI2/PCI Express* Power Management
Active State Power Management (ASPM) support using L1 state, L0s is not supported.
§
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5Thermal Management
Specifications
5.1 Package Thermal Specifications
The processor requires a thermal solution to maintain temperatures within operating
limits. Any attempt to operate the processor outside these limits may result in
permanent damage to the processor and potentially other components within the
system, see section Section 7.7.1, “Stor age Condition Specifications”. 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 solutions can include active or passive heatsinks
attached to the processor integr ated h eat spreader (IHS). Typical system level thermal
solutions may consist of system fans combined with ducting and venting.
This section provides data necessary for developing a complete thermal solution. For
more information on designing a component lev el thermal solution, refer to the Intel®
Xeon® Processor E5-1600/2600/4600 and E5-160 0 v2/E5-2600 v2 Product Families
Thermal/Mechanical Design Guide.
5.1.1 Thermal Specifications
To allow 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. Thermal solutions
not designed to provide sufficient thermal capability may affect the long-term reliability
of the processor and system. For more details on thermal solution design, please refer
to the Intel® Xeon® Processor E5-1600/2600/4600 and E5-16 00 v2/E5-2600 v2
Product Families Thermal/Mechanical Design Guide.
The processors implement a methodology for managing processor temperatures which
is intended to support acoustic noise reduction through fan speed control and to assu re
processor reliability. Selection of the appropriate fan speed is based on the relative
temperature data reported by the processors Platform Environment Control Interface
(PECI) as described in Section 2.5, “Platform Environment Control Interface (PECI)”.
If the DTS value is less than TCONTROL, then the case temperature is permitted to
exceed the Thermal Profile, but the DTS value must remain at or below TCONTROL.
For TCASE implementations, if DTS is greater than TCONTROL, then the case
temperature must meet the TCASE based Thermal Profiles.
For DTS implementations:
•T
CASE thermal profile can be ignored during processor run time.
If DTS is greater than Tcontrol then follow DT S thermal profile specifications for fan
speed optimization.
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The temperature reported over PECI is alw ays a negative value and represents a delta
below the onset of thermal control circuit (T CC) activation, as indicated by PROCHO T_N
(see Section 7, “Electrical Specifications”). Systems that implement fan speed control
must be designed to use this data. Systems that do not alter the fan speed need to
guarantee the case temperature meets the thermal profile specifications.
The processor thermal profiles for planned SKUs are summarized in Section 5.1.3,
“Processor Operational Thermal Specifications”. Thermal profiles ensure adh erence to
Intel reliability requirements.
Thermal Profile 2U is representative of a volumetrically unconstr ained therm al solution
(that is, industry enabled 2U heatsink). With adherence to the thermal profile, it is
expected that the Thermal Control Circuit (TCC) would be activated for very brief
periods of time when running the most power intensive applications.
Thermal Profile 1U is indicative of a constrained thermal en vironment (that is, 1U form
factor). Because of the reduced cooling capab ility 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 1U will violate the
thermal specifications and may result in permanent damage to the processor. Refer to
the Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product
Families 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 Pow er (TDP) and
the associated TCASE value. It should be noted that the upper point associated with
Thermal Profile 1U.
(x = TDP and y = TCASE_MAX_B @ TDP) represents a thermal solution design point. In
actuality the processor case temperature will not reach this value due to TCC
activation.
For Embedded Servers, Communications and stor age markets Intel has plan SKU’ s that
support Thermal Profiles with nominal and short-term conditions for products intended
for NEBS level 3 thermal ex cursions. For these SK U’ s operation at either the nominal or
short-term thermal profiles should result in virtually no T CC activation. Thermal Profiles
for these SKU’s are found in Section 5.1.4, “Embedded Server Thermal Profiles”.
Intel recommends that complete thermal solution designs target the Thermal Design
Pow er (TDP ). The Adaptive 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. To ensure maximum flexibility for future requirements, systems
should be designed to the Flexible Motherboard (FMB) guidelines, even if a processor
with lower power dissipation is currently planned. The Adaptive Thermal Monitor
feature must be enabled for the processor to remain within its specifications.
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5.1.2 TCASE and DTS Based Thermal Specifications
To simplify compliance to thermal specifications at processor run time, the processor
has added a Digital Thermal Sensor (DTS) based thermal specification. Digital Thermal
Sensor reports a relative die temperature as an offset from TCC activation
temperature. TCASE thermal based specifications are used for heat sink sizing and DTS
based specs are used for acoustic and fan speed optimizations. For the processor
family, firmware (for example, BMC or other platform management devices) will have
DTS based specifications for all SKUs programmed by the customer. Some SKUs at a
sharing the same TDP may share a common TCASE thermal profile but they will have
separate TDTS based thermal profiles.
The processor fan speed control is managed by comparing DTS thermal readings via
PECI against the processor-specific fan speed control reference point, or Tcontrol. Both
Tcontrol and DTS thermal readings are accessible via the processor PECI client. At a
one time readout only, the Fan Speed Control firmware will read the following:
TEMPERATURE_TARGET MS R
Tcontrol via PECI - RdPkgConfig()
TDP via PECI - RdPk gConfig()
Core Count - RdPCIConfigLocal()
DTS PECI commands will also support DTS temperature data readings. Please see
Section 2.5.7, “DTS Temperature Data” for PECI command details.
Also, refer to the Intel® Xeon® Processor E5-1600 /2600/4600 and E5-1600 v2/E5-
2600 v2 Product Families Thermal/Mechanical Design Guide for details on DTS based
thermal solution design considerations.
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5.1.3 Processor Operational Thermal Specifications
Each SKU has a unique thermal profile that ensures reliable operation for the intended
form factor over the processor’s service life. These specifications are based on final
silicon characterization.
The 130W 1S WS SKUs, which are part of the Intel® Xeon® processor E5-1600 v2
product family, are intended for single processor workstations and utilize workstation
specific use conditions for reliability assumptions.
The 150W WS SKU, which is part of the Intel® Xeon® processor E5-2600 v2 product
family, is intended for dual processor workstations and utilizes workstation specific use
conditions for reliability assumptions.
5.1.3.1 Minimum operating case temperature
Minimum case operating temperature is specified at 5°C for every processor SKU.
5.1.3.2 Maximum operating case temperature thermal profiles
Temperature 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
electrical loadline specifications in Chapter 7.
Thermal Design Power (TDP) should be used for processor thermal solution design
targets. TDP is not the maximum power that the processor can dissipate. TDP is
measured at specified maximum TCASE.
Power specifications are defined at all VID values found in Table 7-3. The processor
may be delivered under multiple VIDs for each frequency. Implementation of a
specified thermal profile should result in virtua lly no TCC activation. Furthermore,
utilization of thermal solutions that do not meet the specified thermal profile will result
in increased probability of TCC activation and may incur measur able perform ance loss.
Refer to the Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2
Product Families Thermal/Mechanical Design Guide for system and environmental
implementation details.
Each case temperature thermal profile is unique to each TDP and core count
combination. These TCASE profiles are fully defined by the simple linear equation:
TCASE = PSICA * P + TLA
Where:
PSICA is the Case-to-Ambient thermal resistance of the processor thermal solution.
TLA is the Local Ambient temperature.
P is the processor power dissipation.
Table 5-1 provides the PSICA and TLA parameters that define TCASE thermal profile for
each TDP/Core count combination. Figure 5-1 illustrates the general form of the
resulting linear graph resulting from TCASE = PSICA * P + TLA.
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Table 5-1. TCase Temperature Thermal Specifications
TDP (W) Model Number Core
Count TLA (°C) PSICA (°C/W) Minimum
TCASE (°C) Maximum
TCASE (°C)
150W WS E5-2687W v2 8 39.5 0.217 5.0 72.0
130W 1U E5-2697 v2 12 56.5 0.227 5.0 86.0
E5-2690 v2 10 56.5 0.242 5.0 88.0
EP4S 130W
1U E5-4627 v2 8 56.5 0.242 5.0 88.0
130W 2U
E5-2667 v2 8 49.8 0.186 5.0 74.0
E5-2643 v2 6
E5-2637 v2 4 50.1 0.199 5.0 76.0
130W 1S
E5-1660 v2
E5-1650 v2 642.6 0.211 5.0 70.0
E5-1620 v2 4
115W 1U
E5-2695 v2 12 55.0 0.226 5.0 81.0
E5-2680 v2
E5-2670 v2 10 54.6 0.239 5.0 82.0
EP4S 115W
1U E5-4657L v2 12 55.0 0.226 5.0 81.0
95W 1U
E5-2660 v2 10
52.0 0.242 5.0 75.0
E5-2650L v2
E5-2640 v2 8
EP4S
95W1U
E5-4610 v2 8 51.8 0.223 5.0 73.0
E5-4650 v2
E5-4640 v2
E5-4620 v2 10/8 52.0 0.242 5.0 75.0
E5-4607 v2
E5-4603 6/4 52.6 0.257 5.0 77.0
80W 1U
E5-2630 v2
E5-2620 v2 6
50.5 0.257 5.0 71.0
E5-2609 v2
E5-2603 v2 4
70W 1U E5-2650L v2 10 48.5 0.236 5.0 65.0
60W 1U E5-2630L v2 6 47.9 0.252 5.0 63.0
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5.1.3.3 Digital Thermal Sensor (DTS) thermal profiles
Each DTS thermal profile is unique to each TDP and core count combination. These
TDTS profiles are fully defined by the simple linear equation:
TDTS = PSIPA * P + TLA
Where:
PSIPA is the Processor-to- Ambient thermal resistance of the processor thermal solution.
TLA is the Local Ambient temperature.
P is the processor power dissipation.
Table 5-2 provides the PSIPA and TLA parameters that define TDTS thermal profile for
each TDP/Core count combination. Figure 5-2 illustrates the general form of the
resulting linear graph resulting from TDTS = PSIPA * P + TLA.
5.1.3.4 Digital Thermal Sensor (STS) Specifications
Figure 5-1. TCase Temperature Thermal Profile
Table 5-2. Digital Thermal Sensor (DTS) Specification Summary (Sheet 1 of 2)
TDP (W) Model Number Core
Count TLA (°C) PSIPA(°C/W) Maximum
TDTS (°C)
150W WS E5-2687W v2 8 39.5 0.353 92.4
130W 1U
E5-2697 v2 12 56.5 0.320 98.1
E5-2690 v2 10 56.5 0.353 102.4
E5-4627 v2 8 56.5 0.372 104.9
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130W 2U
E5-2667 v2 8 49.8 0.317 91.0
E5-2643 v2 6 49.8 0.359 96.5
E5-2637 v2 4 50.1 0.422 105.0
130W 1S E5-1660 v2
E5-1650 v2 6 42.6 0.400 94.6
E5-1620 v2 4 42.6 0.480 105.0
115W 1U
E5-2695 v2
E5-4657L v2 12 55.0 0.317 91.4
E5-2680 v2
E5-2670 v2 10 54.6 0.345 94.2
95W 1U
E5-2660 v2
E5-4650 v2
E5-4640 v2 10 52.0 0.348 85.1
E5-4610 v2 8 51.8 0.345 84.6
E5-2650L v2
E5-2640 v2
E5-4620 v2 8 52.0 0.381 88.2
E5-4607 v2 6 52.6 0.422 92.7
E5-4603 4 52.6 0.495 99.6
80W 1U
E5-2630 v2
E5-2620 v2 6 50.5 0.416 83.7
E5-2609 v2
E5-2603 v2 4 50.5 0.474 88.4
70W 1U E5-2650L v2 10 48.5 0.330 71.6
60W 1U E5-2630L v2 6 47.9 0.396 71.6
Table 5-2. Digital Thermal Sensor (DTS) Specification Summary (Sheet 2 of 2)
TDP (W) Model Number Core
Count TLA (°C) PSIPA(°C/W) Maximum
TDTS (°C)
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5.1.4 Embedded Server Thermal Profiles
Network Equipment Building System (NEBS) is the most common set of environm ental
design guidelines applied to telecommunications equipment in the United States.
Embedded server SKU’s target operation at higher case temperatures and/or NEBS
thermal profiles for embedded communications server and storage form factors. The
term “Embedded” is used to refer to thos e segments collectively. Thermal profiles in
this section pertain only to those specific Embedded SKU’s.
The Nominal Thermal Profile must be used for standard operating conditions or for
products that do not require NEBS Level 3 compliance.
The Short-Term Thermal Profile may only be used for short-term excursions to higher
ambient operating temperatures, not to exceed 96 hours per instance, 360 hours per
year, and a maximum of 15 instances per year, as intended by NEBS Level 3.
Operation at the Short- Term Thermal Profile for durations exceeding 360 hours per year
violate the processor thermal specifications and may result in permanent damage to
the processor.
Implementation of the defined thermal profile should result in virtually no TCC
activation. Refer to the Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600
v2/E5-2600 v2 Product Families Thermal/Mechanical Design Guide for system and
environmental implementation details.
5.1.4.1 Embedded Operating Case Tem perature Thermal Profiles
Thermal Design Power (TDP) should be used for processor thermal solution design
targets. TDP is not the maximum power that the processor can dissipate. TDP is
measured at specified maximum TCASE.
Figure 5-2. Digital Thermal Sensor DTS Thermal Profile
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Power specifications are defined at all VID values found in Table 7-3. The processor
may be delivered under multiple VIDs for each frequency. Implementation of a
specified thermal profile should result in virtually no T CC activation. Failure to comply
with the specified thermal profile will result in increased probability of TCC activation
and may incur measur able perform ance loss. Refer to the Intel® Xeon® Processor
E5-1600 v2/E5-2600 v2/E5-4600 v2 Product Families Ther mal/Mechanical Design
Guide for system and environmental implementation details.
Each case temperature thermal profile is unique to each TDP and core count
combination. These TCASE profiles are fully defined by the simple linear equation:
TCASE = PSICA * P + TLA
Where:
PSICA is the Case-to-Ambient thermal resistance of the processor thermal solution.
TLA is the Local Ambient nominal temperature.
P is the processor power dissipation.
The Short-Term thermal profile provides for a 15°C rise of temperature above the
nominal profile due to scenarios such as fan failure or A/C failure. Short-term
excursions to higher ambient operating temperatures are strictly limited 96 hours per
instance, 360 hours per year, and a maximum of 15 instances per year as intended by
NEBS Level 3.
TLA-ST designates the Local Ambient temperature for Short-Term operation.
Table 5-3 provides the PSICA and TLA parameters that define TCASE thermal profile for
each TDP/Core count combination. Figure 5-3 illustrates the general form of the
resulting linear graph resulting from TCASE = PSICA * P + TLA.
Table 5-3. Embedded TCase Temperature Thermal Specifications
TDP
(W) Model
Number Core
Count TLA
(°C) TLA-ST
(°C) PSICA
(°C/W) Minimum
TCASE (°C)
Nominal
Maximum
TCASE (°C)
Short-
Term
Maximum
TCASE (°C)
LV95W E5-2658 v2 10 51 66 0.235 5.0 73.3 88.3
LV70W
E5-2648L v2 10 49 64 0.403 5.0 77.2 92.2
E5-2628L v2 8
LV50W E5-2618L v2 6 52 67 0.541 5.0 79.1 94.1
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110 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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5.1.4.2 Embedded Digital Thermal Sensor (DTS) thermal profiles
The thermal solution is expected to be de veloped in accordance with the Tcase thermal
profile. Operational compliance monitoring of thermal specifications and fan speed
modulation may be done via the D TS based thermal profile.
Each DTS thermal profile is unique to each TDP and core count combination. These
TDTS profiles are fully defined by the simple linear equation:
TDTS = PSIPA * P + TLA
Where:
PSIPA is the Processor-to- Ambient thermal resistance of the processor thermal solution.
TLA is the Local Ambient temperature for the Nominal thermal profile.
TLA-ST designates the Local Ambient temperature for Short-Term operation.
P is the processor power dissipation.
Table 5-4 provides the PSIPA and TLA parameters that define TDTS thermal profile for
each TDP/Core count combination. Figure 5-4 illustrates the general form of the
resulting linear graph resulting from TDTS = PSIPA * P + TLA.
The slope of a DTS profile assumes full fan speed which is not required over much of
the power range. Tcontrol is the temperature above which fans must be at maximum
speed to meet the thermal profile requirements. Tcontrol is different for each SKU and
may be slightly above or below TDTS-Max of the DTS nominal thermal profile for a
particular SKU. At many power levels on most embedded SKU’s, temperatures of the
nominal profile are less than Tcontrol as indicated by the blue shaded region in the D TS
Figure 5-3. Embedded Case Temperature Thermal Profile
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profile graph of Figure 5-4. As a further simplification, operation at DTS temperatures
up to Tcontrol is permitted at all power levels. Compliance to the D TS profile is required
for any temperatures exceeding Tcontrol.
5.1.5 Thermal Metrology
The minimum and maximum case temper atures (TCASE) are measured at the geometric
top center of the processor integr ated heat spreader (IHS). Figure 5-5 illustrates the
location where TCASE temperature measurements should be made. For detailed
guidelines on temperature measurement methodology, refer to the Intel® Xeon®
Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product Families
Thermal/Mechanical Design Guide.
Table 5-4. Embedded DTS Thermal Specifications
TDP (W) Model
Number Core
Count TLA (°C) TLA-ST (°C) PSIPA
(°C/W)
Nominal
Maximum
TDTS (°C)
Short-Term
Maximum
TDTS (°C)
LV95W E5-2658 v2 10 51 66 0.336 82.9 97.9
LV70W E5-2648L v2 10 49 64 0.489 83.2 98.2
LV70W E5-2628L v2 8 49 64 0.503 84.2 99.2
LV50W E5-2618L v2 6 52 67 0.644 84.2 99.2
Figure 5-4. Embedded DTS Thermal Profile
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112 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Notes:
1. Figure is not to scale and is for reference only.
2. This is an example for package size 52.5 x 45 mm.
3. B1: Max = 52.57 mm, Min = 52.43 mm.
4. B2: Max = 45.07 mm, Min = 44.93 mm.
5. C1: Max = 43.1 mm, Min = 42.9 mm.
6. C2: Max = 42.6 mm, Min = 42.4 mm.
7. C3: Max = 2.35 mm, Min = 2.15 mm.
5.2 Processor Core Thermal Features
5.2.1 Processor Temperature
A new feature in the processor is a software readable field in the
TEMPERATURE_TARGET MSR register that contains the minimum temperature at which
the TCC will be activated and PROCHOT_N will be asserted. The TCC activation
temperature is calibrated on a part-by-part basis and normal factory variation may
result in the actual TCC activ ation temperature being higher than the valu e listed in the
register. TCC activation temperatures may change based on processor stepping,
frequency or manufacturing efficiencies.
5.2.2 Adaptive Thermal Monitor
The Adaptive Thermal Monitor feature provides an enhanced method for controlling the
processor temperature when the processor silicon reaches its maximum operating
temperature. Adaptive Thermal Monitor uses Thermal Control Circuit (TCC) activation
to reduce processor power via a combination of methods. The first method
(Frequency/SVID control) involves the processor adjusting its oper ating frequency (via
the core ratio multiplier) and input voltage (via the SVID signals). This combination of
Figure 5-5. Case Temperature ( TCASE) Measurement Location
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reduced frequency and voltage results in a reduction to the processor power
consumption. The second method (clock modulation) reduces power consumption by
modulating (starting and stopping) the internal processor core clocks. The processor
intelligently selects the appropriate T CC method to use on a dynamic basis. BIOS is not
required to select a specific method.
The Adaptive Therma l Monitor feature must be enable d for the processor to be
operating within specifications. Snooping and interrupt processing are performed in
the normal manner while the TC C is active.
With a properly designed and characterized thermal solution, it is anticipated that the
TCC would be activated for very short periods of time when running the most power
intensive applications. The pro cessor performance impact due to these brief periods of
TCC activation is expected to be so minor that it would be immeasurable. An under -
designed thermal solution that is not able to prevent ex cessive activ ation of the T CC in
the anticipated ambient environment may cause a noticeable performance loss, and in
some cases may result in a TC that exceeds the specified maximum temperature which
may affect the long-term reliability of the processor. In addition, a thermal solution that
is significantly under-designed may not be capable of cooling the processor even when
the TC C is active continuously. Refer to the Intel® Xeon® Processor E5-
1600/2600/4600 and E5-1600 v2/E5-260 0 v2 Product Families Thermal/Mechanical
Design Guide for information on designing a compliant thermal 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.
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5.2.2.1 Frequency/SVID Control
The processor uses Frequency/SVID control whereby TCC activation causes the
processor to adjust its operating frequency (via the core r atio multiplier) and VCC input
voltage (via the SVID signals). This combination of reduced frequency and voltage
results in a reduction to the processor power consumption.
This method includes multiple operating points, each consisting of a specific operating
frequency and voltage. The first operating point represents the normal operating
condition for the processor. The remaining points consist of both lower operating
frequencies and voltages. When the TCC is activ ated, the processor automatically
transitions to the new lower oper ating frequency. This transition occurs very rapidly (on
the order of microseconds).
Once the new operating frequency is engaged, the processor will transition to the new
core operating voltage by issuing a new SVID code to the VCC voltage regulator. The
voltage regulator must support dynamic SVID steps to support this method. During the
voltage change, it will be n ecessary to transition through multiple SVID codes to reach
the target operating voltage. Each step will be one SVID table entry (see Table 7-3,
“VR12.0 Reference Code Voltage Identification (VID) Table.). The processor continues
to execute instructions during the voltage transition. Operation at the lower voltages
reduces the power consumption of the processor.
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 operating
temperature, and the hysteresis timer has expired, the operating frequency and
voltage transition back to the normal system operating point via the intermediate
SVID/frequency points. Transition of the SVID code will occur first, to insure proper
operation once the processor reaches its normal operating frequency. Refer to
Figure 5-6 for an illustration of this ordering.
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5.2.2.2 Clock Modulation
Clock modulation is performed by alternately turning the clocks off and on at a duty
cycle specific to the processor (factory configured to 37.5% on and 62.5% off for TM1).
The period of the duty cycle is configured to 32 microseconds when the TCC is active.
Cycle times are independent of processor frequency. 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 operating temperature, and the
hysteresis timer has expired, the T CC goes inactive and clock modulation ceases. Clock
modulation is automatically engaged as part of the TCC activation when the
Frequency/SVID targets are at their minimum settings. It may also be initiated by
software at a configurable duty cycle.
5.2.3 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 Adaptive Thermal Monitor feature. On-Demand
mode is intended as a means to reduce system level power consumption. Systems
must not rely on software usage of this mechanism to limit the processor temper ature.
If bit 4 of the IA32_CLOCK_MODULATION MSR is set to a ‘1’, the processor will
immediately reduce its power consumption via modulation (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 3:0 of
the same IA32_CLOCK_MODULATION MSR. In On-Demand mode, the duty cycle can
be programmed from 6.25% on / 93.75% off to 93.75% on / 6.25% off in 6.25%
Figure 5-6. Frequency and Voltage Ordering
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increments. On-Demand mode may be used in conjunction with the Adaptive Thermal
Monitor; however, 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.
5.2.4 PROCHOT_N Signal
An external signal, PROCHOT_N (processor hot), is asserted when the processor core
temperature has reached its maximum operating temperature. If Adaptive Thermal
Monitor is enabled (note it must be enabled for the processor to be operating within
specification), the TCC will be active when PROCHOT_N is asserted. The processor can
be configured to generate an interrupt upon the assertion or de-assertion of
PROCHOT_N. Refer to the Intel® Xeon® Processor E5 v2 Product Family Processor
Datasheet, Volume Two: Registers for specific register and programming details.
The PROCHOT_N signal is bi-directional in that it can either signal when the processor
(any core) has reached its maximum operating temperature or be driven from an
external source to activate the TC C. The ability to activate the TCC via PROCH OT_N can
provide a means for thermal protection of system components.
As an output, PROCHOT_N will go active when the processor temper ature monitoring
sensor detects that one or more cores has reached its maximum safe operating
temperature. This indicates that the processor Thermal Control Circuit (TCC) has been
activated, if enabled. As an input, assertion of PROCHOT_N by the system will activate
the TCC, if enabled, for all cores. TCC activation due to PROCHOT_N assertion by the
system will result in the processor immediately transitioning to the minimum frequency
and corresponding voltage (using Freq/SVID control). Clock modulation is not activated
in this case. The TCC will remain active until the system de-asserts PROCHOT_N.
PROCHOT_N can allow voltage regulator (VR) thermal designs to target maximum
sustained current instead of maximum current. Systems should still provide proper
cooling for the VR, and rely on PRO CHOT_N as a backup in case of system cooling
failure. The system thermal design should a llow the pow er deliv ery circuitry to oper ate
within its temperature specification ev en while the processor is operating at its Thermal
Design Power.
With a properly designed and characterized thermal solution, it is anticipated that
PROCHOT_N will be asserted for very short periods of time when running the most
power intensive applications. An under-designed thermal solution that is not able to
prevent excessive assertion of PROCHOT_N in the anticipated ambient environment
may cause a noticeable performance loss.
5.2.5 THERMTRIP_N Signal
Regardless of whether Adaptive Thermal Monitor is enabled, in the event of a
catastrophic cooling failure, the processor will autom atically shut down when the silicon
has reached an elevated temperature (refer to the THERMTRIP_N definition in
Chapter 6, “Signal Descriptions”). At this point, the THERMTRIP_N signal will go active
and stay active. THERMTRIP_N activ ation is independent of processor activity and does
not generate any Intel® QuickPath Interconnect transactions. If THERMTRIP_N is
asserted, all processor supplies (VCC, VTTA, VTTD, VSA, VCCPLL, VCCD) must be
removed within the timeframe provided. The temperature at which THERMTRIP_N
asserts is not user configurable and is not software visible.
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5.2.6 Integrated Memory Controller (IMC) Thermal Features
5.2.6.1 DRAM Throttling Options
The Integrated Memory Controller (IMC) has two, independent mechanism s that cause
system memory throttling:
Open Loop Thermal Throttling (OLTT) and Hybrid OLTT (OLTT_Hybrid)
Closed Loop Thermal Throttling (CLTT) and Hybrid CLTT (CLTT_Hybrid)
5.2.6.1.1 Open Loop Thermal Throttling (OLTT)
Pure energy based estimation for systems with no BMC or Intel® Management Engine
(Intel® ME). No memory temperature information is provided by the platform or
DIMMs. The CPU is informed o f the ambient temperature estimate by the BIOS or by a
device via the PECI interface. DIMM temperature estimates and bandwidth control are
monitored and managed by the PCU on a per rank basis.
5.2.6.1.2 Hybrid Open Loop Thermal Throttling (OLTT_Hybrid)
Temperature information is provided by the platform (for example, BMC or Intel ME)
through PECI and the PCU interpolates gaps with energy based estimations.
5.2.6.1.3 Closed Loop Thermal Throttling (CLTT)
The processor periodically samples temperatures from the DIMM TSoD devices over a
programmable interval. The PCU determines the hottest DIMM rank from TSoD data
and informs the integrated memory controlle r for use in bandwidth throttlin g decisions.
5.2.6.2 Hybrid Closed Loop Thermal Throttling (CLTT_Hybrid)
The processor periodically samples temperature from the DIMM TSoD devices over a
programmable interval and interpolates gaps or the BMC/Intel ME samples a
motherboard thermal sensor in the memory subsection and provides this data to the
PCU via the PECI interface. This data is combined with an energy based estimations
calculated by the PCU. When needed, system memory is then throttled using CAS
bandwidth control. The processor supports dynamic reprogramming of the memory
thermal limits based on system thermal state by the BMC or Intel ME.
5.2.6.3 MEM_HOT_C01_N and MEM_HOT_C23_N Signal
The processor includes a pair of new bi-directional memory thermal status signals
useful for manageability schemes. Each sign al presents and receives thermal status for
a pair of memory channels (channels 0 & 1 and channels 2 & 3).
Input Function: The processor can periodically sense the MEM_HOT_{C01/C23}_N
signals to detect if the platform is requesting a memory throttling event.
Manageability hardware could drive this signal due to a memory voltage regulator
thermal or electrical issue or because of a detected system thermal event (for
example, fan is going to fail) other system devices are exceeding their thermal
target. The input sense period of these signals are programmable, 100 us is the
default value. The input sense assertion time recognized by the processor is
programmable, 1 us is the default v alue. If the sense assertion time is programmed
to zero, then the processor ignores all external assertions of
MEM_HOT_{C01/C23}_N signals (in effect they become outputs).
Output Function: The output behavior of the MEM_HOT_{C01/C23}_N signals
supports Level mode. In this mode, MEM_HO T_{C01/C23}_N event temperatures
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118 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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are programmable via TEMP_OEM_HI, TEMP_LOW, TEMP_MID, and TEMP_HI
threshold settings in the iMC. In Level mode, when asserted, the signal indicates to
the platform that a BIOS-configured thermal threshold has been reached by one or
more DIMMs in the covered channel pair.
5.2.6.4 Integrated Dual SMBus Master Co ntrollers for System Memory
Interface
The processor includes two integr ated SMBus master controllers running at 100 KHz for
dedicated PCU access to the serial presence detect (SPD) devices and thermal sensors
(TSoD) on the DIMMs. Each controller is responsible for a pair of memory channels and
supports up to eight SMBus slave devices. Note that clock-low stretching is not
supported by the processor. To avoid design complexity and minimize package C -state
transitions, the SMB us interface between the processor and DIMMs must be connected.
The SMBus controllers for the system memory interface support the following SMBus
protocols/commands:
Random byte Read
•Byte Write
•I
2C* Write to Pointer Register
•I
2C Present Pointer Re gister Word Read
•I
2C Pointer Write Register Read.
Refer to the System Management Bus (SMBus) Specification, Revision 2.0 for standing
timing protocols and specific command structure details.
§
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Signal Descriptions
6Signal Descriptions
This chapter describes the processor signals. They are arranged in functional groups
according to their associated interface or category.
6.1 System Memory Interface Signals
Table 6-1. Memory Channel DDR0, DDR1, DDR2, DDR3
Signal Name Description
DDR{0/1/2/3}_BA[2:0] Bank Address. Defines the bank which is the destination for the
current Activate, Read, Write, or Precharge command.
DDR{0/1/2/3}_CAS_N Column Address Strobe.
DDR{0/1/2/3}_CKE[5:0] Clock Enable.
DDR{0/1/2/3}_CLK_DN[3:0]
DDR{0/1/2/3}_CLK_DP[3:0] Differential clocks to the DIMM. All command and control signals
are valid on the rising edge of clock.
DDR{0/1/2/3}_CS_N[9:0] Chip Select. Each signal selects one rank as the target of the
command and address.
DDR{0/1/2/3}_DQ[63:00] Data Bus. DDR3 Data bits.
DDR{0/1/2/3}_DQS_DP[17:00]
DDR{0/1/2/3}_DQS_DN[17:00]
Data strobes. Differential pair, Data/ECC Strobe. Differential
strobes latch data/ECC for each DRAM. Different numbers of
strobes are used depending on whether the connected DRAMs are
x4,x8. Driven with edges in center of data, receive edges are
aligned with data edges .
DDR{0/1/2/3}_ECC[7:0] Check bits. An error correction code is driven along with data on
these lines for DIMMs that support that capability
DDR{0/1/2/3}_MA[15:00] Memory Address. Selects the Row address for Reads and writes,
and the column address for activates. Also used to set values for
DRAM configuration registers.
DDR{0/1/2/3}_MA_PAR Odd parity across Address and Command.
DDR{0/1/2/3}_ODT[5:0] On Die Termination. Enables DR AM on die te rmination duri ng Dat a
Write or Data Read transactions.
DDR{0/1/2/3}_PAR_ERR_N Parity Error detected by Registered DIMM (one for each channel).
DDR{0/1/2/3}_RAS_N Row Address Strobe.
DDR{0/1/2/3}_WE_N Write Enable.
Signal Descriptions
120 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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6.2 PCI Express* Based Interface Signals
Note: PCI Express* Ports 1, 2 and 3 Signals are receive and transmit differential pairs.
Table 6-2. Memory Channel Miscellaneous
Signal Name Description
DDR_RESET_C01_N
DDR_RESET_C23_N
System memory reset: Reset signal from processor to DRAM
devices on the DIMMs. DDR_RESET_C01_N is used for memory
channels 0 and 1 while DDR_RESET_C23_N is used for memory
channels 2 and 3.
DDR_SCL_C01
DDR_SCL_C23
SMBus clock for the dedicated interface to the serial presence
detect (SPD) and thermal sensors (TSoD) on the DIMMs.
DDR_SCL_C01 is used for memory channels 0 and 1 while
DDR_SCL_C23 is used for memory channels 2 and 3.
DDR_SDA_C01
DDR_SDA_C23
SMBus data for the dedicated interface to the serial presence
detect (SPD) and thermal sensors (TSoD) on the DIMMs.
DDR_SDA_C1 is used for memory channels 0 and 1 while
DDR_SDA_C23 is used for memory channels 2 and 3.
DDR_VREFDQRX_C01
DDR_VREFDQRX_C23
Voltage reference for system memory reads.
DDR_VREFDQRX_C01 is used for memory channels 0 and 1 while
DDR_VREFDQRX_C23 is used for memory channels 2 and 3.
DDR_VREFDQTX_C01
DDR_VREFDQTX_C23
Voltage reference for system memory writes.
DDR_VREFDQTX_C01 is used for memory channels 0 and 1 while
DDR_VREFDQTX_C23 is used for memory channels 2 and 3. These
signals are not connected and the re is no functionali ty provided on
these two signals. They are unused by the processor.
DDR{01/23}_RCOMP[2:0] System memory impedance compensation. Impedance
compensation must be terminated on the system board using a
precision resistor.
DRAM_PWR_OK_C01
DRAM_PWR_OK_C23 Power good input signal used to indicate that the VCCD power
supply is stable for memory channels 0 & 1 and channels 2 & 3.
Table 6-3. PCI Express* Port 1 Signals
Signal Name Description
PE1A_RX_DN[3:0]
PE1A_RX_DP[3:0] PCIe Receive Data Input
PE1B_RX_DN[7:4]
PE1B_RX_DP[7:4] PCIe Receive Data Input
PE1A_TX_DN[3:0]
PE1A_TX_DP[3:0] PCIe Transmit Data Output
PE1B_TX_DN[7:4]
PE1B_TX_DP[7:4] PCIe Transmit Data Output
Table 6-4. PCI Expre ss* Port 2 Signals (Sh eet 1 of 2)
Signal Name Description
PE2A_RX_DN[3:0]
PE2A_RX_DP[3:0] PCIe Receive Data Input
PE2B_RX_DN[7:4]
PE2B_RX_DP[7:4] PCIe Receive Data Input
PE2C_RX_DN[11:8]
PE2C_RX_DP[11:8] PCIe Receive Data Input
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Signal Descriptions
PE2D_RX_DN[15:12]
PE2D_RX_DP[15:12] PCIe Receive Data Input
PE2A_TX_DN[3:0]
PE2A_TX_DP[3:0] PCIe Transmit Data Output
PE2B_TX_DN[7:4]
PE2B_TX_DP[7:4] PCIe Transmit Data Output
PE2C_TX_DN[11:8]
PE2C_TX_DP[11:8] PCIe Transmit Data Output
PE2D_TX_DN[15:12]
PE2D_TX_DP[15:12] PCIe Transmit Data Output
Table 6-5. PCI Express* Port 3 Signals
Signal Name Description
PE3A_RX_DN[3:0]
PE3A_RX_DP[3:0] PCIe Receive Data Input
PE3B_RX_DN[7:4]
PE3B_RX_DP[7:4] PCIe Receive Data Input
PE3C_RX_DN[11:8]
PE3C_RX_DP[11:8] PCIe Receive Data Input
PE3D_RX_DN[15:12]
PE3D_RX_DP[15:12] PCIe Receive Data Input
PE3A_TX_DN[3:0]
PE3A_TX_DP[3:0] PCIe Transmit Data Output
PE3B_TX_DN[7:4]
PE3B_TX_DP[7:4] PCIe Transmit Data Output
PE3C_TX_DN[11:8]
PE3C_TX_DP[11:8] PCIe Transmit Data Output
PE3D_TX_DN[15:12]
PE3D_TX_DP[15:12] PCIe Transmit Data Output
Table 6-6. PCI Express* Miscellaneous Signals (Sheet 1 of 2)
Signal Name Description
PE_RBIAS
This input is use d to control PCI Express* bias currents. A 50 ohm
1% tolerance re sist or mus t b e connected from this land to VSS by
the platform. PE_RBIAS is required to be connected as if the link is
being used even wh en PCIe* is not used.
PE_RBIAS_SENSE
Provides dedicated bias resistor sensing to minimize the voltage
drop caused by packaging and platform effects. PE_RBIAS_SENSE
is required to be connected as if the link is being used even when
PCIe* is not used.
PE_VREF_CAP PCI Express* voltage reference used to measure the actual output
voltage and comparing it to the assumed voltage. A 0.01uF
capacitor must be connected from this land to VSS.
PEHPSCL
PCI Express* Hot-Plug SMBus Clock: Provides PCI Expres s* hot-
plug support via a de dicated SMBus interface. R equires an external
general purpose input/output (GPIO) expansion device on the
platform.
Table 6-4. PCI Express* Port 2 Signals (Shee t 2 of 2)
Signal Name Description
Signal Descriptions
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6.3 DMI2/PCI Express* Port 0 Signals
6.4 Intel® QuickPath Interconnect Signals
PEHPSDA
PCI Express* Hot-Plug SMBus Data: Provides PCI Express* hot-
plug support via a dedicated SMBus interface. Requires an external
general purpose input/output (GPIO) expansion device on the
platform.
Table 6-7. DMI2 and PCI Express Port 0 Signals
Signal Name Description
DMI_RX_DN[3:0]
DMI_RX_DP[3:0] DMI2 Receive Data Input
DMI_TX_DP[3:0]
DMI_TX_DN[3:0] DMI2 Transmit Data Output
Table 6-8. Intel QPI Port 0 and 1 Signals
Signal Name Description
QPI{0/1}_CLKRX_DN/DP Reference Clock Differential Input. These pins provide the PLL
reference clock differential input. The Intel QPI forward clock
frequency is half the Intel QPI data rate.
QPI{0/1}_CLKTX_DN/DP Reference Clock Differential Output. These pins provide the PLL
reference clock differential input. The Intel QPI forward clock
frequency is half the Intel QPI data rate.
QPI{0/1}_DRX_DN/DP[19:00] Intel QPI Receive data input.
QPI{0/1}_DTX_DN/DP[19:00] Intel QPI Transmit data output.
Table 6-9. Intel QPI Miscellaneous Signals
Signal Name Description
QPI_RBIAS This input is used to control Intel QPI bias currents. QPI_RBIAS is
required to be connected as if the link is being used even when
Intel QPI is not used.
QPI_RBIAS_SENSE
Provides dedicated bias resistor sensing to minimize the voltage
drop caused by packaging and platform effects.
QPI_RBIAS_SENSE is required to be connected as if the link is
being used even when Intel QPI is not used.
QPI_VREF_CAP Intel QPI voltage reference used to measure the actual output
voltage and comparing it to the assumed voltage.
Table 6-6. PCI Express* Miscellaneous Signals (Sheet 2 of 2)
Signal Name Description
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Signal Descriptions
6.5 PECI Signal
6.6 System Reference Clock Signals
6.7 JTAG and TAP Signals
Table 6-10. PECI Signals
Signal Name Description
PECI PECI (Platform Environment Control Interface) is the serial
sideband interface to the proces sor and is used primarily for
thermal, power and error management. Details regarding the PECI
electrical specifications, protocols and functions can be found in
the Platform Environmen t C ont rol Interface Specificatio n.
Table 6-11. System Reference Clock (BCLK{0/1}) Signals
Signal Name Description
BCLK{0/1}_D[N/P] Reference Clock Differential input. These pins provide the PLL
reference clock differential input into the processor. 100 MHz
typical BCLK0 is the QPI reference cloc k (system clock) and BCLK1
is the PCI Express* reference clock.
Table 6-12. JTAG and TAP Signals
Signal Name Description
BPM_N[7:0]
Breakpoint and Performance Monitor Signals : I/O s i gnals from th e
processor that indicate the status of breakpoints and
programmable counters used for monitoring processor
performance. These are 100 MHz signals.
EAR_N External Alignment of Reset, used to bring the processo r up int o a
deterministic state. This signal is pulled up on the die, refer to
Table 7-6 for details.
PRDY_N Probe Mode Ready is a processor output used by debug tools to
determine processor debug readiness.
PREQ_N Probe Mode Request is used by debug tools to request debug
operation of the processor.
TCK TCK (Test Clock) provides the clock input for the processor Test
Bus (also known as the Test Access Port).
TDI TDI (Test Data In) transfers serial test data into the processor. TDI
provides the serial input needed for JTAG specification support.
TDO TDO (Test Data Out) transfers seri al test data out of the processor.
TDO provides the seria l output needed for JTAG specification
support.
TMS TMS (Test Mode Select) is a JT AG specification support signal used
by debug tools.
TRST_N TRST_N (Test Reset) resets the Test Access Port (TAP) logic.
TRST_N must be driven low during power on Reset.
Signal Descriptions
124 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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6.8 Serial VID Interface (SVID) Signals
6.9 Processor Asynchronous Sideband and
Miscellaneous Signals
Table 6-13. SVID Signals
SVIDALERT_N Serial VID alert.
SVIDCLK Serial VID clock.
SVIDDATA Serial VID data out.
Table 6-14. Processor Asynchronous Sideband Signals (Sheet 1 of 3)
Signal Name Description
BIST_ENABLE BIST Enable Strap. Input which allows the platform to enable or
disable built-in self test (BIST) on the processor. This signal is
pulled up on the die, refer to Table 7-6 for details.
BMCINIT
BMC Initialization Strap. Indicates whet her Ser vice Process or Boot
Mode should be used. Used in combination with FRMAGENT and
SOCKET_ID inputs.
0: Service Proces sor Boot Mode Disabled. Example boot
modes: Local PCH (this processor hosts a legacy PCH with
firmware behind it), Intel QPI Link Boot (for processors one
hop away from the FW agent), or Intel QPI Link Init (for
processors more than one hop away fro m the firmware agent).
1: Service Processor Boot Mode Enabled. In this mode of
operation, the processor performs the absolute minimum
internal configur ation and then w aits for the Service Processor
to complete its initialization. The sock et boots after receiving a
“GO” handshake signal via a firmware scratchpad register.
This signal is pulled down on the die, refer to Table 7-6 for details.
CAT_ERR_N
Indicates that the system has experienced a fatal or catastrophic
error and cannot continue to operate. The processor will assert
CAT_ERR_N for nonrecoverable machine check errors and other
internal unrecoverable err ors. It is expected that every processo r
in the system will wire-OR CAT_ERR_N for all processors. Since
this is an I/O land, external agents are allowed to assert this land
which will cause the processor to take a machine check exception.
This signal is sampled after PWRGOOD assertion.
On the processor, CAT_ERR_N is used for signaling the following
types of errors:
Legacy MCERR’s, CAT_ERR_N is asserted for 16 BCLKs.
Legacy IERR’s, CAT_ERR_N remains asserted until warm or
cold reset.
CPU_ONLY_RESET Reserved, not used.
ERROR_N[2:0]
Error status signals for integrated I/O (IIO) unit:
0 = Hardware correctable error (no operating system or
firmware action necessary)
1 = Non-fatal error (operating system or firmware action
required to contain and recover)
2 = Fatal error (system reset likely required to recover)
FRMAGENT
Bootable Firmware Agent Strap. This input configuration strap
used in combination with SOCKET_ID to determine whether the
socket is a legacy socket, bootable firmware agent is pres ent, and
DMI links are used in PCIe* mode (instead of DMI2 mode).
The firmware flash ROM is located behind the local PCH attached to
the processor via the DMI2 interface.This signal is pulled down on
the die, refer to Table 7-6 for details.
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Signal Descriptions
MEM_HOT_C01_N
MEM_HOT_C23_N
Memory throttle control. MEM_HO T_C01_N and MEM_HOT_C23_N
signals have two modes of operation – input and output mode.
Input mode is externally asserted and is used to detect external
events such as VR_HOT# from the memory voltage regulator and
causes the processor to throttle th e appropriate memory channels.
Output mode is asserted by the process or known as level mode. In
level mode, the output indicates that a particular branch of
memory subsystem is hot.
MEM_HOT_C01_N is used for memory channels 0 & 1 while
MEM_HOT_C23_N is used for memory channels 2 & 3.
PMSYNC Power Management Sync. A sideband signal to communicate
power manageme nt status from the Platform Controller Hub (PCH)
to the processor.
PROCHOT_N
PROCHOT_N will go active when the processor temperature
monitoring sensor detects that the processor has reached its
maximum safe operating temperature. This indicates that the
processor Thermal Control Circuit has been activated, if enabled.
This signal can also be driven to the processor to activate the
Thermal Control Circuit. This signal is sampled after PWRGOOD
assertion.
If PROCHOT_N is asserted at the deassertion of RESET_N, the
processor will tristate its outputs.
PWRGOOD
Power Good is a processor input. The processor re quires this signal
to be a clean in dication that BCLK, VTTA/VTTD, VSA, VCCPLL, and
VCCD_01 and VCCD_23 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 state.
PWRGOOD can be driven inactive at any time, but clocks and
power must again be stable before a subsequent rising edge of
PWRGOOD. PWRGOOD transitions from inactive to active when all
supplies exce pt VCC are stable. VCC has a VBOOT of zero volts and
is not included in PWRGOOD indication in this phase. However, for
the active to inactive transition, if any CPU power supply (VCC,
VTTA/VTTD, VSA, VCCD, or VCCPLL) is about to fail or is out of
regulation, the PWRGOOD is to be negated.
The 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.
Note: VCC has a Vboot setting of 0.0V and is not included in the
PWRGOOD indication and VS A has a Vboot setting of 0.9V. Refer to
the compatible VR12.0 PWM controller.
RESET_N
Asserting the RESET_N signal resets the processor to a known
state and inv alidates its internal cach es without writing back an y of
their contents. Note some PLL, Intel QuickPath Interconnect and
error states are not effected by reset and only PWRGOOD forces
them to a known state.
RSVD RESERVED . All si gnals that are RSV D must be left unconnecte d on
the board. Refer to Section 7.1.10, “Reserved or Unused Signals”
for details.
SAFE_MODE_BOOT
Safe mode boot Strap. SAFE_MODE_BOOT allows the processor to
wake up safely by disabling all clock gating, this allows BIOS to
load registers or patches if required. This signal is sampled after
PWRGOOD assertion. The signal is pulled down on the die, refer to
Table 7-6 for details.
Table 6-14. Processor Asynchronous Sideband Sign als (Sheet 2 of 3)
Signal Name Description
Signal Descriptions
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SOCKET_ID[1:0]
Socket ID Strap. Socket identification configuration straps for
establishing the PECI address, Intel® QPI Node ID, and other
settings. This signal is used in combination with FRMAGENT to
determine whether the socket is a legacy socket, bootable
firmware agent is present, and DMI links are used in PCIe* mode
(instead of DMI2 mode). Each processor socket consumes one
Node ID, and there are 128 Home Agent tracker entries. This
signal is pulled down on the die, refer to Table 7-6 for details.
TEST[4:0] Test[4:0] must be individually connected to an appropriate power
source or ground through a resistor for proper processor
operation.
THERMTRIP_N
Assertion of THERMTRIP_N (Thermal Trip) indicates one of two
possible critical over-temperature conditions: One, the processor
junction temperatu re has reached a level beyond which pe rmanent
silicon damage may occur and Two, the system memory interface
has exceeded a critical temperature limit set by BIOS.
Measurement of the processor junction temperature is
accomplished through multiple internal thermal sensors that are
monitored by the Digital Thermal Sensor (DTS). Simultaneously,
the Power Control Unit (PCU) monitors external memory
temperatures via the dedicated SMBus interface to the DIMMs. If
any of the DIMMs exceed the BIOS defined limits, the PCU will
signal THERMTRIP_N to prevent damage to the DIMMs. Once
activated, the processor will stop all execution and shut down all
PLLs. To further protect the processor, its core voltage (VCC),
VTTA, VTTD, VSA, VCCPLL, VCCD sup plies must be removed
following the assertion of THERMTRIP_N. Once activated,
THERMTRIP_N remains latched until RESET_N is asserted. While
the assertion of the RESET_N signal may de-as sert THERMTRIP_N,
if the processor's junction temperature remains at or above the
trip level, THERMTRIP_N will again be asserted after RESET_N is
de-asserted. This signal can also be asserted if the system
memory interface has exceeded a critical temperature limit set by
BIOS. This signal is sampled after PWRGOOD assertion.
TXT_AGENT
Intel® Trusted Execution Technology (Intel® TXT) Agent Strap.
0 = Default. The socket is not the Intel® TXT Agent.
1 = The socket is the Intel® TXT Agent.
In non-Scalable DP platforms, the legacy socket (identified by
SOCKET_ID[1:0] = 00b) with Intel® TXT Agent sho uld always set
the TXT _AGENT to 1b.
On Scalable DP platforms the Intel TXT AGENT is at the Node
Controller.
This signal is pulled down on the die, refer to Table 7-6 for details.
TXT_PLTEN
Intel® Trusted Execution Technology (Intel® TXT) Platform Enable
Strap.
0 = The platform is not Intel® TXT enabled. All sockets should be
set to zero. Scalable DP (sDP) platforms should choose this setting
if the Node Controller does not support Intel TXT.
1 = Default. The platform is Intel® TXT en abled. All sock ets should
be set to one. In a non-Scalable DP platform this is the default.
When this is set, Intel TXT functionality requires user to explicitly
enable Intel TXT via BIOS setup.
This signal is pulled up on the die, refer to Table 7-6 for details.
Table 6-14. Processor Asynchronous Sideband Signals (Sheet 3 of 3)
Signal Name Description
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Signal Descriptions
6.10 Processor Power and Ground Supplies
Table 6-15. Miscellaneous Signals
Signal Name Description
IVT_ID_N This output can be used by the platform to determine if the installed
processor is an Intel® Xeon® processor E5-1600 v2 product family, Intel®
Xeon® processor E5-2600 v2 product family or Intel® Xeon® processor E5-
1600/E5-2600 product families.
This is pulled to gr oun d o n the p roc ess or package.This signal is also us ed by
the VCCPLL and VTT rails to switch their output voltage to support future
processors.
SKTOCC_N SKTOCC_N (Sock et occupied) is used to indicate that a processo r is present.
This is pulled to ground on the processor package; there is no connection to
the processor silicon for this signal.
Table 6-16. Power and Ground Signals (Sheet 1 of 2)
Signal Name Description
VCC
Variable power supply for the processo r cor es, lowest le v el cache s
(LLC), ring interface, and home agent. It is provided by a
VRM/EVRD 12.0 compliant regulator for each CPU socket. The
output voltage of this supply is selected by the processor, using the
serial voltage ID (SVID) bus.
Note: VCC has a Vboot setting of 0. 0V and is not included in the
PWRGOOD indication. Refer to the compatible VR12.0
PWM controller.
VCC_SENSE
VSS_VCC_SENSE
VCC_SENSE and VSS_VCC_SENSE provide an isolated, low
impedance connection to the processor core power and ground.
These signals must be connected to the v oltage regulator feedback
circuit, which insures the output voltage (that is, processor
voltage) remains within specification.
VSA_SENSE
VSS_VSA_SENSE
VSA_SENSE and VSS_VSA_SENSE provide an isolated, low
impedance connection to the processor system agent (VSA) power
plane. These signals must be connected to the voltage regulator
feedback circuit, which insures the output voltage (that is,
processor voltage) r emains within specification.
VTTD_SENSE
VSS_VTTD_SENSE
VTTD_SENSE and VSS_VTTD_SENSE provide an isolated, low
impedance connection to the processor I/O power plane. These
signals must be connected to the voltage regulator feedback
circuit, which insures the output voltage (that is, processor
voltage) remains within specification. .
VCCD_01 and VCCD_23
V ariable power supply for the processor system memory interface .
Provided by two VRM/EVRD 12.0 compliant regulators per CPU
socket. VCCD_01 and VCCD_23 are used for memory channels 0,
1, 2, & 3 respectively. The valid voltage of this supply (1.50V or
1.35V) is configured by BIOS after determining the operating
voltages of the installed memory. VCCD_01 and VCCD_23 will also
be referred to as VCCD.
Note: The processor must be provided VCCD_01 and VCCD_23
for proper operation, even in configurations where no
memory is populated. A VRM/EVRD 12.0 controller is
recommended, but not required.
VCCPLL Fixed power supply (1.7V) for the processor phased lock loop
(PLL).
Signal Descriptions
128 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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§
VSA
V ariable power supply for th e processor s ystem agent uni ts. These
include logic (non-I/O) for the integrated I/O controller, the
integrated memory controller (iMC), the Intel® QPI agent, and the
Power Control Unit (PCU). The output voltage of this supply is
selected by the pro cessor, using the serial voltage ID (SVID) bus.
Note: VSA has a Vboot setting of 0.9V. Refer to the compatible
VR12.0 PWM controller.
VSS Processor ground node.
VTTA
VTTD
Combined fixe d analog and digital powe r supply for I/O sect ions of
the processor Intel QPI interface, Direct Media Interface Gen 2
(DMI2) interface, and PCI Express* interface. These signals will
also be referred to as VTT.
Table 6-16. Power and Ground Signals (Sheet 2 of 2)
Signal Name Description
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Electrical Specifications
7Electrical Specifications
7.1 Processor Signaling
The processor includes 2011 lands, which use various signaling technologies. Signals
are grouped by electrical characteristics and buffer type into various signal groups.
These include DDR3 (Reference Clock, Command, Control, and Data), PCI Express*,
DMI2, Intel® QuickPath Interconnect, Platform Environmental Control Interface (PECI),
System Reference Clock, SMBus, JTAG and Test Access Port (TAP), SVID Interface,
Processor Asynchronous Sideband, Miscellaneous, and Power/Other signals. Refer to
Table 7-5 for details.
Intel strongly recommends performing analog simulations o f all interfaces. Please refer
to Section 1.7, “Related Documents” for signal integrity model availability.
7.1.1 System Memory Interface Signal Groups
The system memory interface utilizes DDR3 technology, which consists of numerous
signal groups. These include: Reference Clocks, Command Signals, Control Signals,
and Data Signals. Each group consists of numerous signals, which may utilize various
signaling technologies. Please refer to Table 7-5 for further details. Throughout this
chapter the system memory interface maybe referred to as DDR3.
7.1.2 PCI Express Signals
The PCI Express Signal Group consists of PCI Express* ports 1, 2, and 3, and PCI
Express miscellaneous signals. Please refer to Table 7-5 for further details.
7.1.3 DMI2/PCI Express Signals
The Direct Media Interface Gen 2 (DMI2) sends and receives packets and/or commands
to the PCH. The DMI2 is an extension of the standard PCI Express Specification. The
DMI2/PCI Express Signals consist of DMI2 receive and transmit input/output signals
and a control signal to select DMI2 or PCIe* 2.0 operation for port 0. Please refer to
Table 7-5 for further details.
7.1.4 Intel® QuickPath Interconnect
The processor provides two Intel QPI port for high speed serial transfer between other
processors. Each port consists of two uni-directional links (for transmit and receive). A
differential signaling scheme is utilized, which consists of opposite-polarity (DP, DN)
signal pairs.
Electrical Specifications
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7.1.5 Platform Environmental Control Interface (PECI)
PECI is an Intel proprietary interface that provides a communication channel between
Intel processors and chipset components to external system management logic and
thermal monitoring devices. The processor contains a Digital Thermal Sensor (DTS)
that reports a relative die temperature as an offset from Thermal Control Circuit (TCC)
activation temperature. Temperature sensors located throughout the die are
implemented as analog-to-digital con verters calibrated at the factory. PECI provides an
interface for external devices to read processor temperature, perform processor
manageability functions, and manage processor interface tuning and diagnostics.
The PECI interface operates at a nominal voltage set by VTTD. The set of DC electrical
specifications shown in Table 7-16 is used with devices normally operating from a VTTD
interface supply.
7.1.5.1 Input Device Hysteresis
The PECI client and host input buffers must use a Schmitt-triggered input design for
improved noise immunity. Please refer to Figure 7-1 and Table 7-16.
7.1.6 System Reference Clocks (BCLK{0/1}_DP,
BCLK{0/1}_DN)
The processor core, processor uncore, Intel® QuickPath Interconnect link, PCI
Express* and DDR3 memory interface frequencies) are gener ated from BCLK{0/1}_DP
and BCLK{0/1}_DN signals. There is no direct link between core frequency and Intel
QuickPath Interconnect link frequency (e.g., no core frequency to Intel QuickPath
Interconnect multiplier). The processor maximum core frequency, Intel QuickPath
Interconnect link frequency and DDR memory frequency are set during manufacturing.
It is possible to override the processor core frequency setting using software.
This permits operation at lower core frequencies than the factory set maximum
core frequency.
The processor core frequency is configured during reset by using values stored within
the device during manufacturing. The stored value sets the lowest core multiplier at
which the particular processor can operate. If higher speeds are desired, the
appropriate ratio can be configured via the IA32_PERF_CTL MSR (MSR 199h); Bits
[15:0].
Figure 7-1. Input Dev i ce Hysteresis
Minimum VP
Maximum VP
Minimum VN
Maximum VN
PE CI High Range
PE CI Low R ange
Valid Input
Signal Range
Minimum
Hysteresis
VTTD
PE CI Ground
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Electrical Specifications
Clock multiplying within the processor is provided by the internal phase locked loop
(PLL), which requires a constant frequency BCLK{0/1}_DP, BCLK{0/1}_DN input, with
exceptions for spread spectrum clocking. DC specifications for the BCLK{0/1}_DP,
BCLK{0/1}_DN inputs are provided in Table 7-17. These specifications must be met
while also meeting the associated signal quality specifications outlined in Section 7.9.
7.1.6.1 PLL Power Supply
An on-die PLL filter solution is implemented on the processor. Refer to Table 7-11 for
DC specifications.
7.1.7 JTAG and Test Access Port (TAP) Signals
Due to the voltage levels supported by other components in the JTAG and Test Access
Port (TAP) logic, Intel recommends the processor be first in the TAP chain, followed by
any other components within the system. Please refer to the Intel® Xeon® Processor
E5-1600 v2/E5-2600 v2 Product Families – Boundary Scan Description Language
(BSDL) File for more details. A translation buffer should be used to connect to the rest
of the chain unless one of the other components is capable of accepting an input of the
appropriate voltage. Two copies of each signal may be required with each driving a
different voltage level.
7.1.8 Processor Sideband Signals
The processor include asynchronous sideband signals that provide asynchronous input,
output or I/O signals between the processor and the platform or Platform Controller
Hub. Details can be found in Table 7-5.
All Processor Asynchronous Sideband input signals are required to be
asserted/deasserted for a defined number of BCLKs in order for the processor to
recognize the proper signal state. Refer to Section 7.9 for applicable signal
integrity specifications.
7.1.9 Power, Ground and Sense Signals
Processors also include various other signals including po wer/ground and sense points.
Details can be found in Table 7-5.
7.1.9.1 Power and Ground Lands
All VCC, VCCPLL, VSA, VCCD, VTTA, and VTTD lands must be connected to their respective
processor power planes, while all VSS lands must be connected to the system ground
plane. For clean on-chip power distribution, processors include lands for all required
voltage supplies. These are listed in Table 7-1.
Table 7-1. Power and Ground Lands
Power and
Ground Lands Number of
Lands Comments
VCC 208
Each VCC land must be supplied with the voltage determined by the
SVID Bus signals. Table 7-3 Defines the voltage level associated with
each core SVID pattern.Table 7-11, Figure 7-2, and Figure 7-4
represent VCC static and tr ansient limits. VCC h as a VBO OT setting of
0.0V.
VCCPLL 3Each VCCPLL land is connected to a 1.70 V supply, power the Phase
Lock Loop (PLL) clock generation circuitry. An on-die PLL filter
solution is implemented within the processor.
Electrical Specifications
132 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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7.1.9.2 Decoupling Guidelines
Due to its large number of transistors and high internal clock speeds, the processor is
capable of generating large current swings between low and full power states. This ma y
cause voltages on power planes to sag below their minimum values if bulk decoupling is
not adequate. Large electrolytic bulk capacitors (CBULK), help maintain the output
voltage during current transients, for example coming out of an idle condition. Care
must be taken in the baseboard design to ensure that the voltages provided to the
processor remain within the specifications listed in Table 7-11. Failure to do so can
result in timing violations or reduced lifetime of the processor.
7.1.9.3 Voltage Identification (VID)
The V oltage Identification (VID) specification for the V CC, VSA, VCCD voltage are defined
by the compatible VR12.0 PWM controller. The reference voltage or the VID setting is
set via the SVID communication bus between the processor and the voltage regulator
controller chip. The VID settings are the nominal voltages to be delivered to the
processor's VCC, VSA, VCCD lands. Table 7-3 specifies the reference voltage level
corresponding to the VID value transmitted over serial VID. The VID codes will change
due to temper ature and/or current load changes in order to minimize the power and to
maximize the performance of the part. The specifications are set so that a voltage
regulator can operate with all supported frequencies.
Individual processor VID values may be calibrated during manufacturing such that tw o
processor units with the same core frequency may have different default VID settings.
The processor uses voltage identification signals to support automatic selection of VCC,
VSA, and VCCD power supply voltages. If the processor socket is empty (SKTOCC_N
high), or a “not supported” response is received from the SVID bus, then the voltage
regulation circuit cannot supply the voltage that is requested, the voltage regulator
must disable itself or not power on. Vout MAX register (30h) is programmed by the
processor to set the maximum supported VID code and if th e progr ammed VID code is
higher than the VID supported by the VR, then VR will respond with a “not supported”
acknowledgement. See the compatible VR12.0 PWM controller for further details.
7.1.9.3.1 SVID Commands
The processor provides the ability to operate while transitioning to a new VID setting
and its associated processor voltage rails (VCC, VSA, and VCCD). This is represented by a
DC shift. It should be noted that a low-to-high or high-to-low v oltage state change may
VCCD_01
VCCD_23 51
Each VCCD land is connected to a switch able 1.50 V and 1.35 V supply,
provide power to the processo r DDR3 interface. These supplies also
power the DDR3 memory subsystem. VCCD is also controlled by the
SVID Bus. VCCD is the generic term for VCCD_01, VCCD_23.
VTTA 14 VTT A lands must be supplied by a fixed 1.0V supply.
VTTD 19 VTTD lands must be supplied by a fixed 1.0V supply.
VSA 25 Each VSA land must be supplied with the voltage determined by the
SVID Bus signals, typically set at 0.940V. VSA has a VBOOT setting of
0.9V.
VSS 548 Ground
Table 7-1. Power and Ground Lands
Power and
Ground Lands Number of
Lands Comments
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Electrical Specifications
result in as many VID transitions as necessary to reach the target voltage. Transitions
above the maximum specified VID are not supported. The processor supports the
following VR commands:
SetVID_fast (10 mV/µs for VSA/VCCD),
•SetVID_slow (2.5 mV/µs for VSA/VCCD), and
Slew Rate Decay (downward voltage only and it’s a function of the output
capacitance’s time constant) commands. Table 7-3 and Table 7-20 includes S VI D
step sizes and DC shift ranges. Minimum and maximum voltages must be
maintained as shown in Table 7-11.
The VRM or EVRD utilized must be capable of regulating its output to the value
defined by the new VID. The compatible VR12.0 PWM controller contains further
details.
Power source characteristics must be guaranteed to be stable whenever the supply to
the voltage regulator is stable.
7.1.9.3.2 SetVID Fast Command
The SetVID-fast command contains the target VID in the payload byte. The range of
voltage is defined in the VID table. The VR should ramp to the new VID setting with a
fast slew rate as defined in the slew rate data register. Typically 10 to 20 mV/µs
depending on platform, voltage rail, and the amount of decoupling capacitance.
The SetVID-fast command is preemptive, the VR interrupts its current processes and
moves to the new VID. The SetVID-fast command operates on 1 VR address at a time.
This command is used in the processor for package C6 fast exit and entry.
7.1.9.3.3 SetVID Slow Command
The SetVID-slow command contains the target VID in the payload byte. The range of
voltage is defined in the VID table. The VR should ramp to the new VID setting with a
“slow” slew rate as defined in the slow slew rate data register. The SetVID_Slow is 1/4
slower than the SetVID_fast slew rate.
The SetVID-slow command is preemptive, the VR interrupts its current processes and
moves to the new VID. This is the instruction used for normal P-state voltage
change. This command is used in the processor for the Intel Enhanced SpeedStep
Technology transitions.
7.1.9.3.4 SetVID Decay Command
The SetVID-Decay command is the slowest of the DVID transitions. It is only used for
VID down transitions. The VR does not control the slew rate, the output voltage
declines with the output load current only.
The SetVID- Decay command is preemptive, that is, the VR interrupts its current
processes and moves to the new VID.
7.1.9.3.5 SVID Power State Functions: SetPS
The processor has three power state functions and these will be set seamlessly via the
SVID bus using the SetPS command. Based on the power state command, the SetPS
commands sends information to VR controller to configure the VR to improve e fficiency ,
especially at light loads. For example, typical power states are:
PS(00h): Represents full power or active mode
Electrical Specifications
134 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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PS(01h): Represents a light load 5A to 20A
PS(02h): Represents a very light load <5A
The VR may change its configuration to meet the processor’ s power needs with greater
efficiency. For example, it may reduce the number of active phases, transition from
CCM (Continuous Conduction Mode) to DCM (Discontinuous Conduction Mode) mode,
reduce the switching frequency or pulse skip, or change to asynchronous regulation.
For exam ple, typical power states are 00h = run in norm al mode; a command of 01h=
shed phases mode, and an 02h=pulse skip.
The VR may reduce the number of active phases from PS(00h) to PS(01h) or PS(00h)
to PS(02h) for example. There are multiple VR design schemes that can be used to
maintain a greater efficiency in these different power states, please work with your VR
controller suppliers for optimizations.
The SetPS command sends a byte that is encoded as to what power state the VR
should transition to.
If a power state is not supported by the controller, the slave should acknowledge with
command rejected (11b)
Note the mapping of power states 0-n will be detailed in the compatible VR12.0 PWM
controller.
If the VR is in a low power state and receives a SetVID command moving the VID up
then the VR exits the low power state to normal mode (PS0) to move the voltage up as
fast as possible. The processor must re-issue low pow er state (PS1 or PS2) command if
it is in a low current condition at the new higher voltage. See Figure 7-2 for VR power
state transitions.
7.1.9.3.6 SVID Voltage Rail Addressing
The processor addresses 4 different voltage rail control segments within VR12
(VCC, VCCD_01, VCCD_23, and VSA). The SVID data packet contains a 4-bit
addressing code:
Figure 7-2. VR Power-State Transitions
PS0
PS2PS1
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 135
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Electrical Specifications
Notes:
1. Check with VR vendors for determining the physical address assignment method for their controllers.
2. VR addressing is assigned on a per voltage rail basis.
3. Dual VR controllers will have two addresses with the lowest order address, always being the higher
phase count.
4. For future platform flexibility, the VR controller should include an address offset, as shown with +1
not used.
Table 7-2. SVID Address Usage
PWM Address (HEX) Processor
00 Vcc
01 Vsa
02 VCCD_01
03 +1 not used
04 VCCD_23
05 +1 not used
Table 7-3. VR12.0 Reference Code Voltage Identification (VID) Table (Sheet 1 of 2)
HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD
00 0.00000 55 0.67000 78 0.84500 9B 1.02000 BE 1.19500 E1 1.37000
33 0.50000 56 0.67500 79 0.85000 9C 1.02500 BF 1.20000 E2 1.37500
34 0.50500 57 0.68000 7A 0.85500 9D 1.03000 C0 1.20500 E3 1.38000
35 0.51000 58 0.68500 7B 0.86000 9E 1.03500 C1 1.21000 E4 1.38500
36 0.51500 59 0.69000 7C 0.86500 9F 1.04000 C2 1.21500 E5 1.39000
37 0.52000 5A 0.69500 7D 0.87000 A0 1.04500 C3 1.22000 E6 1.39500
38 0.52500 5B 0.70000 7E 0.87500 A1 1.05000 C4 1.22500 E7 1.40000
39 0.53000 5C 0.70500 7F 0.88000 A2 1.05500 C5 1.23000 E8 1.40500
3A 0.53500 5D 0.71000 80 0.88500 A3 1.06000 C6 1.23500 E9 1.41000
3B 0.54000 5E 0.71500 81 0.89000 A4 1.06500 C7 1.24000 EA 1.41500
3C 0.54500 5F 0.72000 82 0.89500 A5 1.07000 C8 1.24500 EB 1.42000
3D 0.55000 60 0.72500 83 0.90000 A6 1.07500 C9 1.25000 EC 1.42500
3E 0.55500 61 0.73000 84 0.90500 A7 1.08000 CA 1.25500 ED 1.43000
3F 0.56000 62 0.73500 85 0.91000 A8 1.08500 CB 1.26000 EE 1.43500
40 0.56500 63 0.74000 86 0.91500 A9 1.09000 CC 1.26500 EF 1.44000
41 0.57000 64 0.74500 87 0.92000 AA 1.09500 CD 1.27000 F0 1.44500
42 0.57500 65 0.75000 88 0.92500 AB 1.10000 CE 1.27500 F1 1.45000
43 0.58000 66 0.75500 89 0.93000 AC 1.10500 CF 1.28000 F2 1.45500
44 0.58500 67 0.76000 8A 0.93500 AD 1.11000 D0 1.28500 F3 1.46000
45 0.59000 68 0.76500 8B 0.94000 AE 1.11500 D1 1.29000 F4 1.46500
46 0.59500 69 0.77000 8C 0.94500 AF 1.12000 D2 1.29500 F5 1.47000
47 0.60000 6A 0.77500 8D 0.95000 B0 1.12500 D3 1.30000 F6 1.47500
48 0.60500 6B 0.78000 8E 0.95500 B1 1.13000 D4 1.30500 F7 1.48000
49 0.61000 6C 0.78500 8F 0.96000 B2 1.13500 D5 1.31000 F8 1.48500
4A 0.61500 6D 0.79000 90 0.96500 B3 1.14000 D6 1.31500 F9 1.49000
4B 0.62000 6E 0.79500 91 0.97000 B4 1.14500 D7 1.32000 FA 1.49500
4C 0.62500 6F 0.80000 92 0.97500 B5 1.15000 D8 1.32500 FB 1.50000
Electrical Specifications
136 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Notes:
1. 00h = Off State
2. VID Range HEX 01-32 are not used by the processor.
3. For VID Ranges supported see Table 7-11.
4. VCCD is a fixed voltage of 1.35V or 1.5V.
7.1.10 Reserved or Unused Signals
All Reserved (RSVD) signals must not be connected. Connection of these signals to VCC,
VTTA, VTTD, VCCD, VCCPLL, VSS, or to any other signal (including each other) can result in
component malfunction or incompatibility with future processors. See Chapter 8,
“Processor Land Listing” for a land listing of the processor and the location of all
Reserved signals.
For reliable operation, always connect unused inputs or bi-directional signals to an
appropriate signal level. Unused active high inputs should be connected through a
resistor to ground (VSS). Unused outputs maybe left unconnected; however, this may
interfere with some Test Access Port (TAP) functions, complicate debug probing, and
prevent boundary scan testing. A resistor must be used when tying bi-directional
signals to power or ground. When 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.
7.2 Signal Group Summary
Signals are grouped by buffer type and similar characteristics as listed in Table 7-5. The
buffer type indicates which signaling technolo gy and specification s apply to the signals.
4D 0.63000 70 0.80500 93 0.98000 B6 1.15500 D9 1.33000 FC 1.50500
4E 0.63500 71 0.81000 94 0.98500 B7 1.16000 DA 1.33500 FD 1.51000
4F 0.64000 72 0.81500 95 0.99000 B8 1.16500 DB 1.34000 FE 1.51500
50 0.64500 73 0.82000 96 0.99500 B9 1.17000 DC 1.34500 FF 1.52000
51 0.65000 74 0.82500 97 1.00000 BA 1.17500 DD 1.35000
52 0.65500 75 0.83000 98 1.00500 BB 1.18000 DE 1.35500
53 0.66000 76 0.83500 99 1.01000 BC 1.18500 DF 1.36000
54 0.66500 77 0.84000 9A 1.01500 BD 1.19000 E0 1.36500
Table 7-3. VR12.0 Reference Code Vol tage Identification (VID) Table (Sheet 2 of 2)
HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD HEX VCC, VSA,
VCCD
Table 7-4. Signal Description Buffer Types (Sheet 1 of 2)
Signal Description
Analog Analog reference or output. May be used as a threshold voltage or for buffer
compensation
Asynchronous1Signal has no timing relationship with any system reference clock.
CMOS CMOS buffers: 1.0 V or 1.5 V tolerant
DDR3 DDR3 buffers: 1.5 V and 1.35 V tolerant
DMI2 Direct Media Inter face Gen 2 sign als. Thes e signals are compatible with PCI Express*
2.0 and 1.0 Signaling Environment AC Specifications.
Intel® QPI Current-mode 6.4 GT/s and 8.0 GT/s forwarded-clock Intel QuickPath Interconnect
signaling
Open Drain CMOS Open Drain CMOS (ODCMOS) buffers: 1.0V tolerant
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Electrical Specifications
PCI Express* PCI Express* interface signals. These signals are compatible with PCI Express 3.0
Signalling Environment AC Specifications and are AC coupled. The buffers are not
3.3-V tolerant. Refer to the PCIe specification.
Reference Voltage reference signal.
SSTL Source Series Terminated Logic (JEDEC SSTL_15)
1. Qualifier for a buffer type.
Table 7-5. Signal Groups (Sheet 1 of 3)
Differential/Single
Ended Buffer Type Signals1
DDR3 Reference Clocks2
Differential SSTL Output DDR{0/1/2/3}_CLK_D[N/P][3:0]
DDR3 Command Signals2
Single ended SSTL Output
DDR{0/1/2/3}_BA[2:0]
DDR{0/1/2/3}_CAS_N
DDR{0/1/2/3}_MA[15:00]
DDR{0/1/2/3}_MA_PAR
DDR{0/1/2/3}_RAS_N
DDR{0/1/2/3}_WE_N
CMOS1.5v Output DDR_RESET_C{01/23}_N
DDR3 Control Signals2
Single ended
CMOS1.5v Output DDR{0/1/2/3}_CS_N[9:0]
DDR{0/1/2/3}_ODT[5:0]
DDR{0/1/2/3}_CKE[5:0]
Reference Output DDR_VREFDQTX_C{01/23}
Reference Input DDR_VREFDQRX_C{01/23}
DDR{01/23}_RCOMP[2:0]
DDR3 Data Signals2
Differential SSTL Input/Output DDR{0/1/2/3}_DQS_D[N/P][17:00]
Single ended SSTL Input/Output DDR{0/1/2/3}_DQ[63:00]
DDR{0/1/2/3}_ECC[7:0]
SSTL Input DDR{0/1/2/3}_PAR_ERR_N
DDR3 Miscellaneous Signals2
Single ended CMOS1.5v Input DRAM_PWR_OK_C{01/23}
PCI Express* Port 1, 2, & 3 Signals
Differential PCI Expre ss* Input
PE1A_RX_D[N/P][3:0]
PE1B_RX_D[N/P][7:4]
PE2A_RX_D[N/P][3:0]
PE2B_RX_D[N/P][7:4]
PE2C_RX_D[N/P][11:8]
PE2D_RX_D[N/P][15:12]
PE3A_RX_D[N/P][3:0]
PE3B_RX_D[N/P][7:4]
PE3C_RX_D[N/P][11:8]
PE3D_RX_D[N/P][15:12]
Table 7-4. Signal Description Buffer Types (Sheet 2 of 2)
Signal Description
Electrical Specifications
138 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Differential PCI Express* Output
PE1A_TX_D[N/P][3:0]
PE1B_TX_D[N/P][7:4]
PE2A_TX_D[N/P][3:0]
PE2B_TX_D[N/P][7:4]
PE2C_TX_D[N/P][11:8]
PE2D_TX_D[N/P][15:12]
PE3A_TX_D[N/P][3:0]
PE3B_TX_D[N/P][7:4]
PE3C_TX_D[N/P][11:8]
PE3D_TX_D[N/P][15:12]
PCI Express* Miscellaneous Signals
Single ended
Analog Input PE_RBIAS_SENSE
Reference Input/Output PE_RBIAS
PE_VREF_CAP
DMI2/PCI Express* Signals
Differential DMI2 Input DMI_RX_D[N/P][3:0]
DMI2 Output DMI_TX_D[N/P][3:0]
Intel® QuickPath Interconnect (QPI) Signals
Differential
Intel® QPI Input QPI{0/1}_DRX_D[N/P][19:00]
QPI{0/1}_CLKRX_D[N/P]
Intel® QPI Output QPI{0/1}_DTX_D[N/P][19:00]
QPI{0/1}_CLKTX_D[N/P]
Single ended Analog Input QPI_RBIAS_SENSE
Analog Input/Output QPI_RBIAS
Platform Environmental Control Interface (PECI)
Single ended PECI PECI
System Reference Clock (BCLK {0/1})
Differential CMOS1.0v Input BCLK{0/1}_D[N/P]
SMBus
Single ended Open Drain CMOS
Input/Output
DDR_SCL_C{01/23}
DDR_SDA_C{01/23}
PEHPSCL
PEHPSDA
JTAG & TAP Signals
Single ended
CMOS1.0v Input TCK, TDI, TMS, TRST_N
CMOS1.0v Input/Output PREQ_N
CMOS1.0v Output PRDY_N
Open Drain CMOS
Input/Output BPM_N[7:0]
EAR_N
Open Drain CMOS Output TDO
Serial VID Interface (SVID) Signals
Single ended
CMOS1.0v Input SVIDALERT_N
Open Drain CMOS
Input/Output SVIDDATA
Open Drain CMOS Output SVIDCLK
Table 7-5. Signal Groups (Sheet 2 of 3)
Differential/Single
Ended Buffer Type Signals1
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 139
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Electrical Specifications
Notes:
1. Refer to Table 7-19 for details on the RON (Buffer on Resistance) value for this signal.
Processor Asynchronous Sideband Signals
Single ended
CMOS1.0v Input
BIST_ENABLE
BMCINIT
FRMAGENT
PWRGOOD
PMSYNC
RESET_N
SAFE_MODE_BOOT
SOCKET_ID[1:0]
TXT_AGENT
TXT_PLTEN
Open Drain CMOS
Input/Output
CAT_ERR_N
MEM_HOT_C{01/23}_N
PROCHOT_N
Open Drain CMOS Out put ERROR_N[2:0]
THERMTRIP_N
Miscellaneous Signals
N/A Output IVT_ID_N
SKTOCC_N
Power/Other Signals
Power / Ground VCC, VTTA, VTTD, VCCD_01, VCCD_23,VCCPLL, VSA a nd VSS
Sense Points
VCC_SENSE
VSS_VCC_SENSE
VSS_VTTD_SENSE
VTTD_SENSE
VSA_SENSE
VSS_VSA_SENSE
1. Refer to Section 6, “Signal Descriptions for signal description details.
2. DDR{0/1/2/3} refers to DDR3 Channel 0, DDR3 Channel 1, DDR3 Channel 2 and DDR3 Channel 3.
Table 7-6. Signals with On-Die Termination
Signal Name P ull Up /Pull
Down Rail Value Units Notes
DDR{0/1}_PAR_ERR_N Pull Up VCCD_01 65 Ω
DDR{2/3}_PAR_ERR_N Pull Up VCCD_23 65 Ω
BMCINIT Pull Down VSS 2K Ω1
FRMAGENT Pull Down VSS 2K Ω1
TXT_AGENT Pull Down VSS 2K Ω1
SAFE_MODE_BOOT Pull Down VSS 2K Ω1
SOCKET_ID[1:0] Pull Down VSS 2K Ω1
BIST_ENABLE Pull Up VTT 2K Ω1
TXT_PLTEN Pull Up VTT 2K Ω1
EAR_N Pull Up VTT 2K Ω2
Table 7-5. Signal Groups (Sheet 3 of 3)
Differential/Single
Ended Buffer Type Signals1
Electrical Specifications
140 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
7.3 Power-On Configuration (POC) Options
Several configuration options can be configured by hardware. The processor samples
its hardware configuration at reset, on the active-to-inactive transition of RESET_N, or
upon assertion of PWRGOOD (inactive-to-active transition). For specifics on these
options, please refer to Table 7-7.
The sampled information configures the processor for subsequent operation. These
configuration options cannot be changed except by another reset transition of the
latching signal (RESET_N or PWRGOOD).
Notes:
1. Output tri-state option enables Fault Resilient Booting (FRB), for FRB details see Section 7.4. The signal
used to latch PROCHOT_N for enabling FRB mode is RESET_N.
2. BIST_ENABLE is sampled at RESET_N de-assertion (on the falling edge).
3. This signal is sampled after PWRGOOD assertion.
7.4 Fault Resilient Booting (FRB)
The processor supports both socket and core lev el Fault R e silient Booting (FRB), w hich
provides the ability to boot the system as long as there is one processor functional in
the system. One limitation to socket level FRB is that the system cannot boot if the
legacy socket that connects to an active PCH becomes unav ailable since this is the path
to the system BIOS. See Table 7-8 for a list of output tri-state FRB signals.
Socket level FRB will tri-state processor outputs via the PROCHOT_N signal. Assertion
of the PROCHO T_N signal through RESET_N de-assertion will tri-state processor
outputs. Note, that individual core disabling is also supported for those cases where
disabling the entire package is not desired.
The processor extends the FRB capability to the core granularity by maintaining a
register in the uncore so that BIOS or another entity can disable one or more specific
processor cores.
Table 7-7. Power-On Configuration Option Lands
Configuration Option Land Name Notes
Output tri state PROCHOT_N 1
Execute BIST (Built-In Self Test) BIST_ENABLE 2
Enable Service Processor Boot Mode BMCINIT 3
Enable Intel® T rusted Execution T echnology (Intel®
TXT) Platform TXT_PLTEN 3
Power-up Sequence Halt for ITP configuration EAR_N 3
Enable Bootable Firmware Agent FRMAGENT 3
Enable Intel Trusted Execution Technology
(Intel TXT) Agent TXT_AGENT 3
Enable Safe Mode Boot SAFE_MODE_BOOT 3
Configure Socket ID SOCKET_ID[1:0] 3
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7.5 Mixing Processors
Intel supports and validates two and four processor configurations only in which all
processors operate with the same Intel® QuickPath Interconnect frequency, core
frequency, power segment, 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. Combining processors from different power segments
is also not supported.
Note: Processors within a system must operate at the same frequency per bits [15:8] of the
FLEX_RATIO MSR (Address: 194h); however this does not apply to frequency
transitions initiated due to thermal events, Extended HALT, Enhanced Intel SpeedStep
Technology transitions signal. Please refer to the Intel® Xeon® Processor E5 v2
Product Family Processor Datasheet, Volume Two: Registers for details on the
FLEX_RATIO MSR and setting the processor core frequency.
Not all operating systems can support dual processors with mixed frequencies. Mixing
processors of different steppings but the same model (as per CPUID instruction) is
supported provided there is no more than one stepping delta between the processors,
for example, S and S+1.
S and S+1 is defined as mixing of two CPU steppings in the same platform where one
CPU is S (stepping) = CPUID.(EAX=01h):EAX[3:0], and the other is S+1 =
CPUID.(EAX=01h):EAX[3:0]+1. The stepping ID is found in EAX[3:0] after executing
the CPUID instruction with Function 01h.
Details regarding the CPUID instruction are provided in the AP-485, Intel® Processor
Identification and the CPUID Instruction application note, also refer to the Intel®
Xeon® Processor E5 v2 Product Family Specification Update.
Table 7-8. Fault Resilient Booting (Output Tri-State) Signals
Output Tri-State Signal Groups Signals
Intel QPI
QPI0_CLKTX_DN[1:0]
QPI0_CLKTX_DP[1:0]
QPI0_DTX_DN[19:00]
QPI0_DTX_DP[19:00]
QPI1_CLKTX_DN[1:0]
QPI1_CLKTX_DP[1:0]
QPI1_DTX_DN[19:00]
QPI1_DTX_DP[19:00]
SMBus
DDR_SCL_C01
DDR_SDA_C01
DDR_SCL_C23
DDR_SDA_C23
PEHPSCL
PEHPSDA
Processor Sideband
CAT_ERR_N
ERROR_N[2:0]
BPM_N[7:0]
PRDY_N
THERMTRIP_N
PROCHOT_N
PECI
SVID SVIDCLK
Electrical Specifications
142 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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7.6 Flexible Motherboard Guidelines (FMB)
The Flexible Motherboard (FMB) guidelines are estimates of the maximum values the
processor will have over certain time periods. The values are only estimates and
actual specifications for future processors may differ. Processors may or may not
have specifications equal to the FMB value in the foreseeable future. System
designers should meet the FMB values to ensure their systems will be compatible with
future processors.
7.7 Absolute Maximum and Minimum Ratings
Table 7-9 specifies absolute maximum and minimum ratings. 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, but 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.
Although the processor contains protective circuitry to resist damage from Electro-
Static Discharge (ESD), precautions should always be taken to avoid high static
voltages or electric fields.
Notes:
1. For functional operation, all processor electrical, signal qualit y , mech anical, and thermal specifications must
be satisfied.
2. Overshoot and undershoot voltage guidelines for input, output, and I/O signals are outlined in
Section 7.9.5. Excessive overshoot or undershoot on any signal will likely result in permanent damage to
the processor.
7.7.1 Storage Condition Specifications
Environmental storage condition limits define the temperature and relative humidity
limits to which the device is exposed to while being stored in a Moisture Barrier Bag.
The specified storage conditions are for component level prior to board attach (see
notes in Table 7-10 for post board attach limits).
Table 7-10 specifies absolute maximum and minimum storage temper ature limits which
represent the maximum or minimum device condition beyond which damage, latent or
otherwise, may occur. The table also specifies sustained storage temperature, relative
humidity, and time-duration limits. These limits specify the maximum or minimum
Table 7-9 . Processor Absolu t e Mi nimum and Max i mum Ratings
Symbol Parameter Min Max Unit
VCC Processor core voltage with respect to Vss -0.3 1.4 V
VCCPLL Processor PLL voltage with respect to Vss -0.3 2.0 V
VCCD Processor IO supply voltage for DDR3
(standard voltage) with respect to VSS -0.3 1.85 V
VCCD Processor IO supply voltage for DDR3L (low
Voltage) with respect to VSS -0.3 1.7 V
VSA Processor SA voltage with respect to VSS -0.3 1.4 V
VTTA
VTTD
Processor analog IO vo ltage with respect to
VSS -0.3 1.4 V
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 143
Datasheet Volume One of Two
Electrical Specifications
device storage conditions for a sustained period of time. At conditions outside sustained
limits, but within absolute maximum and minimum r atings, quality & reliability ma y be
affected.
Notes:
1. Storage conditions are applicable to storage environments only. In this scenario, the processor must not
receive a clock, and no lands can be connected to a v o ltage 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.
2. These ratings apply to the Intel component and do not include the tray or packaging.
3. Failure to adhere to this specification can affect the long-term reliability of the processor.
4. Non-operating storage limits post board attach: Storage condition limits for the component once attached
to the application board are not specified. Intel does not conduct compone nt level certi fication assessments
post board attach given the multitude of attach methods, socket types and board t ypes used by customer s.
Provided as general guidance only, Inte l board products are spe cified and certified to mee t the following
temperature and humidit y limits (Non-Operating Temperature Limit: -40C to 70C & Humidity: 50% to 90%,
non condensing with a maximum wet bulb of 28C).
5. Device storage temperature qualification methods follow JEDEC High and Low Temperature Storage Life
Standards: JESD22-A119 (low temperature) and JESD22-A103 (high temperature).
7.8 DC Specifications
DC specifications are defined at the processor pads, unless otherwise noted.
DC specifications are only valid while meeting specifications for case temperature
(TCASE specified in Chapter 5), clock frequency, and input voltages. Care should be
taken to read all notes associated with each specification.
7.8.1 Voltage and Current Specifications
Table 7-10. Storage Condition Ratings
Symbol Parameter Min Max Unit
Tabsolute storage The minimum/maximum device storage temperature
beyond which damage (latent or otherwise) may
occur when subjected to for any length of time.
-25 125 °C
Tsustained storage The minimum/maximum device storage temperature
for a sustained period of time. -5 40 °C
Tshort term storage The ambient storage temperature (in shipping media)
for a short period of time. -20 85 °C
RHsustained storage The maximum device storage relative humidity for a
sustained period of time. 60% @ 24 °C
Timesustained storage A prolonged or extended period of time; typically
associated with sustained storage conditions
Unopened bag, includes 6 months storage time by
customer.
0 30 months
Timeshort te rm storage A short period of time (in shipping media). 0 72 hours
Table 7-11. Voltage Specification (Sheet 1 of 2)
Symbol Parameter Voltage
Plane Min Typ Max Unit Notes1
VCC VID VCC VID Range 0.6 1.35 V 2, 3
VRetention
VID
Retention Voltage
VID in package C3
and C6 states 0.65 V 2, 3
VCC Core Voltage
(Launch - FMB) VCC See Table 7-13 and Figure 7-3 V3, 4, 7, 8,
12, 14, 18
Electrical Specifications
144 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Notes:
1. Unless otherwise noted, all specifications in this table apply to all processors. These specifications are based on final silicon
characterization.
2. Individual processor VID values may be calibrated during manufacturing such that two devices at the same speed may have
different settings.
3. These voltages are targets only. A variable voltage source should exist on systems in the event that a different voltage is
required.
4. The VCC voltage specification requirements are measured across the remote sense pin pairs (VCC_SENSE and
VSS_VCC_SENSE) on the processor package. Voltage measurement should be taken with a DC to 100 MHz bandwidth
oscilloscope limit (or DC to 20 MHz for older model oscilloscopes), using a 1.5 pF maximum probe capacitance, and 1M Ω
minimum impedance. The maximum length of the ground wire on the probe should be less than 5 mm to ensure external
noise from the system is not coupled in the scope probe.
5. The VTT A, and VTTD voltage specification requirements are measured across the remote sense pin pairs (VTTD_SENSE and
VSS_VTTD_SENSE) on the processor package. Voltage measurement should be taken with a DC to 100 MHz bandwidth
oscilloscope limit (or DC to 20 MHz for older model oscilloscopes), using a 1.5 pF maximum probe capacitance, and 1M Ω
minimum impedance. The maximum length of the ground wire on the probe should be less than 5 mm to ensure external
noise from the system is not coupled in the scope probe.
6. The VSA voltage specification requirements are measured across the remote sense pin pairs (VSA_SENSE and
VSS_VSA_SENSE) on the processor package. Voltage measurement should be taken with a DC to 100 MHz bandwidt h
oscilloscope limit (or DC to 20 MHz for older model oscilloscopes), using a 1.5 pF maximum probe capacitance, and 1M Ω
minimum impedance. The maximum length of the ground wire on the probe should be less than 5 mm to ensure external
noise from the system is not coupled in the scope probe.
7. The processor s hould not be subjected to an y static VCC level that exceeds the VCC_MAX associated with an y particular current.
Failure to adhere to this specification can shorten processor lifetime.
8. Minimum VCC and maximum ICC are specified at the maximum processor case temperature (TCASE) shown in Section 5,
“Thermal Management Specifications”. ICC_MAX is specified at the relative VCC_MAX point on the VCC load line. Th e processor is
capable of drawing ICC_MAX for up to 5 seconds. Refer to Figure 7-4 for further details on the a verage proc ess or c urre nt d raw
over various time durations.
9. The processor should not be subjected to any static VTT A, VTTD level that exceeds the VTT_MAX associated with any particular
current. Failure to adhere to this specification can shorten processor lifetime.
10. This specification represents the VCC reduction or VCC increase due to each VID transition, see Section 7.1.9.3, “Voltage
Identification (VID)”.
11. Baseboard bandwidth is limited to 20 MHz.
12. FMB is the flexible motherboard guidelines. See Section 7.6 for FMB details.
13. DC + AC + Ripple = Total Tolerance
14. For Power State Functions see Section 7.1.9.3.5.
15. VSA_VID does not have a loadline, the output voltage is exp ec t ed to be the VID value.
16. VCCD tolerance at processor pins. Tolerance for VR at remote sense is ±3.3%*VCCD.
17. The VCCPLL, VCCD01, VCCD23 voltage specification requirements are measured across vias on the platform. Choose VCCPLL,
VCCD01, or VCCD23 vias close to the socket and measure with a DC to 100MHz bandwidth oscilloscope limit (or DC to 20MHz for
older model oscilloscopes), using 1.5 pF maximum probe capacitance, and 1M Ω minimum impedance. The maximum length
of the ground wire on the probe should be less than 5 mm to ensure external noise from the system is not coupled in the
scope probe.
18. VCC has a Vboot setting of 0.0V and is not included in the PWRGOOD indication. Refer to the compatible VR12.0 PWM
controller.
19. VSA has a Vboot setting of 0.9V. Refer to the compatible VR12.0 PWM controller.
VVID_STEP
(Vcc, Vsa,
Vccd)
VID step size d uring
a transition 5.0 mV 10
VCCPLL PLL Voltage VCCPLL 0.955*VCCPLL_TYP 1.7 1.045*VCCPLL_TYP V11, 12, 13,
17
VCCD
(VCCD_01,
VCCD_23)
I/O Voltage for
DDR3 (Standard
Voltage) VCCD 0.95*VCCD_TYP 1.5 1.05*VCCD_TYP V11, 13, 14,
16, 17
VCCD
(VCCD_01.
VCCD_23)
I/O Voltage for
DDR3L (Low
Voltage) VCCD 0.95*VCCD_TYP 1.35 1.075*VCCD_TYP V11, 13, 14,
16, 17
VTT (VTTA,
VTTD) Uncore Voltage
(Launch - FMB) VTT 0.957*VTT_TYP 1.00 1.043*VTT_TYP V3, 5, 9, 12,
13
VSA_VID Vsa VID Range VSA 0.6 0.940 1.25 V 2, 3, 14, 15
VSA
System Agent
Voltage
(Launch - FMB) VSA VSA_VID - 0.057 VSA_VID V
SA_VID + 0.057 V 3, 6, 12,
14, 19
Table 7-11. Voltage Specification (Sheet 2 of 2)
Symbol Parameter Voltage
Plane Min Typ Max Unit Notes1
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 145
Datasheet Volume One of Two
Electrical Specifications
Notes:
1. Unless otherwise noted, all specifications in this table apply to all processors. These specifications are based on final silicon
characterization.
2. Launch to FMB, this is the flexible motherboard guidelines. See Section 7.6 for FMB details.
3. 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 thermal assessment. The voltage regulator is responsible for
monitoring its temperature and asse rting th e ne cessary signal to info rm the proce ssor of a thermal ex curs ion. Plea se refer to
the compatible VR12.0 PWM controller for further details.
4. Specification is at TCASE = 50°C. Characterized by design and not tested.
5. ICCD_01_MAX and ICCD_23_MAX refers only to the processor’s curre nt draw and does not account for the current consumpt ion by
the memory devices. This only applies to Intel® Xeon® processor E5-1600 v2/E5-2600 v2 product families.
6. Minimum VCC and maximum ICC are specified at the maximum processor case temperature (TCASE) shown in Section 5,
“Thermal Management Specifications”. ICC_MAX is specified at the relativ e VCC_MAX point on the VCC load line. The processor is
capable of dr awing I CC_MAX for up to 5 se con ds. Refer to Figure 7-4 for further details on the average processor current draw
over various time durations.
7. Memory Standby Current is characterized by design and not tested.
8. Refer to Table 1-1 for the model numbers of each processor based on TDP and core count.
9. To determine which SKUS are for workstation platforms, refer to Section 5.1.3.
Table 7-12. Processor Current Specifications
Parameter Symbol and
Definition Processor TDP / Core Count TDC (A) Max (A) Notes1
ITT
I/O Termination Supply,
Processor Current on VTTA/VTTD
All Intel® Xeon® processor E5-1600
v2/E5-2600 v2/E5-4600 v2 product
families
20 24 2, 5, 6
ISA
System Agent Supply,
Processor Current on VSA
20 24
ICCD_01
DDR3 Supply, Processor
Current VCCD_01
34
ICCD_23
DDR3 Supply, Processor
Current VCCD_23
34
ICCPLL
PLL Supply, Processor Current
on VCCPLL
22
ICCD_S3
Total processor current on
VCCD_01/VCCD_23
in System S3 Standby State
-- 0.5 7
ICC
Core Supply, Processor Current
on VCC
150W (WS) 8-core 155 185 2, 5, 6
130W 1U 12/10/8-core, 130W 1S WS 6-
core 135 165
130W 2U 8-core (E5-2667 v2) 135 165
130W 2U 6/4-core, 130W 1S WS 4-core 115 150
115W 12/10-core 135 165
95W 10/8/6/4-core 115 135
80W 6/4-core 80 100
70W 10-core 80 100
60W 6-core 70 85
LV95W-10C 115 135
LV70W-10C, LV70W-8C 80 100
LV50W-6C 60 80
Electrical Specifications
146 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Notes:
1. The loadline specification includes both static and transient limits.
2. This table is intended to aid in reading discrete points on graph in Figure 7-3.
Table 7-13. Processor VCC Static and Transient Tolerance
ICC (A) VCC_MAX (V) VCC_TYP (V) VCC_MIN (V) Notes
0 VID + 0.015 VID - 0.000 VID - 0.015 1,2,3,4,5,6
5 VID + 0.011 VID - 0.004 VID - 0.019 1,2,3,4,5,6
10 VID + 0.007 VID - 0.008 VID - 0.023 1,2,3,4,5,6
15 VID + 0.003 VID - 0.012 VID - 0.027 1,2,3,4,5,6
19 VID + 0.000 VID - 0.015 VID - 0.030 1,2,3,4,5,6
25 VID - 0.005 VID - 0.020 VID - 0.035 1,2,3,4,5,6
30 VID - 0.009 VID - 0.024 VID - 0.039 1,2,3,4,5,6
35 VID - 0.013 VID - 0.028 VID - 0.043 1,2,3,4,5,6
40 VID - 0.017 VID - 0.032 VID - 0.047 1,2,3,4,5,6
45 VID - 0.021 VID - 0.036 VID - 0.051 1,2,3,4,5,6
50 VID - 0.025 VID - 0.040 VID - 0.055 1,2,3,4,5,6
55 VID - 0.029 VID - 0.044 VID - 0.059 1,2,3,4,5,6
60 VID - 0.033 VID - 0.048 VID - 0.063 1,2,3,4,5,6
65 VID - 0.037 VID - 0.052 VID - 0.067 1,2,3,4,5,6
70 VID - 0.041 VID - 0.056 VID - 0.071 1,2,3,4,5,6
75 VID - 0.045 VID - 0.060 VID - 0.075 1,2,3,4,5,6
80 VID - 0.049 VID - 0.064 VID - 0.079 1,2,3,4,5,6
85 VID - 0.053 VID - 0.068 VID - 0.083 1,2,3,4,5,6
90 VID - 0.057 VID - 0.072 VID - 0.087 1,2,3,4,5,6
95 VID - 0.061 VID - 0.076 VID - 0.091 1,2,3,4,5,6
100 VID - 0.065 VID - 0.080 VID - 0.095 1,2,3,4,5,6
105 VID - 0.069 VID - 0.084 VID - 0.099 1,2,3,4,5,6
110 VID - 0.073 VID - 0.088 VID - 0.103 1,2,3,4,5,6
115 VID - 0.077 VID - 0.092 VID - 0.107 1,2,3,4,5,6
120 VID - 0.081 VID - 0.096 VID - 0.111 1,2,3,4,5,6
125 VID - 0.085 VID - 0.100 VID - 0.115 1,2,3,4,5,6
130 VID - 0.089 VID - 0.104 VID - 0.119 1,2,3,4,5,6
135 VID - 0.093 VID - 0.108 VID - 0.123 1,2,3,4,5,6
140 VID - 0.097 VID - 0.112 VID - 0.127 1,2,3,4,5,6
145 VID - 0.101 VID - 0.116 VID - 0.131 1,2,3,4,5,6
150 VID - 0.105 VID - 0.120 VID - 0.135 1,2,3,4,5,6
155 VID - 0.109 VID - 0.124 VID - 0.139 1,2,3,4,5,6
160 VID - 0.113 VID - 0.128 VID - 0.143 1,2,3,4,5,6
165 VID - 0.117 VID - 0.132 VID - 0.147 1,2,3,4,5,6
170 VID - 0.121 VID - 0.136 VID - 0.151 1,2,3,4,5,6
175 VID - 0.125 VID - 0.140 VID - 0.155 1,2,3,4,5,6
180 VID - 0.129 VID - 0.144 VID - 0.159 1,2,3,4,5,6
185 VID - 0.133 VID - 0.148 VID - 0.163 1,2,3,4,5,6
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 147
Datasheet Volume One of Two
Electrical Specifications
3. The loadlines specify voltage limits at the die measured at the VCC_SENSE and VSS_VCC_SENSE lands.
Voltage regulation feedback for voltage regulator circuits must also be taken from processor VCC_SENSE
and VSS_VCC_SENSE lands. R efer to the compati ble VR12.0 PWM con trolle r fo r loadline guidelines and VR
implementation details.
4. The Vcc_min and Vcc_max loadlines repr esent static and transient limits. Please see Section 6 for Vcc
Overshoot specifications.
5. The Adaptive Loadline Positioning slope is 0.8 mΩ.
6. For Icc ranges, reference Table 7-12, “Processor Current Specifications.
Figure 7-3. Processor VCC Static and Transient Tolerance Loadlines
Electrical Specifications
148 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
7.8.2 Die Voltage Validation
Core voltage (VCC) overshoot events at the processor must meet the specifications in
Table 7-14 when measured across the VCC_SENSE and VSS_VCC_SENSE lands.
Overshoot ev ents that are < 10 ns in duration ma y be ignored. These measurements of
processor die level overshoot should be taken with a 100 MHz bandwidth limited
oscilloscope.
Notes:
1. The peak current for any 5 second sample does not exceed Icc_max.
2. The average current for any 10 second sample does not exceed the Y value at 10 seconds.
3. The average current for any 20 second period or greater does not exceed Icc_tdc.
4. Turbo performance may be impacted by failing to meet durations specified in this graph. Ensure that the
platform design can handle peak and average current based on the specification.
5. Processor or voltage regulator thermal protection circuitry should not trip for load currents greater than
ICC_TDC.
6. Not 100% tested. Specified by design characterization.
7.8.2.1 VCC Overshoot Specifications
The processor can tolerate short transient overshoot ev ents where VCC ex ceeds 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
VCC_SENSE and VSS_VCC_SENSE lands.
Figure 7-4. Load Current Versus Time
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 149
Datasheet Volume One of Two
Electrical Specifications
Notes:
1. VOS_MAX is the measured overshoot voltage.
2. TOS_MAX is the measured time duration above VccMAX(I1).
3. Istep: Load Release Current Step, for example, I2 to I1, where I2 > I1.
4. VccMAX(I1) = VID - I1*RLL + 15mV
7.8.3 Signal DC Spec ifications
DC specifications are defined at the processor pads, unless otherwise noted.
DC specifications are only valid while meeting specifications for case temperature
(TCASE specified inChapter 5), clock frequency, and input voltages. Care should be
taken to read all notes associated with each specification.
Table 7-14. VCC Overshoot Specifications
Symbol Parameter Min Max Units Figure Notes
VOS_MAX Magnitude of VCC overshoot above VID 65 mV 7-5
TOS_MAX Time duration of VCC overshoot above VccMAX
value at the new lighter load 25 μs7-5
Figure 7-5. VCC Over shoot E xam ple Waveform
0 5 10 15 20 25 30
Voltage [V]
Time [us]
VccMAX (I1)
VID + V
OS_MAX
T
OS_MAX
V
OS_MAX
Table 7-15. DDR3 and DDR3L Signal DC Specifications (Sheet 1 of 2)
Symbol Parameter Min Typ Max Units Notes1
IIL Input Leakage Current -1.4 +1.4 mA 10
Data Signals
VIL Input Low Voltage 0.43*VCCD V2, 3
VIH Input High Voltage 0.57*VCCD V2, 4, 5
RON DDR3 Data Buffer On
Resistance 21 31 Ω6
Data ODT On-Die Termination for Data
Signals 45
90 55
110 Ω8
PAR_ERR_N ODT On-Die Termination for Parity
Error Signals 59 72 Ω
Electrical Specifications
150 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Notes:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
2. The voltage rail VCCD which will be set to 1.50 V or 1.35 V nominal depending on the voltage of all DIMMs connected to the
processor.
3. VIL is the maximum voltage level at a receiving agent that will be interpreted as a logical low value.
4. VIH is the minimum voltage level at a receiving agent that will be interpreted as a logical high value.
5. VIH and VOH may experience excursions above VCCD. However, input signal dr ivers must comply with the signal quality
specifications. Refer to Section 7.9.
6. This is the pull down driver re sistan ce. Refer to processor signal integrity models for I/V characteristics. Re se t driv e does not
have a termination.
7. RVTT_TERM is the termination on the DIMM and not controlled by the processor. Please refer to the applicable DIMM datasheet.
8. The minimum and maximum values for these signals are programmable by BIOS to one o f the pairs.
9. COMP resistance must be provided on the system board with 1% resistors. DDR01_RCOMP[2:0] and DDR23_RCOMP[2:0]
resistors are te rminate d to VSS.
10. Input leakage current is specified for all DDR3 signals.
Reference Clock Signals, Command, and Data Signals
VOL Output Low Voltage (VCCD
/ 2)* (RON
/(RON+RVTT_TERM)) V2, 7
VOH Output High Voltage
VCCD
- ((VCCD
/ 2)*
(RON/(RON+RVTT_TE
RM))
V2, 5, 7
Reference Clock Signal
RON DDR3 Clock Buffer On
Resistance 21 31 Ω6
Command Signals
RON DDR3 Command Buffer On
Resistance 16 24 Ω6
RON DDR3 Reset Buffer On
Resistance 25 75 Ω6
VOL_CMOS1.5v Output Low Voltage, Signals
DDR_RESET_ C{01/23}_N 0.2*VCCD V1,2
VOH_CMOS1.5v Output H i gh Voltage, Signals
DDR_RESET_ C{01/23}_N 0.9*VCCD V1,2
IIL_CMOS1.5v Input Leakage Current -100 +100 μA1,2
Control Signals
RON DDR3 Control Buffer On
Resistance 21 31 Ω6
DDR01_RCOMP[0] COMP Resistance 128.7 130 131.3 Ω9,12
DDR01_RCOMP[1] COMP Resistance 25.8 39 26.1 26.361 Ω9,12
DDR01_RCOMP[2] COMP Resistance 198 200 202 Ω9,12
DDR23_RCOMP[0] COMP Resistance 128.7 130 131.3 Ω9,12
DDR23_RCOMP[1] COMP Resistance 25.839 26.1 26.361 Ω9,12
DDR23_RCOMP[2] COMP Resistance 198 200 202 Ω9,12
DDR3 Miscellaneous Signals
VIL Input Low Voltage
DRAM_PWR_OK_C{01/23} 0.55*VCCD +
0.2 V2, 3,
11, 13
VIH Input High Voltage
DRAM_PWR_OK_C{01/23} 0.55*VCCD
+ 0.3 V2, 4, 5,
11, 13
Table 7-15. DDR3 and DDR3L Signal DC Specifications (Sheet 2 of 2)
Symbol Parameter Min Typ Max Units Notes1
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 151
Datasheet Volume One of Two
Electrical Specifications
11. DRAM_PWR_OK_C{01/23} must have a maximum of 30 ns rise or fall time over VCCD * 0.55 +300 mV and -200 mV and the
edge must be monotonic.
12. The DDR01/23_RCOMP error tolerance is ±15% from the compensated value.
13. DRAM_PWR_OK_C{01/23}: Data Scrambling must be enabled for production environments. Disabling Data scrambling can be
used for debug and testing purposes only. Running systems with Data Scrambling off will make the configuration out of
specification. For details, please reference these documents: Intel® Xeon® Processor E5 v2 Product Family Processor
Datasheet, Volume Two: Registers.
Notes:
1. VTTD supplies the PECI interface. PECI behavior does not affect VTTD min/max specification
2. It is expected that the PECI driver will take into account, the variance in the receiver input thresholds and consequently, be
able to drive its output within safe limits (-0.150 V to 0.275*VTTD for the low level and 0.725*VTTD to VTTD+0.150 V for the
high level).
3. The leakage specification applies to powered devices on the PECI bus.
4. One node is counted for each client and one node for the system host. Extended trace lengths might appear as additional
nodes.
5. Excessive capacitive loading on the PECI line may slow down the signal rise/fall times and consequently limit the maximum bit
rate at which the interface can operate.
Notes:
1. Unless otherwise noted, all specifications in this table apply to all processor frequencies. These specifications are specified at
the processor pad.
2. Crossing Vo ltage is defined as the instantaneous voltage value when the rising edge of BCLK{0/1}_DN is equal to the falling
edge of BCLK{0/1}_DP.
3. VHavg is the statistical average of the VH measured by the oscilloscope.
4. The crossing point must meet the absolute and relative crossing point specifications simultaneously.
5. VHavg can be measured directly using “Vtop” on Agilent* and “High” on Tektronix oscilloscopes.
6. VCROSS is defined as the total variation of all crossing voltages as defined in Note 3.
7. The rising edge of BCLK{0/1}_DN is equal to the falling edge of BCLK{0/1}_DP.
Table 7-16. PECI DC Specifications
Symbol Definition and Conditions Min Max Units Figure Notes1
VIn Input Voltage Range -0.150 VTT V
VHysteresis Hysteresis 0.100 * VTT V
VNNegative-edge threshold voltage 0.275 * VTT 0.500 * VTT V7-1 2
VPPositive-edge threshold voltage 0.550 * VTT 0.725 * VTT V7-1 2
ISOURCE High level output source
VOH = 0.75 * VTT
-6.0 mA
ILeak+ High impedance state leakage to VTTD (Vleak =
VOL) 50 200 µA 3
RON Buffer On Resistance 20 36 Ω
CBus Bus capacitance per node N/A 10 pF 4,5
VNoise Signal noise immunity above 300 MHz 0.100 * VTT N/A Vp-p
Output Edge Rate (50 ohm to VSS, between VIL
and VIH)1.5 4 V/ns
Table 7-17. System Reference Clock (BCLK{0/1}) DC Specifications
Symbol Parameter Signal Min Max Unit Figure Notes1
VBCLK_diff_ih Differential Input High Voltage Differential 0.150 N/A V 7-7
VBCLK_diff_il Differential Input Low Voltage Differential -0.150 V 7-7
Vcross (abs) Absolute Crossing Point Single Ended 0.250 0.550 V 7-6
7-8 2, 4, 7
Vcross(rel) Relative Crossing Point Single Ended 0.250 +
0.5*(VHavg -
0.700)
0.550 +
0.5*(VHavg -
0.700) V7-6 3, 4, 5
ΔVcross Range of Crossing Points Single Ended N/A 0.140 V 6
VTH Threshold Voltage Single Ended Vcross - 0.1 Vcross + 0.1 V
IIL Input Leakage Current N/A 1.50 μA8
Cpad Pad Capacitance N/A 0.9 1.2 pF
Electrical Specifications
152 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
8. For Vin between 0 and Vih.
Note:
1. These signals are measured between VIL and VIH.
2. The signal edge rate must be met or the signal must transition monotonically to the asserted state.
Table 7-18. SMBus DC Specifications
Symbol Parameter Min Max Units Notes
VIL Input Low Voltage 0.3*VTT V
VIH Input High Voltage 0.7*VTT V
VHysteresis Hysteresis 0.1*VTT V
VOL Output Low Voltage 0.2*VTT V
RON Buffer On Resistance 4 14 Ω
ILLeakage Current 50 200 μA
Output Edge R ate (50 ohm to VTT, between VIL
and VIH)0.05 0.6 V/ns
Table 7-19. JTAG and TAP Signals DC Specifications
Symbol Parameter Min Max Units Notes
VIL Input Low Voltage 0.3*VTT V
VIH Input High Voltage 0.7*VTT V
VIL Input Low Voltage: PREQ_N 0.4*VTT V
VIH Input High Voltage: PREQ_N 0.8*VTT V
VOL Output Low Voltage 0.2*VTT V
VHysteresis Hysteresis 0.1*VTT V
RON Buffer On Resistance
BPM_N[7:0], PRDY_N, TDO 414Ω
IIL Input Leakage Current 50 200 μA
Input Edge Rate
Signals: BPM_N[7:0], EAR_N, PREQ_N, TCK,
TDI, TMS, TRST_N
0.05 V/ns 1, 2
Output Edge Rate (50 ohm to VTT)
Signal: BPM_N[7:0], PRDY_N, TDO 0.2 1.5 V/ns 1
Table 7-20. Serial VID Interface (SVID) DC Specifications (Sheet 1 of 2)
Symbol Parameter Min Typ Max Units Notes
VTT CPU I/O Voltage VTT - 3% 1.0 VTT + 3% V
VIL Input Low Vo ltage
Signals SVIDDATA, SVIDALERT_N 0.4*VTT V1
VIH Input High Voltage
Signals SVIDDATA, SVIDALERT_N 0.7*VTT V1
VOL Output Low Voltage
Signals SVIDCLK, SVIDDATA 0.3*VTT V1
VHysteresis Hysteresis 0.05*VTT V1
RON Buffer On Resistance
Signals SVIDCLK, SVIDDATA 414Ω2
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Electrical Specifications
Notes:
1. VTT refers to instantaneous VTT.
2. Measured at 0.31*VTT
3. Vin between 0V and VTT
4. These are measured b etween VIL and VIH.
5. The signal edge rate must be met or the signal must transition monotonically to the asserted state.
Notes:
1. This table applies to the processor sideband and miscellaneous signals specified in Table 7-5.
2. Unless otherwise noted, all specifications in this table apply to all processor frequencies.
3. These signals are measured between VIL and VIH.
IIL Input Leakage Current +/-50 +/-200 μA3,4
Input Edge Rate
Signal: SVIDALERT_N 0.05 V/ns 5, 6
Output Edge Rate (50 ohm to VTT)0.20 1.5V/ns5
Table 7-21. Processor Asynchronous Sideband DC Specifications
Symbol Parameter Min Max Units Notes
CMOS1.0v Signals
VIL_CMOS1.0v Input Low Voltage 0.3*VTT V1,2
VIH_CMOS1.0v Input High Voltage 0.7*VTT V1,2
VHysteresis Hysteresis 0.1*VTT V1,2
IIL_CMOS1.0v Input Leakage Current 50 200 μA1,2
Open Drain CMOS (ODCMOS) Signals
VIL_ODCMOS Input Low Voltage
Signals:
MEM_HOT_C01/23_N,
PROCHOT_N
0.3*VTT V1,2
VIL_ODCMOS Input Low Voltage
Signals: CAT_ERR_N 0.4*VTT V1,2
VIH_ODCMOS Input High Voltage 0.7*V TT V1,2
VOL_ODCMOS Output Low Voltage 0.2*VTT V1,2
VHysteresis Hysteresis
Signals:
MEM_HOT_C01/23_N,
PROCHOT_N
0.1*VTT V1,2
VHysteresis Hysteresis
Signal: CAT_ERR_N 0.05*VTT V1,2
ILeak Input Leakage Current 50 200 μA
RON Buffer On Resistance 4 14 Ω1,2
Output Edge Rate
Signal:MEM_HOT_C{01/23}_
N, ERROR_N[2:0],
THERMTRIP, PROCHOT_N
0.05 0.60 V/ns 3
Output Edge Rate
Signal: CAT_ERR_N 0.2 1.5 V/ns 3
Table 7-20. Serial VID Interface (SVID) DC Specifications (Sheet 2 of 2)
Symbol Parameter Min Typ Max Units Notes
Electrical Specifications
154 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Notes:
1. IVT_ID_N land is pulled to ground pulled to ground on the package.
7.8.3.1 PCI Express* DC Specifications
The processor DC specifications for the PCI Express* are available in the PCI Express
Base Specification - Revision 3.0. This document will provide only the processor
exceptions to the PCI Express Base Specification - Revision 3.0.
7.8.3.2 DMI2/PCI Express* DC Specifications
The processor DC specifications for the DMI2/PCI Express* are available in the PCI
Express Base Specification 2.0 and 1.0. This document will provide only the processor
exceptions to the PCI Express Base Specification 2. 0 and 1.0.
7.8.3.3 Intel® QuickPath Interconnect DC Specifications
Intel QuickPath Interconn ect specifications are defined at the processor lands. In most
cases, termination resistors are not required as these are integr ated into the processor
silicon.
7.8.3.4 Reset and Miscellaneous Signal DC Specifications
For a power-on Reset, RESET_N must stay active for at least 3.5 millisecond after VCC
and BCLK{0/1} have reached their proper specifications. RESET_N must not be kept
asserted for more than 100 ms while PWRGOOD is asserted. RESET_N must be held
asserted for at least 3.5 millisecond before it is deasserted again. RESET_N must be
held asserted before PWRGOOD is asserted. This signal does not have on-die
termination and must be terminated on the system board.
Table 7-22. Miscellaneous Signals DC Specifications
Symbol Parameter Min Typical Max Units Notes
IVT_ID_N Signal
VO_ABS_MAX Output Absolute Max Voltage 1.10 1.80 V 1
IOOutput Current 0 μA1, 3
SKTOCC_N Signal
VO_ABS_MAX Output Absolute Max Voltage 3.30 3.50 V 1
IOMAX Output Max Current 1 mA 2
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 155
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Electrical Specifications
Figure 7-6. BCLK{0/1} Differential Clock Crosspoint Specification
Figure 7-7. BCLK{0/1} Differential Clock Measurement Point for Ringback
Figure 7-8. BCLK{0/1} Single Ended Clock Measurem ent Points for Absolute Cross Point
and Swing
660 670 680 690 700 710 720 730 740 750 760 770 780 790 800 810 820 830 840 850
200
250
300
350
400
450
500
550
600
650
VHavg (m V)
Crossing Point (m V)
550 mV
250 mV
250 + 0.5 (V H avg - 700)
550 + 0.5 (VHavg - 700)
0.0V
VIH = +150 mV
VIL = -150 mV
VRB = + 100 m V
VRB = -100 mV
T STABLE
T STABLE
VRB-Differential
REFCLK + VRB-Differential
VCROSS MAX = 550m V
VCROSS M IN = 250m V
BCLK_DN
BCLK_DP
VMIN = -0.30V
VMAX = 1.40V
Electrical Specifications
156 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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7.9 Signal Quality
Data transfer requires the clean reception of data signals and clock signals. Ringing
below receiver thresholds, non-monotonic signal edges, and ex cessive voltage swings
will adversely affect system timings. Ringback and signal non-monotonicity cannot be
tolerated since these phenomena may inadvertently advance receiver state machines.
Excessive signal swings (overshoot and undershoot) are detrimental to silicon gate
oxide integrity, and can cause device failure if absolute voltage limits are exceeded.
Overshoot and undershoot can also cause timing degradation due to the build up of
inter-symbol interference (ISI) effects.
For these reasons, it is crucial that the designer work towards a solution that provides
acceptable signal quality across all systematic variations encountered in volume
manufacturing.
This section documents signal quality metrics used to derive topology and routing
guidelines through simulation. All specifications are specified at the processor die (pad
measurements).
Specifications for signal quality are for measurements at the processor core only and
are only observable through simulation. Theref ore, proper simulation is the only way to
verify proper timing and signal quality.
7.9.1 DDR3 Signal Quality Specifications
Overshoot (or undershoot) is the absolute value of the maximum voltage above or
below VSS. The overshoot/undershoot specifications limit transitions beyond specified
maximum voltages or VSS due to the fast signal edge rates. The processor can be
damaged by single and/or repeated overshoot or undershoot events on any input,
output, or I/O buffer if the charge is large enough (that is, if the over/undershoot is
great enough). Baseboard designs which meet signal integrity and timing requirements
and which do not exceed the maximum overshoot or undershoot limits listed in
Table 7-23 will insure reliable IO performance for the lifetime of the processor.
7.9.2 I/O Signal Quality Specifications
Signal Quality specifications for PCIe Signals are included as part of the PCIe DC
specifications.
7.9.3 Intel® QuickPath Interconnect Signal Quality
Specifications
Signal Quality specifications for Differential Intel® QuickPath Interconnect Signals are
included as part of the Intel QuickPath Interconnect signal quality specifications.
Various scenarios have been simulated to generate a set of layout guidelines.
7.9.4 Input Reference Clock Signal Quality Specifications
Overshoot/Undershoot and Ringback specifications for BCLK{0/1}_D[N/P] are found in
Table 7-23. Overshoot/Undershoot and Ringback specifications for the DDR3 R eference
Clocks are specified by the DIMM.
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Electrical Specifications
7.9.5 Overshoot/Undershoot Tolerance
Overshoot (or undershoot) is the absolute value of the maximum voltage above or
below VSS, see Figure 7-9. The overshoot/undershoot specifications limit transitions
beyond VCCD or VSS due to the fast signal edge rates. The processor can be damaged
by single and/or repeated overshoot or undershoot events on any input, output, or I/O
buffer if the charge is large enough (that is, if the over/undershoot is great enough).
Determining the impact of an overshoot/undershoot condition requires knowledge of
the magnitude, the pulse direction, and the activity factor (AF). Permanent damage to
the processor is the likely result of excessive overshoot/undershoot.
Baseboard designs which meet signal integrity and timing requirements and which do
not exceed the maximu m overshoot or undershoot limits listed in Table 7-23 will insure
reliable IO performance for the lifetime of the processor.
Notes:
1. These specifications are measured at the processor pad.
2. Refer to Figure 7-9 for description of allowable Overshoot/Undersho ot magnitude and duration.
3. TCH is the minimum high pulse width duration.
4. For PWRGOOD DC specifications see Table 7-21.
7.9.5.1 Overshoot/Undershoot Magnitude
Overshoot/Undershoot magnitude describes the maximum potential difference between
a signal and its voltage reference level. For the processor, both overshoot and
undershoot magnitude are referenced to VSS. It is im portant to note that the o vershoot
and undershoot conditions are separate and their impact must be determined
independently.
The pulse magnitude and duration, and activit y factor must be used to determine if the
overshoot/undershoot pulse is within specifications.
7.9.5.2 Overshoot/Undershoot Pulse Duration
Overshoot/undershoot pulse duration describes the total amount of time that an
overshoot/undershoot event exceeds the overshoot/undershoot reference voltage. The
total time could encompass several oscillations above the reference voltage. Multiple
overshoot/undershoot pulses within a single overshoot/undershoot event may need to
be measured to determine the total pulse duration.
Note: Oscillations below the reference voltage cannot be subtracted from the total
overshoot/undershoot pulse dur ation.
7.9.5.3 Activity Factor
Activity factor (AF) describes the frequency of overshoot (or undershoot) occurrence
relative to a clock. Since the highest frequency of assertion of any common clock signal
is every other clock, an AF = 0.1 indicates that the specific overshoot (or undershoot)
waveform occurs every other clock cycle.
Table 7-23. Processor I/O Overshoot/Under shoot Specifications
Signal Group Minimum
Undershoot Maximum
Overshoot Overshoot
Duration Undershoot
Duration Notes
Intel QuickPath Interconnect -0.2 * VTT 1.2 * VTT 39 ps 15 ps 1,2
DDR3 -0.2 * VCCD 1.2 * VCCD 0.25*TCH 0.1*TCH 1,2,3
System Reference Clock (BCLK{0/1}) -0.3V 1.15V N/A N/A 1,2
PWRGOOD Signal -0.420V VTT + 0.28 N/A N/A 4
Electrical Specifications
158 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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The specification provided in the table show s the maximum pulse duration allowed for a
given overshoot/undershoot magnitude at a specific activity factor. Each table entry is
independent of all others, meaning that the pulse duration reflects the ex istence of
overshoot/undershoot events of that magnitude ONLY. A platform with an
overshoot/undershoot that just meets the pulse duration for a specific magnitude
where the AF < 0.1, means that there can be no other overshoot/undershoot events,
even of lesser magnitude (note that if AF = 0.1, then the event occurs at all times and
no other events can occur).
7.9.5.4 Reading Overshoot/Undershoot Specification Tables
The overshoo t/undersho ot specification for the processor is not a simple single value.
Instead, many factors are needed to determine the over/undershoot specification. In
addition to the magnitude of the overshoot, the following parameters must also be
known: the width of the overshoot and the activity factor (AF). To determine the
allowed overshoot for a particular overshoot event, the following must be done:
1. Determine the signal group a particular signal falls into.
2. Determine the magnitude of the overshoot or the undershoot (relative to VSS).
3. Determine the activity factor (How often does this overshoot occur?).
4. Next, from the appropriate specification table, determine the maximum pulse
duration (in nanoseconds) allowed.
5. Compare the specified maximum pulse duration to the signal being measured. If
the pulse duration measured is less than the pulse duration shown in the table,
then the signal meets the specifications.
Undershoot events must be analyzed separately from overshoot events as they are
mutually exclusive.
7.9.5.5 Determining if a System Meets the Overshoot/Undershoot
Specifications
The overshoot/undershoot specifications listed in the table specify the allowable
overshoot/undersh oot for a single overshoot/undershoot event. However most systems
will have multiple overshoot and/o r undershoot even ts that each have their own set of
parameters (duration, AF and magnitude). While each overshoot on its own may meet
the overshoot specification, when you add the total impact of all ov ershoot ev ents, the
system may fail. A guideline to ensure a system passes the overshoot and undershoot
specifications is shown below.
1. If only one overshoot/undershoot event magnitude occurs, ensure it meets the
over/undershoot specifications in the following tables, OR
2. If multiple overshoots and/or multiple undershoots occur, measure the worst case
pulse duration for each magnitude and compare the results against the AF = 0.1
specifications. If all of these worst case overshoot or undershoot events meet the
specifications (measured time < specifications) in the table (where AF= 0.1), then
the system passes.
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Electrical Specifications
§
Table 7-24. Processor Sideband Signal Group Overshoot/Undershoot Tolerance
Absolute Maximum Overshoot
(V) Absolute Maximum Undershoot
(V) Pulse Duration (ns)
AF=0.1 Pulse Duration (ns)
AF=0.01
1.3335 V 0.2835 V 3 ns 5 ns
1.2600 V 0.210 V 5 ns 5 ns
Figure 7-9. Maximum Acceptable Overshoot/Undershoot Waveform
VSS
Over Shoot
Under Shoot
Over Shoot
Duration Under Shoot
Duration
Electrical Specifications
160 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Processor Land Listing
8Processor Land Listing
This chapter provides sorted land list in Section 8.1 and Section 8.2. Table 8-1 is a
listing of all processor lands ordered alphabetically by land name. Table 8-2 is a listing
of all processor lands ordered by land number.
8.1 Listing by Land Name
Table 8-1. Land Name (Sheet 1 of 50)
Land Name Land No. Buffer Type Direction
BCLK0_DN CM44 CMOS I
BCLK0_DP CN43 CMOS I
BCLK1_DN BA45 CMOS I
BCLK1_DP AW45 CMOS I
BIST_ENABLE AT48 CMOS I
BMCINIT AL47 CMOS I
BPM_N[0] AR43 ODCMOS I/O
BPM_N[1] AT44 ODCMOS I/O
BPM_N[2] AU43 ODCMOS I/O
BPM_N[3] AV44 ODCMOS I/O
BPM_N[4] BB44 ODCMOS I/O
BPM_N[5] AW43 ODCMOS I/O
BPM_N[6] BA43 ODCMOS I/O
BPM_N[7] AY44 ODCMOS I/O
CAT_ERR_N CC51 ODCMOS I/O
CPU_ONLY_RESET AN43 ODCMOS I/O
DDR_RESET_C01_N CB18 CMOS1.5v O
DDR_RESET_C23_N AE27 CMOS1.5v O
DDR_SCL_C01 CY42 ODCMOS I/O
DDR_SCL_C23 U43 ODCMOS I/O
DDR_SDA_C01 CW41 ODCMOS I/O
DDR_SDA_C23 R43 ODCMOS I/O
DDR_VREFDQRX_C0
1BY16 DC I
DDR_VREFDQRX_C2
3J1 DC I
DDR_VREFDQTX_C01 CN41 DC O
DDR_VREFDQTX_C23 P42 DC O
DDR0_BA[0] CM28 SSTL O
DDR0_BA[1] CN27 SSTL O
DDR0_BA[2] CM20 SSTL O
DDR0_CAS_N CL29 SSTL O
DDR0_CKE[0] CL19 SSTL O
DDR0_CKE[1] CM18 SSTL O
DDR0_CKE[2] CH20 SSTL O
DDR0_CKE[3] CP18 SSTL O
DDR0_CKE[4] CF20 SSTL O
DDR0_CKE[5] CE19 SSTL O
DDR0_CLK_DN[0] CF24 SSTL O
DDR0_CLK_DN[1] CE23 SSTL O
DDR0_CLK_DN[2] CE21 SSTL O
DDR0_CLK_DN[3] CF22 SSTL O
DDR0_CLK_DP[0] CH24 SSTL O
DDR0_CLK_DP[1] CG23 SSTL O
DDR0_CLK_DP[2] CG21 SSTL O
DDR0_CLK_DP[3] CH22 SSTL O
DDR0_CS_N[0] CN25 SSTL O
DDR0_CS_N[1] CH26 SSTL O
DDR0_CS_N[2] CC23 SSTL O
DDR0_CS_N[3] CB28 SSTL O
DDR0_CS_N[4] CG27 SSTL O
DDR0_CS_N[5] CF26 SSTL O
DDR0_CS_N[6] CB26 SSTL O
DDR0_CS_N[7] CC25 SSTL O
DDR0_CS_N[8] CL27 SSTL O
DDR0_CS_N[9] CK28 SSTL O
DDR0_DQ[00] CC7 SSTL I/O
DDR0_DQ[01] CD8 SSTL I/O
DDR0_DQ[02] CK8 SSTL I/O
DDR0_DQ[03] CL9 SSTL I/O
DDR0_DQ[04] BY6 SSTL I/O
DDR0_DQ[05] CA7 SSTL I/O
DDR0_DQ[06] CJ7 SSTL I/O
DDR0_DQ[07] CL7 SSTL I/O
DDR0_DQ[08] CB2 SSTL I/O
DDR0_DQ[09] CB4 SSTL I/O
Table 8-1. Land Name (Sheet 2 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
162 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
DDR0_DQ[10] CH4 SSTL I/O
DDR0_DQ[11] CJ5 SSTL I/O
DDR0_DQ[12] CA1 SSTL I/O
DDR0_DQ[13] CA3 SSTL I/O
DDR0_DQ[14] CG3 SSTL I/O
DDR0_DQ[15] CG5 SSTL I/O
DDR0_DQ[16] CK12 SSTL I/O
DDR0_DQ[17] CM12 SSTL I/O
DDR0_DQ[18] CK16 SSTL I/O
DDR0_DQ[19] CM16 SSTL I/O
DDR0_DQ[20] CG13 SSTL I/O
DDR0_DQ[21] CL11 SSTL I/O
DDR0_DQ[22] CJ15 SSTL I/O
DDR0_DQ[23] CL15 SSTL I/O
DDR0_DQ[24] BY10 SSTL I/O
DDR0_DQ[25] BY12 SSTL I/O
DDR0_DQ[26] CB12 SSTL I/O
DDR0_DQ[27] CD12 SSTL I/O
DDR0_DQ[28] BW9 SSTL I/O
DDR0_DQ[29] CA9 SSTL I/O
DDR0_DQ[30] CH10 SSTL I/O
DDR0_DQ[31] CF10 SSTL I/O
DDR0_DQ[32] CE31 SSTL I/O
DDR0_DQ[33] CC31 SSTL I/O
DDR0_DQ[34] CE35 SSTL I/O
DDR0_DQ[35] CC35 SSTL I/O
DDR0_DQ[36] CD30 SSTL I/O
DDR0_DQ[37] CB30 SSTL I/O
DDR0_DQ[38] CD34 SSTL I/O
DDR0_DQ[39] CB34 SSTL I/O
DDR0_DQ[40] CL31 SSTL I/O
DDR0_DQ[41] CJ31 SSTL I/O
DDR0_DQ[42] CL35 SSTL I/O
DDR0_DQ[43] CJ35 SSTL I/O
DDR0_DQ[44] CK30 SSTL I/O
DDR0_DQ[45] CH30 SSTL I/O
DDR0_DQ[46] CK34 SSTL I/O
DDR0_DQ[47] CH34 SSTL I/O
DDR0_DQ[48] CB38 SSTL I/O
DDR0_DQ[49] CD38 SSTL I/O
DDR0_DQ[50] CE41 SSTL I/O
DDR0_DQ[51] CD42 SSTL I/O
Table 8-1. Land Name (Sheet 3 of 50)
Land Name Land No. Buffer Type Direction
DDR0_DQ[52] CC37 SSTL I/O
DDR0_DQ[53] CE37 SSTL I/O
DDR0_DQ[54] CC41 SSTL I/O
DDR0_DQ[55] CB42 SSTL I/O
DDR0_DQ[56] CH38 SSTL I/O
DDR0_DQ[57] CK38 SSTL I/O
DDR0_DQ[58] CH42 SSTL I/O
DDR0_DQ[59] CK42 SSTL I/O
DDR0_DQ[60] CJ37 SSTL I/O
DDR0_DQ[61] CL37 SSTL I/O
DDR0_DQ[62] CJ41 SSTL I/O
DDR0_DQ[63] CL41 SSTL I/O
DDR0_DQS_DN[00] CG7 SSTL I/O
DDR0_DQS_DN[01] CE3 SSTL I/O
DDR0_DQS_DN[02] CH14 SSTL I/O
DDR0_DQS_DN[03] CD10 SSTL I/O
DDR0_DQS_DN[04] CE33 SSTL I/O
DDR0_DQS_DN[05] CL33 SSTL I/O
DDR0_DQS_DN[06] CB40 SSTL I/O
DDR0_DQS_DN[07] CH40 SSTL I/O
DDR0_DQS_DN[08] CE17 SSTL I/O
DDR0_DQS_DN[09] CF8 SSTL I/O
DDR0_DQS_DN[10] CD4 SSTL I/O
DDR0_DQS_DN[11] CL13 SSTL I/O
DDR0_DQS_DN[12] CC11 SSTL I/O
DDR0_DQS_DN[13] CB32 SSTL I/O
DDR0_DQS_DN[14] CH32 SSTL I/O
DDR0_DQS_DN[15] CE39 SSTL I/O
DDR0_DQS_DN[16] CL39 SSTL I/O
DDR0_DQS_DN[17] CF16 SSTL I/O
DDR0_DQS_DP[00] CH8 SSTL I/O
DDR0_DQS_DP[01] CF4 SSTL I/O
DDR0_DQS_DP[02] CK14 SSTL I/O
DDR0_DQS_DP[03] CE11 SSTL I/O
DDR0_DQS_DP[04] CC33 SSTL I/O
DDR0_DQS_DP[05] CJ33 SSTL I/O
DDR0_DQS_DP[06] CD40 SSTL I/O
DDR0_DQS_DP[07] CK40 SSTL I/O
DDR0_DQS_DP[08] CC17 SSTL I/O
DDR0_DQS_DP[09] CE7 SSTL I/O
DDR0_DQS_DP[10] CC5 SSTL I/O
DDR0_DQS_DP[11] CJ13 SSTL I/O
Table 8-1. Land Name (Sheet 4 of 50)
Land Name Land No. Buffer Type Direction
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Processor Land Listing
DDR0_DQS_DP[12] CB10 SSTL I/O
DDR0_DQS_DP[13] CD32 SSTL I/O
DDR0_DQS_DP[14] CK32 SSTL I/O
DDR0_DQS_DP[15] CC39 SSTL I/O
DDR0_DQS_DP[16] CJ39 SSTL I/O
DDR0_DQS_DP[17] CD16 SSTL I/O
DDR0_ECC[0] CE15 SSTL I/O
DDR0_ECC[1] CC15 SSTL I/O
DDR0_ECC[2] CH18 SSTL I/O
DDR0_ECC[3] CF18 SSTL I/O
DDR0_ECC[4] CB14 SSTL I/O
DDR0_ECC[5] CD14 SSTL I/O
DDR0_ECC[6] CG17 SSTL I/O
DDR0_ECC[7] CK18 SSTL I/O
DDR0_MA_PAR CM26 SSTL O
DDR0_MA[00] CL25 SSTL O
DDR0_MA[01] CR25 SSTL O
DDR0_MA[02] CG25 SSTL O
DDR0_MA[03] CK24 SSTL O
DDR0_MA[04] CM24 SSTL O
DDR0_MA[05] CL23 SSTL O
DDR0_MA[06] CN23 SSTL O
DDR0_MA[07] CM22 SSTL O
DDR0_MA[08] CK22 SSTL O
DDR0_MA[09] CN21 SSTL O
DDR0_MA[10] CK26 SSTL O
DDR0_MA[11] CL21 SSTL O
DDR0_MA[12] CK20 SSTL O
DDR0_MA[13] CG29 SSTL O
DDR0_MA[14] CG19 SSTL O
DDR0_MA[15] CN19 SSTL O
DDR0_ODT[0] CE25 SSTL O
DDR0_ODT[1] CE27 SSTL O
DDR0_ODT[2] CH28 SSTL O
DDR0_ODT[3] CF28 SSTL O
DDR0_ODT[4] CB24 SSTL O
DDR0_ODT[5] CC27 SSTL O
DDR0_PAR_ERR_N CC21 SSTL I
DDR0_RAS_N CE29 SSTL O
DDR0_WE_N CN29 SSTL O
DDR01_RCOMP[0] CA17 Analog I
DDR01_RCOMP[1] CC19 Analog I
Table 8-1. Land Name (Sheet 5 of 50)
Land Name Land No. Buffer Type Direction
DDR01_RCOMP[2] CB20 Analog I
DDR1_BA[0] DB26 SSTL O
DDR1_BA[1] DC25 SSTL O
DDR1_BA[2] DF18 SSTL O
DDR1_CAS_N CY30 SSTL O
DDR1_CKE[0] CT20 SSTL O
DDR1_CKE[1] CU19 SSTL O
DDR1_CKE[2] CY18 SSTL O
DDR1_CKE[3] DA17 SSTL O
DDR1_CKE[4] CR19 SSTL O
DDR1_CKE[5] CT18 SSTL O
DDR1_CLK_DN[0] CV20 SSTL O
DDR1_CLK_DN[1] CV22 SSTL O
DDR1_CLK_DN[2] CY24 SSTL O
DDR1_CLK_DN[3] DA21 SSTL O
DDR1_CLK_DP[0] CY20 SSTL O
DDR1_CLK_DP[1] CY22 SSTL O
DDR1_CLK_DP[2] CV24 SSTL O
DDR1_CLK_DP[3] DC21 SSTL O
DDR1_CS_N[0] DB24 SSTL O
DDR1_CS_N[1] CU23 SSTL O
DDR1_CS_N[2] CR23 SSTL O
DDR1_CS_N[3] CR27 SSTL O
DDR1_CS_N[4] CU25 SSTL O
DDR1_CS_N[5] CT24 SSTL O
DDR1_CS_N[6] DA29 SSTL O
DDR1_CS_N[7] CT26 SSTL O
DDR1_CS_N[8] CR21 SSTL O
DDR1_CS_N[9] DA27 SSTL O
DDR1_DQ[00] CP4 SSTL I/O
DDR1_DQ[01] CP2 SSTL I/O
DDR1_DQ[02] CV4 SSTL I/O
DDR1_DQ[03] CY4 SSTL I/O
DDR1_DQ[04] CM4 SSTL I/O
DDR1_DQ[05] CL3 SSTL I/O
DDR1_DQ[06] CV2 SSTL I/O
DDR1_DQ[07] CW3 SSTL I/O
DDR1_DQ[08] DA7 SSTL I/O
DDR1_DQ[09] DC7 SSTL I/O
DDR1_DQ[10] DC11 SSTL I/O
DDR1_DQ[11] DE11 SSTL I/O
DDR1_DQ[12] CY6 SSTL I/O
Table 8-1. Land Name (Sheet 6 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
164 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
DDR1_DQ[13] DB6 SSTL I/O
DDR1_DQ[14] DB10 SSTL I/O
DDR1_DQ[15] DF10 SSTL I/O
DDR1_DQ[16] CR7 SSTL I/O
DDR1_DQ[17] CU7 SSTL I/O
DDR1_DQ[18] CT10 SSTL I/O
DDR1_DQ[19] CP10 SSTL I/O
DDR1_DQ[20] CP6 SSTL I/O
DDR1_DQ[21] CT6 SSTL I/O
DDR1_DQ[22] CW9 SSTL I/O
DDR1_DQ[23] CV10 SSTL I/O
DDR1_DQ[24] CR13 SSTL I/O
DDR1_DQ[25] CU13 SSTL I/O
DDR1_DQ[26] CR17 SSTL I/O
DDR1_DQ[27] CU17 SSTL I/O
DDR1_DQ[28] CT12 SSTL I/O
DDR1_DQ[29] CV12 SSTL I/O
DDR1_DQ[30] CT16 SSTL I/O
DDR1_DQ[31] CV16 SSTL I/O
DDR1_DQ[32] CT30 SSTL I/O
DDR1_DQ[33] CP30 SSTL I/O
DDR1_DQ[34] CT34 SSTL I/O
DDR1_DQ[35] CP34 SSTL I/O
DDR1_DQ[36] CU29 SSTL I/O
DDR1_DQ[37] CR29 SSTL I/O
DDR1_DQ[38] CU33 SSTL I/O
DDR1_DQ[39] CR33 SSTL I/O
DDR1_DQ[40] DA33 SSTL I/O
DDR1_DQ[41] DD32 SSTL I/O
DDR1_DQ[42] DC35 SSTL I/O
DDR1_DQ[43] DA35 SSTL I/O
DDR1_DQ[44] DA31 SSTL I/O
DDR1_DQ[45] CY32 SSTL I/O
DDR1_DQ[46] DF34 SSTL I/O
DDR1_DQ[47] DE35 SSTL I/O
DDR1_DQ[48] CR37 SSTL I/O
DDR1_DQ[49] CU37 SSTL I/O
DDR1_DQ[50] CR41 SSTL I/O
DDR1_DQ[51] CU41 SSTL I/O
DDR1_DQ[52] CT36 SSTL I/O
DDR1_DQ[53] CV36 SSTL I/O
DDR1_DQ[54] CT40 SSTL I/O
Table 8-1. Land Name (Sheet 7 of 50)
Land Name Land No. Buffer Type Direction
DDR1_DQ[55] CV40 SSTL I/O
DDR1_DQ[56] DE37 SSTL I/O
DDR1_DQ[57] DF38 SSTL I/O
DDR1_DQ[58] DD40 SSTL I/O
DDR1_DQ[59] DB40 SSTL I/O
DDR1_DQ[60] DA37 SSTL I/O
DDR1_DQ[61] DC37 SSTL I/O
DDR1_DQ[62] DA39 SSTL I/O
DDR1_DQ[63] DF40 SSTL I/O
DDR1_DQS_DN[00] CT4 SSTL I/O
DDR1_DQS_DN[01] DC9 SSTL I/O
DDR1_DQS_DN[02] CV8 SSTL I/O
DDR1_DQS_DN[03] CR15 SSTL I/O
DDR1_DQS_DN[04] CT32 SSTL I/O
DDR1_DQS_DN[05] CY34 SSTL I/O
DDR1_DQS_DN[06] CR39 SSTL I/O
DDR1_DQS_DN[07] DE39 SSTL I/O
DDR1_DQS_DN[08] DE15 SSTL I/O
DDR1_DQS_DN[09] CR1 SSTL I/O
DDR1_DQS_DN[10] DB8 SSTL I/O
DDR1_DQS_DN[11] CT8 SSTL I/O
DDR1_DQS_DN[12] CP14 SSTL I/O
DDR1_DQS_DN[13] CR31 SSTL I/O
DDR1_DQS_DN[14] DE33 SSTL I/O
DDR1_DQS_DN[15] CT38 SSTL I/O
DDR1_DQS_DN[16] CY38 SSTL I/O
DDR1_DQS_DN[17] DB14 SSTL I/O
DDR1_DQS_DP[00] CR3 SSTL I/O
DDR1_DQS_DP[01] DE9 SSTL I/O
DDR1_DQS_DP[02] CU9 SSTL I/O
DDR1_DQS_DP[03] CU15 SSTL I/O
DDR1_DQS_DP[04] CP32 SSTL I/O
DDR1_DQS_DP[05] DB34 SSTL I/O
DDR1_DQS_DP[06] CU39 SSTL I/O
DDR1_DQS_DP[07] DC39 SSTL I/O
DDR1_DQS_DP[08] DC15 SSTL I/O
DDR1_DQS_DP[09] CT2 SSTL I/O
DDR1_DQS_DP[10] DD8 SSTL I/O
DDR1_DQS_DP[11] CP8 SSTL I/O
DDR1_DQS_DP[12] CT14 SSTL I/O
DDR1_DQS_DP[13] CU31 SSTL I/O
DDR1_DQS_DP[14] DC33 SSTL I/O
Table 8-1. Land Name (Sheet 8 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 165
Datasheet Volume One of Two
Processor Land Listing
DDR1_DQS_DP[15] CP38 SSTL I/O
DDR1_DQS_DP[16] DB38 SSTL I/O
DDR1_DQS_DP[17] CY14 SSTL I/O
DDR1_ECC[0] DE13 SSTL I/O
DDR1_ECC[1] DF14 SSTL I/O
DDR1_ECC[2] DD16 SSTL I/O
DDR1_ECC[3] DB16 SSTL I/O
DDR1_ECC[4] DA13 SSTL I/O
DDR1_ECC[5] DC13 SSTL I/O
DDR1_ECC[6] DA15 SSTL I/O
DDR1_ECC[7] DF16 SSTL I/O
DDR1_MA_PAR DE25 SSTL O
DDR1_MA[00] DC23 SSTL O
DDR1_MA[01] DE23 SSTL O
DDR1_MA[02] DF24 SSTL O
DDR1_MA[03] DA23 SSTL O
DDR1_MA[04] DB22 SSTL O
DDR1_MA[05] DF22 SSTL O
DDR1_MA[06] DE21 SSTL O
DDR1_MA[07] DF20 SSTL O
DDR1_MA[08] DB20 SSTL O
DDR1_MA[09] DA19 SSTL O
DDR1_MA[10] DF26 SSTL O
DDR1_MA[11] DE19 SSTL O
DDR1_MA[12] DC19 SSTL O
DDR1_MA[13] DB30 SSTL O
DDR1_MA[14] DB18 SSTL O
DDR1_MA[15] DC17 SSTL O
DDR1_ODT[0] CT22 SSTL O
DDR1_ODT[1] DA25 SSTL O
DDR1_ODT[2] CY26 SSTL O
DDR1_ODT[3] CV26 SSTL O
DDR1_ODT[4] CU27 SSTL O
DDR1_ODT[5] CY28 SSTL O
DDR1_PAR_ERR_N CU21 SSTL I
DDR1_RAS_N DB28 SSTL O
DDR1_WE_N CV28 SSTL O
DDR2_BA[0] R17 SSTL O
DDR2_BA[1] L17 SSTL O
DDR2_BA[2] P24 SSTL O
DDR2_CAS_N T16 SSTL O
DDR2_CKE[0] AA25 SSTL O
Table 8-1. Land Name (Sheet 9 of 50)
Land Name Land No. Buffer Type Direction
DDR2_CKE[1] T26 SSTL O
DDR2_CKE[2] U27 SSTL O
DDR2_CKE[3] AD24 SSTL O
DDR2_CKE[4] AE25 SSTL O
DDR2_CKE[5] AE23 SSTL O
DDR2_CLK_DN[0] Y24 SSTL O
DDR2_CLK_DN[1] Y22 SSTL O
DDR2_CLK_DN[2] W21 SSTL O
DDR2_CLK_DN[3] W23 SSTL O
DDR2_CLK_DP[0] AB24 SSTL O
DDR2_CLK_DP[1] AB22 SSTL O
DDR2_CLK_DP[2] AA21 SSTL O
DDR2_CLK_DP[3] AA23 SSTL O
DDR2_CS_N[0] AB20 SSTL O
DDR2_CS_N[1] AE19 SSTL O
DDR2_CS_N[2] AD16 SSTL O
DDR2_CS_N[3] AA15 SSTL O
DDR2_CS_N[4] AA19 SSTL O
DDR2_CS_N[5] P18 SSTL O
DDR2_CS_N[6] AB16 SSTL O
DDR2_CS_N[7] Y16 SSTL O
DDR2_CS_N[8] W17 SSTL O
DDR2_CS_N[9] AA17 SSTL O
DDR2_DQ[00] T40 SSTL I/O
DDR2_DQ[01] V40 SSTL I/O
DDR2_DQ[02] P36 SSTL I/O
DDR2_DQ[03] T36 SSTL I/O
DDR2_DQ[04] R41 SSTL I/O
DDR2_DQ[05] U41 SSTL I/O
DDR2_DQ[06] R37 SSTL I/O
DDR2_DQ[07] U37 SSTL I/O
DDR2_DQ[08] AE41 SSTL I/O
DDR2_DQ[09] AD40 SSTL I/O
DDR2_DQ[10] AA37 SSTL I/O
DDR2_DQ[11] AC37 SSTL I/O
DDR2_DQ[12] AC41 SSTL I/O
DDR2_DQ[13] AA41 SSTL I/O
DDR2_DQ[14] AF38 SSTL I/O
DDR2_DQ[15] AE37 SSTL I/O
DDR2_DQ[16] U33 SSTL I/O
DDR2_DQ[17] R33 SSTL I/O
DDR2_DQ[18] W29 SSTL I/O
Table 8-1. Land Name (Sheet 10 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
166 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
DDR2_DQ[19] U29 SSTL I/O
DDR2_DQ[20] T34 SSTL I/O
DDR2_DQ[21] P34 SSTL I/O
DDR2_DQ[22] V30 SSTL I/O
DDR2_DQ[23] T30 SSTL I/O
DDR2_DQ[24] AC35 SSTL I/O
DDR2_DQ[25] AE35 SSTL I/O
DDR2_DQ[26] AE33 SSTL I/O
DDR2_DQ[27] AF32 SSTL I/O
DDR2_DQ[28] AA35 SSTL I/O
DDR2_DQ[29] W35 SSTL I/O
DDR2_DQ[30] AB32 SSTL I/O
DDR2_DQ[31] AD32 SSTL I/O
DDR2_DQ[32] AC13 SSTL I/O
DDR2_DQ[33] AE13 SSTL I/O
DDR2_DQ[34] AG11 SSTL I/O
DDR2_DQ[35] AF10 SSTL I/O
DDR2_DQ[36] AD14 SSTL I/O
DDR2_DQ[37] AA13 SSTL I/O
DDR2_DQ[38] AB10 SSTL I/O
DDR2_DQ[39] AD10 SSTL I/O
DDR2_DQ[40] V6 SSTL I/O
DDR2_DQ[41] Y6 SSTL I/O
DDR2_DQ[42] AF8 SSTL I/O
DDR2_DQ[43] AG7 SSTL I/O
DDR2_DQ[44] U7 SSTL I/O
DDR2_DQ[45] W7 SSTL I/O
DDR2_DQ[46] AD8 SSTL I/O
DDR2_DQ[47] AE7 SSTL I/O
DDR2_DQ[48] R13 SSTL I/O
DDR2_DQ[49] U13 SSTL I/O
DDR2_DQ[50] T10 SSTL I/O
DDR2_DQ[51] V10 SSTL I/O
DDR2_DQ[52] T14 SSTL I/O
DDR2_DQ[53] V14 SSTL I/O
DDR2_DQ[54] R9 SSTL I/O
DDR2_DQ[55] U9 SSTL I/O
DDR2_DQ[56] W3 SSTL I/O
DDR2_DQ[57] Y4 SSTL I/O
DDR2_DQ[58] AF4 SSTL I/O
DDR2_DQ[59] AE5 SSTL I/O
DDR2_DQ[60] U3 SSTL I/O
Table 8-1. Land Name (Sheet 11 of 50)
Land Name Land No. Buffer Type Direction
DDR2_DQ[61] V4 SSTL I/O
DDR2_DQ[62] AF2 SSTL I/O
DDR2_DQ[63] AE3 SSTL I/O
DDR2_DQS_DN[00] T38 SSTL I/O
DDR2_DQS_DN[01] AD38 SSTL I/O
DDR2_DQS_DN[02] W31 SSTL I/O
DDR2_DQS_DN[03] AA33 SSTL I/O
DDR2_DQS_DN[04] AC11 SSTL I/O
DDR2_DQS_DN[05] AB8 SSTL I/O
DDR2_DQS_DN[06] U11 SSTL I/O
DDR2_DQS_DN[07] AC3 SSTL I/O
DDR2_DQS_DN[08] AB28 SSTL I/O
DDR2_DQS_DN[09] W39 SSTL I/O
DDR2_DQS_DN[10] AC39 SSTL I/O
DDR2_DQS_DN[11] T32 SSTL I/O
DDR2_DQS_DN[12] AB34 SSTL I/O
DDR2_DQS_DN[13] AD12 SSTL I/O
DDR2_DQS_DN[14] AA7 SSTL I/O
DDR2_DQS_DN[15] V12 SSTL I/O
DDR2_DQS_DN[16] AD4 SSTL I/O
DDR2_DQS_DN[17] AD28 SSTL I/O
DDR2_DQS_DP[00] V38 SSTL I/O
DDR2_DQS_DP[01] AB38 SSTL I/O
DDR2_DQS_DP[02] U31 SSTL I/O
DDR2_DQS_DP[03] AC33 SSTL I/O
DDR2_DQS_DP[04] AE11 SSTL I/O
DDR2_DQS_DP[05] AC7 SSTL I/O
DDR2_DQS_DP[06] W11 SSTL I/O
DDR2_DQS_DP[07] AB4 SSTL I/O
DDR2_DQS_DP[08] AC27 SSTL I/O
DDR2_DQS_DP[09] U39 SSTL I/O
DDR2_DQS_DP[10] AB40 SSTL I/O
DDR2_DQS_DP[11] V32 SSTL I/O
DDR2_DQS_DP[12] Y34 SSTL I/O
DDR2_DQS_DP[13] AB12 SSTL I/O
DDR2_DQS_DP[14] Y8 SSTL I/O
DDR2_DQS_DP[15] T12 SSTL I/O
DDR2_DQS_DP[16] AC5 SSTL I/O
DDR2_DQS_DP[17] AC29 SSTL I/O
DDR2_ECC[0] AF30 SSTL I/O
DDR2_ECC[1] AF28 SSTL I/O
DDR2_ECC[2] Y26 SSTL I/O
Table 8-1. Land Name (Sheet 12 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 167
Datasheet Volume One of Two
Processor Land Listing
DDR2_ECC[3] AB26 SSTL I/O
DDR2_ECC[4] AB30 SSTL I/O
DDR2_ECC[5] AD30 SSTL I/O
DDR2_ECC[6] W27 SSTL I/O
DDR2_ECC[7] AA27 SSTL I/O
DDR2_MA_PAR M18 SSTL O
DDR2_MA[00] AB18 SSTL O
DDR2_MA[01] R19 SSTL O
DDR2_MA[02] U19 SSTL O
DDR2_MA[03] T20 SSTL O
DDR2_MA[04] P20 SSTL O
DDR2_MA[05] U21 SSTL O
DDR2_MA[06] R21 SSTL O
DDR2_MA[07] P22 SSTL O
DDR2_MA[08] T22 SSTL O
DDR2_MA[09] R23 SSTL O
DDR2_MA[10] T18 SSTL O
DDR2_MA[11] U23 SSTL O
DDR2_MA[12] T24 SSTL O
DDR2_MA[13] R15 SSTL O
DDR2_MA[14] W25 SSTL O
DDR2_MA[15] U25 SSTL O
DDR2_ODT[0] Y20 SSTL O
DDR2_ODT[1] W19 SSTL O
DDR2_ODT[2] AD18 SSTL O
DDR2_ODT[3] Y18 SSTL O
DDR2_ODT[4] AD22 SSTL O
DDR2_ODT[5] AE21 SSTL O
DDR2_PAR_ERR_N AD20 SSTL I
DDR2_RAS_N U17 SSTL O
DDR2_WE_N P16 SSTL O
DDR23_RCOMP[0] U15 Analog I
DDR23_RCOMP[1] AC15 Analog I
DDR23_RCOMP[2] Y14 Analog I
DDR3_BA[0] A17 SSTL O
DDR3_BA[1] E19 SSTL O
DDR3_BA[2] B24 SSTL O
DDR3_CAS_N B14 SSTL O
DDR3_CKE[0] K24 SSTL O
DDR3_CKE[1] M24 SSTL O
DDR3_CKE[2] J25 SSTL O
DDR3_CKE[3] N25 SSTL O
Table 8-1. Land Name (Sheet 13 of 50)
Land Name Land No. Buffer Type Direction
DDR3_CKE[4] R25 SSTL O
DDR3_CKE[5] R27 SSTL O
DDR3_CLK_DN[0] J23 SSTL O
DDR3_CLK_DN[1] J21 SSTL O
DDR3_CLK_DN[2] M20 SSTL O
DDR3_CLK_DN[3] K22 SSTL O
DDR3_CLK_DP[0] L23 SSTL O
DDR3_CLK_DP[1] L21 SSTL O
DDR3_CLK_DP[2] K20 SSTL O
DDR3_CLK_DP[3] M22 SSTL O
DDR3_CS_N[0] G19 SSTL O
DDR3_CS_N[1] J19 SSTL O
DDR3_CS_N[2] F14 SSTL O
DDR3_CS_N[3] G15 SSTL O
DDR3_CS_N[4] K18 SSTL O
DDR3_CS_N[5] G17 SSTL O
DDR3_CS_N[6] F16 SSTL O
DDR3_CS_N[7] E15 SSTL O
DDR3_CS_N[8] D16 SSTL O
DDR3_CS_N[9] K16 SSTL O
DDR3_DQ[00] B40 SSTL I/O
DDR3_DQ[01] A39 SSTL I/O
DDR3_DQ[02] C37 SSTL I/O
DDR3_DQ[03] E37 SSTL I/O
DDR3_DQ[04] F40 SSTL I/O
DDR3_DQ[05] D40 SSTL I/O
DDR3_DQ[06] F38 SSTL I/O
DDR3_DQ[07] A37 SSTL I/O
DDR3_DQ[08] N39 SSTL I/O
DDR3_DQ[09] L39 SSTL I/O
DDR3_DQ[10] L35 SSTL I/O
DDR3_DQ[11] J35 SSTL I/O
DDR3_DQ[12] M40 SSTL I/O
DDR3_DQ[13] K40 SSTL I/O
DDR3_DQ[14] K36 SSTL I/O
DDR3_DQ[15] H36 SSTL I/O
DDR3_DQ[16] A35 SSTL I/O
DDR3_DQ[17] F34 SSTL I/O
DDR3_DQ[18] D32 SSTL I/O
DDR3_DQ[19] F32 SSTL I/O
DDR3_DQ[20] E35 SSTL I/O
DDR3_DQ[21] C35 SSTL I/O
Table 8-1. Land Name (Sheet 14 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
168 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
DDR3_DQ[22] A33 SSTL I/O
DDR3_DQ[23] B32 SSTL I/O
DDR3_DQ[24] M32 SSTL I/O
DDR3_DQ[25] L31 SSTL I/O
DDR3_DQ[26] M28 SSTL I/O
DDR3_DQ[27] L27 SSTL I/O
DDR3_DQ[28] L33 SSTL I/O
DDR3_DQ[29] K32 SSTL I/O
DDR3_DQ[30] N27 SSTL I/O
DDR3_DQ[31] M26 SSTL I/O
DDR3_DQ[32] D12 SSTL I/O
DDR3_DQ[33] A11 SSTL I/O
DDR3_DQ[34] C9 SSTL I/O
DDR3_DQ[35] E9 SSTL I/O
DDR3_DQ[36] F12 SSTL I/O
DDR3_DQ[37] B12 SSTL I/O
DDR3_DQ[38] F10 SSTL I/O
DDR3_DQ[39] A9 SSTL I/O
DDR3_DQ[40] J13 SSTL I/O
DDR3_DQ[41] L13 SSTL I/O
DDR3_DQ[42] J9 SSTL I/O
DDR3_DQ[43] L9 SSTL I/O
DDR3_DQ[44] K14 SSTL I/O
DDR3_DQ[45] M14 SSTL I/O
DDR3_DQ[46] K10 SSTL I/O
DDR3_DQ[47] M10 SSTL I/O
DDR3_DQ[48] E7 SSTL I/O
DDR3_DQ[49] F6 SSTL I/O
DDR3_DQ[50] N7 SSTL I/O
DDR3_DQ[51] P6 SSTL I/O
DDR3_DQ[52] C7 SSTL I/O
DDR3_DQ[53] D6 SSTL I/O
DDR3_DQ[54] L7 SSTL I/O
DDR3_DQ[55] M6 SSTL I/O
DDR3_DQ[56] G3 SSTL I/O
DDR3_DQ[57] H2 SSTL I/O
DDR3_DQ[58] N3 SSTL I/O
DDR3_DQ[59] P4 SSTL I/O
DDR3_DQ[60] F4 SSTL I/O
DDR3_DQ[61] H4 SSTL I/O
DDR3_DQ[62] L1 SSTL I/O
DDR3_DQ[63] M2 SSTL I/O
Table 8-1. Land Name (Sheet 15 of 50)
Land Name Land No. Buffer Type Direction
DDR3_DQS_DN[00] B38 SSTL I/O
DDR3_DQS_DN[01] L37 SSTL I/O
DDR3_DQS_DN[02] G33 SSTL I/O
DDR3_DQS_DN[03] P28 SSTL I/O
DDR3_DQS_DN[04] B10 SSTL I/O
DDR3_DQS_DN[05] L11 SSTL I/O
DDR3_DQS_DN[06] J7 SSTL I/O
DDR3_DQS_DN[07] L3 SSTL I/O
DDR3_DQS_DN[08] G27 SSTL I/O
DDR3_DQS_DN[09] G39 SSTL I/O
DDR3_DQS_DN[10] K38 SSTL I/O
DDR3_DQS_DN[11] B34 SSTL I/O
DDR3_DQS_DN[12] M30 SSTL I/O
DDR3_DQS_DN[13] G11 SSTL I/O
DDR3_DQS_DN[14] M12 SSTL I/O
DDR3_DQS_DN[15] H6 SSTL I/O
DDR3_DQS_DN[16] K4 SSTL I/O
DDR3_DQS_DN[17] H28 SSTL I/O
DDR3_DQS_DP[00] D38 SSTL I/O
DDR3_DQS_DP[01] J37 SSTL I/O
DDR3_DQS_DP[02] E33 SSTL I/O
DDR3_DQS_DP[03] N29 SSTL I/O
DDR3_DQS_DP[04] D10 SSTL I/O
DDR3_DQS_DP[05] N11 SSTL I/O
DDR3_DQS_DP[06] K6 SSTL I/O
DDR3_DQS_DP[07] M4 SSTL I/O
DDR3_DQS_DP[08] E27 SSTL I/O
DDR3_DQS_DP[09] E39 SSTL I/O
DDR3_DQS_DP[10] M38 SSTL I/O
DDR3_DQS_DP[11] D34 SSTL I/O
DDR3_DQS_DP[12] N31 SSTL I/O
DDR3_DQS_DP[13] E11 SSTL I/O
DDR3_DQS_DP[14] K12 SSTL I/O
DDR3_DQS_DP[15] G7 SSTL I/O
DDR3_DQS_DP[16] J3 SSTL I/O
DDR3_DQS_DP[17] F28 SSTL I/O
DDR3_ECC[0] G29 SSTL I/O
DDR3_ECC[1] J29 SSTL I/O
DDR3_ECC[2] E25 SSTL I/O
DDR3_ECC[3] C25 SSTL I/O
DDR3_ECC[4] F30 SSTL I/O
DDR3_ECC[5] H30 SSTL I/O
Table 8-1. Land Name (Sheet 16 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 169
Datasheet Volume One of Two
Processor Land Listing
DDR3_ECC[6] F26 SSTL I/O
DDR3_ECC[7] H26 SSTL I/O
DDR3_MA_PAR B18 SSTL O
DDR3_MA[00] A19 SSTL O
DDR3_MA[01] E21 SSTL O
DDR3_MA[02] F20 SSTL O
DDR3_MA[03] B20 SSTL O
DDR3_MA[04] D20 SSTL O
DDR3_MA[05] A21 SSTL O
DDR3_MA[06] F22 SSTL O
DDR3_MA[07] B22 SSTL O
DDR3_MA[08] D22 SSTL O
DDR3_MA[09] G23 SSTL O
DDR3_MA[10] D18 SSTL O
DDR3_MA[11] A23 SSTL O
DDR3_MA[12] E23 SSTL O
DDR3_MA[13] A13 SSTL O
DDR3_MA[14] D24 SSTL O
DDR3_MA[15] F24 SSTL O
DDR3_ODT[0] L19 SSTL O
DDR3_ODT[1] F18 SSTL O
DDR3_ODT[2] E17 SSTL O
DDR3_ODT[3] J17 SSTL O
DDR3_ODT[4] D14 SSTL O
DDR3_ODT[5] M16 SSTL O
DDR3_PAR_ERR_N G21 SSTL I
DDR3_RAS_N B16 SSTL O
DDR3_WE_N A15 SSTL O
DMI_RX_DN[0] E47 PCIEX I
DMI_RX_DN[1] D48 PCIEX I
DMI_RX_DN[2] E49 PCIEX I
DMI_RX_DN[3] D50 PCIEX I
DMI_RX_DP[0] C47 PCIEX I
DMI_RX_DP[1] B48 PCIEX I
DMI_RX_DP[2] C49 PCIEX I
DMI_RX_DP[3] B50 PCIEX I
DMI_TX_DN[0] D42 PCIEX O
DMI_TX_DN[1] E43 PCIEX O
DMI_TX_DN[2] D44 PCIEX O
DMI_TX_DN[3] E45 PCIEX O
DMI_TX_DP[0] B42 PCIEX O
DMI_TX_DP[1] C43 PCIEX O
Table 8-1. Land Name (Sheet 17 of 50)
Land Name Land No. Buffer Type Direction
DMI_TX_DP[2] B44 PCIEX O
DMI_TX_DP[3] C45 PCIEX O
TXT_PLTEN V52 CMOS I
DRAM_PWR_OK_C01 CW17 CMOS1.5v I
DRAM_PWR_OK_C23 L15 CMOS1.5v I
EAR_N CH56 ODCMOS I/O
ERROR_N[0] BD50 ODCMOS O
ERROR_N[1] CB54 ODCMOS O
ERROR_N[2] BC51 ODCMOS O
FRMAGENT AT50 CMOS I
IVT_ID_N AH42 O
TXT_AGENT AK52 CMOS I
MEM_HOT_C01_N CB22 ODCMOS I/O
MEM_HOT_C23_N E13 ODCMOS I/O
PE_RBIAS AH52 PCIEX3 I/O
PE_RBIAS_SENSE AF52 PCIEX3 I
PE_VREF_CAP AJ43 PCIEX3 I/O
PE1A_RX_DN[0] E51 PCIEX3 I
PE1A_RX_DN[1] F52 PCIEX3 I
PE1A_RX_DN[2] F54 PCIEX3 I
PE1A_RX_DN[3] G55 PCIEX3 I
PE1A_RX_DP[0] C51 PCIEX3 I
PE1A_RX_DP[1] D52 PCIEX3 I
PE1A_RX_DP[2] D54 PCIEX3 I
PE1A_RX_DP[3] E55 PCIEX3 I
PE1A_TX_DN[0] K42 PCIEX3 O
PE1A_TX_DN[1] L43 PCIEX3 O
PE1A_TX_DN[2] K44 PCIEX3 O
PE1A_TX_DN[3] L45 PCIEX3 O
PE1A_TX_DP[0] H42 PCIEX3 O
PE1A_TX_DP[1] J43 PCIEX3 O
PE1A_TX_DP[2] H44 PCIEX3 O
PE1A_TX_DP[3] J45 PCIEX3 O
PE1B_RX_DN[4] L53 PCIEX3 I
PE1B_RX_DN[5] M54 PCIEX3 I
PE1B_RX_DN[6] L57 PCIEX3 I
PE1B_RX_DN[7] M56 PCIEX3 I
PE1B_RX_DP[4] J53 PCIEX3 I
PE1B_RX_DP[5] K54 PCIEX3 I
PE1B_RX_DP[6] J57 PCIEX3 I
PE1B_RX_DP[7] K56 PCIEX3 I
PE1B_TX_DN[4] K46 PCIEX3 O
Table 8-1. Land Name (Sheet 18 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
170 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
PE1B_TX_DN[5] L47 PCIEX3 O
PE1B_TX_DN[6] K48 PCIEX3 O
PE1B_TX_DN[7] L49 PCIEX3 O
PE1B_TX_DP[4] H46 PCIEX3 O
PE1B_TX_DP[5] J47 PCIEX3 O
PE1B_TX_DP[6] H48 PCIEX3 O
PE1B_TX_DP[7] J49 PCIEX3 O
PE2A_RX_DN[0] N55 PCIEX3 I
PE2A_RX_DN[1] V54 PCIEX3 I
PE2A_RX_DN[2] V56 PCIEX3 I
PE2A_RX_DN[3] W55 PCIEX3 I
PE2A_RX_DP[0] L55 PCIEX3 I
PE2A_RX_DP[1] T54 PCIEX3 I
PE2A_RX_DP[2] T56 PCIEX3 I
PE2A_RX_DP[3] U55 PCIEX3 I
PE2A_TX_DN[0] AR49 PCIEX3 O
PE2A_TX_DN[1] AP50 PCIEX3 O
PE2A_TX_DN[2] AR51 PCIEX3 O
PE2A_TX_DN[3] AP52 PCIEX3 O
PE2A_TX_DP[0] AN49 PCIEX3 O
PE2A_TX_DP[1] AM50 PCIEX3 O
PE2A_TX_DP[2] AN51 PCIEX3 O
PE2A_TX_DP[3] AM52 PCIEX3 O
PE2B_RX_DN[4] AD54 PCIEX3 I
PE2B_RX_DN[5] AD56 PCIEX3 I
PE2B_RX_DN[6] AE55 PCIEX3 I
PE2B_RX_DN[7] AF58 PCIEX3 I
PE2B_RX_DP[4] AB54 PCIEX3 I
PE2B_RX_DP[5] AB56 PCIEX3 I
PE2B_RX_DP[6] AC55 PCIEX3 I
PE2B_RX_DP[7] AE57 PCIEX3 I
PE2B_TX_DN[4] AJ53 PCIEX3 O
PE2B_TX_DN[5] AK54 PCIEX3 O
PE2B_TX_DN[6] AR53 PCIEX3 O
PE2B_TX_DN[7] AT54 PCIEX3 O
PE2B_TX_DP[4] AG53 PCIEX3 O
PE2B_TX_DP[5] AH54 PCIEX3 O
PE2B_TX_DP[6] AN53 PCIEX3 O
PE2B_TX_DP[7] AP54 PCIEX3 O
PE2C_RX_DN[10] AL57 PCIEX3 I
PE2C_RX_DN[11] AU57 PCIEX3 I
PE2C_RX_DN[8] AK56 PCIEX3 I
Table 8-1. Land Name (Sheet 19 of 50)
Land Name Land No. Buffer Type Direction
PE2C_RX_DN[9] AM58 PCIEX3 I
PE2C_RX_DP[10] AJ57 PCIEX3 I
PE2C_RX_DP[11] AR57 PCIEX3 I
PE2C_RX_DP[8] AH56 PCIEX3 I
PE2C_RX_DP[9] AK58 PCIEX3 I
PE2C_TX_DN[10] BB54 PCIEX3 O
PE2C_TX_DN[11] BA51 PCIEX3 O
PE2C_TX_DN[8] AY52 PCIEX3 O
PE2C_TX_DN[9] BA53 PCIEX3 O
PE2C_TX_DP[10] AY54 PCIEX3 O
PE2C_TX_DP[11] AW51 PCIEX3 O
PE2C_TX_DP[8] AV52 PCIEX3 O
PE2C_TX_DP[9] AW53 PCIEX3 O
PE2D_RX_DN[12] AV58 PCIEX3 I
PE2D_RX_DN[13] AT56 PCIEX3 I
PE2D_RX_DN[14] BA57 PCIEX3 I
PE2D_RX_DN[15] BB56 PCIEX3 I
PE2D_RX_DP[12] AT58 PCIEX3 I
PE2D_RX_DP[13] AP56 PCIEX3 I
PE2D_RX_DP[14] AY58 PCIEX3 I
PE2D_RX_DP[15] AY56 PCIEX3 I
PE2D_TX_DN[12] AY50 PCIEX3 O
PE2D_TX_DN[13] BA49 PCIEX3 O
PE2D_TX_DN[14] AY48 PCIEX3 O
PE2D_TX_DN[15] BA47 PCIEX3 O
PE2D_TX_DP[12] AV50 PCIEX3 O
PE2D_TX_DP[13] AW49 PCIEX3 O
PE2D_TX_DP[14] AV48 PCIEX3 O
PE2D_TX_DP[15] AW47 PCIEX3 O
PE3A_RX_DN[0] AH44 PCIEX3 I
PE3A_RX_DN[1] AJ45 PCIEX3 I
PE3A_RX_DN[2] AH46 PCIEX3 I
PE3A_RX_DN[3] AC49 PCIEX3 I
PE3A_RX_DP[0] AF44 PCIEX3 I
PE3A_RX_DP[1] AG45 PCIEX3 I
PE3A_RX_DP[2] AF46 PCIEX3 I
PE3A_RX_DP[3] AA49 PCIEX3 I
PE3A_TX_DN[0] K50 PCIEX3 O
PE3A_TX_DN[1] L51 PCIEX3 O
PE3A_TX_DN[2] U47 PCIEX3 O
PE3A_TX_DN[3] T48 PCIEX3 O
PE3A_TX_DP[0] H50 PCIEX3 O
Table 8-1. Land Name (Sheet 20 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 171
Datasheet Volume One of Two
Processor Land Listing
PE3A_TX_DP[1] J51 PCIEX3 O
PE3A_TX_DP[2] R47 PCIEX3 O
PE3A_TX_DP[3] P48 PCIEX3 O
PE3B_RX_DN[4] AB50 PCIEX3 I
PE3B_RX_DN[5] AB52 PCIEX3 I
PE3B_RX_DN[6] AC53 PCIEX3 I
PE3B_RX_DN[7] AC51 PCIEX3 I
PE3B_RX_DP[4] Y50 PCIEX3 I
PE3B_RX_DP[5] Y52 PCIEX3 I
PE3B_RX_DP[6] AA53 PCIEX3 I
PE3B_RX_DP[7] AA51 PCIEX3 I
PE3B_TX_DN[4] T52 PCIEX3 O
PE3B_TX_DN[5] U51 PCIEX3 O
PE3B_TX_DN[6] T50 PCIEX3 O
PE3B_TX_DN[7] U49 PCIEX3 O
PE3B_TX_DP[4] P52 PCIEX3 O
PE3B_TX_DP[5] R51 PCIEX3 O
PE3B_TX_DP[6] P50 PCIEX3 O
PE3B_TX_DP[7] R49 PCIEX3 O
PE3C_RX_DN[10] AH50 PCIEX3 I
PE3C_RX_DN[11] AJ49 PCIEX3 I
PE3C_RX_DN[8] AH48 PCIEX3 I
PE3C_RX_DN[9] AJ51 PCIEX3 I
PE3C_RX_DP[10] AF50 PCIEX3 I
PE3C_RX_DP[11] AG49 PCIEX3 I
PE3C_RX_DP[8] AF48 PCIEX3 I
PE3C_RX_DP[9] AG51 PCIEX3 I
PE3C_TX_DN[10] U45 PCIEX3 O
PE3C_TX_DN[11] AB46 PCIEX3 O
PE3C_TX_DN[8] T46 PCIEX3 O
PE3C_TX_DN[9] AC47 PCIEX3 O
PE3C_TX_DP[10] R45 PCIEX3 O
PE3C_TX_DP[11] Y46 PCIEX3 O
PE3C_TX_DP[8] P46 PCIEX3 O
PE3C_TX_DP[9] AA47 PCIEX3 O
PE3D_RX_DN[12] AJ47 PCIEX3 I
PE3D_RX_DN[13] AR47 PCIEX3 I
PE3D_RX_DN[14] AP46 PCIEX3 I
PE3D_RX_DN[15] AR45 PCIEX3 I
PE3D_RX_DP[12] AG47 PCIEX3 I
PE3D_RX_DP[13] AN47 PCIEX3 I
PE3D_RX_DP[14] AM46 PCIEX3 I
Table 8-1. Land Name (Sheet 21 of 50)
Land Name Land No. Buffer Type Direction
PE3D_RX_DP[15] AN45 PCIEX3 I
PE3D_TX_DN[12] AC45 PCIEX3 O
PE3D_TX_DN[13] AB44 PCIEX3 O
PE3D_TX_DN[14] AA43 PCIEX3 O
PE3D_TX_DN[15] P44 PCIEX3 O
PE3D_TX_DP[12] AA45 PCIEX3 O
PE3D_TX_DP[13] Y44 PCIEX3 O
PE3D_TX_DP[14] AC43 PCIEX3 O
PE3D_TX_DP[15] T44 PCIEX3 O
PECI BJ47 PECI I/O
PEHPSCL BH48 ODCMOS I/O
PEHPSDA BF48 ODCMOS I/O
PMSYNC K52 CMOS I
PRDY_N R53 CMOS O
PREQ_N U53 CMOS I/O
PROCHOT_N BD52 ODCMOS I/O
PWRGOOD BJ53 CMOS I
QPI_RBIAS CE53 Analog I/O
QPI_RBIAS_SENSE CC53 Analog I
QPI_VREF_CAP CU51 QPI I/O
QPI0_CLKRX_DN BM58 QPI I
QPI0_CLKRX_DP BK58 QPI I
QPI0_CLKTX_DN CG45 QPI O
QPI0_CLKTX_DP CE45 QPI O
QPI0_DRX_DN[00] BJ51 QPI I
QPI0_DRX_DN[01] BH52 QPI I
QPI0_DRX_DN[02] BG53 QPI I
QPI0_DRX_DN[03] BG55 QPI I
QPI0_DRX_DN[04] BH56 QPI I
QPI0_DRX_DN[05] BH54 QPI I
QPI0_DRX_DN[06] BH50 QPI I
QPI0_DRX_DN[07] BF58 QPI I
QPI0_DRX_DN[08] BG57 QPI I
QPI0_DRX_DN[09] BN57 QPI I
QPI0_DRX_DN[10] BP56 QPI I
QPI0_DRX_DN[11] BN55 QPI I
QPI0_DRX_DN[12] BP54 QPI I
QPI0_DRX_DN[13] BN53 QPI I
QPI0_DRX_DN[14] BP52 QPI I
QPI0_DRX_DN[15] BR51 QPI I
QPI0_DRX_DN[16] BP50 QPI I
QPI0_DRX_DN[17] BJ49 QPI I
Table 8-1. Land Name (Sheet 22 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
172 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
QPI0_DRX_DN[18] BN49 QPI I
QPI0_DRX_DN[19] BM48 QPI I
QPI0_DRX_DP[00] BG51 QPI I
QPI0_DRX_DP[01] BF52 QPI I
QPI0_DRX_DP[02] BE53 QPI I
QPI0_DRX_DP[03] BE55 QPI I
QPI0_DRX_DP[04] BF56 QPI I
QPI0_DRX_DP[05] BF54 QPI I
QPI0_DRX_DP[06] BF50 QPI I
QPI0_DRX_DP[07] BD58 QPI I
QPI0_DRX_DP[08] BE57 QPI I
QPI0_DRX_DP[09] BL57 QPI I
QPI0_DRX_DP[10] BM56 QPI I
QPI0_DRX_DP[11] BL55 QPI I
QPI0_DRX_DP[12] BM54 QPI I
QPI0_DRX_DP[13] BL53 QPI I
QPI0_DRX_DP[14] BM52 QPI I
QPI0_DRX_DP[15] BN51 QPI I
QPI0_DRX_DP[16] BM50 QPI I
QPI0_DRX_DP[17] BG49 QPI I
QPI0_DRX_DP[18] BR49 QPI I
QPI0_DRX_DP[19] BP48 QPI I
QPI0_DTX_DN[00] BW49 QPI O
QPI0_DTX_DN[01] BW51 QPI O
QPI0_DTX_DN[02] BW53 QPI O
QPI0_DTX_DN[03] BY54 QPI O
QPI0_DTX_DN[04] BW55 QPI O
QPI0_DTX_DN[05] BV58 QPI O
QPI0_DTX_DN[06] BW47 QPI O
QPI0_DTX_DN[07] BW57 QPI O
QPI0_DTX_DN[08] BY56 QPI O
QPI0_DTX_DN[09] BW45 QPI O
QPI0_DTX_DN[10] CF46 QPI O
QPI0_DTX_DN[11] BY52 QPI O
QPI0_DTX_DN[12] CA47 QPI O
QPI0_DTX_DN[13] CA49 QPI O
QPI0_DTX_DN[14] CG47 QPI O
QPI0_DTX_DN[15] CF48 QPI O
QPI0_DTX_DN[16] CF50 QPI O
QPI0_DTX_DN[17] CF52 QPI O
QPI0_DTX_DN[18] CG51 QPI O
QPI0_DTX_DN[19] CG49 QPI O
Table 8-1. Land Name (Sheet 23 of 50)
Land Name Land No. Buffer Type Direction
QPI0_DTX_DP[00] BV50 QPI O
QPI0_DTX_DP[01] BV52 QPI O
QPI0_DTX_DP[02] BU53 QPI O
QPI0_DTX_DP[03] BV54 QPI O
QPI0_DTX_DP[04] BU55 QPI O
QPI0_DTX_DP[05] BT58 QPI O
QPI0_DTX_DP[06] BV48 QPI O
QPI0_DTX_DP[07] BU57 QPI O
QPI0_DTX_DP[08] BV56 QPI O
QPI0_DTX_DP[09] BV46 QPI O
QPI0_DTX_DP[10] CD46 QPI O
QPI0_DTX_DP[11] CA51 QPI O
QPI0_DTX_DP[12] BY48 QPI O
QPI0_DTX_DP[13] BY50 QPI O
QPI0_DTX_DP[14] CE47 QPI O
QPI0_DTX_DP[15] CD48 QPI O
QPI0_DTX_DP[16] CD50 QPI O
QPI0_DTX_DP[17] CD52 QPI O
QPI0_DTX_DP[18] CE51 QPI O
QPI0_DTX_DP[19] CE49 QPI O
QPI1_CLKRX_DN CU55 QPI I
QPI1_CLKRX_DP CR55 QPI I
QPI1_CLKTX_DN CY54 QPI O
QPI1_CLKTX_DP DB54 QPI O
QPI1_DRX_DN[00] CE55 QPI I
QPI1_DRX_DN[01] CF56 QPI I
QPI1_DRX_DN[02] CF54 QPI I
QPI1_DRX_DN[03] CL55 QPI I
QPI1_DRX_DN[04] CM56 QPI I
QPI1_DRX_DN[05] CM54 QPI I
QPI1_DRX_DN[06] CT58 QPI I
QPI1_DRX_DN[07] CU57 QPI I
QPI1_DRX_DN[08] CV56 QPI I
QPI1_DRX_DN[09] CL53 QPI I
QPI1_DRX_DN[10] CM52 QPI I
QPI1_DRX_DN[11] CR53 QPI I
QPI1_DRX_DN[12] CT52 QPI I
QPI1_DRX_DN[13] CL51 QPI I
QPI1_DRX_DN[14] CK50 QPI I
QPI1_DRX_DN[15] CL49 QPI I
QPI1_DRX_DN[16] CM48 QPI I
QPI1_DRX_DN[17] CN47 QPI I
Table 8-1. Land Name (Sheet 24 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 173
Datasheet Volume One of Two
Processor Land Listing
QPI1_DRX_DN[18] CM46 QPI I
QPI1_DRX_DN[19] CN45 QPI I
QPI1_DRX_DP[00] CC55 QPI I
QPI1_DRX_DP[01] CD56 QPI I
QPI1_DRX_DP[02] CD54 QPI I
QPI1_DRX_DP[03] CJ55 QPI I
QPI1_DRX_DP[04] CK56 QPI I
QPI1_DRX_DP[05] CK54 QPI I
QPI1_DRX_DP[06] CP58 QPI I
QPI1_DRX_DP[07] CR57 QPI I
QPI1_DRX_DP[08] CT56 QPI I
QPI1_DRX_DP[09] CJ53 QPI I
QPI1_DRX_DP[10] CK52 QPI I
QPI1_DRX_DP[11] CU53 QPI I
QPI1_DRX_DP[12] CV52 QPI I
QPI1_DRX_DP[13] CN51 QPI I
QPI1_DRX_DP[14] CM50 QPI I
QPI1_DRX_DP[15] CN49 QPI I
QPI1_DRX_DP[16] CK48 QPI I
QPI1_DRX_DP[17] CL47 QPI I
QPI1_DRX_DP[18] CK46 QPI I
QPI1_DRX_DP[19] CL45 QPI I
QPI1_DTX_DN[00] CV48 QPI O
QPI1_DTX_DN[01] CV50 QPI O
QPI1_DTX_DN[02] CW49 QPI O
QPI1_DTX_DN[03] DC53 QPI O
QPI1_DTX_DN[04] DB52 QPI O
QPI1_DTX_DN[05] CW47 QPI O
QPI1_DTX_DN[06] DE51 QPI O
QPI1_DTX_DN[07] DB50 QPI O
QPI1_DTX_DN[08] CV46 QPI O
QPI1_DTX_DN[09] DE49 QPI O
QPI1_DTX_DN[10] DD48 QPI O
QPI1_DTX_DN[11] CW45 QPI O
QPI1_DTX_DN[12] DC47 QPI O
QPI1_DTX_DN[13] DD46 QPI O
QPI1_DTX_DN[14] CV44 QPI O
QPI1_DTX_DN[15] DC45 QPI O
QPI1_DTX_DN[16] DD44 QPI O
QPI1_DTX_DN[17] CW43 QPI O
QPI1_DTX_DN[18] DC43 QPI O
QPI1_DTX_DN[19] DD42 QPI O
Table 8-1. Land Name (Sheet 25 of 50)
Land Name Land No. Buffer Type Direction
QPI1_DTX_DP[00] CT48 QPI O
QPI1_DTX_DP[01] CT50 QPI O
QPI1_DTX_DP[02] CU49 QPI O
QPI1_DTX_DP[03] DA53 QPI O
QPI1_DTX_DP[04] DD52 QPI O
QPI1_DTX_DP[05] CU47 QPI O
QPI1_DTX_DP[06] DC51 QPI O
QPI1_DTX_DP[07] DD50 QPI O
QPI1_DTX_DP[08] CT46 QPI O
QPI1_DTX_DP[09] DC49 QPI O
QPI1_DTX_DP[10] DB48 QPI O
QPI1_DTX_DP[11] CU45 QPI O
QPI1_DTX_DP[12] DE47 QPI O
QPI1_DTX_DP[13] DB46 QPI O
QPI1_DTX_DP[14] CT44 QPI O
QPI1_DTX_DP[15] DE45 QPI O
QPI1_DTX_DP[16] DB44 QPI O
QPI1_DTX_DP[17] CU43 QPI O
QPI1_DTX_DP[18] DE43 QPI O
QPI1_DTX_DP[19] DB42 QPI O
RESET_N CK44 CMOS I
RSVD A53
RSVD AB48
RSVD AJ55
RSVD AL55
RSVD AM44
RSVD AP48
RSVD AR55
RSVD AU55
RSVD AV46
RSVD AY46
RSVD B46
RSVD BC47
RSVD BD44
RSVD BD46
RSVD BD48
RSVD BE43
RSVD BE45
RSVD BE47
RSVD BF46
RSVD BG43
RSVD BG45
Table 8-1. Land Name (Sheet 26 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
174 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
RSVD BH44
RSVD BH46
RSVD BJ43
RSVD BJ45
RSVD BK44
RSVD BL43
RSVD BL45
RSVD BM44
RSVD BM46
RSVD BN47
RSVD BP44
RSVD BP46
RSVD BR43
RSVD BR47
RSVD BT44
RSVD BU43
RSVD BY46
RSVD C53
RSVD CA45
RSVD CD44
RSVD CE43
RSVD CF44
RSVD CG11
RSVD CP54
RSVD CY46
RSVD CY48
RSVD CY56
RSVD CY58
RSVD D46
RSVD D56
RSVD DA57
RSVD DB56
RSVD DC55
RSVD DD54
RSVD DE55
RSVD E53
RSVD E57
RSVD F46
RSVD F56
RSVD F58
RSVD H56
RSVD H58
Table 8-1. Land Name (Sheet 27 of 50)
Land Name Land No. Buffer Type Direction
RSVD J15
RSVD K58
RSVD M48
RSVD W15
RSVD Y48
SAFE_MODE_BOOT DA55 CMOS I
SKTOCC_N BU49 O
SOCKET_ID[0] CY52 CMOS I
SOCKET_ID[1] BC49 CMOS I
SVIDALERT_N CR43 CMOS I
SVIDCLK CB44 ODCMOS O
SVIDDATA BR45 ODCMOS I/O
TCK BY44 CMOS I
TDI BW43 CMOS I
TDO CA43 ODCMOS O
TEST0 DB4 O
TEST1 CW1 O
TEST2 F2 O
TEST3 D4 O
TEST4 BA55 I
THERMTRIP_N BL47 ODCMOS O
TMS BV44 CMOS I
TRST_N CT54 CMOS I
VCC AG19 PWR
VCC AG25 PWR
VCC AG27 PWR
VCC AG29 PWR
VCC AG31 PWR
VCC AG33 PWR
VCC AG35 PWR
VCC AG37 PWR
VCC AG39 PWR
VCC AG41 PWR
VCC AL1 PWR
VCC AL11 PWR
VCC AL13 PWR
VCC AL15 PWR
VCC AL17 PWR
VCC AL3 PWR
VCC AL5 PWR
VCC AL7 PWR
VCC AL9 PWR
Table 8-1. Land Name (Sheet 28 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 175
Datasheet Volume One of Two
Processor Land Listing
VCC AM10 PWR
VCC AM12 PWR
VCC AM14 PWR
VCC AM16 PWR
VCC AM2 PWR
VCC AM4 PWR
VCC AM6 PWR
VCC AM8 PWR
VCC AN1 PWR
VCC AN11 PWR
VCC AN13 PWR
VCC AN15 PWR
VCC AN17 PWR
VCC AN3 PWR
VCC AN5 PWR
VCC AN7 PWR
VCC AN9 PWR
VCC AP10 PWR
VCC AP12 PWR
VCC AP14 PWR
VCC AP16 PWR
VCC AP2 PWR
VCC AP4 PWR
VCC AP6 PWR
VCC AP8 PWR
VCC AU1 PWR
VCC AU11 PWR
VCC AU13 PWR
VCC AU15 PWR
VCC AU17 PWR
VCC AU3 PWR
VCC AU5 PWR
VCC AU7 PWR
VCC AU9 PWR
VCC AV10 PWR
VCC AV12 PWR
VCC AV14 PWR
VCC AV16 PWR
VCC AV2 PWR
VCC AV4 PWR
VCC AV6 PWR
VCC AV8 PWR
Table 8-1. Land Name (Sheet 29 of 50)
Land Name Land No. Buffer Type Direction
VCC AW1 PWR
VCC AW11 PWR
VCC AW13 PWR
VCC AW15 PWR
VCC AW17 PWR
VCC AW3 PWR
VCC AW5 PWR
VCC AW7 PWR
VCC AW9 PWR
VCC AY10 PWR
VCC AY12 PWR
VCC AY14 PWR
VCC AY16 PWR
VCC AY2 PWR
VCC AY4 PWR
VCC AY6 PWR
VCC AY8 PWR
VCC BA1 PWR
VCC BA11 PWR
VCC BA13 PWR
VCC BA15 PWR
VCC BA17 PWR
VCC BA3 PWR
VCC BA5 PWR
VCC BA7 PWR
VCC BA9 PWR
VCC BB10 PWR
VCC BB12 PWR
VCC BB14 PWR
VCC BB16 PWR
VCC BB2 PWR
VCC BB4 PWR
VCC BB6 PWR
VCC BB8 PWR
VCC BE1 PWR
VCC BE11 PWR
VCC BE13 PWR
VCC BE15 PWR
VCC BE17 PWR
VCC BE3 PWR
VCC BE5 PWR
VCC BE7 PWR
Table 8-1. Land Name (Sheet 30 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
176 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
VCC BE9 PWR
VCC BF10 PWR
VCC BF12 PWR
VCC BF14 PWR
VCC BF16 PWR
VCC BF2 PWR
VCC BF4 PWR
VCC BF6 PWR
VCC BF8 PWR
VCC BG1 PWR
VCC BG11 PWR
VCC BG13 PWR
VCC BG15 PWR
VCC BG17 PWR
VCC BG3 PWR
VCC BG5 PWR
VCC BG7 PWR
VCC BG9 PWR
VCC BH10 PWR
VCC BH12 PWR
VCC BH14 PWR
VCC BH16 PWR
VCC BH2 PWR
VCC BH4 PWR
VCC BH6 PWR
VCC BH8 PWR
VCC BJ1 PWR
VCC BJ11 PWR
VCC BJ13 PWR
VCC BJ15 PWR
VCC BJ17 PWR
VCC BJ3 PWR
VCC BJ5 PWR
VCC BJ7 PWR
VCC BJ9 PWR
VCC BK10 PWR
VCC BK12 PWR
VCC BK14 PWR
VCC BK16 PWR
VCC BK2 PWR
VCC BK4 PWR
VCC BK6 PWR
Table 8-1. Land Name (Sheet 31 of 50)
Land Name Land No. Buffer Type Direction
VCC BK8 PWR
VCC BN1 PWR
VCC BN11 PWR
VCC BN13 PWR
VCC BN15 PWR
VCC BN17 PWR
VCC BN3 PWR
VCC BN5 PWR
VCC BN7 PWR
VCC BN9 PWR
VCC BP10 PWR
VCC BP12 PWR
VCC BP14 PWR
VCC BP16 PWR
VCC BP2 PWR
VCC BP4 PWR
VCC BP6 PWR
VCC BP8 PWR
VCC BR1 PWR
VCC BR11 PWR
VCC BR13 PWR
VCC BR15 PWR
VCC BR17 PWR
VCC BR3 PWR
VCC BR5 PWR
VCC BR7 PWR
VCC BR9 PWR
VCC BT10 PWR
VCC BT12 PWR
VCC BT14 PWR
VCC BT16 PWR
VCC BT2 PWR
VCC BT4 PWR
VCC BT6 PWR
VCC BT8 PWR
VCC BU1 PWR
VCC BU11 PWR
VCC BU13 PWR
VCC BU15 PWR
VCC BU17 PWR
VCC BU3 PWR
VCC BU5 PWR
Table 8-1. Land Name (Sheet 32 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 177
Datasheet Volume One of Two
Processor Land Listing
VCC BU7 PWR
VCC BU9 PWR
VCC BV10 PWR
VCC BV12 PWR
VCC BV14 PWR
VCC BV16 PWR
VCC BV2 PWR
VCC BV4 PWR
VCC BV6 PWR
VCC BV8 PWR
VCC BY18 PWR
VCC BY26 PWR
VCC BY28 PWR
VCC BY30 PWR
VCC BY32 PWR
VCC BY34 PWR
VCC BY36 PWR
VCC BY38 PWR
VCC BY40 PWR
VCC CA25 PWR
VCC CA29 PWR
VCC_SENSE BW3 O
VCCD_01 CD20 PWR
VCCD_01 CD22 PWR
VCCD_01 CD24 PWR
VCCD_01 CD26 PWR
VCCD_01 CD28 PWR
VCCD_01 CJ19 PWR
VCCD_01 CJ21 PWR
VCCD_01 CJ23 PWR
VCCD_01 CJ25 PWR
VCCD_01 CJ27 PWR
VCCD_01 CP20 PWR
VCCD_01 CP22 PWR
VCCD_01 CP24 PWR
VCCD_01 CP26 PWR
VCCD_01 CP28 PWR
VCCD_01 CW19 PWR
VCCD_01 CW21 PWR
VCCD_01 CW23 PWR
VCCD_01 CW25 PWR
VCCD_01 CW27 PWR
Table 8-1. Land Name (Sheet 33 of 50)
Land Name Land No. Buffer Type Direction
VCCD_01 DD18 PWR
VCCD_01 DD20 PWR
VCCD_01 DD22 PWR
VCCD_01 DD24 PWR
VCCD_01 DD26 PWR
VCCD_23 AC17 PWR
VCCD_23 AC19 PWR
VCCD_23 AC21 PWR
VCCD_23 AC23 PWR
VCCD_23 AC25 PWR
VCCD_23 C15 PWR
VCCD_23 C17 PWR
VCCD_23 C19 PWR
VCCD_23 C21 PWR
VCCD_23 C23 PWR
VCCD_23 G13 PWR
VCCD_23 H16 PWR
VCCD_23 H18 PWR
VCCD_23 H20 PWR
VCCD_23 H22 PWR
VCCD_23 H24 PWR
VCCD_23 N15 PWR
VCCD_23 N17 PWR
VCCD_23 N19 PWR
VCCD_23 N21 PWR
VCCD_23 N23 PWR
VCCD_23 V16 PWR
VCCD_23 V18 PWR
VCCD_23 V20 PWR
VCCD_23 V22 PWR
VCCD_23 V24 PWR
VCCPLL BY14 PWR
VCCPLL CA13 PWR
VCCPLL CA15 PWR
VSA AE15 PWR
VSA AE17 PWR
VSA AF18 PWR
VSA AG15 PWR
VSA AG17 PWR
VSA AH10 PWR
VSA AH12 PWR
VSA AH14 PWR
Table 8-1. Land Name (Sheet 34 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
178 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
VSA AH16 PWR
VSA AH2 PWR
VSA AH4 PWR
VSA AH6 PWR
VSA AH8 PWR
VSA AJ1 PWR
VSA AJ11 PWR
VSA AJ13 PWR
VSA AJ3 PWR
VSA AJ5 PWR
VSA AJ7 PWR
VSA AJ9 PWR
VSA B54 PWR
VSA G43 PWR
VSA G49 PWR
VSA N45 PWR
VSA N51 PWR
VSA_SENSE AG13 O
VSS A41 GND
VSS A43 GND
VSS A45 GND
VSS A47 GND
VSS A49 GND
VSS A5 GND
VSS A51 GND
VSS A7 GND
VSS AA11 GND
VSS AA29 GND
VSS AA3 GND
VSS AA31 GND
VSS AA39 GND
VSS AA5 GND
VSS AA55 GND
VSS AA9 GND
VSS AB14 GND
VSS AB36 GND
VSS AB42 GND
VSS AB6 GND
VSS AC31 GND
VSS AC9 GND
VSS AD26 GND
VSS AD34 GND
Table 8-1. Land Name (Sheet 35 of 50)
Land Name Land No. Buffer Type Direction
VSS AD36 GND
VSS AD42 GND
VSS AD44 GND
VSS AD46 GND
VSS AD48 GND
VSS AD50 GND
VSS AD52 GND
VSS AD6 GND
VSS AE29 GND
VSS AE31 GND
VSS AE39 GND
VSS AE43 GND
VSS AE47 GND
VSS AE49 GND
VSS AE51 GND
VSS AE9 GND
VSS AF12 GND
VSS AF16 GND
VSS AF20 GND
VSS AF26 GND
VSS AF34 GND
VSS AF36 GND
VSS AF40 GND
VSS AF42 GND
VSS AF54 GND
VSS AF56 GND
VSS AF6 GND
VSS AG1 GND
VSS AG3 GND
VSS AG43 GND
VSS AG5 GND
VSS AG55 GND
VSS AG57 GND
VSS AG9 GND
VSS AH58 GND
VSS AJ15 GND
VSS AJ17 GND
VSS AK10 GND
VSS AK12 GND
VSS AK14 GND
VSS AK16 GND
VSS AK2 GND
Table 8-1. Land Name (Sheet 36 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 179
Datasheet Volume One of Two
Processor Land Listing
VSS AK4 GND
VSS AK42 GND
VSS AK44 GND
VSS AK46 GND
VSS AK48 GND
VSS AK50 GND
VSS AK6 GND
VSS AK8 GND
VSS AL43 GND
VSS AL45 GND
VSS AL49 GND
VSS AL51 GND
VSS AL53 GND
VSS AM56 GND
VSS AN55 GND
VSS AN57 GND
VSS AP42 GND
VSS AP44 GND
VSS AP58 GND
VSS AR1 GND
VSS AR11 GND
VSS AR13 GND
VSS AR15 GND
VSS AR17 GND
VSS AR3 GND
VSS AR5 GND
VSS AR7 GND
VSS AR9 GND
VSS AT10 GND
VSS AT12 GND
VSS AT14 GND
VSS AT16 GND
VSS AT2 GND
VSS AT4 GND
VSS AT46 GND
VSS AT52 GND
VSS AT6 GND
VSS AT8 GND
VSS AU45 GND
VSS AU47 GND
VSS AU49 GND
VSS AU51 GND
Table 8-1. Land Name (Sheet 37 of 50)
Land Name Land No. Buffer Type Direction
VSS AV42 GND
VSS AV54 GND
VSS AV56 GND
VSS AW55 GND
VSS AW57 GND
VSS B36 GND
VSS B52 GND
VSS B6 GND
VSS B8 GND
VSS BB42 GND
VSS BB46 GND
VSS BB48 GND
VSS BB50 GND
VSS BB52 GND
VSS BB58 GND
VSS BC1 GND
VSS BC11 GND
VSS BC13 GND
VSS BC15 GND
VSS BC17 GND
VSS BC3 GND
VSS BC43 GND
VSS BC45 GND
VSS BC5 GND
VSS BC53 GND
VSS BC55 GND
VSS BC57 GND
VSS BC7 GND
VSS BC9 GND
VSS BD10 GND
VSS BD12 GND
VSS BD14 GND
VSS BD16 GND
VSS BD2 GND
VSS BD4 GND
VSS BD54 GND
VSS BD56 GND
VSS BD6 GND
VSS BD8 GND
VSS BE49 GND
VSS BE51 GND
VSS BF42 GND
Table 8-1. Land Name (Sheet 38 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
180 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
VSS BF44 GND
VSS BG47 GND
VSS BH58 GND
VSS BJ55 GND
VSS BJ57 GND
VSS BK42 GND
VSS BK46 GND
VSS BK48 GND
VSS BK50 GND
VSS BK52 GND
VSS BK54 GND
VSS BL1 GND
VSS BL11 GND
VSS BL13 GND
VSS BL15 GND
VSS BL17 GND
VSS BL3 GND
VSS BL49 GND
VSS BL5 GND
VSS BL7 GND
VSS BL9 GND
VSS BM10 GND
VSS BM12 GND
VSS BM14 GND
VSS BM16 GND
VSS BM2 GND
VSS BM4 GND
VSS BM6 GND
VSS BM8 GND
VSS BN43 GND
VSS BN45 GND
VSS BP58 GND
VSS BR53 GND
VSS BR57 GND
VSS BT46 GND
VSS BT48 GND
VSS BT50 GND
VSS BT52 GND
VSS BT54 GND
VSS BT56 GND
VSS BU45 GND
VSS BU51 GND
Table 8-1. Land Name (Sheet 39 of 50)
Land Name Land No. Buffer Type Direction
VSS BW1 GND
VSS BW11 GND
VSS BW13 GND
VSS BW15 GND
VSS BW17 GND
VSS BW5 GND
VSS BW7 GND
VSS BY24 GND
VSS BY4 GND
VSS BY42 GND
VSS BY58 GND
VSS BY8 GND
VSS C11 GND
VSS C13 GND
VSS C3 GND
VSS C33 GND
VSS C39 GND
VSS C41 GND
VSS C5 GND
VSS C55 GND
VSS CA11 GND
VSS CA19 GND
VSS CA27 GND
VSS CA31 GND
VSS CA33 GND
VSS CA35 GND
VSS CA37 GND
VSS CA39 GND
VSS CA41 GND
VSS CA5 GND
VSS CA55 GND
VSS CA57 GND
VSS CB16 GND
VSS CB36 GND
VSS CB46 GND
VSS CB48 GND
VSS CB50 GND
VSS CB52 GND
VSS CB56 GND
VSS CB6 GND
VSS CB8 GND
VSS CC13 GND
Table 8-1. Land Name (Sheet 40 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 181
Datasheet Volume One of Two
Processor Land Listing
VSS CC29 GND
VSS CC3 GND
VSS CC43 GND
VSS CC47 GND
VSS CC49 GND
VSS CC9 GND
VSS CD18 GND
VSS CD36 GND
VSS CD6 GND
VSS CE13 GND
VSS CE5 GND
VSS CE9 GND
VSS CF12 GND
VSS CF14 GND
VSS CF30 GND
VSS CF32 GND
VSS CF34 GND
VSS CF36 GND
VSS CF38 GND
VSS CF40 GND
VSS CF42 GND
VSS CF6 GND
VSS CG15 GND
VSS CG31 GND
VSS CG33 GND
VSS CG35 GND
VSS CG37 GND
VSS CG39 GND
VSS CG41 GND
VSS CG43 GND
VSS CG53 GND
VSS CG9 GND
VSS CH12 GND
VSS CH16 GND
VSS CH36 GND
VSS CH44 GND
VSS CH46 GND
VSS CH48 GND
VSS CH50 GND
VSS CH52 GND
VSS CH54 GND
VSS CH6 GND
Table 8-1. Land Name (Sheet 41 of 50)
Land Name Land No. Buffer Type Direction
VSS CJ11 GND
VSS CJ17 GND
VSS CJ29 GND
VSS CJ3 GND
VSS CJ43 GND
VSS CJ45 GND
VSS CJ47 GND
VSS CJ51 GND
VSS CJ9 GND
VSS CK10 GND
VSS CK36 GND
VSS CK4 GND
VSS CK6 GND
VSS CL17 GND
VSS CL43 GND
VSS CL5 GND
VSS CM10 GND
VSS CM14 GND
VSS CM30 GND
VSS CM32 GND
VSS CM34 GND
VSS CM36 GND
VSS CM38 GND
VSS CM40 GND
VSS CM42 GND
VSS CM6 GND
VSS CM8 GND
VSS CN11 GND
VSS CN13 GND
VSS CN15 GND
VSS CN17 GND
VSS CN3 GND
VSS CN31 GND
VSS CN33 GND
VSS CN35 GND
VSS CN37 GND
VSS CN39 GND
VSS CN5 GND
VSS CN53 GND
VSS CN55 GND
VSS CN57 GND
VSS CN7 GND
Table 8-1. Land Name (Sheet 42 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
182 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
VSS CN9 GND
VSS CP12 GND
VSS CP16 GND
VSS CP36 GND
VSS CP40 GND
VSS CP42 GND
VSS CP44 GND
VSS CP46 GND
VSS CP48 GND
VSS CP50 GND
VSS CP52 GND
VSS CP56 GND
VSS CR11 GND
VSS CR35 GND
VSS CR47 GND
VSS CR49 GND
VSS CR5 GND
VSS CR9 GND
VSS CT28 GND
VSS CT42 GND
VSS CU1 GND
VSS CU11 GND
VSS CU3 GND
VSS CU35 GND
VSS CU5 GND
VSS CV14 GND
VSS CV18 GND
VSS CV30 GND
VSS CV32 GND
VSS CV34 GND
VSS CV38 GND
VSS CV42 GND
VSS CV54 GND
VSS CV58 GND
VSS CV6 GND
VSS CW11 GND
VSS CW13 GND
VSS CW15 GND
VSS CW29 GND
VSS CW31 GND
VSS CW33 GND
VSS CW35 GND
Table 8-1. Land Name (Sheet 43 of 50)
Land Name Land No. Buffer Type Direction
VSS CW37 GND
VSS CW39 GND
VSS CW5 GND
VSS CW51 GND
VSS CW53 GND
VSS CW55 GND
VSS CW57 GND
VSS CW7 GND
VSS CY10 GND
VSS CY12 GND
VSS CY16 GND
VSS CY2 GND
VSS CY36 GND
VSS CY40 GND
VSS CY44 GND
VSS CY50 GND
VSS CY8 GND
VSS D2 GND
VSS D26 GND
VSS D36 GND
VSS D8 GND
VSS DA11 GND
VSS DA3 GND
VSS DA41 GND
VSS DA43 GND
VSS DA45 GND
VSS DA47 GND
VSS DA5 GND
VSS DA51 GND
VSS DA9 GND
VSS DB12 GND
VSS DB2 GND
VSS DB32 GND
VSS DB36 GND
VSS DB58 GND
VSS DC3 GND
VSS DC41 GND
VSS DC5 GND
VSS DD10 GND
VSS DD12 GND
VSS DD14 GND
VSS DD34 GND
Table 8-1. Land Name (Sheet 44 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 183
Datasheet Volume One of Two
Processor Land Listing
VSS DD36 GND
VSS DD38 GND
VSS DD6 GND
VSS DE17 GND
VSS DE41 GND
VSS DE53 GND
VSS DE7 GND
VSS DF12 GND
VSS DF36 GND
VSS DF42 GND
VSS DF44 GND
VSS DF46 GND
VSS DF48 GND
VSS DF50 GND
VSS DF52 GND
VSS DF8 GND
VSS E1 GND
VSS E29 GND
VSS E3 GND
VSS E31 GND
VSS E41 GND
VSS E5 GND
VSS F36 GND
VSS F42 GND
VSS F44 GND
VSS F48 GND
VSS F50 GND
VSS F8 GND
VSS G1 GND
VSS G25 GND
VSS G31 GND
VSS G35 GND
VSS G37 GND
VSS G41 GND
VSS G45 GND
VSS G47 GND
VSS G5 GND
VSS G51 GND
VSS G53 GND
VSS G57 GND
VSS G9 GND
VSS H10 GND
Table 8-1. Land Name (Sheet 45 of 50)
Land Name Land No. Buffer Type Direction
VSS H12 GND
VSS H14 GND
VSS H32 GND
VSS H34 GND
VSS H38 GND
VSS H40 GND
VSS H52 GND
VSS H54 GND
VSS H8 GND
VSS J11 GND
VSS J27 GND
VSS J31 GND
VSS J33 GND
VSS J39 GND
VSS J41 GND
VSS J5 GND
VSS J55 GND
VSS K2 GND
VSS K26 GND
VSS K28 GND
VSS K30 GND
VSS K34 GND
VSS K8 GND
VSS L25 GND
VSS L29 GND
VSS L41 GND
VSS L5 GND
VSS M34 GND
VSS M36 GND
VSS M42 GND
VSS M44 GND
VSS M46 GND
VSS M50 GND
VSS M52 GND
VSS M8 GND
VSS N13 GND
VSS N33 GND
VSS N35 GND
VSS N37 GND
VSS N41 GND
VSS N43 GND
VSS N47 GND
Table 8-1. Land Name (Sheet 46 of 50)
Land Name Land No. Buffer Type Direction
Processor Land Listing
184 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
VSS N49 GND
VSS N5 GND
VSS N53 GND
VSS N9 GND
VSS P10 GND
VSS P12 GND
VSS P14 GND
VSS P26 GND
VSS P30 GND
VSS P32 GND
VSS P38 GND
VSS P40 GND
VSS P54 GND
VSS P56 GND
VSS P8 GND
VSS R11 GND
VSS R29 GND
VSS R3 GND
VSS R31 GND
VSS R35 GND
VSS R39 GND
VSS R5 GND
VSS R55 GND
VSS R7 GND
VSS T28 GND
VSS T4 GND
VSS T42 GND
VSS T6 GND
VSS T8 GND
VSS U35 GND
VSS U5 GND
VSS V26 GND
VSS V28 GND
VSS V34 GND
VSS V36 GND
VSS V42 GND
VSS V44 GND
VSS V46 GND
VSS V48 GND
VSS V50 GND
VSS V8 GND
VSS W13 GND
Table 8-1. Land Name (Sheet 47 of 50)
Land Name Land No. Buffer Type Direction
VSS W33 GND
VSS W37 GND
VSS W41 GND
VSS W43 GND
VSS W45 GND
VSS W47 GND
VSS W5 GND
VSS W51 GND
VSS W53 GND
VSS W9 GND
VSS Y10 GND
VSS Y12 GND
VSS Y28 GND
VSS Y30 GND
VSS Y32 GND
VSS Y36 GND
VSS Y38 GND
VSS Y40 GND
VSS Y42 GND
VSS Y56 GND
VSS_VCC_SENSE BY2 O
VSS_VSA_SENSE AF14 O
VSS_VTTD_SENSE BT42 O
VTTA AE45 PWR
VTTA AE53 PWR
VTTA AM48 PWR
VTTA AM54 PWR
VTTA AU53 PWR
VTTA CA53 PWR
VTTA CC45 PWR
VTTA CG55 PWR
VTTA CJ49 PWR
VTTA CR45 PWR
VTTA CR51 PWR
VTTA DA49 PWR
VTTA W49 PWR
VTTA Y54 PWR
VTTD AF22 PWR
VTTD AF24 PWR
VTTD AG21 PWR
VTTD AG23 PWR
VTTD AM42 PWR
Table 8-1. Land Name (Sheet 48 of 50)
Land Name Land No. Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 185
Datasheet Volume One of Two
Processor Land Listing
8.2 Listing by Land Number
VTTD AT42 PWR
VTTD AY42 PWR
VTTD BD42 PWR
VTTD BH42 PWR
VTTD BK56 PWR
VTTD BL51 PWR
VTTD BM42 PWR
VTTD BR55 PWR
Table 8-1. Land Name (Sheet 49 of 50)
Land Name Land No. Buffer Type Direction
VTTD BU47 PWR
VTTD BV42 PWR
VTTD BY20 PWR
VTTD BY22 PWR
VTTD CA21 PWR
VTTD CA23 PWR
VTTD_SENSE BP42 O
Table 8-1. Land Name (Sheet 50 of 50)
Land Name Land No. Buffer Type Direction
Table 8-2. Land Number (Sheet 1 of 49)
Land No. Land Name Buffer Type Direction
A11 DDR3_DQ[33] SSTL I/O
A13 DDR3_MA[13] SSTL O
A15 DDR3_WE_N SSTL O
A17 DDR3_BA[0] SSTL O
A19 DDR3_MA[00] SSTL O
A21 DDR3_MA[05] SSTL O
A23 DDR3_MA[11] SSTL O
A33 DDR3_DQ[22] SSTL I/O
A35 DDR3_DQ[16] SSTL I/O
A37 DDR3_DQ[07] SSTL I/O
A39 DDR3_DQ[01] SSTL I/O
A41 VSS GND
A43 VSS GND
A45 VSS GND
A47 VSS GND
A49 VSS GND
A5 VSS GND
A51 VSS GND
A53 RSVD
A7 VSS GND
A9 DDR3_DQ[39] SSTL I/O
AA11 VSS GND
AA13 DDR2_DQ[37] SSTL I/O
AA15 DDR2_CS_N[3] SSTL O
AA17 DDR2_CS_N[9] SSTL O
AA19 DDR2_CS_N[4] SSTL O
AA21 DDR2_CLK_DP[2] SSTL O
AA23 DDR2_CLK_DP[3] SSTL O
AA25 DDR2_CKE[0] SSTL O
AA27 DDR2_ECC[7] SSTL I/O
AA29 VSS GND
AA3 VSS GND
AA31 VSS GND
AA33 DDR2_DQS_DN[03] SSTL I/O
AA35 DDR2_DQ[28] SSTL I/O
AA37 DDR2_DQ[10] SSTL I/O
AA39 VSS GND
AA41 DDR2_DQ[13] SSTL I/O
AA43 PE3D_TX_DN[14] PCIEX3 O
AA45 PE3D_TX_DP[12] PCIEX3 O
AA47 PE3C_TX_DP[9] PCIEX3 O
AA49 PE3A_RX_DP[3] PCIEX3 I
AA5 VSS GND
AA51 PE3B_RX_DP[7] PCIEX3 I
AA53 PE3B_RX_DP[6] PCIEX3 I
AA55 VSS GND
AA7 DDR2_DQS_DN[14] SSTL I/O
AA9 VSS GND
AB10 DDR2_DQ[38] SSTL I/O
AB12 DDR2_DQS_DP[13] SSTL I/O
AB14 VSS GND
AB16 DDR2_CS_N[6] SSTL O
AB18 DDR2_MA[00] SSTL O
AB20 DDR2_CS_N[0] SSTL O
AB22 DDR2_CLK_DP[1] SSTL O
AB24 DDR2_CLK_DP[0] SSTL O
Table 8-2. Land Number (Sheet 2 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
186 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
AB26 DDR2_ECC[3] SSTL I/O
AB28 DDR2_DQS_DN[08] SSTL I/O
AB30 DDR2_ECC[4] SSTL I/O
AB32 DDR2_DQ[30] SSTL I/O
AB34 DDR2_DQS_DN[12] SSTL I/O
AB36 VSS GND
AB38 DDR2_DQS_DP[01] SSTL I/O
AB4 DDR2_DQS_DP[07] SSTL I/O
AB40 DDR2_DQS_DP[10] SSTL I/O
AB42 VSS GND
AB44 PE3D_TX_DN[13] PCIEX3 O
AB46 PE3C_TX_DN[11] PCIEX3 O
AB48 RSVD
AB50 PE3B_RX_DN[4] PCIEX3 I
AB52 PE3B_RX_DN[5] PCIEX3 I
AB54 PE2B_RX_DP[4] PCIEX3 I
AB56 PE2B_RX_DP[5] PCIEX3 I
AB6 VSS GND
AB8 DDR2_DQS_DN[05] SSTL I/O
AC11 DDR2_DQS_DN[04] SSTL I/O
AC13 DDR2_DQ[32] SSTL I/O
AC15 DDR23_RCOMP[1] Analog I
AC17 VCCD_23 PWR
AC19 VCCD_23 PWR
AC21 VCCD_23 PWR
AC23 VCCD_23 PWR
AC25 VCCD_23 PWR
AC27 DDR2_DQS_DP[08] SSTL I/O
AC29 DDR2_DQS_DP[17] SSTL I/O
AC3 DDR2_DQS_DN[07] SSTL I/O
AC31 VSS GND
AC33 DDR2_DQS_DP[03] SSTL I/O
AC35 DDR2_DQ[24] SSTL I/O
AC37 DDR2_DQ[11] SSTL I/O
AC39 DDR2_DQS_DN[10] SSTL I/O
AC41 DDR2_DQ[12] SSTL I/O
AC43 PE3D_TX_DP[14] PCIEX3 O
AC45 PE3D_TX_DN[12] PCIEX3 O
AC47 PE3C_TX_DN[9] PCIEX3 O
AC49 PE3A_RX_DN[3] PCIEX3 I
AC5 DDR2_DQS_DP[16] SSTL I/O
AC51 PE3B_RX_DN[7] PCIEX3 I
Table 8-2. Land Number (Sheet 3 of 49)
Land No. Land Name Buffer Type Direction
AC53 PE3B_RX_DN[6] PCIEX3 I
AC55 PE2B_RX_DP[6] PCIEX3 I
AC7 DDR2_DQS_DP[05] SSTL I/O
AC9 VSS GND
AD10 DDR2_DQ[39] SSTL I/O
AD12 DDR2_DQS_DN[13] SSTL I/O
AD14 DDR2_DQ[36] SSTL I/O
AD16 DDR2_CS_N[2] SSTL O
AD18 DDR2_ODT[2] SSTL O
AD20 DDR2_PAR_ERR_N SSTL I
AD22 DDR2_ODT[4] SSTL O
AD24 DDR2_CKE[3] SSTL O
AD26 VSS GND
AD28 DDR2_DQS_DN[17] SSTL I/O
AD30 DDR2_ECC[5] SSTL I/O
AD32 DDR2_DQ[31] SSTL I/O
AD34 VSS GND
AD36 VSS GND
AD38 DDR2_DQS_DN[01] SSTL I/O
AD4 DDR2_DQS_DN[16] SSTL I/O
AD40 DDR2_DQ[09] SSTL I/O
AD42 VSS GND
AD44 VSS GND
AD46 VSS GND
AD48 VSS GND
AD50 VSS GND
AD52 VSS GND
AD54 PE2B_RX_DN[4] PCIEX3 I
AD56 PE2B_RX_DN[5] PCIEX3 I
AD6 VSS GND
AD8 DDR2_DQ[46] SSTL I/O
AE11 DDR2_DQS_DP[04] SSTL I/O
AE13 DDR2_DQ[33] SSTL I/O
AE15 VSA PWR
AE17 VSA PWR
AE19 DDR2_CS_N[1] SSTL O
AE21 DDR2_ODT[5] SSTL O
AE23 DDR2_CKE[5] SSTL O
AE25 DDR2_CKE[4] SSTL O
AE27 DDR_RESET_C23_N CMOS1.5v O
AE29 VSS GND
AE3 DDR2_DQ[63] SSTL I/O
Table 8-2. Land Number (Sheet 4 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 187
Datasheet Volume One of Two
Processor Land Listing
AE31 VSS GND
AE33 DDR2_DQ[26] SSTL I/O
AE35 DDR2_DQ[25] SSTL I/O
AE37 DDR2_DQ[15] SSTL I/O
AE39 VSS GND
AE41 DDR2_DQ[08] SSTL I/O
AE43 VSS GND
AE45 VTTA PWR
AE47 VSS GND
AE49 VSS GND
AE5 DDR2_DQ[59] SSTL I/O
AE51 VSS GND
AE53 VTTA PWR
AE55 PE2B_RX_DN[6] PCIEX3 I
AE57 PE2B_RX_DP[7] PCIEX3 I
AE7 DDR2_DQ[47] SSTL I/O
AE9 VSS GND
AF10 DDR2_DQ[35] SSTL I/O
AF12 VSS GND
AF14 VSS_VSA_SENSE O
AF16 VSS GND
AF18 VSA PWR
AF2 DDR2_DQ[62] SSTL I/O
AF20 VSS GND
AF22 VTTD PWR
AF24 VTTD PWR
AF26 VSS GND
AF28 DDR2_ECC[1] SSTL I/O
AF30 DDR2_ECC[0] SSTL I/O
AF32 DDR2_DQ[27] SSTL I/O
AF34 VSS GND
AF36 VSS GND
AF38 DDR2_DQ[14] SSTL I/O
AF4 DDR2_DQ[58] SSTL I/O
AF40 VSS GND
AF42 VSS GND
AF44 PE3A_RX_DP[0] PCIEX3 I
AF46 PE3A_RX_DP[2] PCIEX3 I
AF48 PE3C_RX_DP[8] PCIEX3 I
AF50 PE3C_RX_DP[10] PCIEX3 I
AF52 PE_RBIAS_SENSE PCIEX3 I
AF54 VSS GND
Table 8-2. Land Number (Sheet 5 of 49)
Land No. Land Name Buffer Type Direction
AF56 VSS GND
AF58 PE2B_RX_DN[7] PCIEX3 I
AF6 VSS GND
AF8 DDR2_DQ[42] SSTL I/O
AG1 VSS GND
AG11 DDR2_DQ[34] SSTL I/O
AG13 VSA_SENSE O
AG15 VSA PWR
AG17 VSA PWR
AG19 VCC PWR
AG21 VTTD PWR
AG23 VTTD PWR
AG25 VCC PWR
AG27 VCC PWR
AG29 VCC PWR
AG3 VSS GND
AG31 VCC PWR
AG33 VCC PWR
AG35 VCC PWR
AG37 VCC PWR
AG39 VCC PWR
AG41 VCC PWR
AG43 VSS GND
AG45 PE3A_RX_DP[1] PCIEX3 I
AG47 PE3D_RX_DP[12] PCIEX3 I
AG49 PE3C_RX_DP[11] PCIEX3 I
AG5 VSS GND
AG51 PE3C_RX_DP[9] PCIEX3 I
AG53 PE2B_TX_DP[4] PCIEX3 O
AG55 VSS GND
AG57 VSS GND
AG7 DDR2_DQ[43] SSTL I/O
AG9 VSS GND
AH10 VSA PWR
AH12 VSA PWR
AH14 VSA PWR
AH16 VSA PWR
AH2 VSA PWR
AH4 VSA PWR
AH42 IVT_ID_N O
AH44 PE3A_RX_DN[0] PCIEX3 I
AH46 PE3A_RX_DN[2] PCIEX3 I
Table 8-2. Land Number (Sheet 6 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
188 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
AH48 PE3C_RX_DN[8] PCIEX3 I
AH50 PE3C_RX_DN[10] PCIEX3 I
AH52 PE_RBIAS PCIEX3 I/O
AH54 PE2B_TX_DP[5] PCIEX3 O
AH56 PE2C_RX_DP[8] PCIEX3 I
AH58 VSS GND
AH6 VSA PWR
AH8 VSA PWR
AJ1 VSA PWR
AJ11 VSA PWR
AJ13 VSA PWR
AJ15 VSS GND
AJ17 VSS GND
AJ3 VSA PWR
AJ43 PE_VREF_CAP PCIEX3 I/O
AJ45 PE3A_RX_DN[1] PCIEX3 I
AJ47 PE3D_RX_DN[12] PCIEX3 I
AJ49 PE3C_RX_DN[11] PCIEX3 I
AJ5 VSA PWR
AJ51 PE3C_RX_DN[9] PCIEX3 I
AJ53 PE2B_TX_DN[4] PCIEX3 O
AJ55 RSVD
AJ57 PE2C_RX_DP[10] PCIEX3 I
AJ7 VSA PWR
AJ9 VSA PWR
AK10 VSS GND
AK12 VSS GND
AK14 VSS GND
AK16 VSS GND
AK2 VSS GND
AK4 VSS GND
AK42 VSS GND
AK44 VSS GND
AK46 VSS GND
AK48 VSS GND
AK50 VSS GND
AK52 TXT_AGENT CMOS I
AK54 PE2B_TX_DN[5] PCIEX3 O
AK56 PE2C_RX_DN[8] PCIEX3 I
AK58 PE2C_RX_DP[9] PCIEX3 I
AK6 VSS GND
AK8 VSS GND
Table 8-2. Land Number (Sheet 7 of 49)
Land No. Land Name Buffer Type Direction
AL1 VCC PWR
AL11 VCC PWR
AL13 VCC PWR
AL15 VCC PWR
AL17 VCC PWR
AL3 VCC PWR
AL43 VSS GND
AL45 VSS GND
AL47 BMCINIT CMOS I
AL49 VSS GND
AL5 VCC PWR
AL51 VSS GND
AL53 VSS GND
AL55 RSVD
AL57 PE2C_RX_DN[10] PCIEX3 I
AL7 VCC PWR
AL9 VCC PWR
AM10 VCC PWR
AM12 VCC PWR
AM14 VCC PWR
AM16 VCC PWR
AM2 VCC PWR
AM4 VCC PWR
AM42 VTTD PWR
AM44 RSVD
AM46 PE3D_RX_DP[14] PCIEX3 I
AM48 VTTA PWR
AM50 PE2A_TX_DP[1] PCIEX3 O
AM52 PE2A_TX_DP[3] PCIEX3 O
AM54 VTTA PWR
AM56 VSS GND
AM58 PE2C_RX_DN[9] PCIEX3 I
AM6 VCC PWR
AM8 VCC PWR
AN1 VCC PWR
AN11 VCC PWR
AN13 VCC PWR
AN15 VCC PWR
AN17 VCC PWR
AN3 VCC PWR
AN43 CPU_ONLY_RESET ODCMOS I/O
AN45 PE3D_RX_DP[15] PCIEX3 I
Table 8-2. Land Number (Sheet 8 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 189
Datasheet Volume One of Two
Processor Land Listing
AN47 PE3D_RX_DP[13] PCIEX3 I
AN49 PE2A_TX_DP[0] PCIEX3 O
AN5 VCC PWR
AN51 PE2A_TX_DP[2] PCIEX3 O
AN53 PE2B_TX_DP[6] PCIEX3 O
AN55 VSS GND
AN57 VSS GND
AN7 VCC PWR
AN9 VCC PWR
AP10 VCC PWR
AP12 VCC PWR
AP14 VCC PWR
AP16 VCC PWR
AP2 VCC PWR
AP4 VCC PWR
AP42 VSS GND
AP44 VSS GND
AP46 PE3D_RX_DN[14] PCIEX3 I
AP48 RSVD
AP50 PE2A_TX_DN[1] PCIEX3 O
AP52 PE2A_TX_DN[3] PCIEX3 O
AP54 PE2B_TX_DP[7] PCIEX3 O
AP56 PE2D_RX_DP[13] PCIEX3 I
AP58 VSS GND
AP6 VCC PWR
AP8 VCC PWR
AR1 VSS GND
AR11 VSS GND
AR13 VSS GND
AR15 VSS GND
AR17 VSS GND
AR3 VSS GND
AR43 BPM_N[0] ODCMOS I/O
AR45 PE3D_RX_DN[15] PCIEX3 I
AR47 PE3D_RX_DN[13] PCIEX3 I
AR49 PE2A_TX_DN[0] PCIEX3 O
AR5 VSS GND
AR51 PE2A_TX_DN[2] PCIEX3 O
AR53 PE2B_TX_DN[6] PCIEX3 O
AR55 RSVD
AR57 PE2C_RX_DP[11] PCIEX3 I
AR7 VSS GND
Table 8-2. Land Number (Sheet 9 of 49)
Land No. Land Name Buffer Type Direction
AR9 VSS GND
AT10 VSS GND
AT12 VSS GND
AT14 VSS GND
AT16 VSS GND
AT2 VSS GND
AT4 VSS GND
AT42 VTTD PWR
AT44 BPM_N[1] ODCMOS I/O
AT46 VSS GND
AT48 BIST_ENABLE CMOS I
AT50 FRMAGENT CMOS I
AT52 VSS GND
AT54 PE2B_TX_DN[7] PCIEX3 O
AT56 PE2D_RX_DN[13] PCIEX3 I
AT58 PE2D_RX_DP[12] PCIEX3 I
AT6 VSS GND
AT8 VSS GND
AU1 VCC PWR
AU11 VCC PWR
AU13 VCC PWR
AU15 VCC PWR
AU17 VCC PWR
AU3 VCC PWR
AU43 BPM_N[2] ODCMOS I/O
AU45 VSS GND
AU47 VSS GND
AU49 VSS GND
AU5 VCC PWR
AU51 VSS GND
AU53 VTTA PWR
AU55 RSVD
AU57 PE2C_RX_DN[11] PCIEX3 I
AU7 VCC PWR
AU9 VCC PWR
AV10 VCC PWR
AV12 VCC PWR
AV14 VCC PWR
AV16 VCC PWR
AV2 VCC PWR
AV4 VCC PWR
AV42 VSS GND
Table 8-2. Land Number (Sheet 10 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
190 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
AV44 BPM_N[3] ODCMOS I/O
AV46 RSVD
AV48 PE2D_TX_DP[14] PCIEX3 O
AV50 PE2D_TX_DP[12] PCIEX3 O
AV52 PE2C_TX_DP[8] PCIEX3 O
AV54 VSS GND
AV56 VSS GND
AV58 PE2D_RX_DN[12] PCIEX3 I
AV6 VCC PWR
AV8 VCC PWR
AW1 VCC PWR
AW11 VCC PWR
AW13 VCC PWR
AW15 VCC PWR
AW17 VCC PWR
AW3 VCC PWR
AW43 BPM_N[5] ODCMOS I/O
AW45 BCLK1_DP CMOS I
AW47 PE2D_TX_DP[15] PCIEX3 O
AW49 PE2D_TX_DP[13] PCIEX3 O
AW5 VCC PWR
AW51 PE2C_TX_DP[11] PCIEX3 O
AW53 PE2C_TX_DP[9] PCIEX3 O
AW55 VSS GND
AW57 VSS GND
AW7 VCC PWR
AW9 VCC PWR
AY10 VCC PWR
AY12 VCC PWR
AY14 VCC PWR
AY16 VCC PWR
AY2 VCC PWR
AY4 VCC PWR
AY42 VTTD PWR
AY44 BPM_N[7] ODCMOS I/O
AY46 RSVD
AY48 PE2D_TX_DN[14] PCIEX3 O
AY50 PE2D_TX_DN[12] PCIEX3 O
AY52 PE2C_TX_DN[8] PCIEX3 O
AY54 PE2C_TX_DP[10] PCIEX3 O
AY56 PE2D_RX_DP[15] PCIEX3 I
AY58 PE2D_RX_DP[14] PCIEX3 I
Table 8-2. Land Number (Sheet 11 of 49)
Land No. Land Name Buffer Type Direction
AY6 VCC PWR
AY8 VCC PWR
B10 DDR3_DQS_DN[04] SSTL I/O
B12 DDR3_DQ[37] SSTL I/O
B14 DDR3_CAS_N SSTL O
B16 DDR3_RAS_N SSTL O
B18 DDR3_MA_PAR SSTL O
B20 DDR3_MA[03] SSTL O
B22 DDR3_MA[07] SSTL O
B24 DDR3_BA[2] SSTL O
B32 DDR3_DQ[23] SSTL I/O
B34 DDR3_DQS_DN[11] SSTL I/O
B36 VSS GND
B38 DDR3_DQS_DN[00] SSTL I/O
B40 DDR3_DQ[00] SSTL I/O
B42 DMI_TX_DP[0] PCIEX O
B44 DMI_TX_DP[2] PCIEX O
B46 RSVD
B48 DMI_RX_DP[1] PCIEX I
B50 DMI_RX_DP[3] PCIEX I
B52 VSS GND
B54 VSA PWR
B6 VSS GND
B8 VSS GND
BA1 VCC PWR
BA11 VCC PWR
BA13 VCC PWR
BA15 VCC PWR
BA17 VCC PWR
BA3 VCC PWR
BA43 BPM_N[6] ODCMOS I/O
BA45 BCLK1_DN CMOS I
BA47 PE2D_TX_DN[15] PCIEX3 O
BA49 PE2D_TX_DN[13] PCIEX3 O
BA5 VCC PWR
BA51 PE2C_TX_DN[11] PCIEX3 O
BA53 PE2C_TX_DN[9] PCIEX3 O
BA55 TEST4 I
BA57 PE2D_RX_DN[14] PCIEX3 I
BA7 VCC PWR
BA9 VCC PWR
BB10 VCC PWR
Table 8-2. Land Number (Sheet 12 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 191
Datasheet Volume One of Two
Processor Land Listing
BB12 VCC PWR
BB14 VCC PWR
BB16 VCC PWR
BB2 VCC PWR
BB4 VCC PWR
BB42 VSS GND
BB44 BPM_N[4] ODCMOS I/O
BB46 VSS GND
BB48 VSS GND
BB50 VSS GND
BB52 VSS GND
BB54 PE2C_TX_DN[10] PCIEX3 O
BB56 PE2D_RX_DN[15] PCIEX3 I
BB58 VSS GND
BB6 VCC PWR
BB8 VCC PWR
BC1 VSS GND
BC11 VSS GND
BC13 VSS GND
BC15 VSS GND
BC17 VSS GND
BC3 VSS GND
BC43 VSS GND
BC45 VSS GND
BC47 RSVD
BC49 SOCKET_ID[1] CMOS I
BC5 VSS GND
BC51 ERROR_N[2] ODCMOS O
BC53 VSS GND
BC55 VSS GND
BC57 VSS GND
BC7 VSS GND
BC9 VSS GND
BD10 VSS GND
BD12 VSS GND
BD14 VSS GND
BD16 VSS GND
BD2 VSS GND
BD4 VSS GND
BD42 VTTD PWR
BD44 RSVD
BD46 RSVD
Table 8-2. Land Number (Sheet 13 of 49)
Land No. Land Name Buffer Type Direction
BD48 RSVD
BD50 ERROR_N[0] ODCMOS O
BD52 PROCHOT_N ODCMOS I/O
BD54 VSS GND
BD56 VSS GND
BD58 QPI0_DRX_DP[07] QPI I
BD6 VSS GND
BD8 VSS GND
BE1 VCC PWR
BE11 VCC PWR
BE13 VCC PWR
BE15 VCC PWR
BE17 VCC PWR
BE3 VCC PWR
BE43 RSVD
BE45 RSVD
BE47 RSVD
BE49 VSS GND
BE5 VCC PWR
BE51 VSS GND
BE53 QPI0_DRX_DP[02] QPI I
BE55 QPI0_DRX_DP[03] QPI I
BE57 QPI0_DRX_DP[08] QPI I
BE7 VCC PWR
BE9 VCC PWR
BF10 VCC PWR
BF12 VCC PWR
BF14 VCC PWR
BF16 VCC PWR
BF2 VCC PWR
BF4 VCC PWR
BF42 VSS GND
BF44 VSS GND
BF46 RSVD
BF48 PEHPSDA ODCMOS I/O
BF50 QPI0_DRX_DP[06] QPI I
BF52 QPI0_DRX_DP[01] QPI I
BF54 QPI0_DRX_DP[05] QPI I
BF56 QPI0_DRX_DP[04] QPI I
BF58 QPI0_DRX_DN[07] QPI I
BF6 VCC PWR
BF8 VCC PWR
Table 8-2. Land Number (Sheet 14 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
192 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
BG1 VCC PWR
BG11 VCC PWR
BG13 VCC PWR
BG15 VCC PWR
BG17 VCC PWR
BG3 VCC PWR
BG43 RSVD
BG45 RSVD
BG47 VSS GND
BG49 QPI0_DRX_DP[17] QPI I
BG5 VCC PWR
BG51 QPI0_DRX_DP[00] QPI I
BG53 QPI0_DRX_DN[02] QPI I
BG55 QPI0_DRX_DN[03] QPI I
BG57 QPI0_DRX_DN[08] QPI I
BG7 VCC PWR
BG9 VCC PWR
BH10 VCC PWR
BH12 VCC PWR
BH14 VCC PWR
BH16 VCC PWR
BH2 VCC PWR
BH4 VCC PWR
BH42 VTTD PWR
BH44 RSVD
BH46 RSVD
BH48 PEHPSCL ODCMOS I/O
BH50 QPI0_DRX_DN[06] QPI I
BH52 QPI0_DRX_DN[01] QPI I
BH54 QPI0_DRX_DN[05] QPI I
BH56 QPI0_DRX_DN[04] QPI I
BH58 VSS GND
BH6 VCC PWR
BH8 VCC PWR
BJ1 VCC PWR
BJ11 VCC PWR
BJ13 VCC PWR
BJ15 VCC PWR
BJ17 VCC PWR
BJ3 VCC PWR
BJ43 RSVD
BJ45 RSVD
Table 8-2. Land Number (Sheet 15 of 49)
Land No. Land Name Buffer Type Direction
BJ47 PECI PECI I/O
BJ49 QPI0_DRX_DN[17] QPI I
BJ5 VCC PWR
BJ51 QPI0_DRX_DN[00] QPI I
BJ53 PWRGOOD CMOS I
BJ55 VSS GND
BJ57 VSS GND
BJ7 VCC PWR
BJ9 VCC PWR
BK10 VCC PWR
BK12 VCC PWR
BK14 VCC PWR
BK16 VCC PWR
BK2 VCC PWR
BK4 VCC PWR
BK42 VSS GND
BK44 RSVD
BK46 VSS GND
BK48 VSS GND
BK50 VSS GND
BK52 VSS GND
BK54 VSS GND
BK56 VTTD PWR
BK58 QPI0_CLKRX_DP QPI I
BK6 VCC PWR
BK8 VCC PWR
BL1 VSS GND
BL11 VSS GND
BL13 VSS GND
BL15 VSS GND
BL17 VSS GND
BL3 VSS GND
BL43 RSVD
BL45 RSVD
BL47 THERMTRIP_N ODCMOS O
BL49 VSS GND
BL5 VSS GND
BL51 VTTD PWR
BL53 QPI0_DRX_DP[13] QPI I
BL55 QPI0_DRX_DP[11] QPI I
BL57 QPI0_DRX_DP[09] QPI I
BL7 VSS GND
Table 8-2. Land Number (Sheet 16 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 193
Datasheet Volume One of Two
Processor Land Listing
BL9 VSS GND
BM10 VSS GND
BM12 VSS GND
BM14 VSS GND
BM16 VSS GND
BM2 VSS GND
BM4 VSS GND
BM42 VTTD PWR
BM44 RSVD
BM46 RSVD
BM48 QPI0_DRX_DN[19] QPI I
BM50 QPI0_DRX_DP[16] QPI I
BM52 QPI0_DRX_DP[14] QPI I
BM54 QPI0_DRX_DP[12] QPI I
BM56 QPI0_DRX_DP[10] QPI I
BM58 QPI0_CLKRX_DN QPI I
BM6 VSS GND
BM8 VSS GND
BN1 VCC PWR
BN11 VCC PWR
BN13 VCC PWR
BN15 VCC PWR
BN17 VCC PWR
BN3 VCC PWR
BN43 VSS GND
BN45 VSS GND
BN47 RSVD
BN49 QPI0_DRX_DN[18] QPI I
BN5 VCC PWR
BN51 QPI0_DRX_DP[15] QPI I
BN53 QPI0_DRX_DN[13] QPI I
BN55 QPI0_DRX_DN[11] QPI I
BN57 QPI0_DRX_DN[09] QPI I
BN7 VCC PWR
BN9 VCC PWR
BP10 VCC PWR
BP12 VCC PWR
BP14 VCC PWR
BP16 VCC PWR
BP2 VCC PWR
BP4 VCC PWR
BP42 VTTD_SENSE O
Table 8-2. Land Number (Sheet 17 of 49)
Land No. Land Name Buffer Type Direction
BP44 RSVD
BP46 RSVD
BP48 QPI0_DRX_DP[19] QPI I
BP50 QPI0_DRX_DN[16] QPI I
BP52 QPI0_DRX_DN[14] QPI I
BP54 QPI0_DRX_DN[12] QPI I
BP56 QPI0_DRX_DN[10] QPI I
BP58 VSS GND
BP6 VCC PWR
BP8 VCC PWR
BR1 VCC PWR
BR11 VCC PWR
BR13 VCC PWR
BR15 VCC PWR
BR17 VCC PWR
BR3 VCC PWR
BR43 RSVD
BR45 SVIDDATA ODCMOS I/O
BR47 RSVD
BR49 QPI0_DRX_DP[18] QPI I
BR5 VCC PWR
BR51 QPI0_DRX_DN[15] QPI I
BR53 VSS GND
BR55 VTTD PWR
BR57 VSS GND
BR7 VCC PWR
BR9 VCC PWR
BT10 VCC PWR
BT12 VCC PWR
BT14 VCC PWR
BT16 VCC PWR
BT2 VCC PWR
BT4 VCC PWR
BT42 VSS_VTTD_SENSE O
BT44 RSVD
BT46 VSS GND
BT48 VSS GND
BT50 VSS GND
BT52 VSS GND
BT54 VSS GND
BT56 VSS GND
BT58 QPI0_DTX_DP[05] QPI O
Table 8-2. Land Number (Sheet 18 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
194 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
BT6 VCC PWR
BT8 VCC PWR
BU1 VCC PWR
BU11 VCC PWR
BU13 VCC PWR
BU15 VCC PWR
BU17 VCC PWR
BU3 VCC PWR
BU43 RSVD
BU45 VSS GND
BU47 VTTD PWR
BU49 SKTOCC_N O
BU5 VCC PWR
BU51 VSS GND
BU53 QPI0_DTX_DP[02] QPI O
BU55 QPI0_DTX_DP[04] QPI O
BU57 QPI0_DTX_DP[07] QPI O
BU7 VCC PWR
BU9 VCC PWR
BV10 VCC PWR
BV12 VCC PWR
BV14 VCC PWR
BV16 VCC PWR
BV2 VCC PWR
BV4 VCC PWR
BV42 VTTD PWR
BV44 TMS CMOS I
BV46 QPI0_DTX_DP[09] QPI O
BV48 QPI0_DTX_DP[06] QPI O
BV50 QPI0_DTX_DP[00] QPI O
BV52 QPI0_DTX_DP[01] QPI O
BV54 QPI0_DTX_DP[03] QPI O
BV56 QPI0_DTX_DP[08] QPI O
BV58 QPI0_DTX_DN[05] QPI O
BV6 VCC PWR
BV8 VCC PWR
BW1 VSS GND
BW11 VSS GND
BW13 VSS GND
BW15 VSS GND
BW17 VSS GND
BW3 VCC_SENSE O
Table 8-2. Land Number (Sheet 19 of 49)
Land No. Land Name Buffer Type Direction
BW43 TDI CMOS I
BW45 QPI0_DTX_DN[09] QPI O
BW47 QPI0_DTX_DN[06] QPI O
BW49 QPI0_DTX_DN[00] QPI O
BW5 VSS GND
BW51 QPI0_DTX_DN[01] QPI O
BW53 QPI0_DTX_DN[02] QPI O
BW55 QPI0_DTX_DN[04] QPI O
BW57 QPI0_DTX_DN[07] QPI O
BW7 VSS GND
BW9 DDR0_DQ[28] SSTL I/O
BY10 DDR0_DQ[24] SSTL I/O
BY12 DDR0_DQ[25] SSTL I/O
BY14 VCCPLL PWR
BY16 DDR_VREFDQRX_C01 DC I
BY18 VCC PWR
BY2 VSS_VCC_SENSE O
BY20 VTTD PWR
BY22 VTTD PWR
BY24 VSS GND
BY26 VCC PWR
BY28 VCC PWR
BY30 VCC PWR
BY32 VCC PWR
BY34 VCC PWR
BY36 VCC PWR
BY38 VCC PWR
BY4 VSS GND
BY40 VCC PWR
BY42 VSS GND
BY44 TCK CMOS I
BY46 RSVD
BY48 QPI0_DTX_DP[12] QPI O
BY50 QPI0_DTX_DP[13] QPI O
BY52 QPI0_DTX_DN[11] QPI O
BY54 QPI0_DTX_DN[03] QPI O
BY56 QPI0_DTX_DN[08] QPI O
BY58 VSS GND
BY6 DDR0_DQ[04] SSTL I/O
BY8 VSS GND
C11 VSS GND
C13 VSS GND
Table 8-2. Land Number (Sheet 20 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 195
Datasheet Volume One of Two
Processor Land Listing
C15 VCCD_23 PWR
C17 VCCD_23 PWR
C19 VCCD_23 PWR
C21 VCCD_23 PWR
C23 VCCD_23 PWR
C25 DDR3_ECC[3] SSTL I/O
C3 VSS GND
C33 VSS GND
C35 DDR3_DQ[21] SSTL I/O
C37 DDR3_DQ[02] SSTL I/O
C39 VSS GND
C41 VSS GND
C43 DMI_TX_DP[1] PCIEX O
C45 DMI_TX_DP[3] PCIEX O
C47 DMI_RX_DP[0] PCIEX I
C49 DMI_RX_DP[2] PCIEX I
C5 VSS GND
C51 PE1A_RX_DP[0] PCIEX3 I
C53 RSVD
C55 VSS GND
C7 DDR3_DQ[52] SSTL I/O
C9 DDR3_DQ[34] SSTL I/O
CA1 DDR0_DQ[12] SSTL I/O
CA11 VSS GND
CA13 VCCPLL PWR
CA15 VCCPLL PWR
CA17 DDR01_RCOMP[0] Analog I
CA19 VSS GND
CA21 VTTD PWR
CA23 VTTD PWR
CA25 VCC PWR
CA27 VSS GND
CA29 VCC PWR
CA3 DDR0_DQ[13] SSTL I/O
CA31 VSS GND
CA33 VSS GND
CA35 VSS GND
CA37 VSS GND
CA39 VSS GND
CA41 VSS GND
CA43 TDO ODCMOS O
CA45 RSVD
Table 8-2. Land Number (Sheet 21 of 49)
Land No. Land Name Buffer Type Direction
CA47 QPI0_DTX_DN[12] QPI O
CA49 QPI0_DTX_DN[13] QPI O
CA5 VSS GND
CA51 QPI0_DTX_DP[11] QPI O
CA53 VTTA PWR
CA55 VSS GND
CA57 VSS GND
CA7 DDR0_DQ[05] SSTL I/O
CA9 DDR0_DQ[29] SSTL I/O
CB10 DDR0_DQS_DP[12] SSTL I/O
CB12 DDR0_DQ[26] SSTL I/O
CB14 DDR0_ECC[4] SSTL I/O
CB16 VSS GND
CB18 DDR_RESET_C01_N CMOS1.5v O
CB2 DDR0_DQ[08] SSTL I/O
CB20 DDR01_RCOMP[2] Analog I
CB22 MEM_HOT_C01_N ODCMOS I/O
CB24 DDR0_ODT[4] SSTL O
CB26 DDR0_CS_N[6] SSTL O
CB28 DDR0_CS_N[3] SSTL O
CB30 DDR0_DQ[37] SSTL I/O
CB32 DDR0_DQS_DN[13] SSTL I/O
CB34 DDR0_DQ[39] SSTL I/O
CB36 VSS GND
CB38 DDR0_DQ[48] SSTL I/O
CB4 DDR0_DQ[09] SSTL I/O
CB40 DDR0_DQS_DN[06] SSTL I/O
CB42 DDR0_DQ[55] SSTL I/O
CB44 SVIDCLK ODCMOS O
CB46 VSS GND
CB48 VSS GND
CB50 VSS GND
CB52 VSS GND
CB54 ERROR_N[1] ODCMOS O
CB56 VSS GND
CB6 VSS GND
CB8 VSS GND
CC11 DDR0_DQS_DN[12] SSTL I/O
CC13 VSS GND
CC15 DDR0_ECC[1] SSTL I/O
CC17 DDR0_DQS_DP[08] SSTL I/O
CC19 DDR01_RCOMP[1] Analog I
Table 8-2. Land Number (Sheet 22 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
196 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
CC21 DDR0_PAR_ERR_N SSTL I
CC23 DDR0_CS_N[2] SSTL O
CC25 DDR0_CS_N[7] SSTL O
CC27 DDR0_ODT[5] SSTL O
CC29 VSS GND
CC3 VSS GND
CC31 DDR0_DQ[33] SSTL I/O
CC33 DDR0_DQS_DP[04] SSTL I/O
CC35 DDR0_DQ[35] SSTL I/O
CC37 DDR0_DQ[52] SSTL I/O
CC39 DDR0_DQS_DP[15] SSTL I/O
CC41 DDR0_DQ[54] SSTL I/O
CC43 VSS GND
CC45 VTTA PWR
CC47 VSS GND
CC49 VSS GND
CC5 DDR0_DQS_DP[10] SSTL I/O
CC51 CAT_ERR_N ODCMOS I/O
CC53 QPI_RBIAS_SENSE Analog I
CC55 QPI1_DRX_DP[00] QPI I
CC7 DDR0_DQ[00] SSTL I/O
CC9 VSS GND
CD10 DDR0_DQS_DN[03] SSTL I/O
CD12 DDR0_DQ[27] SSTL I/O
CD14 DDR0_ECC[5] SSTL I/O
CD16 DDR0_DQS_DP[17] SSTL I/O
CD18 VSS GND
CD20 VCCD_01 PWR
CD22 VCCD_01 PWR
CD24 VCCD_01 PWR
CD26 VCCD_01 PWR
CD28 VCCD_01 PWR
CD30 DDR0_DQ[36] SSTL I/O
CD32 DDR0_DQS_DP[13] SSTL I/O
CD34 DDR0_DQ[38] SSTL I/O
CD36 VSS GND
CD38 DDR0_DQ[49] SSTL I/O
CD4 DDR0_DQS_DN[10] SSTL I/O
CD40 DDR0_DQS_DP[06] SSTL I/O
CD42 DDR0_DQ[51] SSTL I/O
CD44 RSVD
CD46 QPI0_DTX_DP[10] QPI O
Table 8-2. Land Number (Sheet 23 of 49)
Land No. Land Name Buffer Type Direction
CD48 QPI0_DTX_DP[15] QPI O
CD50 QPI0_DTX_DP[16] QPI O
CD52 QPI0_DTX_DP[17] QPI O
CD54 QPI1_DRX_DP[02] QPI I
CD56 QPI1_DRX_DP[01] QPI I
CD6 VSS GND
CD8 DDR0_DQ[01] SSTL I/O
CE11 DDR0_DQS_DP[03] SSTL I/O
CE13 VSS GND
CE15 DDR0_ECC[0] SSTL I/O
CE17 DDR0_DQS_DN[08] SSTL I/O
CE19 DDR0_CKE[5] SSTL O
CE21 DDR0_CLK_DN[2] SSTL O
CE23 DDR0_CLK_DN[1] SSTL O
CE25 DDR0_ODT[0] SSTL O
CE27 DDR0_ODT[1] SSTL O
CE29 DDR0_RAS_N SSTL O
CE3 DDR0_DQS_DN[01] SSTL I/O
CE31 DDR0_DQ[32] SSTL I/O
CE33 DDR0_DQS_DN[04] SSTL I/O
CE35 DDR0_DQ[34] SSTL I/O
CE37 DDR0_DQ[53] SSTL I/O
CE39 DDR0_DQS_DN[15] SSTL I/O
CE41 DDR0_DQ[50] SSTL I/O
CE43 RSVD
CE45 QPI0_CLKTX_DP QPI O
CE47 QPI0_DTX_DP[14] QPI O
CE49 QPI0_DTX_DP[19] QPI O
CE5 VSS GND
CE51 QPI0_DTX_DP[18] QPI O
CE53 QPI_RBIAS Analog I/O
CE55 QPI1_DRX_DN[00] QPI I
CE7 DDR0_DQS_DP[09] SSTL I/O
CE9 VSS GND
CF10 DDR0_DQ[31] SSTL I/O
CF12 VSS GND
CF14 VSS GND
CF16 DDR0_DQS_DN[17] SSTL I/O
CF18 DDR0_ECC[3] SSTL I/O
CF20 DDR0_CKE[4] SSTL O
CF22 DDR0_CLK_DN[3] SSTL O
CF24 DDR0_CLK_DN[0] SSTL O
Table 8-2. Land Number (Sheet 24 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 197
Datasheet Volume One of Two
Processor Land Listing
CF26 DDR0_CS_N[5] SSTL O
CF28 DDR0_ODT[3] SSTL O
CF30 VSS GND
CF32 VSS GND
CF34 VSS GND
CF36 VSS GND
CF38 VSS GND
CF4 DDR0_DQS_DP[01] SSTL I/O
CF40 VSS GND
CF42 VSS GND
CF44 RSVD
CF46 QPI0_DTX_DN[10] QPI O
CF48 QPI0_DTX_DN[15] QPI O
CF50 QPI0_DTX_DN[16] QPI O
CF52 QPI0_DTX_DN[17] QPI O
CF54 QPI1_DRX_DN[02] QPI I
CF56 QPI1_DRX_DN[01] QPI I
CF6 VSS GND
CF8 DDR0_DQS_DN[09] SSTL I/O
CG11 RSVD
CG13 DDR0_DQ[20] SSTL I/O
CG15 VSS GND
CG17 DDR0_ECC[6] SSTL I/O
CG19 DDR0_MA[14] SSTL O
CG21 DDR0_CLK_DP[2] SSTL O
CG23 DDR0_CLK_DP[1] SSTL O
CG25 DDR0_MA[02] SSTL O
CG27 DDR0_CS_N[4] SSTL O
CG29 DDR0_MA[13] SSTL O
CG3 DDR0_DQ[14] SSTL I/O
CG31 VSS GND
CG33 VSS GND
CG35 VSS GND
CG37 VSS GND
CG39 VSS GND
CG41 VSS GND
CG43 VSS GND
CG45 QPI0_CLKTX_DN QPI O
CG47 QPI0_DTX_DN[14] QPI O
CG49 QPI0_DTX_DN[19] QPI O
CG5 DDR0_DQ[15] SSTL I/O
CG51 QPI0_DTX_DN[18] QPI O
Table 8-2. Land Number (Sheet 25 of 49)
Land No. Land Name Buffer Type Direction
CG53 VSS GND
CG55 VTTA PWR
CG7 DDR0_DQS_DN[00] SSTL I/O
CG9 VSS GND
CH10 DDR0_DQ[30] SSTL I/O
CH12 VSS GND
CH14 DDR0_DQS_DN[02] SSTL I/O
CH16 VSS GND
CH18 DDR0_ECC[2] SSTL I/O
CH20 DDR0_CKE[2] SSTL O
CH22 DDR0_CLK_DP[3] SSTL O
CH24 DDR0_CLK_DP[0] SSTL O
CH26 DDR0_CS_N[1] SSTL O
CH28 DDR0_ODT[2] SSTL O
CH30 DDR0_DQ[45] SSTL I/O
CH32 DDR0_DQS_DN[14] SSTL I/O
CH34 DDR0_DQ[47] SSTL I/O
CH36 VSS GND
CH38 DDR0_DQ[56] SSTL I/O
CH4 DDR0_DQ[10] SSTL I/O
CH40 DDR0_DQS_DN[07] SSTL I/O
CH42 DDR0_DQ[58] SSTL I/O
CH44 VSS GND
CH46 VSS GND
CH48 VSS GND
CH50 VSS GND
CH52 VSS GND
CH54 VSS GND
CH56 EAR_N ODCMOS I/O
CH6 VSS GND
CH8 DDR0_DQS_DP[00] SSTL I/O
CJ11 VSS GND
CJ13 DDR0_DQS_DP[11] SSTL I/O
CJ15 DDR0_DQ[22] SSTL I/O
CJ17 VSS GND
CJ19 VCCD_01 PWR
CJ21 VCCD_01 PWR
CJ23 VCCD_01 PWR
CJ25 VCCD_01 PWR
CJ27 VCCD_01 PWR
CJ29 VSS GND
CJ3 VSS GND
Table 8-2. Land Number (Sheet 26 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
198 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
CJ31 DDR0_DQ[41] SSTL I/O
CJ33 DDR0_DQS_DP[05] SSTL I/O
CJ35 DDR0_DQ[43] SSTL I/O
CJ37 DDR0_DQ[60] SSTL I/O
CJ39 DDR0_DQS_DP[16] SSTL I/O
CJ41 DDR0_DQ[62] SSTL I/O
CJ43 VSS GND
CJ45 VSS GND
CJ47 VSS GND
CJ49 VTTA PWR
CJ5 DDR0_DQ[11] SSTL I/O
CJ51 VSS GND
CJ53 QPI1_DRX_DP[09] QPI I
CJ55 QPI1_DRX_DP[03] QPI I
CJ7 DDR0_DQ[06] SSTL I/O
CJ9 VSS GND
CK10 VSS GND
CK12 DDR0_DQ[16] SSTL I/O
CK14 DDR0_DQS_DP[02] SSTL I/O
CK16 DDR0_DQ[18] SSTL I/O
CK18 DDR0_ECC[7] SSTL I/O
CK20 DDR0_MA[12] SSTL O
CK22 DDR0_MA[08] SSTL O
CK24 DDR0_MA[03] SSTL O
CK26 DDR0_MA[10] SSTL O
CK28 DDR0_CS_N[9] SSTL O
CK30 DDR0_DQ[44] SSTL I/O
CK32 DDR0_DQS_DP[14] SSTL I/O
CK34 DDR0_DQ[46] SSTL I/O
CK36 VSS GND
CK38 DDR0_DQ[57] SSTL I/O
CK4 VSS GND
CK40 DDR0_DQS_DP[07] SSTL I/O
CK42 DDR0_DQ[59] SSTL I/O
CK44 RESET_N CMOS I
CK46 QPI1_DRX_DP[18] QPI I
CK48 QPI1_DRX_DP[16] QPI I
CK50 QPI1_DRX_DN[14] QPI I
CK52 QPI1_DRX_DP[10] QPI I
CK54 QPI1_DRX_DP[05] QPI I
CK56 QPI1_DRX_DP[04] QPI I
CK6 VSS GND
Table 8-2. Land Number (Sheet 27 of 49)
Land No. Land Name Buffer Type Direction
CK8 DDR0_DQ[02] SSTL I/O
CL11 DDR0_DQ[21] SSTL I/O
CL13 DDR0_DQS_DN[11] SSTL I/O
CL15 DDR0_DQ[23] SSTL I/O
CL17 VSS GND
CL19 DDR0_CKE[0] SSTL O
CL21 DDR0_MA[11] SSTL O
CL23 DDR0_MA[05] SSTL O
CL25 DDR0_MA[00] SSTL O
CL27 DDR0_CS_N[8] SSTL O
CL29 DDR0_CAS_N SSTL O
CL3 DDR1_DQ[05] SSTL I/O
CL31 DDR0_DQ[40] SSTL I/O
CL33 DDR0_DQS_DN[05] SSTL I/O
CL35 DDR0_DQ[42] SSTL I/O
CL37 DDR0_DQ[61] SSTL I/O
CL39 DDR0_DQS_DN[16] SSTL I/O
CL41 DDR0_DQ[63] SSTL I/O
CL43 VSS GND
CL45 QPI1_DRX_DP[19] QPI I
CL47 QPI1_DRX_DP[17] QPI I
CL49 QPI1_DRX_DN[15] QPI I
CL5 VSS GND
CL51 QPI1_DRX_DN[13] QPI I
CL53 QPI1_DRX_DN[09] QPI I
CL55 QPI1_DRX_DN[03] QPI I
CL7 DDR0_DQ[07] SSTL I/O
CL9 DDR0_DQ[03] SSTL I/O
CM10 VSS GND
CM12 DDR0_DQ[17] SSTL I/O
CM14 VSS GND
CM16 DDR0_DQ[19] SSTL I/O
CM18 DDR0_CKE[1] SSTL O
CM20 DDR0_BA[2] SSTL O
CM22 DDR0_MA[07] SSTL O
CM24 DDR0_MA[04] SSTL O
CM26 DDR0_MA_PAR SSTL O
CM28 DDR0_BA[0] SSTL O
CM30 VSS GND
CM32 VSS GND
CM34 VSS GND
CM36 VSS GND
Table 8-2. Land Number (Sheet 28 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 199
Datasheet Volume One of Two
Processor Land Listing
CM38 VSS GND
CM4 DDR1_DQ[04] SSTL I/O
CM40 VSS GND
CM42 VSS GND
CM44 BCLK0_DN CMOS I
CM46 QPI1_DRX_DN[18] QPI I
CM48 QPI1_DRX_DN[16] QPI I
CM50 QPI1_DRX_DP[14] QPI I
CM52 QPI1_DRX_DN[10] QPI I
CM54 QPI1_DRX_DN[05] QPI I
CM56 QPI1_DRX_DN[04] QPI I
CM6 VSS GND
CM8 VSS GND
CN11 VSS GND
CN13 VSS GND
CN15 VSS GND
CN17 VSS GND
CN19 DDR0_MA[15] SSTL O
CN21 DDR0_MA[09] SSTL O
CN23 DDR0_MA[06] SSTL O
CN25 DDR0_CS_N[0] SSTL O
CN27 DDR0_BA[1] SSTL O
CN29 DDR0_WE_N SSTL O
CN3 VSS GND
CN31 VSS GND
CN33 VSS GND
CN35 VSS GND
CN37 VSS GND
CN39 VSS GND
CN41 DDR_VREFDQTX_C01 DC O
CN43 BCLK0_DP CMOS I
CN45 QPI1_DRX_DN[19] QPI I
CN47 QPI1_DRX_DN[17] QPI I
CN49 QPI1_DRX_DP[15] QPI I
CN5 VSS GND
CN51 QPI1_DRX_DP[13] QPI I
CN53 VSS GND
CN55 VSS GND
CN57 VSS GND
CN7 VSS GND
CN9 VSS GND
CP10 DDR1_DQ[19] SSTL I/O
Table 8-2. Land Number (Sheet 29 of 49)
Land No. Land Name Buffer Type Direction
CP12 VSS GND
CP14 DDR1_DQS_DN[12] SSTL I/O
CP16 VSS GND
CP18 DDR0_CKE[3] SSTL O
CP2 DDR1_DQ[01] SSTL I/O
CP20 VCCD_01 PWR
CP22 VCCD_01 PWR
CP24 VCCD_01 PWR
CP26 VCCD_01 PWR
CP28 VCCD_01 PWR
CP30 DDR1_DQ[33] SSTL I/O
CP32 DDR1_DQS_DP[04] SSTL I/O
CP34 DDR1_DQ[35] SSTL I/O
CP36 VSS GND
CP38 DDR1_DQS_DP[15] SSTL I/O
CP4 DDR1_DQ[00] SSTL I/O
CP40 VSS GND
CP42 VSS GND
CP44 VSS GND
CP46 VSS GND
CP48 VSS GND
CP50 VSS GND
CP52 VSS GND
CP54 RSVD
CP56 VSS GND
CP58 QPI1_DRX_DP[06] QPI I
CP6 DDR1_DQ[20] SSTL I/O
CP8 DDR1_DQS_DP[11] SSTL I/O
CR1 DDR1_DQS_DN[09] SSTL I/O
CR11 VSS GND
CR13 DDR1_DQ[24] SSTL I/O
CR15 DDR1_DQS_DN[03] SSTL I/O
CR17 DDR1_DQ[26] SSTL I/O
CR19 DDR1_CKE[4] SSTL O
CR21 DDR1_CS_N[8] SSTL O
CR23 DDR1_CS_N[2] SSTL O
CR25 DDR0_MA[01] SSTL O
CR27 DDR1_CS_N[3] SSTL O
CR29 DDR1_DQ[37] SSTL I/O
CR3 DDR1_DQS_DP[00] SSTL I/O
CR31 DDR1_DQS_DN[13] SSTL I/O
CR33 DDR1_DQ[39] SSTL I/O
Table 8-2. Land Number (Sheet 30 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
200 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
CR35 VSS GND
CR37 DDR1_DQ[48] SSTL I/O
CR39 DDR1_DQS_DN[06] SSTL I/O
CR41 DDR1_DQ[50] SSTL I/O
CR43 SVIDALERT_N CMOS I
CR45 VTTA PWR
CR47 VSS GND
CR49 VSS GND
CR5 VSS GND
CR51 VTTA PWR
CR53 QPI1_DRX_DN[11] QPI I
CR55 QPI1_CLKRX_DP QPI I
CR57 QPI1_DRX_DP[07] QPI I
CR7 DDR1_DQ[16] SSTL I/O
CR9 VSS GND
CT10 DDR1_DQ[18] SSTL I/O
CT12 DDR1_DQ[28] SSTL I/O
CT14 DDR1_DQS_DP[12] SSTL I/O
CT16 DDR1_DQ[30] SSTL I/O
CT18 DDR1_CKE[5] SSTL O
CT2 DDR1_DQS_DP[09] SSTL I/O
CT20 DDR1_CKE[0] SSTL O
CT22 DDR1_ODT[0] SSTL O
CT24 DDR1_CS_N[5] SSTL O
CT26 DDR1_CS_N[7] SSTL O
CT28 VSS GND
CT30 DDR1_DQ[32] SSTL I/O
CT32 DDR1_DQS_DN[04] SSTL I/O
CT34 DDR1_DQ[34] SSTL I/O
CT36 DDR1_DQ[52] SSTL I/O
CT38 DDR1_DQS_DN[15] SSTL I/O
CT4 DDR1_DQS_DN[00] SSTL I/O
CT40 DDR1_DQ[54] SSTL I/O
CT42 VSS GND
CT44 QPI1_DTX_DP[14] QPI O
CT46 QPI1_DTX_DP[08] QPI O
CT48 QPI1_DTX_DP[00] QPI O
CT50 QPI1_DTX_DP[01] QPI O
CT52 QPI1_DRX_DN[12] QPI I
CT54 TRST_N CMOS I
CT56 QPI1_DRX_DP[08] QPI I
CT58 QPI1_DRX_DN[06] QPI I
Table 8-2. Land Number (Sheet 31 of 49)
Land No. Land Name Buffer Type Direction
CT6 DDR1_DQ[21] SSTL I/O
CT8 DDR1_DQS_DN[11] SSTL I/O
CU1 VSS GND
CU11 VSS GND
CU13 DDR1_DQ[25] SSTL I/O
CU15 DDR1_DQS_DP[03] SSTL I/O
CU17 DDR1_DQ[27] SSTL I/O
CU19 DDR1_CKE[1] SSTL O
CU21 DDR1_PAR_ERR_N SSTL I
CU23 DDR1_CS_N[1] SSTL O
CU25 DDR1_CS_N[4] SSTL O
CU27 DDR1_ODT[4] SSTL O
CU29 DDR1_DQ[36] SSTL I/O
CU3 VSS GND
CU31 DDR1_DQS_DP[13] SSTL I/O
CU33 DDR1_DQ[38] SSTL I/O
CU35 VSS GND
CU37 DDR1_DQ[49] SSTL I/O
CU39 DDR1_DQS_DP[06] SSTL I/O
CU41 DDR1_DQ[51] SSTL I/O
CU43 QPI1_DTX_DP[17] QPI O
CU45 QPI1_DTX_DP[11] QPI O
CU47 QPI1_DTX_DP[05] QPI O
CU49 QPI1_DTX_DP[02] QPI O
CU5 VSS GND
CU51 QPI_VREF_CAP QPI I/O
CU53 QPI1_DRX_DP[11] QPI I
CU55 QPI1_CLKRX_DN QPI I
CU57 QPI1_DRX_DN[07] QPI I
CU7 DDR1_DQ[17] SSTL I/O
CU9 DDR1_DQS_DP[02] SSTL I/O
CV10 DDR1_DQ[23] SSTL I/O
CV12 DDR1_DQ[29] SSTL I/O
CV14 VSS GND
CV16 DDR1_DQ[31] SSTL I/O
CV18 VSS GND
CV2 DDR1_DQ[06] SSTL I/O
CV20 DDR1_CLK_DN[0] SSTL O
CV22 DDR1_CLK_DN[1] SSTL O
CV24 DDR1_CLK_DP[2] SSTL O
CV26 DDR1_ODT[3] SSTL O
CV28 DDR1_WE_N SSTL O
Table 8-2. Land Number (Sheet 32 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 201
Datasheet Volume One of Two
Processor Land Listing
CV30 VSS GND
CV32 VSS GND
CV34 VSS GND
CV36 DDR1_DQ[53] SSTL I/O
CV38 VSS GND
CV4 DDR1_DQ[02] SSTL I/O
CV40 DDR1_DQ[55] SSTL I/O
CV42 VSS GND
CV44 QPI1_DTX_DN[14] QPI O
CV46 QPI1_DTX_DN[08] QPI O
CV48 QPI1_DTX_DN[00] QPI O
CV50 QPI1_DTX_DN[01] QPI O
CV52 QPI1_DRX_DP[12] QPI I
CV54 VSS GND
CV56 QPI1_DRX_DN[08] QPI I
CV58 VSS GND
CV6 VSS GND
CV8 DDR1_DQS_DN[02] SSTL I/O
CW1 TEST1 O
CW11 VSS GND
CW13 VSS GND
CW15 VSS GND
CW17 DRAM_PWR_OK_C01 CMOS1.5v I
CW19 VCCD_01 PWR
CW21 VCCD_01 PWR
CW23 VCCD_01 PWR
CW25 VCCD_01 PWR
CW27 VCCD_01 PWR
CW29 VSS GND
CW3 DDR1_DQ[07] SSTL I/O
CW31 VSS GND
CW33 VSS GND
CW35 VSS GND
CW37 VSS GND
CW39 VSS GND
CW41 DDR_SDA_C01 ODCMOS I/O
CW43 QPI1_DTX_DN[17] QPI O
CW45 QPI1_DTX_DN[11] QPI O
CW47 QPI1_DTX_DN[05] QPI O
CW49 QPI1_DTX_DN[02] QPI O
CW5 VSS GND
CW51 VSS GND
Table 8-2. Land Number (Sheet 33 of 49)
Land No. Land Name Buffer Type Direction
CW53 VSS GND
CW55 VSS GND
CW57 VSS GND
CW7 VSS GND
CW9 DDR1_DQ[22] SSTL I/O
CY10 VSS GND
CY12 VSS GND
CY14 DDR1_DQS_DP[17] SSTL I/O
CY16 VSS GND
CY18 DDR1_CKE[2] SSTL O
CY2 VSS GND
CY20 DDR1_CLK_DP[0] SSTL O
CY22 DDR1_CLK_DP[1] SSTL O
CY24 DDR1_CLK_DN[2] SSTL O
CY26 DDR1_ODT[2] SSTL O
CY28 DDR1_ODT[5] SSTL O
CY30 DDR1_CAS_N SSTL O
CY32 DDR1_DQ[45] SSTL I/O
CY34 DDR1_DQS_DN[05] SSTL I/O
CY36 VSS GND
CY38 DDR1_DQS_DN[16] SSTL I/O
CY4 DDR1_DQ[03] SSTL I/O
CY40 VSS GND
CY42 DDR_SCL_C01 ODCMOS I/O
CY44 VSS GND
CY46 RSVD
CY48 RSVD
CY50 VSS GND
CY52 SOCKET_ID[0] CMOS I
CY54 QPI1_CLKTX_DN QPI O
CY56 RSVD
CY58 RSVD
CY6 DDR1_DQ[12] SSTL I/O
CY8 VSS GND
D10 DDR3_DQS_DP[04] SSTL I/O
D12 DDR3_DQ[32] SSTL I/O
D14 DDR3_ODT[4] SSTL O
D16 DDR3_CS_N[8] SSTL O
D18 DDR3_MA[10] SSTL O
D2 VSS GND
D20 DDR3_MA[04] SSTL O
D22 DDR3_MA[08] SSTL O
Table 8-2. Land Number (Sheet 34 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
202 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
D24 DDR3_MA[14] SSTL O
D26 VSS GND
D32 DDR3_DQ[18] SSTL I/O
D34 DDR3_DQS_DP[11] SSTL I/O
D36 VSS GND
D38 DDR3_DQS_DP[00] SSTL I/O
D4 TEST3 O
D40 DDR3_DQ[05] SSTL I/O
D42 DMI_TX_DN[0] PCIEX O
D44 DMI_TX_DN[2] PCIEX O
D46 RSVD
D48 DMI_RX_DN[1] PCIEX I
D50 DMI_RX_DN[3] PCIEX I
D52 PE1A_RX_DP[1] PCIEX3 I
D54 PE1A_RX_DP[2] PCIEX3 I
D56 RSVD
D6 DDR3_DQ[53] SSTL I/O
D8 VSS GND
DA11 VSS GND
DA13 DDR1_ECC[4] SSTL I/O
DA15 DDR1_ECC[6] SSTL I/O
DA17 DDR1_CKE[3] SSTL O
DA19 DDR1_MA[09] SSTL O
DA21 DDR1_CLK_DN[3] SSTL O
DA23 DDR1_MA[03] SSTL O
DA25 DDR1_ODT[1] SSTL O
DA27 DDR1_CS_N[9] SSTL O
DA29 DDR1_CS_N[6] SSTL O
DA3 VSS GND
DA31 DDR1_DQ[44] SSTL I/O
DA33 DDR1_DQ[40] SSTL I/O
DA35 DDR1_DQ[43] SSTL I/O
DA37 DDR1_DQ[60] SSTL I/O
DA39 DDR1_DQ[62] SSTL I/O
DA41 VSS GND
DA43 VSS GND
DA45 VSS GND
DA47 VSS GND
DA49 VTTA PWR
DA5 VSS GND
DA51 VSS GND
DA53 QPI1_DTX_DP[03] QPI O
Table 8-2. Land Number (Sheet 35 of 49)
Land No. Land Name Buffer Type Direction
DA55 SAFE_MODE_BOOT CMOS I
DA57 RSVD
DA7 DDR1_DQ[08] SSTL I/O
DA9 VSS GND
DB10 DDR1_DQ[14] SSTL I/O
DB12 VSS GND
DB14 DDR1_DQS_DN[17] SSTL I/O
DB16 DDR1_ECC[3] SSTL I/O
DB18 DDR1_MA[14] SSTL O
DB2 VSS GND
DB20 DDR1_MA[08] SSTL O
DB22 DDR1_MA[04] SSTL O
DB24 DDR1_CS_N[0] SSTL O
DB26 DDR1_BA[0] SSTL O
DB28 DDR1_RAS_N SSTL O
DB30 DDR1_MA[13] SSTL O
DB32 VSS GND
DB34 DDR1_DQS_DP[05] SSTL I/O
DB36 VSS GND
DB38 DDR1_DQS_DP[16] SSTL I/O
DB4 TEST0 O
DB40 DDR1_DQ[59] SSTL I/O
DB42 QPI1_DTX_DP[19] QPI O
DB44 QPI1_DTX_DP[16] QPI O
DB46 QPI1_DTX_DP[13] QPI O
DB48 QPI1_DTX_DP[10] QPI O
DB50 QPI1_DTX_DN[07] QPI O
DB52 QPI1_DTX_DN[04] QPI O
DB54 QPI1_CLKTX_DP QPI O
DB56 RSVD
DB58 VSS GND
DB6 DDR1_DQ[13] SSTL I/O
DB8 DDR1_DQS_DN[10] SSTL I/O
DC11 DDR1_DQ[10] SSTL I/O
DC13 DDR1_ECC[5] SSTL I/O
DC15 DDR1_DQS_DP[08] SSTL I/O
DC17 DDR1_MA[15] SSTL O
DC19 DDR1_MA[12] SSTL O
DC21 DDR1_CLK_DP[3] SSTL O
DC23 DDR1_MA[00] SSTL O
DC25 DDR1_BA[1] SSTL O
DC3 VSS GND
Table 8-2. Land Number (Sheet 36 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 203
Datasheet Volume One of Two
Processor Land Listing
DC33 DDR1_DQS_DP[14] SSTL I/O
DC35 DDR1_DQ[42] SSTL I/O
DC37 DDR1_DQ[61] SSTL I/O
DC39 DDR1_DQS_DP[07] SSTL I/O
DC41 VSS GND
DC43 QPI1_DTX_DN[18] QPI O
DC45 QPI1_DTX_DN[15] QPI O
DC47 QPI1_DTX_DN[12] QPI O
DC49 QPI1_DTX_DP[09] QPI O
DC5 VSS GND
DC51 QPI1_DTX_DP[06] QPI O
DC53 QPI1_DTX_DN[03] QPI O
DC55 RSVD
DC7 DDR1_DQ[09] SSTL I/O
DC9 DDR1_DQS_DN[01] SSTL I/O
DD10 VSS GND
DD12 VSS GND
DD14 VSS GND
DD16 DDR1_ECC[2] SSTL I/O
DD18 VCCD_01 PWR
DD20 VCCD_01 PWR
DD22 VCCD_01 PWR
DD24 VCCD_01 PWR
DD26 VCCD_01 PWR
DD32 DDR1_DQ[41] SSTL I/O
DD34 VSS GND
DD36 VSS GND
DD38 VSS GND
DD40 DDR1_DQ[58] SSTL I/O
DD42 QPI1_DTX_DN[19] QPI O
DD44 QPI1_DTX_DN[16] QPI O
DD46 QPI1_DTX_DN[13] QPI O
DD48 QPI1_DTX_DN[10] QPI O
DD50 QPI1_DTX_DP[07] QPI O
DD52 QPI1_DTX_DP[04] QPI O
DD54 RSVD
DD6 VSS GND
DD8 DDR1_DQS_DP[10] SSTL I/O
DE11 DDR1_DQ[11] SSTL I/O
DE13 DDR1_ECC[0] SSTL I/O
DE15 DDR1_DQS_DN[08] SSTL I/O
DE17 VSS GND
Table 8-2. Land Number (Sheet 37 of 49)
Land No. Land Name Buffer Type Direction
DE19 DDR1_MA[11] SSTL O
DE21 DDR1_MA[06] SSTL O
DE23 DDR1_MA[01] SSTL O
DE25 DDR1_MA_PAR SSTL O
DE33 DDR1_DQS_DN[14] SSTL I/O
DE35 DDR1_DQ[47] SSTL I/O
DE37 DDR1_DQ[56] SSTL I/O
DE39 DDR1_DQS_DN[07] SSTL I/O
DE41 VSS GND
DE43 QPI1_DTX_DP[18] QPI O
DE45 QPI1_DTX_DP[15] QPI O
DE47 QPI1_DTX_DP[12] QPI O
DE49 QPI1_DTX_DN[09] QPI O
DE51 QPI1_DTX_DN[06] QPI O
DE53 VSS GND
DE55 RSVD
DE7 VSS GND
DE9 DDR1_DQS_DP[01] SSTL I/O
DF10 DDR1_DQ[15] SSTL I/O
DF12 VSS GND
DF14 DDR1_ECC[1] SSTL I/O
DF16 DDR1_ECC[7] SSTL I/O
DF18 DDR1_BA[2] SSTL O
DF20 DDR1_MA[07] SSTL O
DF22 DDR1_MA[05] SSTL O
DF24 DDR1_MA[02] SSTL O
DF26 DDR1_MA[10] SSTL O
DF34 DDR1_DQ[46] SSTL I/O
DF36 VSS GND
DF38 DDR1_DQ[57] SSTL I/O
DF40 DDR1_DQ[63] SSTL I/O
DF42 VSS GND
DF44 VSS GND
DF46 VSS GND
DF48 VSS GND
DF50 VSS GND
DF52 VSS GND
DF8 VSS GND
E1 VSS GND
E11 DDR3_DQS_DP[13] SSTL I/O
E13 MEM_HOT_C23_N ODCMOS I/O
E15 DDR3_CS_N[7] SSTL O
Table 8-2. Land Number (Sheet 38 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
204 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
E17 DDR3_ODT[2] SSTL O
E19 DDR3_BA[1] SSTL O
E21 DDR3_MA[01] SSTL O
E23 DDR3_MA[12] SSTL O
E25 DDR3_ECC[2] SSTL I/O
E27 DDR3_DQS_DP[08] SSTL I/O
E29 VSS GND
E3 VSS GND
E31 VSS GND
E33 DDR3_DQS_DP[02] SSTL I/O
E35 DDR3_DQ[20] SSTL I/O
E37 DDR3_DQ[03] SSTL I/O
E39 DDR3_DQS_DP[09] SSTL I/O
E41 VSS GND
E43 DMI_TX_DN[1] PCIEX O
E45 DMI_TX_DN[3] PCIEX O
E47 DMI_RX_DN[0] PCIEX I
E49 DMI_RX_DN[2] PCIEX I
E5 VSS GND
E51 PE1A_RX_DN[0] PCIEX3 I
E53 RSVD
E55 PE1A_RX_DP[3] PCIEX3 I
E57 RSVD
E7 DDR3_DQ[48] SSTL I/O
E9 DDR3_DQ[35] SSTL I/O
F10 DDR3_DQ[38] SSTL I/O
F12 DDR3_DQ[36] SSTL I/O
F14 DDR3_CS_N[2] SSTL O
F16 DDR3_CS_N[6] SSTL O
F18 DDR3_ODT[1] SSTL O
F2 TEST2 O
F20 DDR3_MA[02] SSTL O
F22 DDR3_MA[06] SSTL O
F24 DDR3_MA[15] SSTL O
F26 DDR3_ECC[6] SSTL I/O
F28 DDR3_DQS_DP[17] SSTL I/O
F30 DDR3_ECC[4] SSTL I/O
F32 DDR3_DQ[19] SSTL I/O
F34 DDR3_DQ[17] SSTL I/O
F36 VSS GND
F38 DDR3_DQ[06] SSTL I/O
F4 DDR3_DQ[60] SSTL I/O
Table 8-2. Land Number (Sheet 39 of 49)
Land No. Land Name Buffer Type Direction
F40 DDR3_DQ[04] SSTL I/O
F42 VSS GND
F44 VSS GND
F46 RSVD
F48 VSS GND
F50 VSS GND
F52 PE1A_RX_DN[1] PCIEX3 I
F54 PE1A_RX_DN[2] PCIEX3 I
F56 RSVD
F58 RSVD
F6 DDR3_DQ[49] SSTL I/O
F8 VSS GND
G1 VSS GND
G11 DDR3_DQS_DN[13] SSTL I/O
G13 VCCD_23 PWR
G15 DDR3_CS_N[3] SSTL O
G17 DDR3_CS_N[5] SSTL O
G19 DDR3_CS_N[0] SSTL O
G21 DDR3_PAR_ERR_N SSTL I
G23 DDR3_MA[09] SSTL O
G25 VSS GND
G27 DDR3_DQS_DN[08] SSTL I/O
G29 DDR3_ECC[0] SSTL I/O
G3 DDR3_DQ[56] SSTL I/O
G31 VSS GND
G33 DDR3_DQS_DN[02] SSTL I/O
G35 VSS GND
G37 VSS GND
G39 DDR3_DQS_DN[09] SSTL I/O
G41 VSS GND
G43 VSA PWR
G45 VSS GND
G47 VSS GND
G49 VSA PWR
G5 VSS GND
G51 VSS GND
G53 VSS GND
G55 PE1A_RX_DN[3] PCIEX3 I
G57 VSS GND
G7 DDR3_DQS_DP[15] SSTL I/O
G9 VSS GND
H10 VSS GND
Table 8-2. Land Number (Sheet 40 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 205
Datasheet Volume One of Two
Processor Land Listing
H12 VSS GND
H14 VSS GND
H16 VCCD_23 PWR
H18 VCCD_23 PWR
H2 DDR3_DQ[57] SSTL I/O
H20 VCCD_23 PWR
H22 VCCD_23 PWR
H24 VCCD_23 PWR
H26 DDR3_ECC[7] SSTL I/O
H28 DDR3_DQS_DN[17] SSTL I/O
H30 DDR3_ECC[5] SSTL I/O
H32 VSS GND
H34 VSS GND
H36 DDR3_DQ[15] SSTL I/O
H38 VSS GND
H4 DDR3_DQ[61] SSTL I/O
H40 VSS GND
H42 PE1A_TX_DP[0] PCIEX3 O
H44 PE1A_TX_DP[2] PCIEX3 O
H46 PE1B_TX_DP[4] PCIEX3 O
H48 PE1B_TX_DP[6] PCIEX3 O
H50 PE3A_TX_DP[0] PCIEX3 O
H52 VSS GND
H54 VSS GND
H56 RSVD
H58 RSVD
H6 DDR3_DQS_DN[15] SSTL I/O
H8 VSS GND
J1 DDR_VREFDQRX_C23 DC I
J11 VSS GND
J13 DDR3_DQ[40] SSTL I/O
J15 RSVD
J17 DDR3_ODT[3] SSTL O
J19 DDR3_CS_N[1] SSTL O
J21 DDR3_CLK_DN[1] SSTL O
J23 DDR3_CLK_DN[0] SSTL O
J25 DDR3_CKE[2] SSTL O
J27 VSS GND
J29 DDR3_ECC[1] SSTL I/O
J3 DDR3_DQS_DP[16] SSTL I/O
J31 VSS GND
J33 VSS GND
Table 8-2. Land Number (Sheet 41 of 49)
Land No. Land Name Buffer Type Direction
J35 DDR3_DQ[11] SSTL I/O
J37 DDR3_DQS_DP[01] SSTL I/O
J39 VSS GND
J41 VSS GND
J43 PE1A_TX_DP[1] PCIEX3 O
J45 PE1A_TX_DP[3] PCIEX3 O
J47 PE1B_TX_DP[5] PCIEX3 O
J49 PE1B_TX_DP[7] PCIEX3 O
J5 VSS GND
J51 PE3A_TX_DP[1] PCIEX3 O
J53 PE1B_RX_DP[4] PCIEX3 I
J55 VSS GND
J57 PE1B_RX_DP[6] PCIEX3 I
J7 DDR3_DQS_DN[06] SSTL I/O
J9 DDR3_DQ[42] SSTL I/O
K10 DDR3_DQ[46] SSTL I/O
K12 DDR3_DQS_DP[14] SSTL I/O
K14 DDR3_DQ[44] SSTL I/O
K16 DDR3_CS_N[9] SSTL O
K18 DDR3_CS_N[4] SSTL O
K2 VSS GND
K20 DDR3_CLK_DP[2] SSTL O
K22 DDR3_CLK_DN[3] SSTL O
K24 DDR3_CKE[0] SSTL O
K26 VSS GND
K28 VSS GND
K30 VSS GND
K32 DDR3_DQ[29] SSTL I/O
K34 VSS GND
K36 DDR3_DQ[14] SSTL I/O
K38 DDR3_DQS_DN[10] SSTL I/O
K4 DDR3_DQS_DN[16] SSTL I/O
K40 DDR3_DQ[13] SSTL I/O
K42 PE1A_TX_DN[0] PCIEX3 O
K44 PE1A_TX_DN[2] PCIEX3 O
K46 PE1B_TX_DN[4] PCIEX3 O
K48 PE1B_TX_DN[6] PCIEX3 O
K50 PE3A_TX_DN[0] PCIEX3 O
K52 PMSYNC CMOS I
K54 PE1B_RX_DP[5] PCIEX3 I
K56 PE1B_RX_DP[7] PCIEX3 I
K58 RSVD
Table 8-2. Land Number (Sheet 42 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
206 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
K6 DDR3_DQS_DP[06] SSTL I/O
K8 VSS GND
L1 DDR3_DQ[62] SSTL I/O
L11 DDR3_DQS_DN[05] SSTL I/O
L13 DDR3_DQ[41] SSTL I/O
L15 DRAM_PWR_OK_C23 CMOS1.5v I
L17 DDR2_BA[1] SSTL O
L19 DDR3_ODT[0] SSTL O
L21 DDR3_CLK_DP[1] SSTL O
L23 DDR3_CLK_DP[0] SSTL O
L25 VSS GND
L27 DDR3_DQ[27] SSTL I/O
L29 VSS GND
L3 DDR3_DQS_DN[07] SSTL I/O
L31 DDR3_DQ[25] SSTL I/O
L33 DDR3_DQ[28] SSTL I/O
L35 DDR3_DQ[10] SSTL I/O
L37 DDR3_DQS_DN[01] SSTL I/O
L39 DDR3_DQ[09] SSTL I/O
L41 VSS GND
L43 PE1A_TX_DN[1] PCIEX3 O
L45 PE1A_TX_DN[3] PCIEX3 O
L47 PE1B_TX_DN[5] PCIEX3 O
L49 PE1B_TX_DN[7] PCIEX3 O
L5 VSS GND
L51 PE3A_TX_DN[1] PCIEX3 O
L53 PE1B_RX_DN[4] PCIEX3 I
L55 PE2A_RX_DP[0] PCIEX3 I
L57 PE1B_RX_DN[6] PCIEX3 I
L7 DDR3_DQ[54] SSTL I/O
L9 DDR3_DQ[43] SSTL I/O
M10 DDR3_DQ[47] SSTL I/O
M12 DDR3_DQS_DN[14] SSTL I/O
M14 DDR3_DQ[45] SSTL I/O
M16 DDR3_ODT[5] SSTL O
M18 DDR2_MA_PAR SSTL O
M2 DDR3_DQ[63] SSTL I/O
M20 DDR3_CLK_DN[2] SSTL O
M22 DDR3_CLK_DP[3] SSTL O
M24 DDR3_CKE[1] SSTL O
M26 DDR3_DQ[31] SSTL I/O
M28 DDR3_DQ[26] SSTL I/O
Table 8-2. Land Number (Sheet 43 of 49)
Land No. Land Name Buffer Type Direction
M30 DDR3_DQS_DN[12] SSTL I/O
M32 DDR3_DQ[24] SSTL I/O
M34 VSS GND
M36 VSS GND
M38 DDR3_DQS_DP[10] SSTL I/O
M4 DDR3_DQS_DP[07] SSTL I/O
M40 DDR3_DQ[12] SSTL I/O
M42 VSS GND
M44 VSS GND
M46 VSS GND
M48 RSVD
M50 VSS GND
M52 VSS GND
M54 PE1B_RX_DN[5] PCIEX3 I
M56 PE1B_RX_DN[7] PCIEX3 I
M6 DDR3_DQ[55] SSTL I/O
M8 VSS GND
N11 DDR3_DQS_DP[05] SSTL I/O
N13 VSS GND
N15 VCCD_23 PWR
N17 VCCD_23 PWR
N19 VCCD_23 PWR
N21 VCCD_23 PWR
N23 VCCD_23 PWR
N25 DDR3_CKE[3] SSTL O
N27 DDR3_DQ[30] SSTL I/O
N29 DDR3_DQS_DP[03] SSTL I/O
N3 DDR3_DQ[58] SSTL I/O
N31 DDR3_DQS_DP[12] SSTL I/O
N33 VSS GND
N35 VSS GND
N37 VSS GND
N39 DDR3_DQ[08] SSTL I/O
N41 VSS GND
N43 VSS GND
N45 VSA PWR
N47 VSS GND
N49 VSS GND
N5 VSS GND
N51 VSA PWR
N53 VSS GND
N55 PE2A_RX_DN[0] PCIEX3 I
Table 8-2. Land Number (Sheet 44 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 207
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Processor Land Listing
N7 DDR3_DQ[50] SSTL I/O
N9 VSS GND
P10 VSS GND
P12 VSS GND
P14 VSS GND
P16 DDR2_WE_N SSTL O
P18 DDR2_CS_N[5] SSTL O
P20 DDR2_MA[04] SSTL O
P22 DDR2_MA[07] SSTL O
P24 DDR2_BA[2] SSTL O
P26 VSS GND
P28 DDR3_DQS_DN[03] SSTL I/O
P30 VSS GND
P32 VSS GND
P34 DDR2_DQ[21] SSTL I/O
P36 DDR2_DQ[02] SSTL I/O
P38 VSS GND
P4 DDR3_DQ[59] SSTL I/O
P40 VSS GND
P42 DDR_VREFDQTX_C23 DC O
P44 PE3D_TX_DN[15] PCIEX3 O
P46 PE3C_TX_DP[8] PCIEX3 O
P48 PE3A_TX_DP[3] PCIEX3 O
P50 PE3B_TX_DP[6] PCIEX3 O
P52 PE3B_TX_DP[4] PCIEX3 O
P54 VSS GND
P56 VSS GND
P6 DDR3_DQ[51] SSTL I/O
P8 VSS GND
R11 VSS GND
R13 DDR2_DQ[48] SSTL I/O
R15 DDR2_MA[13] SSTL O
R17 DDR2_BA[0] SSTL O
R19 DDR2_MA[01] SSTL O
R21 DDR2_MA[06] SSTL O
R23 DDR2_MA[09] SSTL O
R25 DDR3_CKE[4] SSTL O
R27 DDR3_CKE[5] SSTL O
R29 VSS GND
R3 VSS GND
R31 VSS GND
R33 DDR2_DQ[17] SSTL I/O
Table 8-2. Land Number (Sheet 45 of 49)
Land No. Land Name Buffer Type Direction
R35 VSS GND
R37 DDR2_DQ[06] SSTL I/O
R39 VSS GND
R41 DDR2_DQ[04] SSTL I/O
R43 DDR_SDA_C23 ODCMOS I/O
R45 PE3C_TX_DP[10] PCIEX3 O
R47 PE3A_TX_DP[2] PCIEX3 O
R49 PE3B_TX_DP[7] PCIEX3 O
R5 VSS GND
R51 PE3B_TX_DP[5] PCIEX3 O
R53 PRDY_N CMOS O
R55 VSS GND
R7 VSS GND
R9 DDR2_DQ[54] SSTL I/O
T10 DDR2_DQ[50] SSTL I/O
T12 DDR2_DQS_DP[15] SSTL I/O
T14 DDR2_DQ[52] SSTL I/O
T16 DDR2_CAS_N SSTL O
T18 DDR2_MA[10] SSTL O
T20 DDR2_MA[03] SSTL O
T22 DDR2_MA[08] SSTL O
T24 DDR2_MA[12] SSTL O
T26 DDR2_CKE[1] SSTL O
T28 VSS GND
T30 DDR2_DQ[23] SSTL I/O
T32 DDR2_DQS_DN[11] SSTL I/O
T34 DDR2_DQ[20] SSTL I/O
T36 DDR2_DQ[03] SSTL I/O
T38 DDR2_DQS_DN[00] SSTL I/O
T4 VSS GND
T40 DDR2_DQ[00] SSTL I/O
T42 VSS GND
T44 PE3D_TX_DP[15] PCIEX3 O
T46 PE3C_TX_DN[8] PCIEX3 O
T48 PE3A_TX_DN[3] PCIEX3 O
T50 PE3B_TX_DN[6] PCIEX3 O
T52 PE3B_TX_DN[4] PCIEX3 O
T54 PE2A_RX_DP[1] PCIEX3 I
T56 PE2A_RX_DP[2] PCIEX3 I
T6 VSS GND
T8 VSS GND
U11 DDR2_DQS_DN[06] SSTL I/O
Table 8-2. Land Number (Sheet 46 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
208 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
U13 DDR2_DQ[49] SSTL I/O
U15 DDR23_RCOMP[0] Analog I
U17 DDR2_RAS_N SSTL O
U19 DDR2_MA[02] SSTL O
U21 DDR2_MA[05] SSTL O
U23 DDR2_MA[11] SSTL O
U25 DDR2_MA[15] SSTL O
U27 DDR2_CKE[2] SSTL O
U29 DDR2_DQ[19] SSTL I/O
U3 DDR2_DQ[60] SSTL I/O
U31 DDR2_DQS_DP[02] SSTL I/O
U33 DDR2_DQ[16] SSTL I/O
U35 VSS GND
U37 DDR2_DQ[07] SSTL I/O
U39 DDR2_DQS_DP[09] SSTL I/O
U41 DDR2_DQ[05] SSTL I/O
U43 DDR_SCL_C23 ODCMOS I/O
U45 PE3C_TX_DN[10] PCIEX3 O
U47 PE3A_TX_DN[2] PCIEX3 O
U49 PE3B_TX_DN[7] PCIEX3 O
U5 VSS GND
U51 PE3B_TX_DN[5] PCIEX3 O
U53 PREQ_N CMOS I/O
U55 PE2A_RX_DP[3] PCIEX3 I
U7 DDR2_DQ[44] SSTL I/O
U9 DDR2_DQ[55] SSTL I/O
V10 DDR2_DQ[51] SSTL I/O
V12 DDR2_DQS_DN[15] SSTL I/O
V14 DDR2_DQ[53] SSTL I/O
V16 VCCD_23 PWR
V18 VCCD_23 PWR
V20 VCCD_23 PWR
V22 VCCD_23 PWR
V24 VCCD_23 PWR
V26 VSS GND
V28 VSS GND
V30 DDR2_DQ[22] SSTL I/O
V32 DDR2_DQS_DP[11] SSTL I/O
V34 VSS GND
V36 VSS GND
V38 DDR2_DQS_DP[00] SSTL I/O
V4 DDR2_DQ[61] SSTL I/O
Table 8-2. Land Number (Sheet 47 of 49)
Land No. Land Name Buffer Type Direction
V40 DDR2_DQ[01] SSTL I/O
V42 VSS GND
V44 VSS GND
V46 VSS GND
V48 VSS GND
V50 VSS GND
V52 TXT_PLTEN CMOS I
V54 PE2A_RX_DN[1] PCIEX3 I
V56 PE2A_RX_DN[2] PCIEX3 I
V6 DDR2_DQ[40] SSTL I/O
V8 VSS GND
W11 DDR2_DQS_DP[06] SSTL I/O
W13 VSS GND
W15 RSVD
W17 DDR2_CS_N[8] SSTL O
W19 DDR2_ODT[1] SSTL O
W21 DDR2_CLK_DN[2] SSTL O
W23 DDR2_CLK_DN[3] SSTL O
W25 DDR2_MA[14] SSTL O
W27 DDR2_ECC[6] SSTL I/O
W29 DDR2_DQ[18] SSTL I/O
W3 DDR2_DQ[56] SSTL I/O
W31 DDR2_DQS_DN[02] SSTL I/O
W33 VSS GND
W35 DDR2_DQ[29] SSTL I/O
W37 VSS GND
W39 DDR2_DQS_DN[09] SSTL I/O
W41 VSS GND
W43 VSS GND
W45 VSS GND
W47 VSS GND
W49 VTTA PWR
W5 VSS GND
W51 VSS GND
W53 VSS GND
W55 PE2A_RX_DN[3] PCIEX3 I
W7 DDR2_DQ[45] SSTL I/O
W9 VSS GND
Y10 VSS GND
Y12 VSS GND
Y14 DDR23_RCOMP[2] Analog I
Y16 DDR2_CS_N[7] SSTL O
Table 8-2. Land Number (Sheet 48 of 49)
Land No. Land Name Buffer Type Direction
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 209
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Processor Land Listing
§
Y18 DDR2_ODT[3] SSTL O
Y20 DDR2_ODT[0] SSTL O
Y22 DDR2_CLK_DN[1] SSTL O
Y24 DDR2_CLK_DN[0] SSTL O
Y26 DDR2_ECC[2] SSTL I/O
Y28 VSS GND
Y30 VSS GND
Y32 VSS GND
Y34 DDR2_DQS_DP[12] SSTL I/O
Y36 VSS GND
Y38 VSS GND
Y4 DDR2_DQ[57] SSTL I/O
Y40 VSS GND
Y42 VSS GND
Y44 PE3D_TX_DP[13] PCIEX3 O
Y46 PE3C_TX_DP[11] PCIEX3 O
Y48 RSVD
Y50 PE3B_RX_DP[4] PCIEX3 I
Y52 PE3B_RX_DP[5] PCIEX3 I
Y54 VTTA PWR
Y56 VSS GND
Y6 DDR2_DQ[41] SSTL I/O
Y8 DDR2_DQS_DP[14] SSTL I/O
Table 8-2. Land Number (Sheet 49 of 49)
Land No. Land Name Buffer Type Direction
Processor Land Listing
210 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
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Package Mechanical Specifications
9Package Mechanical
Specifications
The processor is packaged in a Flip-Chip Land Grid Array (FCLGA12) package that
interfaces with the baseboard via an LGA2011-0 socket. The package consists of a
processor mounted on a substrate land-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. Figu re 9-1 show s a sketch
of the processor package components and how they are assembled together. Refer to
the Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product
Families Thermal/Mechanical Design Guide for complete details on the LGA2011-0
socket.
The package components shown in Figure 9-1 include the following:
1. Integrated Heat Spreader (IHS)
2. Thermal Interface Material (TIM)
3. Processor core (die)
4. P ackage substrate
5. Capacitors
Note:
1. Socket and baseboard are included for r eference and are not part of the processor package.
9.1 Package Size and SKUs
The processor is supported in two package sizes:
Package A: 52.5 mm x 45 mm and
Package B: 52.5 mm x 51 mm
Below is a table that shows the associated processor SKUs with the package sizes. For
details on processor SKU information, see Table 1-1, “HCC, MCC, and LCC SKU Table
Summary.
Figure 9-1. Processor Package Assembly Sketch
IHS
Substrate
System B oard
Capacitors
TIM
LGA 201 1-0 Socke t
Die
Package Mechanical Specifications
212 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
9.2 Package Mechanical Drawing (PMD)
The package mechanical drawings are shown as package A size 52.5 mm x 45 mm,
Figure 9-2 and Figure 9-3, and package B size 52.5 mm x 51 mm Figure 9-4 and
Figure 9-5. The dr awings include dimensions necessary to design a thermal solution for
the processor. These dimensions include:
1. Package reference with tolerances (total height, length, width, and so forth)
2. IHS parallelism and tilt
3. Land dimensions
4. Top-side and back-side component keep-out dimensions
5. Reference datums
6. All drawing dimensions are in mm.
7. Guidelines on potential IHS flatness variation with socket load plate actuation and
installation of the cooling solution is available in the Intel® Xeon® Processor E5-
1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product Families
Thermal/Mechanical Design Guide.
Table 9-1. Processor Package Sizes
Package Size and Processor TDP SKU Notes1
Package A: MCC and LCC die siz e
52.5 mm x 45 mm (Figure 9-2 and Figure 9-3)
150W (8-core)
130W 1U (10/8-core)
130W 2U (8/6/4-core)
130W 1S WS (6/4-core)
115W (10-core)
95W (10/8/6/4-core)
80W (6/4-core)
70W (10-core)
60W (6-core)
LV95W-10C
LV70W-10C and LV70W-8C
LV50W-6C
Package B: HCC die size
52.5 mm x 51 mm (Figure 9-4 and Figure 9-5)
130W (12-core)
115W (12-core)
95W (8-core) 2
Notes:
1. Processor SKU’s are subject to change and any processor SKU can be supported in either package size.
2. This SKU is an E5-4610 v2.
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 213
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Package Mechanical Specifications
Figure 9-2. Processor PMD Package A (52.5 x 45 mm) Sheet 1 of 2
Package Mechanical Specifications
214 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 9-3. Processor PMD Package A (52.5 x 45 mm) Sheet 2 of 2
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 215
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Package Mechanical Specifications
Figure 9-4. Processor PMD Package B (52.5 x 51 mm) Sheet 1 of 2
Package Mechanical Specifications
216 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 9-5. Processor PMD Package B (52.5 x 51 mm) Sheet 2 of 2
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 217
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Package Mechanical Specifications
9.3 Processor Component Keep-Out Zones
The processor may contain components on the substrate that define component
keep-out zone requirements. A thermal and mechanical solution design must not
intrude into the required keep-out zones. Do not contact the Test Pad Area with
conductive material. Decoupling capacitors are typically mounted to either the topside
or land-side of the package substrate. See Figure 9-3 through Figure 9-4 for keep-out
zones. The location and quantity of package capacitors may change due to
manufacturing efficiencies but will remain within the component keep-in.
9.4 Package Loading Specifications
Table 9-2 provides load specifications for the processor package. These maximum
limits should not be exceeded during heatsink assembly, shipping conditions, or
standard use condition. Exceeding these limits during test may result in component
failure. The processor substrate should not be used as a mechanical reference or load-
bearing surface for thermal solutions.
.
Notes:
1. These specifications apply to uniform compressive loading in a direction normal to the processor IHS.
2. This is the maximum static force that can be applie d b y the heatsink and Independent Loading Mechanism
(ILM).
3. These specifications are based on limited testing for design characterization. Loading limits are for the
package constrained by the limits of the processor socket.
4. Dynamic loading is defined as an 11 ms duration average load superimposed on the static load
requirement.
5. See Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product Families
Thermal/Mechanical Design Guide for minimum socket load to engage processor within socket.
9.5 Package Handling Guidelines
Table 9-3 includes a list of guidelines on package handling in terms of recommended
maximum loading on the processor IHS relative to a fixed substrate. These package
handling loads may be experienced during heatsink removal.
9.6 Package Insertion Specifications
The processor can be inserted into and removed from an LGA2011-0 socket 15 times.
The socket should meet the LGA2011-0 requirements detailed in the Intel® Xeon®
Processor E5-1600/2600/4600 and E5-1600 v2/E5-2600 v2 Product Families
Thermal/Mechanical Design Guide.
Table 9-2. Processor Loading Specifications
Parameter Maximum Notes
Static Compressive Load 890 N [200 lbf] 1, 2, 3, 5
Dynamic Load 540 N [121 lbf] 1, 3, 4, 5
Table 9-3. Package Handling Guidelines
Parameter Maximum Recommended Notes
Shear 80 lbs (36.287 kg)
Tensile 35 lbs (15.875 kg)
Torque 35 in.lbs (15.875 kg-cm)
Package Mechanical Specifications
218 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
9.7 Processor Mass Specification
The typical mass of the processor is currently 45 gr ams. This mass [weight] includes all
the components that are included in the package.
9.8 Processor Materials
Table 9-4 lists some of the package components and associated materials.
9.9 Processor Markings
Figure 9-6 shows the topside markings on the processor. This diagram is to aid in the
identification of the processor.
Notes:
1. XXXXX = Country of Origin
2. SPEED Format = X.XXGHz and no rounding
§
Table 9-4. Processor Materials
Component Material
Integrated Heat Spreader (IHS) Nickel Plated Copper
Substrate Halogen Free, Fiber Reinforced Resin
Substrate Lands Gold Plated Copper
Figure 9-6. Processor Top-Side Markings
Legend: M ark Text (Production Mark):
GRP1LINE1: i{M}{C}YY
GRP1LINE2: SUB-BRAND PROC#
GRP1LINE3: SSPEC SPEED
GRP1LINE4: XXXXX
GRP1LINE5: {FPO} {e4}
GRP1LINE1
GRP1LINE2
GRP1LINE3
GRP1LINE4
GRP1LINE5
LOT NO S /N
0
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 219
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Boxed Processor Specifications
10 Boxed Processor Specifications
10.1 Introduction
Intel box e d processors are intended for system integrators who build systems from
components available through distribution channels. The Intel® Xeon® processor E5-
2600 v2 product family (LGA2011-0) processors will be offered as Intel boxed
processors, however the thermal solutions will be sold separately.
Boxe d processors will not include a thermal solution in the box. Intel will offer boxed
thermal solutions separ ately through the same distribution channels. Please reference
Section 10.1.1 - Section 10.1.3 for a description of Boxed Processor thermal solutions.
10.1.1 Available Boxed Thermal Solution Configurations
Intel will offer three different Boxed Heat Sink solutions to support LGA2011-0
Boxe d Processors:
Boxed Intel® Thermal Solution STS200C(Order Code BXSTS200C): A Passive /
Active Combination Heat Sink Solution that is intended for processors with a TDP
up to 150W in a pedestal or 130W in 2U+ chassis with appropriate ducting.
Boxed Intel® Thermal Solution STS200P(Order Code BXSTS200P): A 25.5 mm Tall
Passive Heat Sink Solution that is intended for processors with a TDP of 130W or
lower in 1U, or 2U chassis with appropriate ducting. Check with Blade manufacturer
for compatibility.
Boxed Intel® Thermal Solution STS200PNRW (Order Code BXSTS200PNRW): A
25.5 mm Tall Passive Heat Sink Solution that is intended for processors with a TDP
of 130W or lower in 1U, or 2U chassis with appropriate ducting. Compatible with
the narrow processor integrated load mechanism. Check with Blade manufacturer
for compatibility.
10.1.2 Intel Thermal Solution STS200C
(Passive/Active Combination Heat Sink Solution)
The STS200C, based on a 2U passive heat sink with a removable fan, is intended for
use with processors with TDP’ s up to 150W in active configuration and 130W in passive
configuration. This heat pipe-based solution is intended to be used as either a passive
heat sink in a 2U or larger chassis, or as an active heat sink for pedestal chassis.
Figure 10-1 and Figure 10-2 are representations of the heat sink solution. Altho ugh the
active combination solution with the remo vable fan installed mechanically fits into a 2U
keepout, its use has not been validated in that configuration.
The STS200C in the active fan configuration is primarily designed to be used in a
pedestal chassis where sufficient air inlet space is present. The STS200C with the fan
removed, as with any passive thermal solution, will require the use of chassis ducting
and are targeted for use in rack mount or ducted pedestal servers. The retention
solution used for these products is called ILM Retention System (ILM-RS).
Boxed Processor Specifications
220 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
The STS200C utilizes a fan capable of 4-pin pulse width modulated (PWM) control. Use
of a 4-pin PWM controlled active thermal solution helps customers meet acoustic
targets in pedestal platforms through the baseboard’ s ability to directly control the RPM
of the processor heat sink fan. See Section 10.3 for more details on fan speed control.
Also see Section 2.5, “Platform Environment Control Interface (PECI)” for more on the
PWM and PECI interface along with Digital Thermal Sensors (DTS).
10.1.3 Intel Thermal Solution STS200P and STS200PNRW
(Boxed 25.5 mm Tall Passive Heat Sink Solutions)
The STS200P and STS200PNRW are available for use with boxed processors that have
TDP’ s of 130W and lower. These 25.5 mm Tall passive solutions are designed to be used
in SSI Blades, 1U, and 2U chassis where ducting is present. The use of a 25.5 mm Tall
heatsink in a 2U chassis is recommended to achieve a lower heatsink TLA and more
flexibility in system design optimization. Figure 10-3 is a representation of the heat
Figure 10-1. STS200C Passive/Active Combin ation Heat Sink (w ith Removable Fan)
Figure 10-2. STS200C Passive/Active Combin ation Heat Sin k (w ith Fan Removed)
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 221
Datasheet Volume One of Two
Boxed Processor Specifications
sink solutions. The retention solution used for the STS200P Heat Sink Solution is called
the ILM Retention System (ILM-RS).The retention solution used for the STS200PNRW
Narrow Heat Sink Solution is called the Narrow ILM R etention System (Narrow ILM-RS).
10.2 Mechanical Specifications
This section documents the mechanical specifications of the boxed processor solution.
10.2.1 Boxed Processor Heat Sink Dimensions and Baseboard
Keepout Zones
The boxed processor and boxed thermal solutions will be sold separately. Clearance is
required around the thermal solution to ensure unimpeded airflow for proper cooling.
Baseboard keepout zones are Figu re 10-4 - Figure 10-7. Physical space requirements
and dimensions for the boxed processor and assembled heat sink are shown in
Figure 10-8 and Figure 10-9. Mechanical drawings for the 4-pin fan header and 4-pin
connector used for the active fan heat sink solution are represented in Figure 10-10
and Figure 10-11.
None of the heat sink solutions exceed a mass of 550 grams. Note that this is per
processor, a dual processor system will have up to 1100 grams total mass in the heat
sinks. See Section 9.7 for details on the processor mass test.
Figure 10-3. STS200P and STS 20 0PNRW 25.5 m m Tall Passive Heat Sin ks
Boxed Processor Specifications
222 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 10-4. Boxed Processor Motherboard Ke epout Zones (1 o f 4)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
2X 46.0
SOCKET ILM
HOLE PATTERN
2X 69.2
SOCKET ILM
HOLE PATTERN
2200 MISSION COLLEGE BLVD.
R
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
4X
SOCKET ILM
MOUNTING HOLES
3.8
93.0
MAX THERMAL
SOLUTION ENVELOPE
AND MECHANICAL PART CLEARANCE
(FINGER ACCESS NOT INCLUDED)
93.0
MAX THERMAL
SOLUTION ENVELOPE AND
MECHANICAL PART CLEARANCE
(51.0 )
SOCKET BODY OUTLINE
(FOR REFERENCE ONLY)
(58.5 )
SOCKET BODY OUTLINE
(FOR REFERENCE ONLY)
G11950 1 B
DWG. NO SHT. REV
SHEET 1 OF 4
DO NOT SCALE DRAWING
SCALE: 1
BG11950D
REV
DRAWING NUMBER
SIZE
LGA 2011 ENABLING KEEPOUT ZONES
TITLE
PTMI
DEPARTMENT
N/AN/A
FINISHMATERIAL
DATEAPPROVED BY
07/05/10NEAL ULEN
DATECHECKED BY
06/30/10D. LLAPITAN
DATEDRAWN BY
06/30/10D. LLAPITAN
DATEDESIGNED BY
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN MM
TOLERANCES:
.X ± 0.0 Angles ± 0.0 °
.XX ± 0.00
.XXX ± 0.000
THIRD ANGLE PROJECTION
REVISION HISTORY
ZONE REV DESCRIPTION DATE APPR
-A
INITIAL RELEASE FOR FUTURE BOARD BUILDS DEVIATING FROM E59036.
CHANGED ZONE 4, UPDATED NOTES FOR CLARIFICATION.
ADDED A NEW ZONE 7 ON PRIMARY SIDE.
CHANGED ZONE 8 FOR UPDATED BACKPLATE.
REMOVED HEATSINK HOLE MOUNTING LOCATIONS
REMOVED LEVER FINGER ACCESS TABS OUTSIDE 93.5x93.5 SQUARE.
REDUCED MAX THERMAL RETENTION OUTLINE TO 93X93MM.
06/30/10
-
B
ADDED NOTE 8 FOR FURTHER CLARIFICATION
08/26/10
DL
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
NOTES:
1. THIS DRAWING TO BE USED IN CORELATION WITH SUPPLIED 3D DATA BASE FILE. ALL DIMENSIONS AND
TOLERANCES ON THIS DRAWING TAKE PRECEDENCE OVER SUPPLIED FILE.
2. DIMENSIONS STATED IN MILLIMETERS AND DEFINE ZONES, THEY HAVE NO TOLERANCES ASSOCIATED
WITH THEM.
3. SOCKET KEEP OUT DIMENSIONS SHOWN FOR REFERNCE ONLY.
4. MAXIMUM OUTLINE OF SOCKET MUST BE PLACED SYMMETRIC TO THE ILM HOLE PATTERN FOR PROPER
ILM AND SOCKET FUNCTION.
5 A HEIGHT RESTRICTION ZONE IS DEFINED AS ONE WHERE ALL COMPONENTS PLACED ON THE
SURFACE OF THE MOTHERBOARD MUST HAVE A MAXIMUM HEIGHT NO GREATER THAN THE HEIGHT
DEFINED BY THAT ZONE.
ALL ZONES DEFINED WITHIN THE 93.5 X 93.5 MM OUTLINE REPRESENT SPACE THAT RESIDES BENEATH
THE HEATSINK FOOTPRINT.
UNLESS OTHERWISE NOTED ALL VIEW DIMENSION ARE NOMINAL. ALL HEIGHT RESTRICTIONS ARE
MAXIMUMS. NEITHER ARE DRIVEN BY IMPLIED TOLERANCES.
A HEIGHT RESTRICTION OF 0.0 MM REPRESENTS THE TOP (OR BOTTOM) SURFACE OF THE MOTHERBOARD
AS THE MAXIMUM HEIGHT. THIS IS A NO COMPONENT PLACEMENT ZONE INCLUDING SOLDER BUMPS.
SEE NOTE 6 FOR ADDITIONAL DETAILS.
6 ASSUMING A GENERIC A MAXIMUM COMPONENT HEIGHT ZONE.
CHOICE OF AND COMPONENT PLACEMENT IN THIS ZONE MUST INCLUDE:
- COMPONENT NOMINAL HEIGHT
- COMPONENT TOLERANCES
- COMPONENT PLACEMENT TILT
- SOLDER REFLOW THICKNESS
DO NOT PLACE COMPONENTS IN THIS ZONE THAT WILL EXCEED THIS MAXIMUM COMPONENT HEIGHT.
7 ASSUMES PLACEMENT OF A 0805 CAPACITOR WITH DIMENSIONS:
- CAP NOMINAL HEIGHT = 1.25MM (0.049")
- COMPONENT MAX MATERIAL CONDITION HEIGHT NOT TO EXCEED 1.50MM.
8 SIZE & HEIGHT OF FINGER ACCESS TO BE DETERMINED BY SYSTEM/BOARD ARCHITECT. THIS IS ILM
MECHANICAL CLEARANCE ONLY AND FINGER AND/OR TOOL ACCESS SHOULD DETERMINED SEPERATELY.
BALL 1 CORNER
POSITIONAL MARKING
(FOR REFERENCE ONLY)
2X FINGER
ACCESS 8
LEGEND, SHEETS 1 & 2 ONLY
ZONE 1:
0.0 MM MAX COMPONENT HEIGHT, NO COMPONENT PLACEMENT,
SOCKET, ILM, AND FINGER ACCESS KEEPIN ZONE
ZONE 2:
7.2 MM MAX COMPONENT HEIGHT. 6
ZONE 3:
0.0 MM MAX COMPONENT HEIGHT, NO COMPONENT PLACEMENT,
NO ROUTE ZONE
ZONE 4:
1.67 MM MAX COMPONENT HEIGHT AFTER REFLOW 5 6
1.50 MM MAX (MMC) COMPONENT HEIGHT BEFORE REFLOW 5 7
ZONE 5:
1.6 MM MAX COMPONENT HEIGHT. 6
ZONE 6:
1.5 MM MAX COMPONENT HEIGHT. 6
ZONE 7:
1.9 MM MAX COMPONENT HEGHT. 6
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 223
Datasheet Volume One of Two
Boxed Processor Specifications
Figure 10-5. Boxed Processor Motherboard Keepout Zones (2 of 4)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
2200 MISSION COLLEGE BLVD.
R
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
12.80
18.20
2X 7.05
2X 34.05
2X 3.30
2X 4.50
2X 41.46
2X 73.55
2X 31.55
2X 22.75
2X 3.45
2X 30.0°
2X 67.57
2X 8.80
NPTH
SOCKET ILM
MOUNTING HOLES
3.80 +.06
-.03
4.80
4.55
2X 92.0
2X 25.25
2X 53.808
(93.0 )
(93.0 )
G11950 2 B
DWG. NO SHT. REV
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
SHEET 2 OF 4
DO NOT SCALE DRAWING
SCALE: 1.000
PTMI BG11950D
REV
DRAWING NUMBER
SIZE
DEPARTMENT
AS VIEWED FROM PRIMARY
SIDE OF MAINBOARD
4X 6.5
COPPER WEAR PAD
ON PRIMARY SURFACE,
BRING AS CLOSE TO HOLE
EDGE AS POSSIBLE
SEE DETAIL A
SEE DETAIL B
4.0SCALE
ADETAIL
4.0SCALE
BDETAIL
Boxed Processor Specifications
224 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 10-6. Boxed Processor Motherboard Ke epout Zones (3 o f 4)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
2X 23.40
2200 MISSION COLLEGE BLVD.
R
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
2X 5.0
2X 26.50
14.0 R TYP1.00
22.37
4X
NO ROUTE
ZONE THRU
ALL LAYERS
4.8
81.5
71.5
4X R7.0
G11950 3 B
DWG. NO SHT. REV
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
SHEET 3 OF 4
DO NOT SCALE DRAWING
SCALE: 1.000
PTMI BG11950D
REV
DRAWING NUMBER
SIZE
DEPARTMENT
AS VIEWED FROM SECONDARY
SIDE OF MAINBOARD
LEGEND, SHEET 3 ONLY
ZONE 8:
NO COMPONENT PLACEMENT, STIFFENING PLATE CONTACT AREA
ZONE 9:
1.8 MM MAX COMPONENT HEIGHT FOR SSI BLADES CONFIGURATION
* ALL OTHER FORM FACTORS DEPENDANT ON SYSTEM CONSTRAINTS.
ZONE 10:
NO COMPONENT PLACEMENT & NO ROUTE ZONE
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 225
Datasheet Volume One of Two
Boxed Processor Specifications
Figure 10-7. Boxed Processor Motherboard Keepout Zones (4 of 4)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
76.50
81.50
2200 MISSION COLLEGE BLVD.
R
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
MIN97.0° MIN97.0°
93.0
93.00
4.38
.03
G11950 4 B
DWG. NO SHT. REV
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
SHEET 4 OF 4
DO NOT SCALE DRAWING
SCALE: 1.500
PTMI BG11950D
REV
DRAWING NUMBER
SIZE
DEPARTMENT
SECONDARY SIDE
3D HEIGHT RESTRICTION ZONES
PRIMARY SIDE
3D HEIGHT RESTRICTION ZONES
AND VOLUMETRIC SWEEPS OF LOADPLATE
AND LEVER OPENING/CLOSING
TOP SURFACE OF MOTHERBOARD
VOLUMETRIC SWEEPS FOR
LOADPLATE AND LEVERS
DURING OPENING AND CLOSING
Boxed Processor Specifications
226 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 10-8. Boxed Processor Heat Sink Volumetric (1 of 2)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
R
4X 12.00+1.00
0
0.472+0.039
-0.000
[]
4X 12.00+1.00
0
0.472+0.039
-0.000
[]
64.00 MAX.
[2.520]
B
91.50 0
-0.25
3.602+0.000
-0.009
[]
A91.50 0
-0.25
3.602+0.000
-0.009
[]
C
E95132 1 B
DWG. NO SHT. REV
SHEET 1 OF 2DO NOT SCALE DRAWINGSCALE: 1
BE95132D
REVDRAWING NUMBERSIZE
ROMLEY 2U HS VOLUMETRIC,
DIE CAST BASES ONLY
TITLE
EASD / PTMI
DEPARTMENT
SEE NOTESSEE NOTES
FINISHMATERIAL
DATEAPPROVED BY
--
3/29/10D. LLAPITAN
DATECHECKED BY
3/29/10N. ULEN
DATEDRAWN BY
3/29/10N. ULEN
DATEDESIGNED BY
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5-1994
DIMENSIONS ARE IN MILLIMETERS
TOLERANCES:
.X # .5 Angles # 1.0$
.XX # 0.25
.XXX # 0.127
THIRD ANGLE PROJECTION
REVISION HISTORY
ZONE REV DESCRIPTION DATE APPROVED
2B2 A VOLUME FOR DIE CAST GEOMETRY
INTEGRATED SPRING/SCREW CUP FEATURE IN TO
CAST GEOMETRY
3/29/10 -
B ROLLED PART TO -002
CHANGED SPRING CUP GEOMETRY TO FIT DELRIN SPACER
7/21/10
THIS DRAWING CONTAINS INTEL CORPORAT ION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONT ENTS
MAY NOT BE DISCLOSED, REPRODUCED, DI SPLAYED OR MODIFIED, WITHOUT THE PRI OR WRITTEN CONSENT OF INTEL CORPORAT ION.
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH
SUPPLIED 3D DATABASE FILE. ALL DIMENSIONS AND TOLERANCES
ON THIS DRAWING TAKE PRECEDENCE OVER SUPPLIED FILE.
2. PRIMARY DIMENSIONS STATED IN MILLIMETERS,
[BRACKETED] DIMENSIONS STATED IN INCHES.
CRITICAL TO FUNCTION DIMENSION.
3. ALL DIMENSION AND TOLERANCES PER ANSI Y14.5-1994.
4. HEAT SINK VOLUMETRIC. ALL HEAT SINK GEOMETRY
MUST FIT WITHIN THE SPACE DEFINED BY THIS DRAWING..
6. REMOVE ALL BURRS, SHARP EDGES, GREASES, AND/OR
SOLVENTS AFTER MACHINING AND FIN ASSEMBLY.
7. LOCAL FLATNESS ZONE .076 MM [0.003"] CENTERED ON
HEAT SINK BASE.
8. NO EXPOSED CORNER FINS ALLOWED. CHAMFER ALL
EXPOSED FIN CORNERS TO THE VALUE SPECIFIED.
9 CRITICAL TO FUNCTION DIMENSION.
TOP VIEW
AIRFLOW DIRECTION
SEE NOTE 8
SEE NOTE 4
PARTS LIST
DESCRIPTIONPART NUMBERITEM NOQTY
ROMLEY 2U HS VOLUMETRICE95132-002TOP
Intel Xeon Processor E5 Product
Family 2U Volumetric Die Cast
Bases Only
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 227
Datasheet Volume One of Two
Boxed Processor Specifications
Figure 10-9. Boxed Processor Heat Sink Volumetric (2 of 2)
13
4
5678
B
C
D
A
123
4
5678
B
C
D
A
AA
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
R
38.00#0.50
1.496#0.019[]
38.00#0.50
1.496#0.019[]
80.00
[3.150]
80.00
[3.150]
1.00
0.039[]
ORDINATE BASELINE0.00
0.000[]
BASE THICKNESS 9
4.50#0.13
0.177#0.005[]
5.50
0.217[]
9
7.95+0.13
0
0.313+0.005
-0.000
[]
9
5.40+0.13
0
0.213+0.005
-0.000
[]
10.450
[0.4114]
E95132 2 B
DWG. NO SHT. REV
THIS DRAWING CONTAINS INTEL CORPORAT ION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONT ENTS
MAY NOT BE DISCLOSED, REPRODUCED, DI SPLAYED OR MODIFIED, WITHOUT THE PRI OR WRITTEN CONSENT OF INTEL CORPORAT ION.
SHEET 2 OF 2DO NOT SCALE DRAWINGSCALE: 1.500
PTMI BE95132D
REVDRAWING NUMBERSIZEDEPARTMENT
FLATNESS ZONE,
SEE NOTE 7
BOTTOM VIEW
9
9
AIRFLOW DIRECTION
AIRFLOW DIRECTION
TOP VIEW
SECTION A-A
SEE DETAIL B
SEE DETAIL C
DETAIL B
SCALE 10.000
0.5 x 45 $
ALL AROUND
DETAIL C
SCALE 6.000
3.0 [0.118] X 45 $ TYP
SEE NOTE 8
0.077 [0.0030]
0.1 [0.00] A B C
Boxed Processor Specifications
228 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
Figure 10-10.4-Pin Fan Cable Connector (For Active Heat Sink)
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 229
Datasheet Volume One of Two
Boxed Processor Specifications
Figure 10-11.4-Pin Base Baseboard Fan Header (For Active Heat Sink)
Boxed Processor Specifications
230 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
10.2.2 Boxed Processor Retention Mechanism and Heat Sink
Support (ILM-RS)
Baseboards designed for use by a system integrator should include holes that are in
proper alignment with each other to support the boxed processor.
The standard and narrow ILM-RSs are designed to extend air-cooling capability through
the use of larger heat sinks with minimal airflow blockage and bypass. ILM-RS
retention transfers load to the baseboard via the ILM Assembly. The ILM-RS spring,
captive in the heatsink, provides the necessary compressive load for the thermal
interface material. For specific design details on the standard and narrow ILM-RS and
the Backplate please refer to the Intel® Xeon® Processor E5-1600/2600/4600 and E5-
1600 v2/E5-2600 v2 Product Families Thermal/Mechanical De sign Guide.
All components of the ILM-RS heat sink solution will be captive to the heat sink and will
only require a Phillips screwdriver to attach to the ILM Backplate Assembly. When
installing the ILM-RS the screws should be tightened until they will no longer turn
easily. This should represent approximately 8 inch-pounds of torque. More than that
may damage the retention mechanism components.
10.3 Fan Power Supply [STS200C]
The 4-pin PWM controlled thermal solution is being offered to help provide be tte r
control over pedestal chassis acoustics. This is achieved through more accurate
measurement of processor die temperature through the processor’s Digital Thermal
Sensors. Fan RPM is modulated through the 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 Figure 10-12 and Table 10-1 for details on the 4-pin active heat sink solution
connectors.
The fan power header on the baseboard must be positioned to allow the fan heat sink
power cable to reach it. The fan power header identification and location must be
documented in the suppliers platform documentation, or on the baseboard itself. The
baseboard fan power header should be positioned within 177.8 mm [7 in.] from the
center of the processor socket.
Table 10-1. PWM Fan Frequency Specifications For 4-Pin Active Thermal Solution
Description Min Frequency Nominal Frequency Max Frequency Unit
PWM Control Frequency
Range 21,000 25,000 28,000 Hz
Table 10-2. PWM Fan Characteristics for Active Thermal Solution
Description Min Typical Max
Steady Max
Startup Unit
+12V: 12-Volt Supply 10.8 12 12 13.2 V
IC: Fa n Current Draw N/A 1.25 1.5 2.2 A
Sense Pulse Freq uency 2 Pulses per fan
revolution
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 231
Datasheet Volume One of Two
Boxed Processor Specifications
10.3.1 Boxed Processor Cooling Requirements
As previously stated the boxed processor will have three thermal solutions available.
Each configuration will require unique design considerations. Meeting the processor’s
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 Chapter 5, “Thermal Management
Specifications” of this document.
10.3.1.1 STS200C (Passive / Active Combination Heat Sink Solution)
The active configuration of the combination solution is designed to help pedestal
chassis users to meet the thermal processor requirements without the use of processor
chassis ducting. However, it is strongly recommended to implement some form of air
duct to meet memory cooling and processor TLA temperature requirements. Please
reference the Intel® Xeon® Processor E5-1600 v2/E5-2400 v2/E5-2600 v2 Product
Families and Intel® C600 Chipset P latform Controller Hub (PCH) in a Pedestal Server
System Design Guide for an example of system ducting designed to be used with the
active configuration. Use of the active configuration in a 2U rackmount chassis is not
recommended.
In the passive configuration it is assumed that a chassis duct will be implemented.
For a list processor and thermal solution boundary conditions, such as Psica, TLA,
airflow, flow impedance, and so forth, see Table 10-4. It is recommended that the
ambient air temperature outside of the chassis be kept at or below 35 °C. Meeting the
processor’s temperature specification is the responsibility of the system integrator.
This thermal solution is for use with processor SKUs no higher than 150W (10 Core) or
130W (6, 8, and 10 core).
Figure 10-12.Fan Cable Connector Pin Out For 4-P in Active Thermal Solution
Table 10-3. PWM Fan Connector Pin and Wire Description
Pin Number Signal Wire Color
1 Ground Black
2 Power (+12V) Yellow
3 Sense: 2 pulse per r evolution Green
4 Control: 21KHz - 28KHz Blue
Boxed Processor Specifications
232 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
10.3.1.2 STS200P and STS200PNRW (25.5mm Tall Passive Heat Sink Solution)
(Blade + 1U + 2U Rack)
These passive solutions are intended for use in S SI Blade, 1U or 2U rack configurations.
It is assumed that a chassis duct will be implemented in all configurations.
For a list processor and thermal solution boundary conditions, such as Psica, TLA,
airflow, flow impedance, and so forth, see Table 10-4. It is recommended that the
ambient air temperature outside of the chassis be kept at or below 35 °C. Meeting the
processor’s temperature specification is the responsibility of the system integrator.
These thermal solutions are for use with processor SKUs no higher than 130W (8 and
10Core), or 80W (6 Core).
Note: Please refer to the Intel® Xeon® Processor E5-1600/2600/4600 and E5-1600 v2/E5-
2600 v2 Product Families Thermal/Mechanical Design Guide for detailed mechanical
drawings of the STS200P and STS200PNRW.
Table 10-4. Server Thermal Solution Boundary Conditions (Sheet 1 of 2)
TDP Thermal Solution ΨCA2
(˚C/W) TLA 1 (˚C) Airflow 3
(CFM)
Delta P
(inch of
H2O)
Heatsink
Volumetric4
(mm)
150W - 8 Core STS200C (with fan) 0.208 40.8 Max RPM NA 91.5x91.5x64
130W - 12 Core STS200C (with fan) 0.208 59.0 Max RPM NA 91.5x91.5x64
130W - 12 Core STS200P 0.252 53.2 16 0.406 91.5x91.5x25.5
130W - 12 Core STS200C (without fan) 0.208 59.0 26 0.14 91.5x91.5x64
130W - 10/8 Core STS200C (with fan) 0.206 61.2 Max RPM NA 91.5x91.5x64
130W - 10/8 Core STS200P 0.268 53.2 16 0.406 91.5x91.5x25.5
130W - 10/8 Core STS200PNRW 0.279 51.7 14 0.347 70x106x25.5
130W - 10/8 Core STS200C (without fan) 0.206 61.2 26 0.14 91.5x91.5x64
130W - 8 Core (2U) STS200C (with fan) 0.207 47.1 Max RPM NA 91.5x91.5x64
130W - 8 Core (2U) STS200C (without fan) 0 .207 47.1 26 0.14 91.5x91.5x64
130W - 6 Core (2U) STS200C (with fan) 0.206 47.2 Max RPM NA 91.5x91.5x64
130W - 6 Core (2U) STS200C (without fan) 0 .206 47.2 26 0.14 91.5x91.5x64
130W - 1S 4 Core STS200C (with fan) 0.221 41.3 Max RPM NA 91.5x91.5x64
130W - 1S 4 Core STS200P 0.283 33.2 16 0.406 91.5x91.5x25.5
130W - 1S 4 Core STS200PNRW 0.294 31.8 14 0.347 70x106x25.5
130W - 1S 4 Core STS200C (w ithout fan) 0.221 41.3 26 0.14 91.5x91.5x64
130W - 4 Core (2U) STS200C (with fan) 0.220 41.4 Max RPM NA 91.5x91.5x64
130W - 4 Core (2U) STS200C (without fan) 0 .220 41.4 26 0.14 91.5x91.5x64
115W - 12 Core STS200C (with fan) 0.207 57.2 Max RPM NA 91.5x91.5x64
115W - 12 Core STS200P 0.188 59.4 16 0.406 91.5x91.5x25.5
115W - 12 Core STS200C (without fan) 0.207 57.2 26 0.14 91.5x91.5x64
115W - 10 Core STS200C (with fan) 0.201 58.9 Max RPM NA 91.5x91.5x64
115W - 10 Core STS200P 0.263 51.8 16 0.406 91.5x91.5x25.5
115W - 10 Core STS200PNRW 0.274 50.5 14 0.347 70x106x25.5
115W - 10 Core STS200C (without fan) 0.201 58.9 26 0.14 91.5x91.5x64
Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families 233
Datasheet Volume One of Two
Boxed Processor Specifications
Notes:
1. Local ambient temperature of the air entering the heatsink or fan. System ambient and altitude are assumed 35C and sea
level.
2. Max target (mean + 3 sigma) for thermal characterization para meter.
3. Airflow through the heatsink fins with zero bypass. Max target for pressure drop (dP) measured in inches H2O.
4. Dimensions of heatsinks do not include socket or processor.
5. This is a tray product only. Alternate thermal profiles are available with higher TLA, see specific processor specifications for
details.
6. Refer to Table 1-1 for the model numbers of each processor based on TDP and core count.
95W - 10/8 Core STS200C (with fan) 0.201 55.9 Max RPM NA 91.5x91.5x64
95W - 10/8 Core STS200P 0.263 50.0 16 0.406 91.5x91.5x25.5
95W - 10/8 Core STS200PNRW 0.274 49.0 14 0.347 70x106x25.5
95W - 10/8 Core STS200C (without fan) 0.201 55.9 26 0.14 91.5x91.5x64
95W - 6/4 Core STS200C (with fan) 0.223 55.8 Max RPM NA 91.5x91.5x64
95W - 6/4 Core STS200P 0.285 49.9 16 0.406 91.5x91.5x25.5
95W - 6/4 Core STS200PNRW 0.296 48.9 14 0.347 70x106x25.5
95W - 6/4 Core STS200C (without fan) 0.223 55.8 26 0.14 91.5x91.5x64
80W - 6/4 Core STS200C (with fan) 0.223 53.2 Max RPM NA 91.5x91.5x64
80W - 6/4 Core STS200P 0.285 48.2 16 0.406 91.5x91.5x25.5
80W - 6/4 Core STS200PNRW 0.296 47.3 14 0.347 70x106x25.5
80W - 6/4 Core STS200C (without fan) 0.223 53.2 26 0.14 91.5x91.5x64
70W - 10 Core STS200C (with fan) 0.199 51.1 Max RPM NA 91.5x91.5x64
70W - 10 Core STS200P 0.261 46.7 16 0.406 91.5x91.5x25.5
70W - 10 Core STS200PNRW 0.272 46.0 14 0.347 70x106x25.5
70W - 10 Core STS200C (without fan) 0.199 51.1 26 0.14 91.5x91.5x64
60W - 6 Core STS200C (with fan) 0.217 50.0 Max RPM NA 91.5x91.5x64
60W - 6 Core STS200P 0.279 46.3 16 0.406 91.5x91.5x25.5
60W - 6 Core STS200PNRW 0.290 45.6 14 0.347 70x106 x25.5
60W - 6 Core STS200C (without fan) 0.217 50.0 26 0.14 91.5x91.5x64
LV95W - 10 C ore5STS200P 0.261 48.5 1 6 0.406 91.5x91.5x25.5
LV70W - 10 C ore5STS200P 0.259 58.9 1 6 0.406 91.5x91.5x25.5
STS200P 0.262 58.9 16 0.406 91.5x91.5x25.5
LV50W - 6 C ore5STS200P 0.276 66.7 16 0.406 91.5x91.5x25.5
Table 10-4. Server Thermal Solution Boundary Conditions (Sheet 2 of 2)
TDP Thermal Solution ΨCA2
(˚C/W) TLA 1 (˚C) Airflow 3
(CFM)
Delta P
(inch of
H2O)
Heatsink
Volumetric4
(mm)
Boxed Processor Specifications
234 Intel® Xeon® Processor E5-1600/E5-2600/E5-4600 v2 Product Families
Datasheet Volume One of Two
10.4 Boxed Processor Contents
The Boxed Processor and Boxed Thermal Solution contents are outlined below.
Boxed Processor
Intel® Xeon® processor E5-2600 v2 product family
Installation and warranty manual
Intel Inside Logo
Boxed Thermal Solution
Thermal solution assembly
Thermal interface material (pre-applied)
Installation and warranty manual
§