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Intel BX80637G2010 4.4 PCI Express* Power Management, 4.5 DMI Power Management, 4.6 Graphics Power Management

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Power Management

60 Datasheet, Volume 1

4.4 PCI Express* Power Management

• Active power management support using L0s and L1 states.

• All inputs and outputs disabled in L2/L3 Ready state.

Note: PCIe* interface does not support Hot-Plug.

Note: An increase in power consumption may be observed when PCIe Active State Power

Management (ASPM) capabilities are disabled.

4.5 DMI Power Management

• Active power management support using L0s/L1 state.

4.6 Graphics Power Management

4.6.1 Intel® Rapid Memory Power Management (Intel® RMPM) 

(also known as CxSR)

The Intel Rapid Memory Power Management (Intel RMPM) puts rows of memory into

self-refresh mode during C3/C6 to allow the system to remain in the lower power states

longer. Processors routinely save power during runtime conditions by entering the C3,

C6 state. Intel RMPM is an indirect method of power saving that can have a significant

effect on the system as a whole.

4.6.2 Intel® Graphics Performance Modulation Technology

(Intel® GPMT)

Intel Graphics Power Modulation Technology (Intel® GPMT) is a method for saving

power in the graphics adapter while continuing to display and process data in the

adapter. This method will switch the render frequency and/or render voltage

dynamically between higher and lower power states supported on the platform based

on render engine workload.

In products where Intel® Graphics Dynamic Frequency (also known as Turbo Boost

Technology) is supported and enabled, the functionality of Intel GPMT will be

maintained by Intel Graphics Dynamic Frequency (also known as Turbo Boost

Tec hno log y) .

4.6.3 Graphics Render C-State

Render C-State (RC6) is a technique designed to optimize the average power to the

graphics render engine during times of idleness of the render engine. Render C-state is

entered when the graphics render engine, blitter engine and the video engine have no

workload being currently worked on and no outstanding graphics memory transactions.

When the idleness condition is met then the Processor Graphics will program the VR

into a low voltage state (~0 V) through the SVID bus.

Caution: Long term reliability cannot be assured unless all the Low Power Idle States are

enabled.

Contents

Main 2 Contents Page Page Figures Tables Page Revision History 1 Figure 1-1. Desktop Processor Platform DDR3 PECI Intel Processor 1.1 Processor Feature Details 1.1.1 Supported Technologies 1.2 Interfaces 1.2.1 System Memory Support 1.2.2 PCI Express* Page 1.2.3 Direct Media Interface (DMI) 1.2.4 Platform Environment Control Interface (PECI) 1.2.5 Processor Graphics 1.2.6 Intel Flexible Display Interface (Intel FDI) 1.3 Power Management Support 1.3.1 Processor Core 1.3.2 System 1.3.3 Memory Controller 1.3.4 PCI Express* 1.4 Processor SKU Definitions 1.5 Package Introduction 18 Datasheet, Volume 1 1.6 Processor Compatibility PCH Figure 1-2. Desktop Processor Compatibility Diagram VCCIO VR VDDQ VR VCore VR VCCSA VR 1.7 Terminology Table 1-2. Terminology (Sheet 1 of 3) Table 1-2. Terminology (Sheet 2 of 3) Table 1-2. Terminology (Sheet 3 of 3) 1.8 Related Documents Table 1-3. Related Documents 2 2.1 System Memory Interface 2.1.1 System Memory Technology Supported 2.1.2 System Memory Timing Support Table 2-2. Supported UDIMM Module Configurations Table 2-3. Supported SO-DIMM Module Configurations (AIO Only) 2.1.3 System Memory Organization Modes 2.1.3.1 Single-Channel Mode 2.1.3.2 Dual-Channel Mode Intel Flex Memory Technology Mode 2.1.4 Rules for Populating Memory Slots 2.1.5 Technology Enhancements of Intel Fast Memory Access (Intel FMA) 2.1.5.1 Just-in-Time Command Scheduling 2.1.5.2 Command Overlap 2.1.5.3 Out-of-Order Scheduling 2.1.6 Data Scrambling 2.2 PCI Express* Interface 2.2.1 PCI Express* Architecture 2.2.1.1 Transaction Layer 2.2.1.2 Data Link Layer 2.2.1.3 Physical Layer 2.2.2 PCI Express* Configuration Mechanism 2.2.3 PCI Express* Port 2.2.3.1 PCI Express* Lanes Connection 2.3 Direct Media Interface (DMI) 2.3.1 DMI Error Flow 2.3.2 Processor / PCH Compatibility Assumptions 2.3.3 DMI Link Down 2.4 Processor Graphics Controller (GT) 2.4.1 3D and Video Engines for Graphics Processing 2.4.1.1 3D Engine Execution Units 2.4.1.2 3D Pipeline 2.4.1.3 Video Engine 2.4.1.4 2D Engine 2.4.2 Processor Graphics Display 2.4.2.1 Display Planes 2.4.2.2 Display Pipes 2.4.2.3 Display Ports 2.4.3 Intel Flexible Display Interface (Intel FDI) 2.4.4 Multi Graphics Controllers Multi-Monitor Support 2.5 Platform Environment Control Interface (PECI) 2.6 Interface Clocking 2.6.1 Internal Clocking Requirements 3 3.1 Intel Virtualization Technology (Intel VT) 3.1.3 Intel Virtualization Technology (Intel VT) for Directed I/O (Intel VT-d) Objectives 3.1.4 Intel Virtualization Technology (Intel VT) for Directed I/O (Intel VT-d) Features 3.2 Intel Trusted Execution Technology (Intel TXT) 3.3 Intel Hyper-Threading Technology (Intel HT Technology) 3.4 Intel Turbo Boost Technology 3.4.1 Intel Turbo Boost Technology Frequency 3.4.2 Intel Turbo Boost Technology Graphics Frequency 3.5 Intel Advanced Vector Extensions (Intel AVX) 3.6 Security and Cryptography Technologies 3.6.1 Intel Advanced Encryption Standard New Instructions (Intel AES-NI) 3.6.2 PCLMULQDQ Instruction 3.6.3 RDRAND Instruction 3.7 Intel 64 Architecture x2APIC 3.8 Supervisor Mode Execution Protection (SMEP) 3.9 Power Aware Interrupt Routing (PAIR) 4 G0 Working G3 Mechanical Off G1 Sleeping 4.1 Advanced Configuration and Power Interface (ACPI) States Supported The ACPI states supported by the processor are described in this section. 4.1.3 Integrated Memory Controller States 4.1.1 System States 4.1.2 Processor Core / Package Idle States 4.1.4 PCI Express* Link States 4.1.5 Direct Media Interface (DMI) States 4.1.7 Interface State Combinations 4.1.6 Processor Graphics Controller States Table 4-4. PCI Express* Link States 4.2 Processor Core Power Management 4.2.1 Enhanced Intel SpeedStep Technology 4.2.2 Low-Power Idle States Processor Package State Core 0 State C1 C1E C6C3 Core 1 State C0 4.2.3 Requesting Low-Power Idle States 4.2.4 Core C-states 4.2.4.1 Core C0 State 4.2.4.2 Core C1 / C1E State 4.2.4.3 Core C3 State 4.2.4.4 Core C6 State 4.2.4.5 C-State Auto-Demotion 4.2.5 Package C-States 4.2.5.1 Package C0 4.2.5.2 Package C1/C1E 4.2.5.3 Package C3 State 4.2.5.4 Package C6 State 4.3 Integrated Memory Controller (IMC) Power Management 4.3.1 Disabling Unused System Memory Outputs 4.3.2 DRAM Power Management and Initialization 4.3.2.1 Initialization Role of CKE 4.3.2.2 Conditional Self-Refresh 4.3.2.3 Dynamic Power Down Operation 4.3.2.4 DRAM I/O Power Management 4.3.3 DDR Electrical Power Gating (EPG) 4.4 PCI Express* Power Management 4.5 DMI Power Management 4.6 Graphics Power Management 4.6.1 Intel Rapid Memory Power Management (Intel RMPM) (also known as CxSR) 4.6.2 Intel Graphics Performance Modulation Technology (Intel GPMT) 4.7 Graphics Thermal Power Management Page 5 Page 6 6.1 System Memory Interface Signals Table 6-2. Memory Channel A Signals 6.2 Memory Reference and Compensation Signals Table 6-3. Memory Channel B Signals Table 6-4. Memory Reference and Compensation 6.3 Reset and Miscellaneous Signals Table 6-5. Reset and Miscellaneous Signals 6.4 PCI Express*-based Interface Signals 6.5 Intel Flexible Display (Intel FDI) Interface Signals Table 6-6. PCI Express* Graphics Interface Signals Table 6-7. Intel Flexible Display (Intel FDI) Interface 6.6 Direct Media Interface (DMI) Signals 6.7 Phase Lock Loop (PLL) Signals 6.8 Test Access Points (TAP) Signals Table 6-8. Direct Media Interface (DMI) Sign als Processor to PCH Serial Interface Table 6-9. Phase Lock Loop (PLL) Signals Table 6-10. Test Access Points (TAP) Signals 6.9 Error and Thermal Protection Signals Table 6-11. Error and Thermal Protection Signals 6.10 Power Sequencing Signals Table 6-12. Power Sequencing Signals 6.11 Processor Power Signals 6.12 Sense Signals Table 6-13. Processor Power Signals Table 6-14. Sense Signals 6.13 Ground and Non-Critical to Function (NCTF) Signals 6.14 Processor Internal Pull-Up / Pull-Down Resistors Table 6-15. Ground and Non-Critical to Function (NCTF) Signals Table 6-16. Processor Internal Pull-Up / Pull-Down Resistors 7 7.1 Power and Ground Lands 7.2 Decoupling Guidelines 7.2.1 Voltage Rail Decoupling 7.3 Processor Clocking (BCLK[0], BCLK#[0]) 7.3.1 Phase Lock Loop (PLL) Power Supply 7.4 VCC Voltage Identification (VID) Table 7-1. VR 12.0 Voltage Identification Definition (Sheet 1 of 3) Table 7-1. VR 12.0 Volt age Identification Definition (Sheet 2 of 3) Table 7-1. VR 12.0 Voltage Identification Definition (Sheet 3 of 3) 7.5 System Agent (SA) VCC VID 7.6 Reserved or Unused Signals 7.7 Signal Groups Table 7-2. Signal Groups (Sheet 1 of 2) 7.8 Test Access Port (TAP) Connection 7.9 Storage Conditions Specifications 7.10 DC Specifications 7.10.1 Voltage and Current Specifications Page Table 7-5. Processor System Agent I/O Buffer Supply DC Voltage and Current Specifications Table 7-6. Processor Graphics VID based (VAXG) Supply DC Voltage and Current Specifications Table 7-7. DDR3 Signal Group DC Specifications (Sheet 1 of 2) Table 7-7. D DR3 Signal Group DC Specifications (Sheet 2 of 2) Table 7-8. Control Sideband and TAP Signal Group DC Specifications Table 7-9. PCI Express* DC Specifications 7.11 Platform Environmental Control Interface (PECI) DC Specifications 7.11.1 PECI Bus Architecture 7.11.2 DC Characteristics PECI Ground PECI Low Range Maximum V Minimum V Page 8 Information 8.1 Processor Land Assignments Processor Land and Signal Information 94 Datasheet, Volume 1 Figure 8-1. LGA Socket Land Map Page Page Page Page Page Page Page Page Page Page Page Processor Land and Signal Information Page Page 9 DDR Data Swizzling Table 9-1. DDR Data Swizz ling Table Channel A Table 9-1. DDR Data Swizzling Table Channel A Table 9-2. D DR Data Swizzling table Channel B Table 9-2. DDR Data Swizzling table Channel B