Intel® Quartus® Prime Pro Edition User Guide: Power Analysis and Optimization

Download PDF
ID 683174
Date 10/04/2021
Public

A newer version of this document is available. Customers should click here to go to the newest version.

Document Table of Contents
Document Table of Contents x
1. Power Analysis 2. Power Optimization 3. Power Analysis and Optimization Document Archive A. Intel® Quartus® Prime Pro Edition User Guides
1. Power Analysis x
1.1. Power Analysis Tools 1.2. Running the Power Analyzer 1.3. Specifying Power Analyzer Input 1.4. Viewing Power Analysis Reports 1.5. Power Analysis in Modular Design Flows 1.6. Scripting Support 1.7. Power Analysis Revision History
1.3. Specifying Power Analyzer Input x
1.3.1. Settings for Power Analysis 1.3.2. Specifying Signal Activity Data 1.3.3. Specifying the Default Toggle Rate 1.3.4. Specifying Toggle Rates for Specific Nodes 1.3.5. Avoiding Simulation Node Name Match
1.3.2. Specifying Signal Activity Data x
1.3.2.1. Using Simulation Signal Activity Data in Power Analysis 1.3.2.2. Signal Activities from RTL (Functional) Simulation, Supplemented by Vectorless Estimation 1.3.2.3. Signal Activities from Vectorless Estimation and User-Supplied Input Pin Activities 1.3.2.4. Signal Activities from User Defaults Only
1.3.2.1. Using Simulation Signal Activity Data in Power Analysis x
1.3.2.1.1. Generating Signal Activity Data for Power Analysis 1.3.2.1.2. Generating Standard Delay Output for Power Analysis 1.3.2.1.3. Simulation Glitch Filtering
1.3.2.2. Signal Activities from RTL (Functional) Simulation, Supplemented by Vectorless Estimation x
1.3.2.2.1. RTL Simulation Limitation
1.3.4. Specifying Toggle Rates for Specific Nodes x
1.3.4.1. Clock Node Toggle Rates
1.5. Power Analysis in Modular Design Flows x
1.5.1. Complete Design Simulation Power Analysis Flow 1.5.2. Modular Design Simulation Power Analysis Flow 1.5.3. Multiple Simulation Power Analysis Flow 1.5.4. Overlapping Simulation Power Analysis Flow 1.5.5. Partial Design Simulation Power Analysis Flow 1.5.6. Vectorless Estimation Power Analysis Flow
1.5.5. Partial Design Simulation Power Analysis Flow x
1.5.5.1. Specifying Start and End Time for Signal Activity Calculations
1.6. Scripting Support x
1.6.1. Running the Power Analyzer from the Command–Line
2. Power Optimization x
2.1. Factors Affecting Power Consumption 2.2. Design Space Explorer II for Power-Driven Optimization 2.3. Power-Driven Compilation 2.4. Design Guidelines 2.5. Power Optimization Advisor 2.6. Power Optimization Revision History
2.1. Factors Affecting Power Consumption x
2.1.1. Design Activity and Power Analysis 2.1.2. Device Selection 2.1.3. Environmental Conditions 2.1.4. Device Resource Usage 2.1.5. Signal Activity
2.1.4. Device Resource Usage x
2.1.4.1. Number, Type, and Loading of I/O Pins 2.1.4.2. Number and Type of Hard Logic Blocks 2.1.4.3. Number and Type of Global Signals
2.1.5. Signal Activity x
2.1.5.1. Toggle Rate 2.1.5.2. Static Probability
2.3. Power-Driven Compilation x
2.3.1. Power-Driven Synthesis 2.3.2. Power-Driven Fitter 2.3.3. Area-Driven Synthesis 2.3.4. Gate-Level Register Retiming 2.3.5. Intel® Quartus® Prime Compiler Settings 2.3.6. Assignment Editor Options
2.3.1. Power-Driven Synthesis x
2.3.1.1. Memory Block Optimization 2.3.1.2. Power-Aware Logic Mapping 2.3.1.3. Power-Aware Memory Balancing
2.4. Design Guidelines x
2.4.1. Clock Power Management 2.4.2. Pipelining and Retiming 2.4.3. Architectural Optimization 2.4.4. I/O Power Guidelines 2.4.5. Dynamically Controlled On-Chip Terminations (OCT) 2.4.6. Memory Optimization (M20K/MLAB) 2.4.7. DDR Memory Controller Settings 2.4.8. DSP Implementation 2.4.9. Reducing High-Speed Tile (HST) Usage 2.4.10. Unused Transceiver Channels 2.4.11. Periphery Power reduction XCVR Settings
2.4.1. Clock Power Management x
2.4.1.1. Clock Enable in Memory Blocks 2.4.1.2. LAB Clock Power 2.4.1.3. Clock Enables 2.4.1.4. Global Signals 2.4.1.5. Merge Clocks
2.4.1.2. LAB Clock Power x
2.4.1.2.1. LAB-Wide Clock Enable Example
2.4.1.4. Global Signals x
2.4.1.4.1. Viewing Clock Details in the Chip Planner
2.4.6. Memory Optimization (M20K/MLAB) x
2.4.6.1. Implementation 2.4.6.2. Rd/Wr Enables
2.4.11. Periphery Power reduction XCVR Settings x
2.4.11.1. Transceiver Settings 2.4.11.2. I/O Current Strength
2.5. Power Optimization Advisor x
2.5.1. Set Realistic Timing Constraints 2.5.2. Appropriate Device Family 2.5.3. Dynamic Power 2.5.4. Static Power 2.5.5. Appropriate I/O Standards 2.5.6. Use RAM Blocks 2.5.7. Shut Down RAM Blocks 2.5.8. Clock Enables on Logic 2.5.9. Pipeline Logic to Reduce Glitching
2.5.1. Set Realistic Timing Constraints x
2.5.1.1. Find Timing Information
1. Power Analysis
2. Power Optimization
3. Power Analysis and Optimization Document Archive
A. Intel® Quartus® Prime Pro Edition User Guides

2.4.3. Architectural Optimization

Design-level architectural optimizations allow you to take advantage of device architecture features. These features include dedicated memory, DSPs, or multiplier blocks that can perform memory or arithmetic-related functions. You can reduce power consumption by choosing blocks in place of LUTs. For example, you can build large shift registers from RAM-based FIFO buffers instead of building the shift registers from the LE registers.
Related Information
Level Two Title