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2.3.2.1. Using Simulation Signal Activity Data in Power Analysis
2.3.2.2. Signal Activities from RTL (Functional) Simulation, Supplemented by Vectorless Estimation
2.3.2.3. Signal Activities from Vectorless Estimation and User-Supplied Input Pin Activities
2.3.2.4. Signal Activities from User Defaults Only
2.5.1. Complete Design Simulation Power Analysis Flow
2.5.2. Modular Design Simulation Power Analysis Flow
2.5.3. Multiple Simulation Power Analysis Flow
2.5.4. Overlapping Simulation Power Analysis Flow
2.5.5. Partial Design Simulation Power Analysis Flow
2.5.6. Vectorless Estimation Power Analysis Flow
3.4.1. Clock Power Management
3.4.2. Pipelining and Retiming
3.4.3. Architectural Optimization
3.4.4. I/O Power Guidelines
3.4.5. Dynamically Controlled On-Chip Terminations (OCT)
3.4.6. Memory Optimization (M20K/MLAB)
3.4.7. DDR Memory Controller Settings
3.4.8. DSP Implementation
3.4.9. Reducing High-Speed Tile (HST) Usage
3.4.10. Unused Transceiver Channels
3.4.11. Periphery Power reduction XCVR Settings
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2.3. Specifying Power Analyzer Input
The Power Analyzer accuracy is driven by design factors, operating conditions, and signal activity data that affect power consumption. The following figure shows how the Power Analyzer interprets these inputs and generates results in the Power Analysis report:
Figure 2. Power Analyzer High-Level Flow
To obtain accurate I/O power estimates, the Power Analyzer requires full compilation of your design, in addition to specifying the following settings:
- The electrical standard on each I/O cell.
- The board trace model on each I/O standard in the design.
- Timing assignments for all the clocks in your design, or use a simulation-based flow to generate activity data.
Note: For accurate results, ensure that any .VCD file used with the Power Analyzer is the result of gate-level simulation.