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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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3.5.9. Pipeline Logic to Reduce Glitching
Long chains of cascaded logic blocks can create glitches due to path delay differences between the input signals. Inserting Flip-Flops to cut these long chains terminates the propagation of glitches to consecutive logic cells.
Circuits that heavily use of XIO functions (for example, Cyclic redundancy check) tend to glitch significantly when cascaded. Add pipeline registers or re-architect to reduce signal toggling.
Glitch Prone Design
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