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2.1. What's New In This Version
2.2. Partial Reconfiguration Terminology
2.3. Partial Reconfiguration Process Sequence
2.4. Internal Host Partial Reconfiguration
2.5. External Host Partial Reconfiguration
2.6. Partial Reconfiguration Design Flow
2.7. Partial Reconfiguration Design Considerations
2.8. Hierarchical Partial Reconfiguration
2.9. Partial Reconfiguration Design Timing Analysis
2.10. Partial Reconfiguration Design Simulation
2.11. Partial Reconfiguration Design Debugging
2.12. Partial Reconfiguration Security ( Intel® Stratix® 10 Designs and Intel Agilex® 7 Designs)
2.13. PR Bitstream Compression and Encryption ( Intel® Arria® 10 and Intel® Cyclone® 10 GX Designs)
2.14. Avoiding PR Programming Errors
2.15. Exporting a Version-Compatible Compilation Database for PR Designs
2.16. Creating a Partial Reconfiguration Design Revision History
2.6.1. Step 1: Identify Partial Reconfiguration Resources
2.6.2. Step 2: Create Design Partitions
2.6.3. Step 3: Floorplan the Design
2.6.4. Step 4: Add the Partial Reconfiguration Controller Intel® FPGA IP
2.6.5. Step 5: Define Personas
2.6.6. Step 6: Create Revisions for Personas
2.6.7. Step 7: Compile the Base Revision and Export the Static Region
2.6.8. Step 8: Setup PR Implementation Revisions
2.6.9. Step 9: Program the FPGA Device
2.6.9.1. Generating PR Bitstream Files
2.6.9.2. Generating PR Bitstream Files
2.6.9.3. Partial Reconfiguration Bitstream Compatibility Checking
2.6.9.4. Raw Binary Programming File Byte Sequence Transmission Examples
2.6.9.5. Generating a Merged .pmsf File from Multiple .pmsf Files ( Intel® Arria® 10 and Intel® Cyclone® 10 GX Designs)
2.7.1. Partial Reconfiguration Design Guidelines
2.7.2. PR Design Timing Closure Best Practices
2.7.3. PR File Management
2.7.4. Evaluating PR Region Initial Conditions
2.7.5. Creating Wrapper Logic for PR Regions
2.7.6. Creating Freeze Logic for PR Regions
2.7.7. Resetting the PR Region Registers
2.7.8. Promoting Global Signals in a PR Region
2.7.9. Planning Clocks and other Global Routing
2.7.10. Implementing Clock Enable for On-Chip Memories
3.1. Internal and External PR Host Configurations
3.2. Partial Reconfiguration Controller Intel FPGA IP
3.3. Partial Reconfiguration Controller Intel Arria® 10/Cyclone® 10 FPGA IP
3.4. Partial Reconfiguration External Configuration Controller Intel FPGA IP
3.5. Partial Reconfiguration Region Controller Intel® FPGA IP
3.6. Avalon® Memory-Mapped Partial Reconfiguration Freeze Bridge IP
3.7. Avalon® Streaming Partial Reconfiguration Freeze Bridge IP
3.8. Generating and Simulating Intel® FPGA IP
3.9. Intel® Quartus® Prime Pro Edition User Guide: Partial Reconfiguration Archive
3.10. Partial Reconfiguration Solutions IP User Guide Revision History
3.3.1. Agent Interface
3.3.2. Reconfiguration Sequence
3.3.3. Interrupt Interface
3.3.4. Parameters
3.3.5. Ports
3.3.6. Timing Specifications
3.3.7. PR Control Block and CRC Block Verilog HDL Manual Instantiation
3.3.8. PR Control Block and CRC Block VHDL Manual Instantiation
3.3.9. PR Control Block Signals
3.3.10. Configuring an External Host for Intel® Arria® 10 or Intel® Cyclone® 10 GX Designs
3.8.1. Specifying the IP Core Parameters and Options ( Intel® Quartus® Prime Pro Edition)
3.8.2. Running the Freeze Bridge Update script
3.8.3. IP Core Generation Output ( Intel® Quartus® Prime Pro Edition)
3.8.4. Intel® Arria® 10 and Intel® Cyclone® 10 GX PR Control Block Simulation Model
3.8.5. Generating the PR Persona Simulation Model
3.8.6. Secure Device Manager Partial Reconfiguration Simulation Model
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2.13.2. Clock-to-Data Ratio for Bitstream Encryption and Compression ( Intel® Arria® 10 or Intel® Cyclone® 10 GX Designs)
The following table lists the valid combinations of bitstream encryption and compression. The Clock-to-Data (CD) ratio is defined as the number of clock cycles that each cycle of data must remain valid before the next clock cycle. For example, a CD ratio of 4 means that the data must remain valid for 4 clock cycles before the next cycle. Enhanced decompression uses the same CD ratio as plain bitstreams (that is, with both encryption and compression off). When enhanced compression is enabled, always refer to x16 data width. If you use compression and enhanced compression together, the CD ratio follows the compression bitstream - 4. If you use plain and enhanced compression together, the CD ratio follows the plain bitstream - 1.
Configuration Data Width | AES Encryption | Basic Compression | CD Ratio |
---|---|---|---|
x8 | Off | Off | 1 |
Off | On | 2 | |
On | Off | 1 | |
x16 | Off | Off | 1 |
Off | On | 4 | |
On | Off | 2 | |
x32 | Off | Off | 1 |
Off | On | 8 | |
On | Off | 4 |
Use the exact CD ratio that the Valid combinations and CD Ratio for Bitstream Encryption and Compression table specifies for different bitstream types. The CD ratio for plain .rbf must be 1. The CD ratio for compressed .rbf must be 2, 4 or 8, depending on the width. Do not specify the CD ratio as the necessary minimum to support different bitstream types.