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1. About the PHY Lite for Parallel Interfaces IP
2. PHY Lite for Parallel Interfaces Intel® FPGA IP (phylite_ph2) for Intel Agilex® 7 M-Series Devices
3. PHY Lite for Parallel Interfaces Intel® FPGA IP (altera_phylite_s20) for Intel Agilex® 7 F-Series and I-Series Devices
4. PHY Lite for Parallel Interfaces Intel® FPGA IP for Intel® Stratix® 10 Devices
5. PHY Lite for Parallel Interfaces Intel® FPGA IP for Intel® Arria® 10 and Intel® Cyclone® 10 GX Devices
6. PHY Lite for Parallel Interfaces Intel® FPGA IP User Guide Document Archives
7. Document Revision History for the PHY Lite for Parallel Interfaces Intel® FPGA IP User Guide
3.2.1. Intel Agilex® 7 F-Series and I-Series I/O Sub-bank Interconnects
3.2.2. Intel Agilex® 7 F-Series and I-Series Input DQS/Strobe Tree
3.2.3. PHY Lite for Parallel Interfaces Intel® FPGA IP for Intel Agilex® 7 F-Series and I-Series Devices Top Level Interfaces
3.2.4. Dynamic Reconfiguration
3.2.5. I/O Timing
4.5.6.4.1. Timing Closure: Dynamic Reconfiguration
4.5.6.4.2. Timing Closure: Input Strobe Setup and Hold Delay Constraints
4.5.6.4.3. Timing Closure: Output Strobe Setup and Hold Delay Constraints
4.5.6.4.4. Timing Closure: Non Edge-Aligned Input Data
4.5.6.4.5. I/O Timing Violation
4.5.6.4.6. Internal FPGA Path Timing Violation
5.5.6.4.1. Timing Closure: Dynamic Reconfiguration
5.5.6.4.2. Timing Closure: Input Strobe Setup and Hold Delay Constraints
5.5.6.4.3. Timing Closure: Output Strobe Setup and Hold Delay Constraints
5.5.6.4.4. Timing Closure: Non Edge-Aligned Input Data
5.5.6.4.5. I/O Timing Violation
5.5.6.4.6. Internal FPGA Path Timing Violation
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5.5.6.4.6. Internal FPGA Path Timing Violation
If timing violations are reported at the internal FPGA paths (such as <instance_name>_usr_clk or <instance_name>_phy_clk_*), consider the following guidelines:
If setup time violation is reported, lower the clock rate of the user logic from full-rate to half-rate, or from half-rate to quarter-rate. This reduces the frequency requirement of the IP core-to-core data transfer.
If hold time violation is observed, you may increase hold uncertainty value to equal or higher than the violation amount in the .sdc file. This will provide a more stringent constraint during design fitting. Following is an example to increase the hold uncertainty.
If {$::quartus(nameofexecutable) != “quartus_sta”}{ set_clock_uncertainty -from [<instance_name>_phy_clk_*] -to [<instance_name>_phy_clk_*] -hold 0.3 -add set_clock_uncertainty -from [<instance_name>_usr_clk] -to [<instance_name>_usr_clk] -hold 0.3 -add }
However, increasing the hold uncertainty value may cause setup timing violation at slow corner.