1. Introduction to Intel® FPGA Design Flow for AMD* Xilinx* Users
2. Technology Comparison
3. FPGA Tools Comparison
4. AMD* Xilinx* to Intel® FPGA Design Conversion
5. Conclusion
6. AN 307: Intel® FPGA Design Flow for AMD* Xilinx* Users Archives
7. Document Revision History for Intel® FPGA Design Flow for AMD* Xilinx* Users
3.3.1. Project Creation
3.3.2. Design Entry
3.3.3. IP Status
3.3.4. Design Constraints
3.3.5. Synthesis
3.3.6. Design Implementation
3.3.7. Finalize Pinout
3.3.8. Viewing and Editing Design Placement
3.3.9. Static Timing Analysis
3.3.10. Generation of Device Programming Files
3.3.11. Power Analysis
3.3.12. Simulation
3.3.13. Hardware Verification
3.3.14. View Netlist
3.3.15. Design Optimization
3.3.16. Techniques to Improve Productivity
3.3.17. Partial Reconfiguration
3.3.18. Cross-Probing in the Quartus® Prime Pro Edition Software
4.2.1.2.1. Memory Mode
4.2.1.2.2. Clocking Mode
4.2.1.2.3. Write and Read Operation Triggering
4.2.1.2.4. Read-During-Write Operation at the Same Address
4.2.1.2.5. Error Correction Code (ECC)
4.2.1.2.6. Byte Enable
4.2.1.2.7. Address Clock Enable
4.2.1.2.8. Parity Bit Support
4.2.1.2.9. Memory Initialization
4.2.1.2.10. Output Synchronous Set/Reset
4.2.1.2.3. Write and Read Operation Triggering
Ensure to resolve potential write contentions external to the RAM, because writing to the same address location at both ports results in unknown data storage at that location. Therefore, knowing when the write operation was triggered is crucial.
For Arria® 10 devices, the write operation in Intel® FPGA memory can occur at either falling clock edges or rising clock edges, depending on the type of embedded memory block. For Agilex™ 7 and Stratix® 10 devices, the write operation is triggered at rising clock edges.
To avoid delta delay, do not trigger control signals together with clock signals.
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