Visible to Intel only — GUID: haw1707919849748
Ixiasoft
1. About the External Memory Interfaces Agilex™ 5 FPGA IP
2. Agilex™ 5 FPGA EMIF IP – Introduction
3. Agilex™ 5 FPGA EMIF IP – Product Architecture
4. Agilex™ 5 FPGA EMIF IP – End-User Signals
5. Agilex™ 5 FPGA EMIF IP – Simulating Memory IP
6. Intel® Agilex™ 5 FPGA EMIF IP - DDR4 Support
7. Intel® Agilex™ 5 FPGA EMIF IP - LPDDR4 Support
8. Intel® Agilex™ 5 FPGA EMIF IP - LPDDR5 Support
9. Agilex™ 5 FPGA EMIF IP – Timing Closure
10. Agilex™ 5 FPGA EMIF IP – Controller Optimization
11. Agilex™ 5 FPGA EMIF IP – Debugging
12. Document Revision History for External Memory Interfaces (EMIF) IP User Guide
3.2.1. Agilex™ 5 EMIF Architecture: I/O Subsystem
3.2.2. Agilex™ 5 EMIF Architecture: I/O SSM
3.2.3. Agilex™ 5 EMIF Architecture: HSIO Bank
3.2.4. Agilex™ 5 EMIF Architecture: I/O Lane
3.2.5. Agilex™ 5 EMIF Architecture: Input DQS Clock Tree
3.2.6. Agilex™ 5 EMIF Architecture: PHY Clock Tree
3.2.7. Agilex™ 5 EMIF Architecture: PLL Reference Clock Networks
3.2.8. Agilex™ 5 EMIF Architecture: Clock Phase Alignment
3.2.9. User Clock in Different Core Access Modes
6.4.3.1. 1 Rank x 8 Discrete (Memory Down) Topology
6.4.3.2. 1 Rank x 16 Discrete (Memory Down) Topology
6.4.3.3. VREF_CA/RESET Signal Routing Guidelines for 1 Rank x 8 and 1 Rank x 16 Discrete (Memory Down) Topology
6.4.3.4. Skew Matching Guidelines for DDR4 (Memory Down) Discrete Configurations
6.4.3.5. Power Delivery Recommendation for DDR4 Discrete Configurations
6.4.3.6. DDR4 Simulation Strategy
11.1. Interface Configuration Performance Issues
11.2. Functional Issue Evaluation
11.3. Timing Issue Characteristics
11.4. Verifying Memory IP Using the Signal Tap Logic Analyzer
11.5. Generating Traffic with the Test Engine IP
11.6. Guidelines for Developing HDL for Traffic Generator
11.7. Hardware Debugging Guidelines
11.8. Create a Simplified Design that Demonstrates the Same Issue
11.9. Measure Power Distribution Network
11.10. Measure Signal Integrity and Setup and Hold Margin
11.11. Vary Voltage
11.12. Operate at a Lower Speed
11.13. Determine Whether the Issue Exists in Previous Versions of Software
11.14. Determine Whether the Issue Exists in the Current Version of Software
11.15. Try A Different PCB
11.16. Try Other Configurations
11.17. Debugging Checklist
11.18. Categorizing Hardware Issues
11.19. Signal Integrity Issues
11.20. Characteristics of Signal Integrity Issues
11.21. Evaluating Signal Integrity Issues
11.22. Skew
11.23. Crosstalk
11.24. Power System
11.25. Clock Signals
11.26. Address and Command Signals
11.27. Read Data Valid Window and Eye Diagram
11.28. Write Data Valid Window and Eye Diagram
11.29. Hardware and Calibration Issues
11.30. Memory Timing Parameter Evaluation
11.31. Verify that the Board Has the Correct Memory Component or DIMM Installed
Visible to Intel only — GUID: haw1707919849748
Ixiasoft
7.3.3.1. LPDDR4 Discrete Component/Memory Down Topology (up to 32 bits interface)
LPDDR4 memory down supports single-rank configuration up to 32 bits. There are four DRAM interface signal groupings, namely: data group, command-address group, control group, and clock group. The connection between the FPGA and DRAM device uses point-to-point topology as depicted in the following two figures.
The following figure illustrates the stripline routing for inner pins.
Figure 41. Stripline Routing for Data, CA, CTRL and Clock Signals Point-to-Point Topology
The following figure illustrates the microstrip routing for the edge pins per byte.
Figure 42. Microstrip Routing for Data Signals Point-to-Point Topology
The following figure shows the connection topology for CA, CLK, CTRL signals for LPDDR4 topology in daisy-chain and T-Line connections.
Figure 43. Stripline Routing for CA, CLK, CTRL Daisy-chain and T-Line Topology
The following tables provide a comprehensive routing guideline for each of the LPDDR4 signals based on memory down topology. For example, the trace impedance, the total trace length, the maximum length of the main trace routing can be derived by subtracting break-out and break-in trace segment length routed from total trace length.
|
The above table shows the stripline routing guideline for LPDDR4 memory down topology. The h value in the table represents the minimum substrate height from signal layer to reference layer. The signal trace width, and minimum spacing/gaps (in mils) between edge to edge of signal traces are based on the default stackup; however, PCB designers can use the target impedance for any other stackups.
The table below shows microstrip routing for LPDDR4 memory down topology.
|
Reset signal routing design also follows the CMD/ADD/CTRL routing design. Keep the space at least 5xh between the Reset signal to other signals on the same layer (measured edge to edge). There is no requirement to have skew matching between Reset signal and CLK signal.
Skew matching for LPDDR4 interfaces consists of both package routing skew and PCB physical routing skew. You must maintain skew matching of CA and CTRL with respect to the clock signals to ensure signals at the receiver are correctly sampled. In addition, there are skew matching requirement for DQ and DQS within a byte group, DQS and CLK. The table below provides a detailed skew matching guideline to facilitate PCB trace routing efforts. In this table, the length matching criteria represents a default PCB on an Intel platform board design; you must always follow the skew matching criteria in any other stackup.
|
LPDDR4 eye margin is sensitive to crosstalk, especially when the signals are routed on deep layers in stackup. The deep-layer vertical transition induces more vertical coupling between signals and hence more crosstalk.
The maximum data rate of LPDDR4 depends on the DDR memory down configuration and the type of PCB stackup. Reduced data transfer rate is seen whenever 2 x rank LPDDR4 memory down configuration is used.