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1. About the External Memory Interfaces Intel Agilex® 7 M-Series FPGA IP
2. Intel Agilex® 7 M-Series FPGA EMIF IP – Introduction
3. Intel Agilex® 7 M-Series FPGA EMIF IP – Product Architecture
4. Intel Agilex 7 M-Series FPGA EMIF IP – End-User Signals
5. Intel Agilex® 7 M-Series FPGA EMIF IP – Simulating Memory IP
6. Intel Agilex 7 M-Series FPGA EMIF IP – DDR4 Support
7. Intel Agilex® 7 M-Series FPGA EMIF IP – DDR5 Support
8. Intel Agilex 7 M-Series FPGA EMIF IP – LPDDR5 Support
9. Intel Agilex® 7 M-Series FPGA EMIF IP – Timing Closure
10. Intel Agilex® 7 M-Series FPGA EMIF IP – Controller Optimization
11. Intel Agilex® 7 M-Series FPGA EMIF IP – Debugging
12. Document Revision History for External Memory Interfaces Intel Agilex® 7 M-Series FPGA IP User Guide
3.1.1. Intel Agilex® 7 M-Series EMIF Architecture: I/O Subsystem
3.1.2. Intel Agilex® 7 M-Series EMIF Architecture: I/O SSM
3.1.3. Intel Agilex® 7 M-Series EMIF Architecture: I/O Bank
3.1.4. Intel Agilex® 7 M-Series EMIF Architecture: I/O Lane
3.1.5. Intel Agilex® 7 M-Series EMIF Architecture: Input DQS Clock Tree
3.1.6. Intel Agilex® 7 M-Series EMIF Architecture: PHY Clock Tree
3.1.7. Intel Agilex® 7 M-Series EMIF Architecture: PLL Reference Clock Networks
3.1.8. Intel Agilex® 7 M-Series EMIF Architecture: Clock Phase Alignment
3.1.9. User Clock in Different Core Access Modes
6.2.4.1. Address and Command Pin Placement for DDR4
6.2.4.2. DDR4 Data Width Mapping
6.2.4.3. General Guidelines - DDR4
6.2.4.4. x4 DIMM Implementation
6.2.4.5. Specific Pin Connection Requirements
6.2.4.6. Command and Address Signals
6.2.4.7. Clock Signals
6.2.4.8. Data, Data Strobes, DM/DBI, and Optional ECC Signals
6.3.5.1. Single Rank x 8 Discrete (Component) Topology
6.3.5.2. Single Rank x 16 Discrete (Component) Topology
6.3.5.3. ADDR/CMD Reference Voltage/RESET Signal Routing Guidelines for Single Rank x 8 and Single Rank x 16 Discrete (Component) Topologies
6.3.5.4. Skew Matching Guidelines for DDR4 Discrete Configurations
6.3.5.5. Power Delivery Recommendations for DDR4 Discrete Configurations
6.3.5.6. Intel Agilex® 7 M-Series EMIF Pin Swapping Guidelines
7.2.1. Intel Agilex® 7 M-Series FPGA EMIF IP Interface Pins
7.2.2. Intel Agilex® 7 M-Series FPGA EMIF IP Resources
7.2.3. Pin Guidelines for Intel Agilex® 7 M-Series FPGA EMIF IP
7.2.4. Pin Placements for Intel Agilex 7 M-Series FPGA DDR5 EMIF IP
7.2.5. Intel Agilex® 7 M-Series EMIF Pin Swapping Guidelines
7.3.1. PCB Stack-up and Design Considerations
7.3.2. General Design Considerations
7.3.3. DDR Differential Signals Routing
7.3.4. Ground Plane and Return Path
7.3.5. RDIMM, UDIMM, and SODIMM Break-in Layout Guidelines
7.3.6. DRAM Break-in Layout Guidelines
7.3.7. DDR5 PCB Layout Guidelines
7.3.8. DDR5 Simulation Strategy
7.3.7.1. DDR5 Discrete Component/Memory Down Topology: up to 40-Bit Interface (1 Rank x8 or x16, 2 Rank x8 or x16)
7.3.7.2. Routing Guidelines for DDR5 Memory Down: 1 Rank or 2 Rank (x8 bit or x16 bit) Configurations
7.3.7.3. Routing Guidelines for DDR5 RDIMM, UDIMM, and SODIMM Configurations
7.3.7.4. Example of a DDR5 layout on Intel FPGA Platform Board
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. Debugging with the External Memory Interface Debug Toolkit
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8.2.3.1. General Guidelines - LPDDR5
You should follow the recommended guidelines when performing pin placement for all external memory interface pins targeting Intel Agilex® 7 M-Series devices, whether you are using the hard memory controller or your own solution.
Note: PHY only, RLDRAMx, and QDRx are not supported with HPS.
Observe the following general guidelines when placing pins for your Intel Agilex® 7 M-Series external memory interface:
- Ensure that the pins of a single external memory interface reside on the same edge I/O.
- The address and command pins and their associated clock pins in the address and command bank must follow a fixed pin-out scheme, as defined in the table in the Address and Command Pin Placement for LPDDR5 topic.
- Not every byte lane can function as an address and command lane or a data lane. The pin assignment must adhere to the LPDDR5 data width mapping defined in LPDDR5 Data Width Mapping .
- A byte lane must not be used by both address and command pins and data pins.
- An external memory interface can occupy one or more banks on the same edge. When an interface must occupy multiple banks, ensure that those banks are adjacent to one another.
- If an I/O bank is shared between two interfaces—meaning that two sub-banks belong to two different EMIF interfaces—then both the interfaces must share the same voltage.
- Sharing of I/O lanes within a sub-bank for two different EMIF interfaces is not permitted; I/O lanes within a sub-bank can be assigned to one EMIF interface only.
- Any pin in the same bank that is not used by an external memory interface may not be available for use as a general purpose I/O pin:
- For fabric EMIF, unused pins in an I/O lane assigned to an EMIF interface cannot be used as general-purpose I/O pins. In the same sub-bank, pins in an I/O lane that is not assigned to an EMIF interface, can be used as general-purpose I/O pins.
- For HPS EMIF, unused pins in an I/O lane assigned to an EMIF interface cannot be used as general-purpose I/O pins. In the same bank, pins in an I/O lane that is not assigned to an EMIF interface cannot be used as general-purpose I/O pins either.
- All address and command pins and their associated clock pins (CK_t and CK_c) must reside within a single sub-bank. The sub-bank containing the address and command pins is identified as the address and command sub-bank. Refer to the table in LPDDR5 Data Width Mapping for the supported address and command and data lane placements for DDR5.
- The address and command pins and their associated clock pins in the address and command bank must follow a fixed pin-out scheme, as defined in the Intel Agilex® 7 M-Series External Memory Interface Pin Information file.
- An external memory interface can occupy one or more banks on the same edge. When an interface must occupy multiple banks, ensure the following:
- That the banks are adjacent to one another.
- That you used only the supported data width mapping as defined in the table in LPDDR5 Data Width Mapping . Be aware that not every byte lane can be used as an address and command lane or a data lane.
- An unused I/O lane in the address and command sub-bank can serve to implement a data group, such as a x8 DQS group. The data group must be from the same controller as the address and command signals.
- An I/O lane must not be used by both address and command pins and data pins.
- Place read data groups according to the DQS grouping in the pin table and Pin Planner. Read data strobes (such as RDQS_t and RDQS_c) must reside at physical pins capable of functioning as RDQS_t and RDQS_c for a specific read data group size. You must place the associated read data pins (DQ), within the same group.
- One of the sub-banks in the device (typically the sub-bank within corner bank 3A) may not be available if you use certain device configuration schemes. For some schemes, there may be an I/O lane available for EMIF data group.
- AVST-8 – This is contained entirely within the SDM, therefore all lanes of sub-bank 3A can be used by the external memory interface.
- AVST-16/AVST-32– Lanes 4, 5, 6, and 7 are all effectively occupied and are not usable by the external memory interface.
- Two memory interfaces cannot share an I/O 48 sub-bank.