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1. About the External Memory Interfaces Agilex™ 7 M-Series FPGA IP
2. Agilex™ 7 M-Series FPGA EMIF IP – Introduction
3. Agilex™ 7 M-Series FPGA EMIF IP – Product Architecture
4. Agilex™ 7 M-Series FPGA EMIF IP – End-User Signals
5. Agilex™ 7 M-Series FPGA EMIF IP – Simulating Memory IP
6. Agilex™ 7 M-Series FPGA EMIF IP – DDR4 Support
7. Agilex™ 7 M-Series FPGA EMIF IP – DDR5 Support
8. Agilex™ 7 M-Series FPGA EMIF IP – LPDDR5 Support
9. Agilex™ 7 M-Series FPGA EMIF IP – Timing Closure
10. Agilex™ 7 M-Series FPGA EMIF IP – Controller Optimization
11. Agilex™ 7 M-Series FPGA EMIF IP – Debugging
12. Document Revision History for External Memory Interfaces Agilex™ 7 M-Series FPGA IP User Guide
3.1.1. Agilex™ 7 M-Series EMIF Architecture: I/O Subsystem
3.1.2. Agilex™ 7 M-Series EMIF Architecture: I/O SSM
3.1.3. Agilex™ 7 M-Series EMIF Architecture: I/O Bank
3.1.4. Agilex™ 7 M-Series EMIF Architecture: I/O Lane
3.1.5. Agilex™ 7 M-Series EMIF Architecture: Input DQS Clock Tree
3.1.6. Agilex™ 7 M-Series EMIF Architecture: PHY Clock Tree
3.1.7. Agilex™ 7 M-Series EMIF Architecture: PLL Reference Clock Networks
3.1.8. Agilex™ 7 M-Series EMIF Architecture: Clock Phase Alignment
3.1.9. User Clock in Different Core Access Modes
4.1.1. ref_clk for External Memory Interfaces (EMIF) IP
4.1.2. core_init_n for External Memory Interfaces (EMIF) IP
4.1.3. usr_async_clk for External Memory Interfaces (EMIF) IP
4.1.4. usr_clk for External Memory Interfaces (EMIF) IP
4.1.5. usr_rst_n for External Memory Interfaces (EMIF) IP
4.1.6. s0_axi4 for External Memory Interfaces (EMIF) IP
4.1.7. mem for External Memory Interfaces (EMIF) IP
4.1.8. oct for External Memory Interfaces (EMIF) IP
4.2.1. ref_clk for External Memory Interfaces (EMIF) IP
4.2.2. core_init_n for External Memory Interfaces (EMIF) IP
4.2.3. usr_async_clk for External Memory Interfaces (EMIF) IP
4.2.4. usr_clk for External Memory Interfaces (EMIF) IP
4.2.5. usr_rst_n for External Memory Interfaces (EMIF) IP
4.2.6. s0_axi4 for External Memory Interfaces (EMIF) IP
4.2.7. mem for External Memory Interfaces (EMIF) IP
4.2.8. i3c for External Memory Interfaces (EMIF) IP
4.2.9. mem_lbd for External Memory Interfaces (EMIF) IP
4.2.10. mem_lbs for External Memory Interfaces (EMIF) IP
4.2.11. oct for External Memory Interfaces (EMIF) IP
4.3.1. ref_clk for External Memory Interfaces (EMIF) IP
4.3.2. core_init_n for External Memory Interfaces (EMIF) IP
4.3.3. usr_async_clk for External Memory Interfaces (EMIF) IP
4.3.4. usr_clk for External Memory Interfaces (EMIF) IP
4.3.5. usr_rst_n for External Memory Interfaces (EMIF) IP
4.3.6. s0_axi4 for External Memory Interfaces (EMIF) IP
4.3.7. mem for External Memory Interfaces (EMIF) IP
4.3.8. oct for External Memory Interfaces (EMIF) IP
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
Data Bus Connection Mapping Flow
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. 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 an Altera 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. Debugging with the External Memory Interface Debug Toolkit
11.6. Generating Traffic with the Test Engine IP
11.7. Guidelines for Developing HDL for Traffic Generator
11.8. Guidelines for Traffic Generator Status Check
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6.2.4.4. x4 DIMM Implementation
DIMMS using a x4 DQS configuration require remapping of the DQS signals to achieve compatibility between the EMIF IP and the JEDEC standard DIMM socket connections.
The necessary remapping is shown in the table below. You can implement this DQS remapping in either RTL logic or in your schematic wiring connections.
DIMM | Quartus® Prime EMIF IP | |||
---|---|---|---|---|
DQS0_A | DQ[3:0]_A | DQS0 | DQ[3:0]_A | |
DQS5_A | DQ[7:4]_A | DQS1 | DQ[7:4]_A | |
DQS1_A | DQ[11:8]_A | DQS2 | DQ[11:8]_A | |
DQS6_A | DQ[15:12]_A | DQS3 | DQ[15:12]_A | |
DQS2_A | DQ[19:16]_A | DQS4 | DQ[19:16]_A | |
DQS7_A | DQ[23:20]_A | DQS5 | DQ[23:20]_A | |
DQS3_A | DQ[27:24]_A | DQS6 | DQ[27:24]_A | |
DQS8_A | DQ[31:28]_A | DQS7 | DQ[31:28]_A | |
DQS4_A | CB[3:0]_A | DQS8 | CB[3:0]_A | |
DQS9_A | CB[7:4]_A | DQS9 | CB[7:4]_A | |
DQS0_B | DQ[3:0]_B | DQS10 | DQ[3:0]_B | |
DQS5_B | DQ[7:4]_B | DQS11 | DQ[7:4]_B | |
DQS1_B | DQ[11:8]_B | DQS12 | DQ[11:8]_B | |
DQS6_B | DQ[15:12]_B | DQS13 | DQ[15:12]_B | |
DQS2_B | DQ[19:16]_B | DQS14 | DQ[19:16]_B | |
DQS7_B | DQ[23:20]_B | DQS15 | DQ[23:20]_B | |
DQS3_B | DQ[27:24]_B | DQS16 | DQ[27:24]_B | |
DQS8_B | DQ[31:28]_B | DQS17 | DQ[31:28]_B | |
DQS4_B | CB[3:0]_B | DQS18 | CB[3:0]_B | |
DQS9_B | CB[7:4]_B | DQS19 | CB[7:4]_B |
Data Bus Connection Mapping Flow
- Connect all FPGA DQ pins accordingly to DIMM DQ pins. No remapping is required.
- DQS/DQSn remapping is required either on the board schematics or in the RTL code.
When designing a board to support x4 DQS groups, Altera recommends that you make it compatible for x8 mode, for the following reasons:
- Provides the flexibility of x4 and x8 DIMM support.
- Allows use of x8 DQS group connectivity rules.
- Allows use of x8 timing rules for matching. Adhere to x4/x8 interoperability rules when designing a DIMM interface, even if the primary use case is to support x4 DIMMs only, because doing so facilitates debug and future migration capabilities. Regardless, the rules for length matching for two nibbles in a x4 interface must match those of the signals for a corresponding x8 interface, as the data terminations are turned on and off at the same time for both x4 DQS groups in an I/O lane. If the two x4 DQS groups were to have significantly different trace delays, it could adversely affect signal integrity. Trace delays for two nibbles packed within the IO12 lanes are matched using the same guidelines as a single x8 byte lane.