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1. Planning Pin and FPGA Resources
2. DDR2 and DDR3 SDRAM Board Design Guidelines
3. Dual-DIMM DDR2 and DDR3 SDRAM Board Design Guidelines
4. LPDDR2 SDRAM Board Design Guidelines
5. RLDRAM II and RLDRAM 3 Board Design Guidelines
6. QDR II/II+ SRAM Board Design Guidelines
7. Implementing and Parameterizing Memory IP
8. Simulating Memory IP
9. Analyzing Timing of Memory IP
10. Debugging Memory IP
11. Optimizing the Controller
12. PHY Considerations
13. Power Estimation Methods for External Memory Interfaces
1.1.1. Estimating Pin Requirements
1.1.2. DDR, DDR2, and DDR3 SDRAM Clock Signals
1.1.3. DDR, DDR2, and DDR3 SDRAM Command and Address Signals
1.1.4. DDR, DDR2, and DDR3 SDRAM Data, Data Strobes, DM/DBI, and Optional ECC Signals
1.1.5. DDR, DDR2, and DDR3 SDRAM DIMM Options
1.1.6. QDR II and QDR II+ SRAM Clock Signals
1.1.7. QDR II and QDR II+ SRAM Command Signals
1.1.8. QDR II and QDR II+ SRAM Address Signals
1.1.9. QDR II and QDR II+ SRAM Data, BWS, and QVLD Signals
1.1.10. RLDRAM II and RLDRAM 3 Clock Signals
1.1.11. RLDRAM II and RLDRAM 3 Commands and Addresses
1.1.12. RLDRAM II and RLDRAM 3 Data, DM and QVLD Signals
1.1.13. LPDDR2 Clock Signal
1.1.14. LPDDR2 Command and Address Signal
1.1.15. LPDDR2 Data, Data Strobe, and DM Signals
1.1.16. Maximum Number of Interfaces
1.1.17. OCT Support
1.1.16.1. Maximum Number of DDR SDRAM Interfaces Supported per FPGA
1.1.16.2. Maximum Number of DDR2 SDRAM Interfaces Supported per FPGA
1.1.16.3. Maximum Number of DDR3 SDRAM Interfaces Supported per FPGA
1.1.16.4. Maximum Number of QDR II and QDR II+ SRAM Interfaces Supported per FPGA
1.1.16.5. Maximum Number of RLDRAM II Interfaces Supported per FPGA
1.1.16.6. Maximum Number of LPDDR2 SDRAM Interfaces Supported per FPGA
1.2.1. General Pin-out Guidelines for UniPHY-based External Memory Interface IP
1.2.2. Pin-out Rule Exceptions for ×36 Emulated QDR II and QDR II+ SRAM Interfaces in Arria II, Stratix III and Stratix IV Devices
1.2.3. Pin-out Rule Exceptions for RLDRAM II and RLDRAM 3 Interfaces
1.2.4. Pin-out Rule Exceptions for QDR II and QDR II+ SRAM Burst-length-of-two Interfaces
1.2.5. Pin Connection Guidelines Tables
1.2.6. PLLs and Clock Networks
1.2.5.1. DDR3 SDRAM With Leveling Interface Pin Utilization Applicable for Arria V GZ, Stratix III, Stratix IV, and Stratix V Devices
1.2.5.2. QDR II and QDR II+ SRAM Pin Utilization for Arria II, Arria V, Stratix III, Stratix IV, and Stratix V Devices
1.2.5.3. RLDRAM II CIO Pin Utilization for Arria II GZ, Arria V, Stratix III, Stratix IV, and Stratix V Devices
1.2.5.4. LPDDR2 Pin Utilization for Arria V, Cyclone V, and MAX 10 FPGA Devices
1.2.5.5. Additional Guidelines for Arria V GZ and Stratix V Devices
1.2.5.6. Additional Guidelines for Arria V ( Except Arria V GZ) Devices
1.2.5.7. Additional Guidelines for MAX 10 Devices
1.2.5.8. Additional Guidelines for Cyclone V Devices
1.2.6.1. Number of PLLs Available in Intel® Device Families
1.2.6.2. Number of Enhanced PLL Clock Outputs and Dedicated Clock Outputs Available in Intel® Device Families
1.2.6.3. Number of Clock Networks Available in Intel® Device Families
1.2.6.4. Clock Network Usage in UniPHY-based Memory Interfaces—DDR2 and DDR3 SDRAM (1) (2)
1.2.6.5. Clock Network Usage in UniPHY-based Memory Interfaces—RLDRAM II, and QDR II and QDR II+ SRAM
1.2.6.6. PLL Usage for DDR, DDR2, and DDR3 SDRAM Without Leveling Interfaces
1.2.6.7. PLL Usage for DDR3 SDRAM With Leveling Interfaces
2.1. Leveling and Dynamic Termination
2.2. DDR2 Terminations and Guidelines
2.3. DDR3 Terminations in Arria V, Cyclone V, Stratix III, Stratix IV, and Stratix V
2.4. Layout Approach
2.5. Channel Signal Integrity Measurement
2.6. Design Layout Guidelines
2.7. Package Deskew
2.8. Document Revision History
3.2.1. Overview of ODT Control
3.2.2. DIMM Configuration
3.2.3. Dual-DIMM Memory Interface with Slot 1 Populated
3.2.4. Dual-DIMM with Slot 2 Populated
3.2.5. Dual-DIMM Memory Interface with Both Slot 1 and Slot 2 Populated
3.2.6. Dual-DIMM DDR2 Clock, Address, and Command Termination and Topology
3.2.7. Control Group Signals
3.2.8. Clock Group Signals
7.2.1.1. DDR2 SDRAM Controller with UniPHY Intel FPGA IP Interfaces
7.2.1.2. DDR3 SDRAM Controller with UniPHY Intel FPGA IP Interfaces
7.2.1.3. LPDDR2 SDRAM Controller with UniPHY Intel FPGA IP Interfaces
7.2.1.4. QDR II and QDR II+ SRAM Controller with UniPHY Intel FPGA IP Interfaces
7.2.1.5. RLDRAM II Controller with UniPHY Intel FPGA IP Interfaces
7.2.1.6. RLDRAM 3 UniPHY Intel FPGA IP Interface
7.2.3.1. PHY Settings for UniPHY IP
7.2.3.2. Memory Parameters for LPDDR2, DDR2 and DDR3 SDRAM Controller with UniPHY Intel FPGA IP
7.2.3.3. Memory Parameters for QDR II and QDR II+ SRAM Controller with UniPHY Intel FPGA IP
7.2.3.4. Memory Parameters for RLDRAM II Controller with UniPHY Intel FPGA IP
7.2.3.5. Memory Timing Parameters for DDR2, DDR3, and LPDDR2 SDRAM Controller with UniPHY Intel FPGA IP
7.2.3.6. Memory Timing Parameters for QDR II and QDR II+ SRAM Controller with UniPHY Intel FPGA IP
7.2.3.7. Memory Timing Parameters for RLDRAM II Controller with UniPHY Intel FPGA IP
7.2.3.8. Memory Parameters for RLDRAM 3 UniPHY Intel FPGA IP
8.2.1. Simulation Scripts
8.2.2. Preparing the Vendor Memory Model
8.2.3. Functional Simulation with Verilog HDL
8.2.4. Functional Simulation with VHDL
8.2.5. Simulating the Example Design
8.2.6. UniPHY Abstract PHY Simulation
8.2.7. PHY-Only Simulation
8.2.8. Post-fit Functional Simulation
8.2.9. Simulation Issues
9.1. Memory Interface Timing Components
9.2. FPGA Timing Paths
9.3. Timing Constraint and Report Files for UniPHY IP
9.4. Timing Analysis Description
9.5. Timing Report DDR
9.6. Report SDC
9.7. Calibration Effect in Timing Analysis
9.8. Timing Model Assumptions and Design Rules
9.9. Common Timing Closure Issues
9.10. Optimizing Timing
9.11. Timing Deration Methodology for Multiple Chip Select DDR2 and DDR3 SDRAM Designs
9.12. Performing I/O Timing Analysis
9.13. Document Revision History
9.4.1.1. Address and Command
9.4.1.2. PHY or Core
9.4.1.3. PHY or Core Reset
9.4.1.4. Read Capture and Write
9.4.1.5. Read Resynchronization
9.4.1.6. DQS versus CK—Arria II GX and Cyclone IV Devices
9.4.1.7. Write Leveling tDQSS
9.4.1.8. Write Leveling tDSH/tDSS
9.4.1.9. DK versus CK (RLDRAM II with UniPHY)
9.4.1.10. Bus Turnaround Time
9.9.1. Missing Timing Margin Report
9.9.2. Incomplete Timing Margin Report
9.9.3. Read Capture Timing
9.9.4. Write Timing
9.9.5. Address and Command Timing
9.9.6. PHY Reset Recovery and Removal
9.9.7. Clock-to-Strobe (for DDR and DDR2 SDRAM Only)
9.9.8. Read Resynchronization and Write Leveling Timing (for SDRAM Only)
10.1. Resource and Planning Issues
10.2. Interface Configuration Performance Issues
10.3. Functional Issue Evaluation
10.4. Timing Issue Characteristics
10.5. Verifying Memory IP Using the Signal Tap II Logic Analyzer
10.6. Hardware Debugging Guidelines
10.7. Categorizing Hardware Issues
10.8. EMIF Debug Toolkit Overview
10.9. Document Revision History
10.3.1. Correct Combination of the Quartus Prime Software and ModelSim* - Intel® FPGA Edition Device Models
10.3.2. Intel® IP Memory Model
10.3.3. Vendor Memory Model
10.3.4. Insufficient Memory in Your PC
10.3.5. Transcript Window Messages
10.3.6. Passing Simulation
10.3.7. Modifying the Example Driver to Replicate the Failure
10.6.1. Create a Simplified Design that Demonstrates the Same Issue
10.6.2. Measure Power Distribution Network
10.6.3. Measure Signal Integrity and Setup and Hold Margin
10.6.4. Vary Voltage
10.6.5. Use Freezer Spray and Heat Gun
10.6.6. Operate at a Lower Speed
10.6.7. Determine Whether the Issue Exists in Previous Versions of Software
10.6.8. Determine Whether the Issue Exists in the Current Version of Software
10.6.9. Try A Different PCB
10.6.10. Try Other Configurations
10.6.11. Debugging Checklist
11.2.1. DDR2 SDRAM Controller
11.2.2. Auto-Precharge Commands
11.2.3. Additive Latency
11.2.4. Bank Interleaving
11.2.5. Command Queue Look-Ahead Depth
11.2.6. Additive Latency and Bank Interleaving
11.2.7. User-Controlled Refresh
11.2.8. Frequency of Operation
11.2.9. Burst Length
11.2.10. Series of Reads or Writes
11.2.11. Data Reordering
11.2.12. Starvation Control
11.2.13. Command Reordering
11.2.14. Bandwidth
11.2.15. Efficiency Monitor
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7.5.8.5. Stratix 10 EMIF IP RLDRAM 3 Parameters: Board
Display Name | Identifier | Description |
---|---|---|
Address and command ISI/crosstalk | BOARD_RLD3_USER_AC_ISI_NS | The address and command window reduction due to ISI and crosstalk effects. The number to be entered is the total loss of margin on both the setup and hold sides (measured loss on the setup side + measured loss on the hold side). Refer to the EMIF Simulation Guidance wiki page for additional information. |
QK/QK# ISI/crosstalk | BOARD_RLD3_USER_RCLK_ISI_NS | QK/QK# ISI/crosstalk describes the reduction of the read data window due to intersymbol interference and crosstalk effects on the QK/QK# signal when driven by the memory device during a read. The number to be entered in the Quartus Prime software is the total of the measured loss of margin on the setup side plus the measured loss of margin on the hold side. Refer to the EMIF Simulation Guidance wiki page for additional information. |
DK/DK# ISI/crosstalk | BOARD_RLD3_USER_WCLK_ISI_NS | DK/DK# ISI/crosstalk describes the reduction of the write data window due to intersymbol interference and crosstalk effects on the DK/DK# signal when driven by the FPGA during a write. The number to be entered in the Quartus Prime software is the total of the measured loss of margin on the setup side plus the measured loss of margin on the hold side. Refer to the EMIF Simulation Guidance wiki page for additional information. |
Write DQ ISI/crosstalk | BOARD_RLD3_USER_WDATA_ISI_NS | The reduction of the write data window due to ISI and crosstalk effects on the DQ signal when driven by the FPGA during a write. The number to be entered is the total of the measured loss of margin on the setup side plus the measured loss of margin on the hold side. Refer to the EMIF Simulation Guidance wiki page for additional information. |
Use default ISI/crosstalk values | BOARD_RLD3_USE_DEFAULT_ISI_VALUES | You can enable this option to use default intersymbol interference and crosstalk values for your topology. Note that the default values are not optimized for your board. For optimal signal integrity, it is recommended that you do not enable this parameter, but instead perform I/O simulation using IBIS models and Hyperlynx*, and manually enter values based on your simulation results, instead of using the default values. |
Display Name | Identifier | Description |
---|---|---|
Average delay difference between address/command and CK | BOARD_RLD3_AC_TO_CK_SKEW_NS | The average delay difference between the address/command signals and the CK signal, calculated by averaging the longest and smallest address/command signal trace delay minus the maximum CK trace delay. Positive values represent address and command signals that are longer than CK signals and negative values represent address and command signals that are shorter than CK signals. |
Maximum board skew within QK group | BOARD_RLD3_BRD_SKEW_WITHIN_QK_NS | Maximum board skew within QK group refers to the largest skew between all DQ and DM pins in a QK group. This value can affect the read capture and write margins. |
Average delay difference between DK and CK | BOARD_RLD3_DK_TO_CK_SKEW_NS | This parameter describes the average delay difference between the DK signals and the CK signal, calculated by averaging the longest and smallest DK trace delay minus the CK trace delay. Positive values represent DK signals that are longer than CK signals and negative values represent DK signals that are shorter than CK signals. |
Package deskewed with board layout (address/command bus) | BOARD_RLD3_IS_SKEW_WITHIN_AC_DESKEWED | Enable this parameter if you are compensating for package skew on the address, command, control, and memory clock buses in the board layout. Include package skew in calculating the following board skew parameters. |
Package deskewed with board layout (QK group) | BOARD_RLD3_IS_SKEW_WITHIN_QK_DESKEWED | If you are compensating for package skew on the QK bus in the board layout (hence checking the box here), please include package skew in calculating the following board skew parameters. |
Maximum CK delay to device | BOARD_RLD3_MAX_CK_DELAY_NS | The maximum CK delay to device refers to the delay of the longest CK trace from the FPGA to any device. |
Maximum DK delay to device | BOARD_RLD3_MAX_DK_DELAY_NS | The maximum DK delay to device refers to the delay of the longest DK trace from the FPGA to any device. |
Maximum system skew within address/command bus | BOARD_RLD3_PKG_BRD_SKEW_WITHIN_AC_NS | Maximum system skew within address/command bus refers to the largest skew between the address and command signals. |
Maximum delay difference between devices | BOARD_RLD3_SKEW_BETWEEN_DIMMS_NS | This parameter describes the largest propagation delay on the DQ signals between ranks. For example, in a two-rank configuration where devices are placed in series, there is an extra propagation delay for DQ signals going to and coming back from the furthest device compared to the nearest device. This parameter is only applicable when there is more than one rank. |
Maximum skew between DK groups | BOARD_RLD3_SKEW_BETWEEN_DK_NS | This parameter describes the largest skew between DK signals in different DK groups. |