MIPI D-PHY IP User Guide: Agilex™ 5 FPGAs

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ID 817561
Date 4/01/2024
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Document Table of Contents
Document Table of Contents x
1. About the Agilex™ 5 FPGA MIPI D-PHY IP 2. Introduction 3. Agilex™ 5 MIPI D-PHY Architecture 4. MIPI D-PHY Interface Design Guidelines 5. Configuring and Generating the MIPI D-PHY IP 6. Interface Signals and Register Maps 7. Document Revision History for Agilex™ 5 FPGA MIPI D-PHY IP User Guide
1. About the Agilex™ 5 FPGA MIPI D-PHY IP x
1.1. Release Information
2. Introduction x
2.1. Supported Data Lanes and Clock Lane Per Single HSIO Bank 2.2. Unsupported Features
3. Agilex™ 5 MIPI D-PHY Architecture x
3.1. Agilex™ 5 MIPI D-PHY TX 3.2. Agilex™ 5 MIPI D-PHY RX 3.3. Initialization and Reset Sequences 3.4. Calibration 3.5. CSR Clock Domain Crossing (CDC)
4. MIPI D-PHY Interface Design Guidelines x
4.1. Identifying Pin Assignments Based on Byte Location 4.2. Assigning the RZQ pin and Dedicated Reference Clock Pin for MIPI D-PHY IP 4.3. Supported I/O Features in MIPI D-PHY I/O Standard 4.4. Using the Remaining I/O Pin from Same Byte Location 4.5. I/O Bank Sharing 4.6. MIPI D-PHY Placement Rules 4.7. MIPI Interface Layout Design Guidelines 4.8. Handling MIPI D-PHY IP Reset
5. Configuring and Generating the MIPI D-PHY IP x
5.1. Creating a MIPI D-PHY Project 5.2. Configuring the D-PHY IP Tab 5.3. Configuring the MIPI D-PHY RX Mode 5.4. Configuring the MIPI D-PHY TX Mode 5.5. Generating the Design Example
5.5. Generating the Design Example x
5.5.1. Generating the Synthesizable MIPI D-PHY Design Example 5.5.2. Generating MIPI D-PHY IP Design Example with External Loopback Enabled for Simulation
5.5.1. Generating the Synthesizable MIPI D-PHY Design Example x
5.5.1.1. Design Example Block Diagram 5.5.1.2. External Interfaces
5.5.2. Generating MIPI D-PHY IP Design Example with External Loopback Enabled for Simulation x
5.5.2.1. Simulation Design Example with External Loopback Enabled Block Diagram 5.5.2.2. Simulating MIPI D-PHY IP Design Example with Modelsim* and Questasim* 5.5.2.3. Simulating MIPI D-PHY IP Design Example with Synopsys VCS*, VCSMX*, and Xcelium*
6. Interface Signals and Register Maps x
6.1. Interface Signals 6.2. Register Maps
6.1. Interface Signals x
6.1.1. General Interface Signals 6.1.2. AXI-Lite Interface 6.1.3. Core Register Bus 6.1.4. D-PHY RX PPI Interface Signals 6.1.5. D-PHY TX PPI Interface Signals 6.1.6. AXI-Lite CSR Access
6.2. Register Maps x
6.2.1. D-PHY IP Registers 6.2.2. D-PHY Traffic Generator (TG) Registers
6.2.1. D-PHY IP Registers x
6.2.1.1. IP_ID 6.2.1.2. IP_CAP 6.2.1.3. D0_CAP 6.2.1.4. DN_CAP 6.2.1.5. RX_CAP 6.2.1.6. TX_CAP 6.2.1.7. TX_PREAMBLE_LEN 6.2.1.8. D-PHY_CSR 6.2.1.9. TX_CLK_LANE_PS 6.2.1.10. RX_DLANE_ERR 6.2.1.11. SKEW_CAL_LEN_B0 6.2.1.12. SKEW_CAL_LEN_B1 6.2.1.13. SKEW_CAL_LEN_B2 6.2.1.14. SKEW_CAL_LEN_B3 6.2.1.15. ALT_CAL_LEN_B0 6.2.1.16. ALT_CAL_LEN_B1 6.2.1.17. ALT_CAL_LEN_B2 6.2.1.18. ALT_CAL_LEN_B3 6.2.1.19. CLK_CSR 6.2.1.20. CLK_STATUS 6.2.1.21. DLANE_CSR_0 6.2.1.22. DLANE_STATUS_0 6.2.1.23. RX_DLANE_DESKEW_DELAY_0 6.2.1.24. RX_DLANE_ERR_0 6.2.1.25. DLANE_CSR_1 6.2.1.26. DLANE_STATUS_1 6.2.1.27. RX_DLANE_DESKEW_DELAY_1 6.2.1.28. RX_DLANE_ERR_1 6.2.1.29. DLANE_CSR_2 6.2.1.30. DLANE_STATUS_2 6.2.1.31. RX_DLANE_DESKEW_DELAY_2 6.2.1.32. RX_DLANE_ERR_2 6.2.1.33. DLANE_CSR_3 6.2.1.34. DLANE_STATUS_3 6.2.1.35. RX_DLANE_DESKEW_DELAY_3 6.2.1.36. RX_DLANE_ERR_3 6.2.1.37. DLANE_CSR_4 6.2.1.38. DLANE_STATUS_4 6.2.1.39. RX_DLANE_DESKEW_DELAY_4 6.2.1.40. RX_DLANE_ERR_4 6.2.1.41. DLANE_CSR_5 6.2.1.42. DLANE_STATUS_5 6.2.1.43. RX_DLANE_DESKEW_DELAY_5 6.2.1.44. RX_DLANE_ERR_5 6.2.1.45. DLANE_CSR_6 6.2.1.46. DLANE_STATUS_6 6.2.1.47. RX_DLANE_DESKEW_DELAY_6 6.2.1.48. RX_DLANE_ERR_6 6.2.1.49. DLANE_CSR_7 6.2.1.50. DLANE_STATUS_7 6.2.1.51. RX_DLANE_DESKEW_DELAY_7 6.2.1.52. RX_DLANE_ERR_7 6.2.1.53. TX_LPX 6.2.1.54. TX_HS_EXIT 6.2.1.55. TX_LP_EXIT 6.2.1.56. TX_CLK_PREPARE 6.2.1.57. TX_CLK_ZERO 6.2.1.58. TX_CLK_POST 6.2.1.59. TX_CLK_PRE 6.2.1.60. TX_HS_PREPARE 6.2.1.61. TX_HS_ZERO 6.2.1.62. TX_HS_TRAIL 6.2.1.63. TX_INIT 6.2.1.64. TX_WAKE 6.2.1.65. RX_CLK_LOSS_DETECT 6.2.1.66. RX_CLK_SETTLE 6.2.1.67. RX_HS_SETTLE 6.2.1.68. RX_INIT 6.2.1.69. RX_CLK_POST 6.2.1.70. RX_CAL_REG_CTRL 6.2.1.71. RX_CAL_STATUS_D-PHY 6.2.1.72. RX_CAL_SKEW_W_START_MUX 6.2.1.73. RX_CAL_SKEW_W_END_MUX 6.2.1.74. RX_CAL_ALT_W_START_MUX 6.2.1.75. RX__CAL_ALT_W_END_MUX 6.2.1.76. RX_DESKEW_DELAY_MUX 6.2.1.77. RX_CAL_STATUS_LANE_MUX 6.2.1.78. PRBS_INIT_0 6.2.1.79. PRBS_INIT_1 6.2.1.80. PRBS_INIT_2 6.2.1.81. PRBS_INIT_3 6.2.1.82. PRBS_INIT_4 6.2.1.83. PRBS_INIT_5 6.2.1.84. PRBS_INIT_6 6.2.1.85. TX_TM_CONTROL 6.2.1.86. TX_MNL_IO_0 6.2.1.87. TX_MNL_D_LP_EN 6.2.1.88. RX_TM_CONTROL
6.2.2. D-PHY Traffic Generator (TG) Registers x
6.2.2.1. TG_TOP_CTRL_0 6.2.2.2. TG_TOP_CTRL_1 6.2.2.3. TG_TOP_DONE 6.2.2.4. TG_TOP_FAIL 6.2.2.5. TG_TOP_TEST_EN 6.2.2.6. TG_TOP_TEST_LINK 6.2.2.7. TARGET_TEST_CNT 6.2.2.8. TCHK_CONTROL 6.2.2.9. TCHK_LINK_STATUS 6.2.2.10. HS_DONE_LANES 6.2.2.11. TCHK_LINK_ERR_STATUS 6.2.2.12. LANE_ERROR_SOT_LANES 6.2.2.13. CAL_ERROR_LANES 6.2.2.14. HS_ERR_LANES 6.2.2.15. HS_TEST_CNT 6.2.2.16. LPDT_TEST_CNT 6.2.2.17. TRIGGER_TEST_CNT 6.2.2.18. ULPS_TEST_CNT 6.2.2.19. TG_RX_OVRD_DATA_PAT 6.2.2.20. TG_RX_BIT_ERROR_CNT 6.2.2.21. TG_RX_HS_TXFER_CNT 6.2.2.22. TG_LINK_CONTROL 6.2.2.23. TG_INIT_CNT 6.2.2.24. TG_HS_LEN 6.2.2.25. TG_LP_LEN 6.2.2.26. TG_SKEW_CAL 6.2.2.27. TG_ALT_CAL 6.2.2.28. TG_PER_SKEW_CAL_LEN 6.2.2.29. TG_TEST_CNT 6.2.2.30. TG_OVRD_DATA_PAT 6.2.2.31. TG_TX_HS_TXFER_CNT
1. About the Agilex™ 5 FPGA MIPI D-PHY IP
2. Introduction
3. Agilex™ 5 MIPI D-PHY Architecture
4. MIPI D-PHY Interface Design Guidelines
5. Configuring and Generating the MIPI D-PHY IP
6. Interface Signals and Register Maps
7. Document Revision History for Agilex™ 5 FPGA MIPI D-PHY IP User Guide

5.5.2. Generating MIPI D-PHY IP Design Example with External Loopback Enabled for Simulation

To generate the design example for simulation with external loopback in the MIPI D-PHY IP, follow these steps:

  1. On the Example Design tab, ensure that the Simulation parameter is set to True.
  2. Choose the required Simulation HDL format, either Verilog or VHDL.
  3. On the Example Design tab under the D-PHY IP tab, ensure that the Sim External Loopback Enable parameter is set to true.
  4. For the TX link, ensure that the Skew calibration enable and Periodic calibration enable parameters under Link n Calibration are set to True.
  5. For the RX link, ensure that the Skew calibration enable parameter under Link n Calibration is set to True.
  6. Ensure that both the RX and TX links have the same bit rate and number of data lanes.
  7. Configure the parameters as appropriate for your needs and click File > Save to save the current settings into the IP variation file (<user instance name>.ip)

Section Content
Simulation Design Example with External Loopback Enabled Block Diagram
Simulating MIPI D-PHY IP Design Example with Modelsim* and Questasim*
Simulating MIPI D-PHY IP Design Example with Synopsys VCS*, VCSMX*, and Xcelium*

Level Two Title