E-tile Hard IP Intel® Agilex™ Design Example User Guide: Ethernet, E-tile CPRI PHY and Dynamic Reconfiguration

Download PDF
ID 683860
Date 9/26/2022
Public

A newer version of this document is available. Customers should click here to go to the newest version.

Document Table of Contents
Document Table of Contents x
1. About E-tile Hard IP Intel® Agilex™ Design Example User Guide 2. E-tile Ethernet IP for Intel® Agilex™ FPGA Design Example 3. E-tile CPRI PHY Intel® FPGA IP Design Example 4. E-Tile Dynamic Reconfiguration Design Example 5. E-tile Hard IP Intel® Agilex™ Design Examples User Guide Archives
2. E-tile Ethernet IP for Intel® Agilex™ FPGA Design Example x
2.1. Quick Start Guide 2.2. 10GE/25GE with Optional RS-FEC Design Examples 2.3. 100GE with Optional RS-FEC Design Example 2.4. Ethernet Toolkit Overview 2.5. Document Revision History for the E-tile Hard IP for Ethernet Intel® Agilex™ FPGA IP Design Example User Guide
2.1. Quick Start Guide x
2.1.1. Directory Structure 2.1.2. Generating the Design 2.1.3. Simulating the E-tile Ethernet IP for Intel Agilex FPGA Design Example Testbench 2.1.4. Compiling the Compilation-Only Project 2.1.5. Compiling and Configuring the Design Example in Hardware 2.1.6. Testing the E-tile Ethernet IP for Intel Agilex FPGA Hardware Design Example
2.1.6. Testing the E-tile Ethernet IP for Intel Agilex FPGA Hardware Design Example x
2.1.6.1. 10GE/25GE Design Example 2.1.6.2. 100GE MAC+PCS with Optional (528,514) RS-FEC or (544,514) RS-FEC and Adaptation Flow Hardware Design Example 2.1.6.3. 100GE PCS Only with Optional (528,514) RS-FEC or (544,514) RS-FEC, and Optional PTP Hardware Design Example
2.2. 10GE/25GE with Optional RS-FEC Design Examples x
2.2.1. Simulation Design Examples 2.2.2. Hardware Design Examples 2.2.3. 10GE/25GE Design Example Interface Signals 2.2.4. 10GE/25GE Design Examples Registers
2.2.1. Simulation Design Examples x
2.2.1.1. Non-PTP 10GE/25GE MAC+PCS with Optional RS-FEC Simulation Design Example 2.2.1.2. PTP 10GE/25GE MAC+PCS with Optional RS-FEC Simulation Design Example 2.2.1.3. 10GE/25GE PCS Only, OTN, or FlexE with Optional RS-FEC Simulation Design Example 2.2.1.4. 10GE/25GE Custom PCS with Optional RS-FEC Simulation Design Example
2.2.2. Hardware Design Examples x
2.2.2.1. 10GE/25GE MAC+PCS with Optional RS-FEC and PTP Hardware Design Example Components 2.2.2.2. 10GE/25GE PCS Only with Optional RS-FEC Hardware Design Example Components 2.2.2.3. 10GE/25GE Custom PCS with Optional RS-FEC Hardware Design Example
2.3. 100GE with Optional RS-FEC Design Example x
2.3.1. Simulation Design Examples 2.3.2. Hardware Design Examples 2.3.3. 100GE MAC+PCS with Optional RS-FEC Design Example Interface Signals 2.3.4. 100GE PCS with Optional RS-FEC Design Example Interface Signals 2.3.5. 100GE MAC+PCS with Optional RS-FEC Design Example Registers 2.3.6. 100GE PCS with Optional RS-FEC Design Example Registers
2.3.1. Simulation Design Examples x
2.3.1.1. Non-PTP E-tile Ethernet IP for Intel Agilex FPGA 100GE MAC+PCS with Optional RS-FEC Simulation Design Example 2.3.1.2. E-tile Ethernet IP for Intel Agilex FPGA 100GE MAC+PCS with Optional RS-FEC and PTP Simulation Design Example 2.3.1.3. E-tile Ethernet IP for Intel Agilex FPGA 100GE PCS Only with Optional RS-FEC Simulation Design Example 2.3.1.4. E-tile Ethernet IP for Intel Agilex FPGA 100GE OTN with Optional RS-FEC Simulation Design Example 2.3.1.5. E-tile Ethernet IP for Intel Agilex FPGA 100GE FlexE with Optional RS-FEC Simulation Design Example
2.3.2. Hardware Design Examples x
2.3.2.1. 100GE MAC+PCS with Optional RS-FEC and PMA Adaptation Flow Hardware Design Example Components 2.3.2.2. 100GE MAC+PCS with Optional RS-FEC and PTP Hardware Design Example 2.3.2.3. 100GE PCS with Optional RS-FEC Hardware Design Example Components 2.3.2.4. Ethernet Adaptation Flow for 100G (CAUI-2) PAM4 <---> 100G (CAUI-4) NRZ Dynamic Reconfiguration Design Example
2.4. Ethernet Toolkit Overview x
2.4.1. Features
3. E-tile CPRI PHY Intel® FPGA IP Design Example x
3.1. E-tile CPRI PHY Intel® FPGA IP Quick Start Guide 3.2. E-tile CPRI PHY Design Example Description 3.3. Document Revision History for the E-tile CPRI PHY Intel® FPGA IP Design Example User Guide
3.1. E-tile CPRI PHY Intel® FPGA IP Quick Start Guide x
3.1.1. Hardware and Software Requirements 3.1.2. Generating the Design 3.1.3. Directory Structure 3.1.4. Simulating the Design Example Testbench 3.1.5. Compiling the Compilation-Only Project 3.1.6. Compiling and Configuring the Design Example in Hardware 3.1.7. Testing the E-tile CPRI PHY Intel® FPGA IP Hardware Design Example
3.2. E-tile CPRI PHY Design Example Description x
3.2.1. Features 3.2.2. Simulation Design Example 3.2.3. Hardware Design Example 3.2.4. Interface Signals 3.2.5. Design Example Register Map for Reconfiguration
4. E-Tile Dynamic Reconfiguration Design Example x
4.1. Quick Start Guide 4.2. 10G/25G Ethernet Dynamic Reconfiguration Design Examples 4.3. 25G Ethernet to CPRI Dynamic Reconfiguration Design Example 4.4. CPRI Dynamic Reconfiguration Design Examples 4.5. 100G Ethernet Dynamic Reconfiguration Design Example 4.6. Document Revision History for the E-tile Dynamic Reconfiguration Design Example
4.1. Quick Start Guide x
4.1.1. Directory Structure 4.1.2. Generating the Design 4.1.3. Simulating the E-Tile Dynamic Reconfiguration Design Example Testbench 4.1.4. Compiling and Configuring the Design Example in Hardware 4.1.5. Testing the E-tile Dynamic Reconfiguration Hardware Design Example
4.1.2. Generating the Design x
4.1.2.1. Design Example Parameters
4.1.3. Simulating the E-Tile Dynamic Reconfiguration Design Example Testbench x
4.1.3.1. Running the Simulation with Default HEX File 4.1.3.2. Running the Simulation with New HEX File 4.1.3.3. Performing the Link Initialization
4.1.5. Testing the E-tile Dynamic Reconfiguration Hardware Design Example x
4.1.5.1. Running the Design Example in Hardware 4.1.5.2. Power Management Setting for Agilex Transceiver Signal Integrity Development Kit
4.2. 10G/25G Ethernet Dynamic Reconfiguration Design Examples x
4.2.1. Functional Description 4.2.2. Simulation Design Examples 4.2.3. Hardware Design Examples 4.2.4. 10GE/25GE Design Example Interface Signals 4.2.5. 10GE/25GE Design Examples Registers 4.2.6. Dynamic Reconfiguration Flow for 25GbE PTP FEC to 25GbE PTP Non-FEC
4.2.1. Functional Description x
4.2.1.1. Clocking Scheme
4.2.2. Simulation Design Examples x
4.2.2.1. 10GE/25GE MAC+PCS with RS-FEC and PTP Simulation Dynamic Reconfiguration Design Example Components 4.2.2.2. 10GE/25GE MAC+PCS with RS-FEC Simulation Dynamic Reconfiguration Design Example Components
4.2.3. Hardware Design Examples x
4.2.3.1. 10GE/25GE MAC+PCS with RS-FEC and PTP Hardware Dynamic Reconfiguration Design Example Components 4.2.3.2. 10GE/25GE MAC+PCS with RS-FEC Hardware Dynamic Reconfiguration Design Example Components
4.3. 25G Ethernet to CPRI Dynamic Reconfiguration Design Example x
4.3.1. Functional Description 4.3.2. Simulation Design Examples 4.3.3. Hardware Design Examples 4.3.4. 25G Ethernet to CPRI Design Example Interface Signals 4.3.5. 25G Ethernet to CPRI Design Examples Registers 4.3.6. Dynamic Reconfiguration Flow for 25GbE PTP FEC to 24G CPRI FEC
4.3.1. Functional Description x
4.3.1.1. Clocking Scheme 4.3.1.2. Reset
4.3.2. Simulation Design Examples x
4.3.2.1. 25GE MAC+PCS with RS-FEC and PTP to CPRI Simulation Dynamic Reconfiguration Design Example Components
4.3.3. Hardware Design Examples x
4.3.3.1. 25GE MAC+PCS with RS-FEC and PTP to CPRI Hardware Dynamic Reconfiguration Design Example Components
4.4. CPRI Dynamic Reconfiguration Design Examples x
4.4.1. Functional Description 4.4.2. Simulation Design Examples 4.4.3. Hardware Design Examples 4.4.4. CPRI Design Example Interface Signals 4.4.5. CPRI Design Example Registers 4.4.6. Dynamic Reconfiguration Flow for 24G CPRI FEC to 24G CPRI Non-FEC
4.4.1. Functional Description x
4.4.1.1. Clocking Scheme
4.4.2. Simulation Design Examples x
4.4.2.1. 24G CPRI PHY with RS-FEC Simulation Dynamic Reconfiguration Design Example Components 4.4.2.2. 9.8G CPRI PHY Simulation Dynamic Reconfiguration Design Example Components
4.4.3. Hardware Design Examples x
4.4.3.1. CPRI PHY with RS-FEC Hardware Dynamic Reconfiguration Design Example Components
4.5. 100G Ethernet Dynamic Reconfiguration Design Example x
4.5.1. Functional Description 4.5.2. Testing the 100G Ethernet Dynamic Reconfiguration Hardware Design Example 4.5.3. Simulation Design Examples 4.5.4. 100GE DR Hardware Design Examples 4.5.5. 100G Ethernet Dynamic Reconfiguration Design Example Interface Signals 4.5.6. 100G Ethernet Dynamic Reconfiguration Examples Registers 4.5.7. Steps to Enable FEC 4.5.8. Steps to Disable FEC
4.5.2. Testing the 100G Ethernet Dynamic Reconfiguration Hardware Design Example x
4.5.2.1. Dynamic Reconfiguration Flow in 100G Ethernet Dynamic Reconfiguration Example Design
4.5.3. Simulation Design Examples x
4.5.3.1. 100GE MAC+PCS with Optional RS-FEC Dynamic Reconfiguration Simulation Design Example 4.5.3.2. Simulating the E-tile Ethernet IP for Intel Agilex FPGA Design Example Testbench
4.5.4. 100GE DR Hardware Design Examples x
4.5.4.1. 100GE MAC+PCS with Optional RS-FEC Dynamic Reconfiguration Hardware Design Example Components
4.5.7. Steps to Enable FEC x
4.5.7.1. Configuring for 100G NRZ with RSFEC [KR-FEC (528,514)] 4.5.7.2. Configuring for 100G NRZ with RSFEC [KP-FEC (544,514)] 4.5.7.3. Configuring for 100G PAM4 with RSFEC [KP-FEC (544,514)] Transceiver configuration: Ethernet configuration: RS-FEC configuration:
1. About E-tile Hard IP Intel® Agilex™ Design Example User Guide
2. E-tile Ethernet IP for Intel® Agilex™ FPGA Design Example
3. E-tile CPRI PHY Intel® FPGA IP Design Example
4. E-Tile Dynamic Reconfiguration Design Example
5. E-tile Hard IP Intel® Agilex™ Design Examples User Guide Archives

4.5.7.3. Configuring for 100G PAM4 with RSFEC [KP-FEC (544,514)]

Transceiver configuration:

  • [T1] Write 0xC7 to Transceiver channel register 0x4[7:0] for active channels; write 0xE7 to Transceiver channel register 0x4[7:0] for unused channels.
  • [T2] Write 0x2E to Transceiver channel register 0x5[7:0] for both active and unused channels.
  • [T3] Write 0x0F to Transceiver channel register 0x6[7:0] for active channels; write 0x2F to Transceiver channel register 0x6[7:0] for unused channels.
  • [T4] Write 0x96 to Transceiver channel register 0x7[7:0] for active and unused channel.
  • [T5] Write 0xAA to Transceiver channel register 0xA4[7:0] for both active and unused channels.
  • [T6] Write 0xAA to Transceiver channel register 0xA8[7:0] for both active and unused channels.
  • [T7] Write 0xEE to Transceiver channel register 0xB0[7:0] for both active and unused channels.
  • [T8] Write 0x07 to Transceiver channel register 0xE8[7:0] for active channels; write 0x0 to Transceiver channel register 0xE8[7:0] for unused channels.
Note: Repeat steps [T1] to [T8] for the respective active and unused Transceiver channel.

Ethernet configuration:

  • [E1] Write 0x32A9E to Ethernet register 0x37A
  • [E2] Write 0x9FFD81E8 to Ethernet register 0x40B
  • [E3] Clear bits [3] and [9] of Ethernet register 0x30E (Disable RX PCS Alignment)

RS-FEC configuration:

  • [R1] Write 0x0F00 to RS-FEC register 0x04 (Re-enable RS-FEC)
  • [R2] Write 0x0000 to RS-FEC register 0x10
  • [R3] Write 0x1111 to RS-FEC register 0x14
  • [R4] Write 0x0080 to RS-FEC register 0x30
  • [R5] Write 0x08 to RS-FEC register 0x40
  • [R6] Write 0x08 to RS-FEC register 0x44
  • [R7] Write 0x08 to RS-FEC register 0x48
  • [R8] Write 0x08 to RS-FEC register 0x4C
Level Two Title