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2.1.1. Directory Structure
2.1.2. Generating the Design
2.1.3. Simulating the E-tile Ethernet IP for Intel Agilex® 7 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® 7 FPGA Hardware Design Example
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
2.3.1. 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
2.3.1.1. Non-PTP E-tile Ethernet IP for Intel Agilex® 7 FPGA 100GE MAC+PCS with Optional RS-FEC Simulation Design Example
2.3.1.2. E-tile Ethernet IP for Intel Agilex® 7 FPGA 100GE MAC+PCS with Optional RS-FEC and PTP Simulation Design Example
2.3.1.3. E-tile Ethernet IP for Intel Agilex® 7 FPGA 100GE PCS Only with Optional RS-FEC Simulation Design Example
2.3.1.4. E-tile Ethernet IP for Intel Agilex® 7 FPGA 100GE OTN with Optional RS-FEC Simulation Design Example
2.3.1.5. E-tile Ethernet IP for Intel Agilex® 7 FPGA 100GE FlexE with Optional RS-FEC Simulation Design Example
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
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
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
4.5.1. 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
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3.2.3. Hardware Design Example
Figure 27. E-tile CPRI PHY Intel® FPGA IP Core Hardware Design Examples High Level Block Diagram
The E-tile CPRI PHY Intel® FPGA IP core hardware design example includes the following components:
- E-tile CPRI PHY Intel® FPGA IP core.
- Packet client logic block that generates and receives traffic.
- Round trip counter.
- IOPLL to generate sampling clock for deterministic latency logic inside the IP, and round trip counter component at testbench.
- Channel PLL to generate external AIB clocks for the IP.
- Avalon® -MM address decoder to decode reconfiguration address space for CPRI, transceiver, and RS-FEC modules during reconfiguration accesses.
- Sources and probes for asserting resets and monitoring the clocks and a few status bits.
- JTAG controller that communicates with the System Console. You communicate with the client logic through System Console.
- The example design targets an Intel Agilex® 7 TX Transceiver Signal Integrity Development Kit.