2.1. Installation and Licensing for LL 100GbE IP Core for Stratix® V Devices
2.2. Installing and Licensing Intel® FPGA IP Cores
2.3. Specifying the IP Core Parameters and Options
2.4. IP Core Parameters
2.5. Files Generated for Stratix V Variations
2.6. Files Generated for Arria 10 Variations
2.7. Integrating Your IP Core in Your Design
2.8. IP Core Testbenches
2.9. Compiling the Full Design and Programming the FPGA
2.10. Initializing the IP Core
2.7.1. Pin Assignments
2.7.2. External Transceiver Reconfiguration Controller Required in Stratix V Designs
2.7.3. Transceiver PLL Required in Arria 10 Designs
2.7.4. Handling Potential Jitter in Intel® Arria® 10 Devices
2.7.5. External Time-of-Day Module for Variations with 1588 PTP Feature
2.7.6. External TX MAC PLL
2.7.7. Placement Settings for the LL 100GbE Core
3.2.1. LL 100GbE IP Core TX Datapath
3.2.2. LL 100GbE IP Core TX Data Bus Interfaces
3.2.3. LL 100GbE IP Core RX Datapath
3.2.4. LL 100GbE IP Core RX Data Bus Interfaces
3.2.5. Low Latency 100GbE CAUI–4 PHY
3.2.6. External Reconfiguration Controller
3.2.7. External Transceiver PLL
3.2.8. External TX MAC PLL
3.2.9. Congestion and Flow Control Using Pause Frames
3.2.10. Pause Control and Generation Interface
3.2.11. Pause Control Frame Filtering
3.2.12. Link Fault Signaling Interface
3.2.13. Statistics Counters Interface
3.2.14. 1588 Precision Time Protocol Interfaces
3.2.15. PHY Status Interface
3.2.16. Transceiver PHY Serial Data Interface
3.2.17. Control and Status Interface
3.2.18. Arria 10 Transceiver Reconfiguration Interface
3.2.19. Clocks
3.2.20. Resets
3.2.2.1. LL 100GbE IP Core User Interface Data Bus
3.2.2.2. LL 100GbE IP Core TX Data Bus with Adapters (Avalon-ST Interface)
3.2.2.3. LL 100GbE IP Core TX Data Bus Without Adapters (Custom Streaming Interface)
3.2.2.4. Bus Quantization Effects With Adapters
3.2.2.5. User Interface to Ethernet Transmission
3.2.3.1. LL 100GbE IP Core RX Filtering
3.2.3.2. LL 100GbE IP Core Preamble Processing
3.2.3.3. LL 100GbE IP Core FCS (CRC-32) Removal
3.2.3.4. LL 100GbE IP Core CRC Checking
3.2.3.5. LL 100GbE IP Core Malformed Packet Handling
3.2.3.6. RX CRC Forwarding
3.2.3.7. Inter-Packet Gap
3.2.3.8. RX RSFEC
3.2.3.9. Pause Ignore
3.2.3.10. Control Frame Identification
3.4.1.1. PHY Registers
3.4.1.2. Link Fault Signaling Registers
3.4.1.3. LL 100GbE IP Core MAC Configuration Registers
3.4.1.4. Pause Registers
3.4.1.5. TX Statistics Registers
3.4.1.6. RX Statistics Registers
3.4.1.7. 1588 PTP Registers
3.4.1.8. TX Reed-Solomon FEC Registers
3.4.1.9. RX Reed-Solomon FEC Registers
3.2.3.9. Pause Ignore
If you turn on flow control by setting Flow control mode to the value of Standard flow control or Priority-based flow control in the LL 100GbE parameter editor, the IP core processes incoming pause frames by default. However, when the pause frame receive enable bit (for standard flow control) or bits (for priority-based flow control) is or are not set, the IP core does not process incoming pause frames. In this case, the MAC TX traffic is not affected by the valid pause frames.
If you turn off flow control by setting Flow control mode to the value of No flow control in the LL 100GbE parameter editor, the IP core does not process incoming pause frames.