E-Tile Hard IP User Guide: E-Tile Hard IP for Ethernet and E-Tile CPRI PHY Intel® FPGA IPs

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ID 683468
Date 7/23/2024
Public
Document Table of Contents
Document Table of Contents x
1. About E-Tile Hard IP User Guide 2. About the E-Tile Hard IP for Ethernet Intel® FPGA IP Core 3. About the E-Tile CPRI PHY Intel® FPGA IP 4. Supported Tools 5. E-Tile Hard IP User Guide Archives
2. About the E-Tile Hard IP for Ethernet Intel® FPGA IP Core x
2.1. E-Tile Hard IP for Ethernet Intel® FPGA IP Supported Features 2.2. E-Tile Hard IP for Ethernet Intel® FPGA IP Overview 2.3. IP Core Device Family and Speed Grade Support 2.4. IP Core Verification 2.5. Resource Utilization 2.6. Release Information 2.7. Getting Started 2.8. E-Tile Hard IP for Ethernet Intel FPGA IP Parameters 2.9. Functional Description 2.10. Reset 2.11. Interfaces and Signals 2.12. Register Descriptions 2.13. Document Revision History for the E-Tile Hard IP for Ethernet Intel FPGA IP Core
2.3. IP Core Device Family and Speed Grade Support x
2.3.1. E-Tile Hard IP for Ethernet Intel® FPGA IP Device Family Support 2.3.2. E-Tile Hard IP for Ethernet Intel® FPGA IP Device Speed Grade Support
2.4. IP Core Verification x
2.4.1. Simulation Environment 2.4.2. Compilation Checking 2.4.3. Hardware Testing
2.7. Getting Started x
2.7.1. Installing and Licensing Intel® FPGA IP Cores 2.7.2. Specifying the IP Core Parameters and Options 2.7.3. Generated File Structure 2.7.4. Integrating Your IP Core in Your Design 2.7.5. IP Core Testbenches 2.7.6. Compiling the Full Design
2.7.1. Installing and Licensing Intel® FPGA IP Cores x
2.7.1.1. Intel® FPGA IP Evaluation Mode
2.7.4. Integrating Your IP Core in Your Design x
2.7.4.1. Channel Placement 2.7.4.2. Pin Assignments 2.7.4.3. Clock Requirements 2.7.4.4. External Time-of-Day Module for Variations with 1588 PTP Feature 2.7.4.5. SDC for Multiple E-Tile Instances
2.7.4.1. Channel Placement x
2.7.4.1.1. Guidelines and Restrictions for 24-bonded Channels Variant 2.7.4.1.2. Guidelines and Restrictions for 16-bonded Channels Variant
2.8. E-Tile Hard IP for Ethernet Intel FPGA IP Parameters x
2.8.1. Parameter Editor Parameters 2.8.2. RTL Parameters
2.9. Functional Description x
2.9.1. E-Tile Hard IP for Ethernet Intel FPGA IP MAC 2.9.2. 1588 Precision Time Protocol Interfaces 2.9.3. PCS, OTN, FlexE, and Custom PCS Modes 2.9.4. Auto-Negotiation and Link Training 2.9.5. TX and RX RS-FEC 2.9.6. PMA Direct Mode 2.9.7. Dynamic Reconfiguration 2.9.8. Ethernet Adaptation Flow for 10G/25G and 100G/4x25G Dynamic Reconfiguration Design Example 2.9.9. Ethernet Adaptation Flow for 100G (CAUI-2) PAM4 <---> 100G (CAUI-4) NRZ Dynamic Reconfiguration Design Example 2.9.10. Ethernet Adaptation Flow with PTP or with External AIB Clocking 2.9.11. Ethernet Adaptation Flow with Non-external AIB Clocking
2.9.1. E-Tile Hard IP for Ethernet Intel FPGA IP MAC x
2.9.1.1. MAC TX Datapath 2.9.1.2. MAC RX Datapath 2.9.1.3. Congestion and Flow Control Using PAUSE or Priority Flow Control (PFC) 2.9.1.4. Pause Control and Generation Interface 2.9.1.5. Pause Control Frame Filtering 2.9.1.6. Link Fault Signaling 2.9.1.7. Order of Ethernet Transmission
2.9.1.1. MAC TX Datapath x
2.9.1.1.1. TX Preamble, Start, and SFD Insertion 2.9.1.1.2. Source Address Insertion 2.9.1.1.3. Length/Type Field Processing 2.9.1.1.4. Frame Padding 2.9.1.1.5. Frame Check Sequence (CRC-32) Insertion 2.9.1.1.6. Inter-Packet Gap Generation and Insertion
2.9.1.2. MAC RX Datapath x
2.9.1.2.1. RX Preamble Processing 2.9.1.2.2. RX Strict SFD Checking 2.9.1.2.3. RX FCS Checking 2.9.1.2.4. RX Malformed Packet Handling 2.9.1.2.5. Removing PAD Bytes and FCS Bytes from RX Frames 2.9.1.2.6. RX Undersized Frames, Oversized Frames, and Frames with Length Errors 2.9.1.2.7. Inter-Packet Gap
2.9.1.3. Congestion and Flow Control Using PAUSE or Priority Flow Control (PFC) x
2.9.1.3.1. Conditions Triggering XOFF Frame Transmission 2.9.1.3.2. Conditions Triggering XON Frame Transmission
2.9.1.6. Link Fault Signaling x
2.9.1.6.1. Determining Link Fault Condition
2.9.2. 1588 Precision Time Protocol Interfaces x
2.9.2.1. Implementing a 1588 System That Includes a E-Tile Hard IP for Ethernet Intel FPGA IP 2.9.2.2. PTP Timestamp Accuracy 2.9.2.3. PTP Transmit Functionality 2.9.2.4. PTP Receive Functionality 2.9.2.5. External Time-of-Day Module for 1588 PTP Variations 2.9.2.6. PTP Timestamp and TOD Formats 2.9.2.7. 10G/25G TX and RX Unit Interval Adjustment 2.9.2.8. 10G/25G TX and RX PTP Extra Latency 2.9.2.9. 100G PTP TX User Flow 2.9.2.10. 100G PTP RX User Flow 2.9.2.11. 100G RX Virtual Lane Offset Calculation for No FEC Variants 2.9.2.12. 100G UI Adjustment 2.9.2.13. Minimum and Maximum Reference Time (TAM) Interval for UI Measurement (Hardware) 2.9.2.14. PTP System Considerations 2.9.2.15. Logic Lock Regions Requirements for PTP Accuracy Advanced Mode
2.9.3. PCS, OTN, FlexE, and Custom PCS Modes x
2.9.3.1. PCS Only Mode 2.9.3.2. OTN Mode 2.9.3.3. FlexE Mode 2.9.3.4. Custom PCS Mode
2.10. Reset x
2.10.1. Reset Sequence
2.10.1. Reset Sequence x
2.10.1.1. Reset Sequence with External AIB Clocking
2.11. Interfaces and Signals x
2.11.1. TX MAC Interface to User Logic 2.11.2. RX MAC Interface to User Logic 2.11.3. TX PCS Interface to User Logic 2.11.4. RX PCS Interface to User Logic 2.11.5. FlexE and OTN Mode TX Interface 2.11.6. FlexE and OTN Mode RX Interface 2.11.7. TX Custom PCS Interface to User Logic 2.11.8. RX Custom PCS Interface to User Logic 2.11.9. PMA Direct Interface 2.11.10. Custom Rate Interface 2.11.11. Deterministic Latency Interface 2.11.12. 1588 PTP Interface 2.11.13. Ethernet Link and Transceiver Signals 2.11.14. Reconfiguration Interfaces and Signals 2.11.15. Miscellaneous Status and Debug Signals 2.11.16. Reset Signals 2.11.17. Clocks
2.11.14. Reconfiguration Interfaces and Signals x
2.11.14.1. Ethernet Reconfiguration Interfaces 2.11.14.2. Transceiver Reconfiguration Interfaces 2.11.14.3. RS-FEC Reconfiguration Interfaces 2.11.14.4. PTP Reconfiguration Interfaces
2.11.17. Clocks x
2.11.17.1. Asynchronous Adapter Clock in 10G/25G Mode 2.11.17.2. Asynchronous Adapter Clock in 100G Mode 2.11.17.3. Clock Network Use Cases
2.11.17.3. Clock Network Use Cases x
2.11.17.3.1. Single 25G Ethernet Channel (with FEC) 2.11.17.3.2. Single 10G Ethernet Channel (without FEC) 2.11.17.3.3. Four 25G Ethernet Channels (with FEC) within a Single FEC Block 2.11.17.3.4. Ethernet 25G x 4 (FEC Off) 2.11.17.3.5. 10G/25G Ethernet Channel with Basic PTP Accuracy Mode 2.11.17.3.6. 10G/25G Ethernet Channel with Advanced PTP Accuracy Mode 2.11.17.3.7. 100G Ethernet with Aggregated FEC 2.11.17.3.8. 100G Ethernet with PTP 2.11.17.3.9. Single 25G Synchronous Ethernet Channel 2.11.17.3.10. Multiple 25G Synchronous Ethernet Channels
2.12. Register Descriptions x
2.12.1. Auto Negotiation and Link Training Registers 2.12.2. PHY Registers 2.12.3. TX MAC Registers 2.12.4. RX MAC Registers 2.12.5. Pause and Priority- Based Flow Control Registers 2.12.6. TX Statistics Counter Registers 2.12.7. RX Statistics Counter Registers 2.12.8. 1588 PTP Registers 2.12.9. RS-FEC Registers 2.12.10. PMA Registers
2.12.1. Auto Negotiation and Link Training Registers x
2.12.1.1. ANLT Sequencer Config 2.12.1.2. ANLT Sequencer Status 2.12.1.3. Auto Negotiation Config Register 1 2.12.1.4. Auto Negotiation Config Register 2 2.12.1.5. Auto Negotiation Status Register 2.12.1.6. Auto Negotiation Config Register 3 2.12.1.7. Auto Negotiation Config Register 4 2.12.1.8. Auto Negotiation Config Register 5 2.12.1.9. Auto Negotiation Config Register 6 2.12.1.10. Auto Negotiation Status Register 1 2.12.1.11. Auto Negotiation Status Register 2 2.12.1.12. Auto Negotiation Status Register 3 2.12.1.13. Auto Negotiation Status Register 4 2.12.1.14. Auto Negotiation Status Register 5 2.12.1.15. AN Channel Override 2.12.1.16. Consortium Next Page Override 2.12.1.17. Consortium Next Page Link Partner Status 2.12.1.18. Link Training Config Register 1 2.12.1.19. Link Training Status Register 1 2.12.1.20. Link Training Config Register for Lane 0 2.12.1.21. Link Training Config Register for Lane 1 2.12.1.22. Link Training Config Register for Lane 2 2.12.1.23. Link Training Config Register for Lane 3
2.12.2. PHY Registers x
2.12.2.1. PHY Module Revision ID 2.12.2.2. PHY Scratch Register 2.12.2.3. Loopback Mode 2.12.2.4. PHY Configuration 2.12.2.5. Reset Sequencer RS-FEC Disable 2.12.2.6. RX CDR PLL Locked 2.12.2.7. TX Datapath Ready 2.12.2.8. Frame Errors Detected 2.12.2.9. Clear Frame Errors 2.12.2.10. RX PCS Status for AN/LT 2.12.2.11. PCS Error Injection 2.12.2.12. Alignment Marker Lock 2.12.2.13. Change in RX PCS Deskew Status 2.12.2.14. BER Count 2.12.2.15. Transfer Ready (AIB reset) Status for EHIP, ELANE, and PTP Channels 2.12.2.16. EHIP, ELANE, and RS-FEC Reset Status 2.12.2.17. PCS Virtual Lane 0 2.12.2.18. PCS Virtual Lane 1 2.12.2.19. PCS Virtual Lane 2 2.12.2.20. PCS Virtual Lane 3 2.12.2.21. Recovered Clock Frequency in KHz 2.12.2.22. TX Clock Frequency in KHz 2.12.2.23. Configuration Fields for TX PLD 2.12.2.24. Status for TX PLDs 2.12.2.25. Status for Dynamic Deskew Buffer 2.12.2.26. Configuration for RX PLD Block 2.12.2.27. Configuration for RX PCS 2.12.2.28. BIP Counter 0 2.12.2.29. BIP Counter 1 2.12.2.30. BIP Counter 2 2.12.2.31. BIP Counter 3 2.12.2.32. BIP Counter 4 2.12.2.33. BIP Counter 5 2.12.2.34. BIP Counter 6 2.12.2.35. BIP Counter 7 2.12.2.36. BIP Counter 8 2.12.2.37. BIP Counter 9 2.12.2.38. BIP Counter 10 2.12.2.39. BIP Counter 11 2.12.2.40. BIP Counter 12 2.12.2.41. BIP Counter 13 2.12.2.42. BIP Counter 14 2.12.2.43. BIP Counter 15 2.12.2.44. BIP Counter 16 2.12.2.45. BIP Counter 17 2.12.2.46. BIP Counter 18 2.12.2.47. BIP Counter 19 2.12.2.48. Timer Window for Hi-BER Checks 2.12.2.49. Hi-BER Frame Errors 2.12.2.50. Error Block Count 2.12.2.51. Deskew Depth 0 2.12.2.52. Deskew Depth 1 2.12.2.53. Deskew Depth 2 2.12.2.54. Deskew Depth 3 2.12.2.55. RX PCS Test Error Count
2.12.3. TX MAC Registers x
2.12.3.1. TX MAC Module Revision ID 2.12.3.2. TX MAC Scratch Register 2.12.3.3. Link Fault Configuration 2.12.3.4. IPG Words to remove per Alignment Marker Period 2.12.3.5. Maximum TX Frame Size 2.12.3.6. TX MAC Configuration 2.12.3.7. EHIP TX MAC Feature Configuration 2.12.3.8. TX MAC Source Address Lower Bytes 2.12.3.9. TX MAC Source Address Higher Bytes
2.12.4. RX MAC Registers x
2.12.4.1. RX MAC Module Revision ID 2.12.4.2. RX MAC Scratch Register 2.12.4.3. Maximum RX Frame Size 2.12.4.4. RX CRC Forwarding 2.12.4.5. Link Fault Status 2.12.4.6. RX MAC Configuration 2.12.4.7. EHIP RX MAC Feature Configuration
2.12.5. Pause and Priority- Based Flow Control Registers x
2.12.5.1. TXSFC Module Revision ID 2.12.5.2. TX SFC Scratch Register 2.12.5.3. Enable TX Pause Ports 2.12.5.4. TX Pause Request 2.12.5.5. Enable Automatic TX Pause Retransmission 2.12.5.6. Retransmit Holdoff Quanta 2.12.5.7. Retransmit Pause Quanta 2.12.5.8. Enable TX XOFF 2.12.5.9. Enable Uniform Holdoff 2.12.5.10. Set Uniform Holdoff 2.12.5.11. Lower 4 bytes of the Destination address for Flow Control 2.12.5.12. Higher 2 bytes of the Destination address for Flow Control 2.12.5.13. Lower 4 bytes of the Source address for Flow Control frames 2.12.5.14. Higher 2 bytes of the Source address for Flow Control frames 2.12.5.15. TX Flow Control Feature Configuration 2.12.5.16. Pause Quanta 0 2.12.5.17. Pause Quanta 1 2.12.5.18. Pause Quanta 2 2.12.5.19. Pause Quanta 3 2.12.5.20. Pause Quanta 4 2.12.5.21. Pause Quanta 5 2.12.5.22. Pause Quanta 6 2.12.5.23. Pause Quanta 7 2.12.5.24. PFC Holdoff Quanta 0 2.12.5.25. PFC Holdoff Quanta 1 2.12.5.26. PFC Holdoff Quanta 2 2.12.5.27. PFC Holdoff Quanta 3 2.12.5.28. PFC Holdoff Quanta 4 2.12.5.29. PFC Holdoff Quanta 5 2.12.5.30. PFC Holdoff Quanta 6 2.12.5.31. PFC Holdoff Quanta 7 2.12.5.32. RXSFC Module Revision ID 2.12.5.33. RXSFC Scratch Register 2.12.5.34. Enable RX Pause Frame Processing 2.12.5.35. Forward Flow Control Frames 2.12.5.36. Lower 4 bytes of the Destination address for RX Pause Frames 2.12.5.37. Higher 2 bytes of the Destination address for RX Pause Frames 2.12.5.38. RX Flow Control Feature Configuration
2.12.6. TX Statistics Counter Registers x
2.12.6.1. TX Statistics Registers
2.12.7. RX Statistics Counter Registers x
2.12.7.1. RX Statistics Registers
3. About the E-Tile CPRI PHY Intel® FPGA IP x
3.1. Supported Features 3.2. E-Tile CPRI PHY Intel® FPGA IP Overview 3.3. E-Tile CPRI PHY Device Family Support 3.4. Resource Utilization 3.5. Release Information 3.6. E-Tile CPRI PHY Intel FPGA IP Core Device Speed Grade Support 3.7. Getting Started 3.8. Parameter Settings 3.9. Functional Description 3.10. E-Tile CPRI PHY Intel FPGA IP Interface Signals 3.11. Registers 3.12. Document Revision History for the E-Tile CPRI PHY Intel FPGA IP
3.7. Getting Started x
3.7.1. Installing and Licensing Intel® FPGA IP Cores 3.7.2. Specifying the IP Core Parameters and Options 3.7.3. Generated File Structure 3.7.4. E-Tile CPRI PHY Intel FPGA IP Channel Placement 3.7.5. IP Core Testbenches 3.7.6. Compiling the Full Design
3.7.1. Installing and Licensing Intel® FPGA IP Cores x
3.7.1.1. Intel® FPGA IP Evaluation Mode
3.7.4. E-Tile CPRI PHY Intel FPGA IP Channel Placement x
3.7.4.1. One 24.33024 Gbps channel with RS-FEC 3.7.4.2. Two 24.33024 Gbps Channel with RS-FEC 3.7.4.3. Three 24.33024 Gbps channels with RS-FEC 3.7.4.4. Four 24.33024 Gbps channels with RS-FEC 3.7.4.5. Restrictions
3.9. Functional Description x
3.9.1. CPRI PHY Functional Blocks 3.9.2. Dynamic Reconfiguration
3.9.1. CPRI PHY Functional Blocks x
3.9.1.1. E-Tile Native PHY 3.9.1.2. Soft Reset Sequencer 3.9.1.3. Latency Measurement
3.9.1.3. Latency Measurement x
3.9.1.3.1. Deterministic Latency Calculation
3.10. E-Tile CPRI PHY Intel FPGA IP Interface Signals x
3.10.1. Clock Signals 3.10.2. TX MII Interface 3.10.3. RX MII Interface 3.10.4. TX 8B/10B Interface 3.10.5. RX 8B/10B Interface 3.10.6. Status Interface for 64B/66B Line Rate 3.10.7. Status Interface for 8B/10B Line Rate 3.10.8. Serial I/O Pins 3.10.9. Reconfiguration Interfaces ( Avalon® Memory-Mapped Interface)
3.10.9. Reconfiguration Interfaces ( Avalon® Memory-Mapped Interface) x
3.10.9.1. CPRI PHY Reconfiguration Interface 3.10.9.2. Transceiver Reconfiguration Interface 3.10.9.3. RS-FEC Reconfiguration Interface
3.11. Registers x
3.11.1. PHY Registers 3.11.2. CPRI PHY Registers 3.11.3. PMA Registers 3.11.4. RS-FEC Registers
3.11.3. PMA Registers x
3.11.3.1. Minimizing PMA Adaptation Time
4. Supported Tools x
4.1. E-Tile Channel Placement Tool 4.2. Ethernet Toolkit Overview 4.3. Document Revision History for the E-Tile Channel Placement Tool and the Ethernet Link Inspector
4.2. Ethernet Toolkit Overview x
4.2.1. Features
1. About E-Tile Hard IP User Guide
2. About the E-Tile Hard IP for Ethernet Intel® FPGA IP Core
3. About the E-Tile CPRI PHY Intel® FPGA IP
4. Supported Tools
5. E-Tile Hard IP User Guide Archives

2.11.17. Clocks

You must set the transceiver reference clock (i_clk_ref) frequency to a value that the IP supports.

The Synchronous Ethernet standard, described in the ITU-T G.8261, G.8262, and G.8264 recommendations, requires that the TX clock be filtered to maintain synchronization with the RX reference clock through a sequence of nodes. The expected usage is that user logic drives the transceiver reference clocks with a filtered version of the RX recovered clock signal, to ensure the receive and transmit functions remain synchronized. In this usage model, a design component outside the E-Tile Hard IP for Ethernet Intel FPGA IP performs the filtering.

An alternate clocking arrangement for i_clk_ref can be used to enable the Synchronous Ethernet (SyncE) operation. Two or more channels can share the Off-chip Cleanup PLL clock output. The Primary SyncE clock and the Backup SyncE clock come from the recovered clock output pins of channels connected to the same SyncE network while i_clk_ref connects to the cleanup PLL. SyncE clocking can be also combined with the data path clocking.

Figure 56. Clock Connection in SyncE Operation

SyncE mode, with dedicated reference clock for each channel, is supported when you turn on Enable SyncE With Dedicated Reference Clock Per Channel for single/multiple 10G and 25G Ethernet channels. When this parameter is enabled, Enable external AIB clocking and Enable RS-FEC options are still available but Enable Custom Rate option is disabled as custom cadence connection is done internally.

When Enable SyncE With Dedicated Reference Clock Per Channel is enabled, TX elastic FIFO (eFIFO) is instantiated within the IP. The number of TX eFIFO generated is based on the number of 10G/25G Ethernet channels. The write clock of the eFIFO is o_clk_pll_div66 from TX PMA while the read clock is i_sl_clk_tx input clock and the FIFO has a depth of 32. The write data valid signal of the FIFO is connected to the custom cadence port of the hard IP, hence the write data valid is driven high for 32 write clocks and low for 1 clock cycle.

Table 58.  Clock InputsDescribes the input clocks that you must provide.

Signal Name

Description

i_sl_clk_tx

This clock drives both, the TX datapath and TX interface, for 10G/25G channel.

  • Frequency of 402.83203125 MHz for all modes on a 25G channel. Also applicable for 10G channels when overclocked or when PTP is enabled.
  • Frequency of 161.1328125 MHz for all modes on a 10G channel except for enabled PTP.

This clock must be active during dynamic reconfiguration.

Note: Applicable only when you select Single 10GE/25GE.
i_sl_clk_rx

This clock drives both, the RX datapath and TX interface, for 10/25G channel.

  • Frequency of 402.83203125 MHz for all modes on a 25G channel. Also applicable for 10G channels when overclocked or when PTP is enabled.
  • Frequency of 161.1328125 MHz for all modes on a 10G channel except for enabled PTP.

This clock must be active during dynamic reconfiguration.

Note: Applicable only when you select Single 10GE/25GE.
i_sl_clk_tx[n]

These clocks drive the active TX datapath and TX interface for 10/25G channel when Asynchronous mode is disabled.

These clocks drive the active TX datapath for 10/25G channel when Asynchronous mode is enabled while i_sl_async_clk_tx clocks the TX interface.

Each channel has its own clock input.

  • Frequency of 402.83203125 MHz for all modes on a 25G channel. Also applicable for 10G channels when overclocked or when PTP is enabled.
  • Frequency of 161.1328125 MHz for all modes on a 10G channel except for enabled PTP.

This clock must be active during dynamic reconfiguration.

Note: Applicable only when you select 1 to 4 10GE/25GE with optional RS-FEC or 100GE or 1 to 4 10GE/25GE with optional RS-FEC and 1588 PTP.
i_sl_clk_rx[n]

These clocks drive the active RX datapath and RX interface for 10/25G channel when Asynchronous mode is disabled.

These clocks drive the active RX datapath for 10/25G channel when Asynchronous mode is enabled while i_sl_async_clk_rx clocks the RX interface..

Each channel has its own clock input.

  • Frequency of 402.83203125 MHz for all modes on a 25G channel. Also applicable for 10G channels when overclocked or when PTP is enabled.
  • Frequency of 161.1328125 MHz for all modes on a 10G channel except for enabled PTP.

This clock must be active during dynamic reconfiguration.

Note: Applicable only when you select 1 to 4 10GE/25GE with optional RS-FEC or 100GE or 1 to 4 10GE/25GE with optional RS-FEC and 1588 PTP.
i_clk_tx

This clock drives the TX interface for 100G channel.

The frequency of this clock is 402.83203125 MHz for all modes on a 100G channel RS-FEC(544,514) modes, where the frequency is 415.0390625 MHz.

Note: Applicable only when you select Single 100GE with optional RS-FEC or 100GE or 1 to 4 10GE/25GE with optional RS-FEC and 1588 PTP.

This port is disabled and replaced by i_aib_clk when External AIB clocking is selected.

i_clk_rx

This clock drives the RX interface for 100G channel.

The frequency of this clock is 402.83203125 MHz for all modes on a 100G channel RS-FEC(544,514) modes, where the frequency is 415.0390625 MHz.

Note: Applicable only when you select Single 100GE with optional RS-FEC or 100GE or 1 to 4 10GE/25GE with optional RS-FEC and 1588 PTP.

This port is disabled and replaced by i_aib_clk when External AIB clocking is selected

i_clk_ref

The input clock i_clk_ref is the reference clock for the high-speed serial clocks and the datapath parallel clocks.

This clock must have the following frequencies with a ±100 ppm accuracy per the IEEE 802.3-2015 Ethernet Standard:

  • 156.25 MHz (10G/25G/100G)
  • 322.265625 MHz (10G/25G/100G)
  • 312.500000 MHz (100G)
  • 644.531250 MHz (100G)

Variants with (544,514) RSFEC option only support 156.25 MHz and 312.5 MHz PHY i_clk_ref reference frequency.

The reference clock must be at 156.25 MHz frequency to support Auto Negotiation and Link Training.

In addition, i_clk_ref must meet the jitter specification of the IEEE 802.3-2015 Ethernet Standard

The PLL and clock generation logic use this reference clock to derive the transceiver and PCS clocks. The input clock should be a high quality signal on the appropriate dedicated clock pin. Refer to the Stratix® 10 Device Datasheet or Agilex™ 7 FPGAs and SoCs Device Data Sheet: F-Series and I-Series for transceiver reference clock phase noise specifications.

When using this clock for Synchronous Ethernet, the expected usage is that this signal being driven by a filtered and divided version of o_clk_rec_div64 or o_clk_rec_div66, to ensure the receive and transmit functions remain synchronized. Therefore, you must include an additional component on your board. The IP core does not provide filtering.

Note: Applicable only when you select Single 100GE with optional RS-FEC or 100GE or 1 to 4 10GE/25GE with optional RS-FEC and 1588 PTP.
i_reconfig_clk Avalon® clock for the E-Tile Hard IP for Ethernet Intel FPGA IP transceiver reconfiguration interface, RS-FEC reconfiguration interface, PTP reconfiguration interface, and Ethernet reconfiguration interface. The clock frequency is 100-125 MHz. All reconfiguration interface signals are synchronous to i_reconfig_clk.
Note:
  • When you turn on Enable AN/LT or select any 10G/25G channel variant in the Select Core Variant, i_reconfig_clk is set to 500 MHz in simulation to accelerate IP's simulation.
  • i_reconfig_clk is asynchronous to other clocks in the IP. For an example of clock constraints implementation, please refer to Synopsys Design Constraints (.sdc) file generated with the example design.
i_aib_clk This clock is used for all internal datapath provided externally by user.

This clock must be driven by a clock running at the fastest line rate in the design divided by 64 and must be frequency locked to i_aib_2x_clk clock. Phase offset between these two clocks are allowed.

Note: Applicable only when you select Enable external AIB clocking parameter in 10/25/100GE variants.
i_aib_2x_clk This clock must have double the frequency of i_aib_clk clock and is provided externally by user. It is used for clock crossing handling in EMIB interface.

This clock must be frequency locked to i_aib_clk clock. Phase offset between these two clocks are allowed.

Note: Applicable only when you select Enable external AIB clocking parameter in 10/25/100GE variants.
i_sl_async_clk_tx[n] This clock drives the TX interface for 25G channel when Asynchronous mode is enabled.

The clock frequency must be within 390.625 MHz to 402.83203125 MHz.

Note: Applicable only when you select Enable asynchronous adapter clocks parameter.
i_sl_async_clk_rx[n] This clock drives the RX interface for 25G channel when Asynchronous mode is enabled.

The clock frequency must be within 390.625 MHz to 402.83203125 MHz.

Note: Applicable only when you select Enable asynchronous adapter clocks parameter.
i_sl_clk_tx_tod[n-1:0] TX interface Time Of Day (ToD) Clock.

The o_clk_pll_div66[n-1:0] must drive this clock. The clock frequency varies based on the Ethernet variant:

  • 156.25 MHz (10G)
  • 390.625 MHz (25G)
Note: Applicable only when you set the PTP Accuracy Mode parameter to Advanced Mode. For more information, refer to the PTP Timestamp Accuracy section.
i_sl_clk_rx_tod[n-1:0] RX interface Time Of Day (ToD) Clock.

The o_clk_rec_div66[n-1:0] must drive this clock. The clock frequency varies based on the Ethernet variant:

  • 156.25 MHz (10G)
  • 390.625 MHz (25G)
Note: Applicable only when you set the PTP Accuracy Mode parameter to Advanced Mode. For more information, refer to the PTP Timestamp Accuracy section.
i_clk_ptp_sample Sample clock for PTP measurement.

This is an external clock provided to the design with frequency of 114.285714 MHz (with required period of 8.75 ns) with ± 100 ppm.

Note: Applicable only when you set the PTP Accuracy Mode parameter to Advanced Mode. For more information, refer to the PTP Timestamp Accuracy section.
Table 59.  Clock OutputsDescribes the output clocks that the IP core provides. In most cases these clocks participate in internal clocking of the IP core as well.

Signal Name

Description

o_clk_pll_div64[n]

Hard IP for Ethernet block clock.

Supports the following clock frequencies:

  • 402.83203125 MHz for 25G and 100G with optional RS-FEC(528,514) channels
  • 402.83203125 MHz for 10G PTP and 25G PTP channels
  • 415.0390625 MHz for 100G with RS-FEC(544,514) channel
  • 161.1328125 MHz for 10G channels

This clock is reliable only after o_tx_pll_locked is asserted.

o_clk_pll_div66[n]

Hard IP for Ethernet block clock times 64/66.

Supports the following clock frequencies:

  • 390.625 MHz for 25G and 100G with optional RS-FEC(528,514) channels
  • 402.4621 MHz for 100G with RS-FEC(544,514)
  • 156.25 MHz for 10G channels

This clock is reliable only after o_tx_pll_locked is asserted.

o_clk_rec_div64[n] Derived from RX recovered clock. This clock supports the SyncE standard.
The RX recovered clock frequency is:
  • 161.1328125 MHz ±100 ppm for 10G channels
  • 402.83203125 MHz ±100 ppm for 25G channels
  • 402.83203125 MHz ±100 ppm for 100G with optional RS-FEC(528,514) channels
  • 415.0390625 MHz ±100 ppm for 100G with RS-FEC(544,514) channels

This clock is reliable only after o_cdr_lock[n] is asserted.

When using this clock for Synchronous Ethernet, the expected usage is that you drive the TX transceiver reference clock with a filtered and divided version of o_clk_rec_div64 or o_clk_rec_div66, to ensure the receive and transmit functions remain synchronized. To do so you must include an additional component on your board. The IP core does not provide filtering.

Note: The RX recovered clock is not available for PTP channels when PTP enabled.
o_clk_rec_div66[ch] Derived from RX recovered clock. This clock supports the Synchronous Ethernet standard.
The RX recovered clock frequency is:
  • 156.25 MHz ±100 ppm for 10G channels
  • 390.625 MHz ±100 ppm for 25G channels
  • 390.625 MHz ±100 ppm for 100G with optional RS-FEC(528,514) channels
  • 402.4621 MHz ±100 ppm for 100G with optional RS-FEC(528,514) channels

This clock is reliable only after o_cdr_lock[n] is asserted.

When using this clock for Synchronous Ethernet, the expected usage is that you drive the TX transceiver PLL reference clock with a filtered and divided version of o_clk_rec_div64 or o_clk_rec_div66, to ensure the receive and transmit functions remain synchronized. To do so you must include an additional component on your board. The IP core does not provide filtering.

Note: The RX recovered clock is not available for PTP channels when PTP enabled.

Section Content
Asynchronous Adapter Clock in 10G/25G Mode
Asynchronous Adapter Clock in 100G Mode
Clock Network Use Cases

Related Information
Level Two Title