GTS Transceiver PHY User Guide: Agilex™ 5 FPGAs and SoCs

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ID 817660
Date 8/04/2025
Public
Document Table of Contents
Document Table of Contents x
1. GTS Transceiver Overview 2. GTS Transceiver Architecture 3. Implementing the GTS PMA/FEC Direct PHY IP 4. Implementing the GTS System PLL Clocks IP 5. Implementing the GTS Reset Sequencer IP 6. GTS PMA/FEC Direct PHY IP Example Design 7. Design Assistance Tools 8. Debugging GTS Transceiver Links with Transceiver Toolkit 9. Document Revision History for the GTS Transceiver PHY User Guide: Agilex™ 5 FPGAs and SoCs
1. GTS Transceiver Overview x
1.1. GTS Transceiver Design Flow
2. GTS Transceiver Architecture x
2.1. Building Blocks 2.2. Channel Placement Rules and Design Requirements 2.3. PMA Architecture 2.4. PCS Architecture 2.5. Forward Error Correction (FEC) Architecture 2.6. Clock Architecture 2.7. Bonding and Deskew
2.1. Building Blocks x
2.1.1. PMA 2.1.2. FEC 2.1.3. PCS 2.1.4. Ethernet MAC 2.1.5. PCI Express* Hard IP 2.1.6. PLL and Clock Networks 2.1.7. Avalon® Memory-Mapped Interface
2.1.1. PMA x
2.1.1.1. Protocol Support Using PMA Direct Mode
2.1.1.1. Protocol Support Using PMA Direct Mode x
2.1.1.1.1. SDI 2.1.1.1.2. HDMI 2.1.1.1.3. CPRI 2.1.1.1.4. GPON 2.1.1.1.5. OTN
2.2. Channel Placement Rules and Design Requirements x
2.2.1. Hard IP Rules 2.2.2. Use Scenario Rules 2.2.3. Unused PMA Rules 2.2.4. General Design Requirement
2.2.3. Unused PMA Rules x
2.2.3.1. Unused PMA Not Planned for Use in the Future 2.2.3.2. Unused PMA Planned for Use in the Future
2.3. PMA Architecture x
2.3.1. Transmitter PMA Architecture 2.3.2. Receiver PMA Architecture 2.3.3. PMA Loopback Modes
2.3.1. Transmitter PMA Architecture x
2.3.1.1. Transmitter Buffer 2.3.1.2. Serializer 2.3.1.3. Data Pattern Generator and Verifier
2.3.2. Receiver PMA Architecture x
2.3.2.1. Receiver Buffer and Equalizer 2.3.2.2. Deserializer 2.3.2.3. CDR Block 2.3.2.4. RX PMA Tuning 2.3.2.5. RX PMA Adaptation Modes
2.3.2.1. Receiver Buffer and Equalizer x
2.3.2.1.1. Control Unit
2.3.2.5. RX PMA Adaptation Modes x
2.3.2.5.1. RX Auto Adaptation Mode 2.3.2.5.2. RX Manual Adaptation Mode 2.3.2.5.3. RX Native Adaptation Mode
2.5. Forward Error Correction (FEC) Architecture x
2.5.1. FEC Loopback Mode
2.6. Clock Architecture x
2.6.1. Reference Clock Network 2.6.2. Datapath Clock Network 2.6.3. System PLL 2.6.4. Datapath Clock Cadences 2.6.5. Shared Clocking Resources Between the GTS Transceiver Bank and HVIO Bank
2.6.1. Reference Clock Network x
2.6.1.1. Single GTS Transceiver Bank Device 2.6.1.2. PMA Primary PLL Configuration
2.6.3. System PLL x
2.6.3.1. I/O PLL in HVIO Bank as System PLL 2.6.3.2. Running PCIe* and Non- PCIe* Protocols in a GTS Transceiver Bank 2.6.3.3. System PLL Clock for FPGA Core 2.6.3.4. System PLL with HVIO Reference Clock
2.7. Bonding and Deskew x
2.7.1. Bonding Architecture 2.7.2. TX Deskew Function
3. Implementing the GTS PMA/FEC Direct PHY IP x
3.1. IP Overview 3.2. Designing with the GTS PMA/FEC Direct PHY IP 3.3. Configuring the GTS PMA/FEC Direct PHY IP 3.4. Dynamically Reconfigurable PHY 3.5. Signal and Port Reference 3.6. Bit Mapping for PMA, FEC, and PCS Mode PHY TX and RX Datapath 3.7. Clocking 3.8. Custom Cadence Generation Ports and Logic 3.9. Asserting Reset 3.10. Bonding Implementation 3.11. Configuration Register 3.12. Configuring the GTS PMA/FEC Direct PHY IP for Hardware Testing 3.13. Configurable Quartus® Prime Software Settings 3.14. Hardware Configuration Using the Avalon® Memory-Mapped Interface
3.1. IP Overview x
3.1.1. PMA Direct Supported Modes 3.1.2. FEC Direct Supported Modes 3.1.3. PCS Direct Supported Modes 3.1.4. Unsupported PMA/FEC/PCS Modes
3.3. Configuring the GTS PMA/FEC Direct PHY IP x
3.3.1. Preset IP Parameter Settings 3.3.2. Mode and Common Datapath Options 3.3.3. Reconfigurable PHY Settings 3.3.4. TX Datapath Options 3.3.5. RX Datapath Options 3.3.6. PMA Configuration Rules for Specific Protocol Mode Implementations 3.3.7. FEC Options 3.3.8. PCS Options 3.3.9. Avalon® Memory-Mapped Interface Options 3.3.10. Register Map IP-XACT Support 3.3.11. Analog Parameter Options
3.3.4. TX Datapath Options x
3.3.4.1. TX PMA Interface Parameters
3.3.5. RX Datapath Options x
3.3.5.1. RX PMA Interface Parameters
3.3.6. PMA Configuration Rules for Specific Protocol Mode Implementations x
3.3.6.1. PMA Configuration Rules for SDI Mode 3.3.6.2. PMA Configuration Rules for HDMI Mode 3.3.6.3. PMA Configuration Rules for CPRI Mode 3.3.6.4. PMA Configuration Rules for GPON Mode 3.3.6.5. PMA Configuration Rules for OTN Mode
3.4. Dynamically Reconfigurable PHY x
3.4.1. Clock Generation and Constraints for Multiple Profiles Design
3.5. Signal and Port Reference x
3.5.1. TX and RX Parallel and Serial Interface Signals 3.5.2. TX and RX Reference Clock and Clock Output Interface Signals 3.5.3. Reset Signals 3.5.4. FEC Signals 3.5.5. Custom Cadence Control and Status Signals 3.5.6. RX PMA Status Signals 3.5.7. TX and RX PMA and Core Interface FIFO Signals 3.5.8. Avalon Memory-Mapped Interface Signals
3.7. Clocking x
3.7.1. Clock Ports 3.7.2. Recommended tx/rx_coreclkin Connection and tx/rx_clkout2 Source 3.7.3. Port Widths and Recommended Connections for tx/rx_coreclkin, tx/rx_clkout, and tx/rx_clkout2 3.7.4. PMA Fractional Mode 3.7.5. Input Reference Clock Buffer Protection 3.7.6. Guidelines for Obtaining the Real-Time GTS TX PLL Lock Status
3.7.5. Input Reference Clock Buffer Protection x
3.7.5.1. Reference Clock Buffer Register Information 3.7.5.2. Re-enabling the Reference Clock Buffers
3.8. Custom Cadence Generation Ports and Logic x
3.8.1. Implementing PMA Direct Mode with TX Core FIFO in Elastic Configuration 3.8.2. Enabling the i_tx_cadence_slow_clk_locked Port
3.9. Asserting Reset x
3.9.1. Reset Signal Requirements 3.9.2. Power On Reset Requirements 3.9.3. Reset Signals—Block Level 3.9.4. Run-time Reset Sequence—TX 3.9.5. Run-time Reset Sequence—RX 3.9.6. Run-time Reset Sequence—TX + RX 3.9.7. RX Data Loss/CDR Lock Loss (Auto-Recovery) 3.9.8. TX PLL Lock Loss
3.10. Bonding Implementation x
3.10.1. Bonding Placement Requirements 3.10.2. Multilane RX Simplex Implementation
3.11. Configuration Register x
3.11.1. GTS PMA and FEC Direct PHY Soft CSR Register Map 3.11.2. GTS PMA Register Map 3.11.3. Accessing Configuration Registers 3.11.4. Configuration Registers for the GTS PMA/FEC Direct PHY IP Reconfigurable PHY
3.11.2. GTS PMA Register Map x
3.11.2.1. Logical Avalon® Memory-Mapped Port Indexing
3.11.3. Accessing Configuration Registers x
3.11.3.1. Accessing GTS PMA and FEC Direct PHY Soft CSR Registers 3.11.3.2. Accessing GTS PMA Registers
3.12. Configuring the GTS PMA/FEC Direct PHY IP for Hardware Testing x
3.12.1. Using Debug Endpoint Interface within the GTS PMA/FEC Direct PHY IP 3.12.2. Using JTAG to Avalon Master Bridge IP
3.12.1. Using Debug Endpoint Interface within the GTS PMA/FEC Direct PHY IP x
3.12.1.1. RTL Connection Example for Debug Endpoint Avalon® Interface
3.12.2. Using JTAG to Avalon Master Bridge IP x
3.12.2.1. RTL Connection Example for JTAG to Avalon Master Bridge IP
3.13. Configurable Quartus® Prime Software Settings x
3.13.1. Configuring the RX Adaptation Mode and PMA Manual Tuning
3.14. Hardware Configuration Using the Avalon® Memory-Mapped Interface x
3.14.1. Direct Register Method 3.14.2. GTS Attribute Access Method
3.14.1. Direct Register Method x
3.14.1.1. Direct Register Method Examples
3.14.2. GTS Attribute Access Method x
3.14.2.1. GTS Attribute Access Method Example 1: Enable or Disable Internal Serial Loopback Mode (RX Auto Adaptation Mode) 3.14.2.2. GTS Attribute Access Method Example 2: Enable or Disable Internal Serial Loopback Mode (RX Manual Adaptation Mode) 3.14.2.3. GTS Attribute Access Method Example 3: Enable or Disable Polarity Inversion of the PMA 3.14.2.4. GTS Attribute Access Method Example 4: Enable PRBS Generator and Checker to Run BER Test
4. Implementing the GTS System PLL Clocks IP x
4.1. IP Parameters 4.2. IP Port List 4.3. Mode of System PLL - System PLL Reference Clock and Output Frequencies 4.4. Guidelines for GTS System PLL Clocks IP Usage 4.5. Guidelines to Indicate System PLL Reference Clock is Ready
4.5. Guidelines to Indicate System PLL Reference Clock is Ready x
4.5.1. Example Flow to Indicate System PLL Reference Clock is Ready
5. Implementing the GTS Reset Sequencer IP x
5.1. IP Requirements 5.2. IP Parameters 5.3. IP Port List 5.4. GTS Reset Sequencer IP General Interface 5.5. GTS Reset Sequencer IP Design Flow 5.6. GTS Reset Sequencer IP Use Cases 5.7. Connecting the Reference Clock Buffer Status to the GTS Reset Sequencer IP
5.6. GTS Reset Sequencer IP Use Cases x
5.6.1. Example Use Case 1 5.6.2. Example Use Case 2
6. GTS PMA/FEC Direct PHY IP Example Design x
6.1. Instantiating the GTS PMA/FEC Direct PHY IP 6.2. Generating the GTS PMA/FEC Direct PHY IP Example Design 6.3. GTS PMA/FEC Direct PHY IP Example Design Functional Description 6.4. Simulating the GTS PMA/FEC Direct PHY IP Example Design Testbench 6.5. Compiling the GTS PMA/FEC Direct PHY IP Example Design 6.6. Hardware Testing the GTS PMA/FEC Direct PHY IP Example Design 6.7. GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design 6.8. Generating the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable Example Design 6.9. GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design Functional Description 6.10. Simulating the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design Testbench 6.11. Compiling the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design 6.12. Hardware Testing the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design
6.2. Generating the GTS PMA/FEC Direct PHY IP Example Design x
6.2.1. Fast Simulation Support 6.2.2. GTS PMA/FEC Direct PHY IP Example Design Directory Structure
6.4. Simulating the GTS PMA/FEC Direct PHY IP Example Design Testbench x
6.4.1. Modifying the Example Design and Performing Simulation
6.8. Generating the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable Example Design x
6.8.1. Fast Simulation Support 6.8.2. GTS PMA/FEC Direct PHY IP Reconfigurable PHY Example Design Directory Structure
7. Design Assistance Tools x
7.1. Clocking and Datapath Tool 7.2. TX Equalizer Tool
8. Debugging GTS Transceiver Links with Transceiver Toolkit x
8.1. GTS Transceiver Toolkit Parameter Settings 8.2. GTS Transceiver Toolkit GUI 8.3. GTS Transceiver Debugging Flow Walkthrough
8.2. GTS Transceiver Toolkit GUI x
8.2.1. Collection View
8.3. GTS Transceiver Debugging Flow Walkthrough x
8.3.1. Modifying the Design to Enable GTS Transceiver Debug Toolkit 8.3.2. Programming the Design into an Altera FPGA 8.3.3. Loading the Design to the Transceiver Toolkit 8.3.4. Creating Transceiver Links 8.3.5. Running BER Tests 8.3.6. Running Eye Viewer Tests 8.3.7. Running Link Optimization Tests
1. GTS Transceiver Overview
2. GTS Transceiver Architecture
3. Implementing the GTS PMA/FEC Direct PHY IP
4. Implementing the GTS System PLL Clocks IP
5. Implementing the GTS Reset Sequencer IP
6. GTS PMA/FEC Direct PHY IP Example Design
7. Design Assistance Tools
8. Debugging GTS Transceiver Links with Transceiver Toolkit
9. Document Revision History for the GTS Transceiver PHY User Guide: Agilex™ 5 FPGAs and SoCs

2.2.3.1. Unused PMA Not Planned for Use in the Future

To save power, you can power down unused GTS transceiver banks that you do not plan to use in the future. Connect the PMA power supplies (VCCEHT_GTS and VCCERT_GTS) of the unused banks to ground to power them down and use the PRESERVE_UNUSED_XCVR .qsf assignment. When grounded, all the GTS transceiver bank resources are not available for use, except the system PLL which remains available to clock the FPGA core logic. This is supported in the following scenarios:
  1. All GTS transceiver banks on the same side are unused. You may ground all the transceiver PMA bank supplies on the unused side.
  2. Some GTS transceiver banks on one side are unused. Depending on devices, only some banks support power down. Refer to Selected E-Series GTS Transceiver Banks that Support Power Down and Selected D-Series GTS Transceiver Banks that Support Power Down for the specific banks that can support power down in this scenario for you to ground the unused PMA bank power supplies.
Table 5.  Selected E-Series GTS Transceiver Banks that Support Power Down
Device 13 GTS Transceiver Banks that Support Power Down 14
B32A Package B23A Package M16A Package 15
A5E 028 1A 1A 1A
A5E 043 1B 16
A5E 052 1A, 4A, or both 1B 16
A5E 065 1A, 4A, or both 1B 16
Table 6.  Selected D-Series GTS Transceiver Banks that Support Power Down
Device GTS Transceiver Banks that Support Power Down14
B32B Package B23D Package
A5D 010 1A, 4A, or both 1A
A5D 025 1A, 4A, or both 1A
A5D 031 1A, 4A, or both 1A
A5D 051 1A and 1B 16
A5D 064 1A and 1B, 4A and 4B, or all 1A, 1B, 4A and 4B 16
Apply the following .qsf assignment to the specific GTS transceiver bank that you want to power down: 
set_instance_assignment -name PRESERVE_UNUSED_XCVR_CHANNEL OFF -to <pinname>
where <pinname> is the pinout location of any transceiver channel in the corresponding bank that you want to power down.
For example: 
set_instance_assignment -name PRESERVE_UNUSED_XCVR_CHANNEL OFF -to BY129
Using A5E 065B B32A device as an example, the GTS transceiver bank 1A, where the BY129 pin resides, is set to power down.
13 A5E 008 and A5E 013 devices have only 1 GTS transceiver bank, which is on the left side. If unused, you can power them down.
14 If all GTS transceiver banks on the same side are unused, you can power them down.
15 Device group B only.
16 No package combination for this device.
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