GTS Transceiver PHY User Guide: Agilex™ 3 FPGAs and SoCs
ID
848344
Date
8/04/2025
Public
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™ 3 FPGAs and SoCs
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
3.3.1. Preset IP Parameter Settings
3.3.2. Mode and Common Datapath Options
3.3.3. TX Datapath Options
3.3.4. RX Datapath Options
3.3.5. PMA Configuration Rules for Specific Protocol Mode Implementations
3.3.6. FEC Options
3.3.7. PCS Options
3.3.8. Avalon® Memory-Mapped Interface Options
3.3.9. Register Map IP-XACT Support
3.3.10. Analog Parameter Options
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
3.7.1. 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
3.14.2.1. 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
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. GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design
6.7. Generating the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable Example Design
6.8. GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design Functional Description
6.9. Simulating the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design Testbench
6.10. Compiling the GTS PMA/FEC Direct PHY IP Dynamically Reconfigurable PHY Example Design
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
2.6.5. Shared Clocking Resources Between the GTS Transceiver Bank and HVIO Bank
There are some GTS transceiver banks that share resources with certain HVIO banks. Refer to the HVIO Bank and GTS Transceiver Channel Sharing table for information on which GTS transceiver and HVIO banks shares clocking resources.
For each transceiver channel, there are four multiplexers that select the clock to be routed to the FPGA core. However, there are more than four sources to choose from both the GTS transceiver channel and also the HVIO bank, therefore not all of them can be used at the same time.
Figure 22. Shared Clocking Resources Between the GTS Transceiver Bank and HVIO Bank
Every channel in a GTS transceiver bank has a selection of five output clock options which are routed through these four multiplexers. These five output clocks are:
- tx_clkout
- tx_clkout2
- rx_clkout
- rx_clkout2
- Input reference clock to core
In the HVIO bank, several sources are also routed through these four multiplexers. They are:
- PLLREFCLK1
- PLLREFCLK2
- SOURCE_SYNC_CLK1
- SOURCE_SYNC_CLK2
Between these four HVIO sources, the routing is spread across different channels of the GTS transceiver bank. The following table lists the channels of the GTS transceiver banks that share its resources with the HVIO bank.
GTS Transceiver Bank | GTS Transceiver Channel Number | HVIO Bank | HVIO Pin |
---|---|---|---|
1A | 2 | 5A | PLLREFCLK1 |
2 | 5A | PLLREFCLK2 | |
0 | 5A | SOURCE_SYNC_CLK1 | |
0 | 5A | SOURCE_SYNC_CLK2 | |
3 | 5B | PLLREFCLK1 | |
3 | 5B | PLLREFCLK2 |
You must ensure that the combination of output clocks that you use between the GTS transceiver bank and the HVIO bank does not exceed four.
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