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ADC- Intel® Arria® 10 Multi-Link Design Overview
ADC- Intel® Arria® 10 Multi-Link Design Implementation Guidelines
Synchronized ADC- Intel® Arria® 10 Multi-Link
Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Migrating the RX Multi-Link Design from Simulation to Synthesis
Document Revision History for Implementing Analog-to-Digital Converter Multi-Link Designs with Intel® Arria® 10 JESD204B RX IP Core
Editing Design Example Platform Designer System for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level HDL for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing TX Simulation Model Platform Designer System for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing TX Simulation Model Top-Level HDL for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing Simulation Testbench for Synchronized ADC- Intel® Arria® 10 Multi-Link
Adding IP Cores Signals in the Subsequent Links to the Simulation Waveform
Updating the Simulation Script
Simulating the Multi-Link Design
Viewing the Simulation Results
Editing Design Example Platform Designer System for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level HDL for Synchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level SDC Constraint for Synchronized ADC- Intel® Arria® 10 Multi-Link
Compiling the Design in Intel® Quartus® Prime Software
Editing Design Example Platform Designer System for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level HDL for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing TX Simulation Model Platform Designer System for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing TX Simulation Model Top-Level HDL for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing TX Simulation Testbench for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Adding IP Cores Signals in the Subsequent Links to the Simulation Waveform
Updating the Simulation Script
Simulating the Multi-Link Design
Viewing the Simulation Results
Editing Design Example Platform Designer System for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level HDL for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Editing Design Example Top-Level SDC Constraint for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
Compiling the Design in Intel® Quartus® Prime Software
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Editing Design Example Top-Level HDL for Unsynchronized ADC- Intel® Arria® 10 Multi-Link
The generate statement in the Verilog HDL file uses the LINK system parameter as an index variable to generate the requisite number of instances for the multi-link use case.
- Open the top-level HDL file (altera_jesd204b_ed_RX.sv) in a text editor.
- Modify the LINK system parameter to reflect the number of links in your design.
- Insert the newly exported ports from the Platform Designer system at the Platform Designer system instantiation.
- Follow these steps to make the connections for the Platform Designer ports:
- For SYNC_N, scale up the dimension of sync_n_out port to match with the number of links.
Example:
output wire [LINK-1:0] sync_n_out,
- Leave the following ports unconnected:
- sof
- somf
- reset_seq_irq
- For the rest of the ports, increase the index of the wires from 0 to 1 and subsequent numbers for the subsequent links.
For example, jesd204_rx_link_data[1] wire should be connected to link 1 IP core and transport layer.
- For SYNC_N, scale up the dimension of sync_n_out port to match with the number of links.
- Save the top-level HDL file changes.
- The transport layer and pattern checker are reset by the reset sequencer in the corresponding altera_jesd204_subsystem_RX and altera_jesd204_subsytem_RX1 Platform Designer subsystems. No modification is needed at the transport layer and pattern checker generation loops.