IQ Mixer Mode Capture
This example shows how to enable the RFSoC built-in numerically-controlled oscillator (NCO) mixer. The mixer design uses a different data format that, instead of providing real signals, provides a complex in-phase and quadrature (IQ) signal to a digital-to-analog converter (DAC) and an analog-to-digital converter (ADC). There is more data to transfer to direct memory access (DMA) and back to MATLAB® given that you need to transfer I and Q samples back. You can accommodate this larger data width by increasing the DMA data width to 128 bits.
You must configure settings such as the local oscillator (LO) mixer frequency and enable other mixer properties that are relevant to the design. To change these properties at run time, you can use the
soc.RFDataConverter System object™. The HDL Workflow Advisor autogenerates a script to assist you with changing properties and uploads a CFG file to the board.
Vivado® Design Suite with a supported version listed in HDL Language Support and Supported Third-Party Tools and Hardware
Xilinx® Zynq® UltraScale+™ ZCU111 evaluation kit or Xilinx Zynq UltraScale+ ZCU216 evaluation kit
HDL Coder Support Package for Xilinx RFSoC Devices
Open the example project and copy the example files to a temporary directory.
1. Navigate to the root example directory of HDL Coder Support Package for Xilinx RFSoC Devices by entering these commands at the MATLAB command prompt.
example_root = (hdlcoder_rfsoc_examples_root) cd (example_root)
2. Copy all of the example files in the
IQDataCapture folder to a temporary directory.
Generate HDL and Synthesize Bitstream
When you enable the mixer in the RFSoC, adhere to the required data formats that the IP expects. For the ADC, the IP core separates the I and Q channels. For the DAC , the IP core concatenates both I and Q channels together. For convenience, this bit concatenation is handled outside of the generated HDL and in Vivado. You need to model the I and Q channels separately for only the DAC and ADC.
This example uses four complex samples per clock cycle at 512 mega samples per second (MSPS). Each I and Q sample is 16 bits, which results in a total of 128 bits for channel I and a total of 128 bits for channel Q. From the Simulink® modeling perspective, two parts (I and Q) that exist, each with four samples per clock cycle.
To proceed with the HDL code generation, right-click the subsystem. Select HDL Code, then click HDL Workflow Advisor. In step 1.1 of the HDL Workflow Advisor, select Target platform as
Xilinx Zynq Ultrascale+ RFSoC ZCU111 Evaluation Kit or
Xilinx Zynq Ultrascale+ RFSoC ZCU216 Evaluation Kit.
In step 1.2, select Reference design as
IQ ADC/DAC Interface.
You can also specify a LO setting, which is used at board startup. The LO setting can be run-time adjustable. Before proceeding to the next step, set these reference design parameters to the indicated values.
AXI4-Stream DMA data width to
ADC sampling rate (MHz) to
ADC decimation mode (xN) to
ADC samples per clock cycle to
ADC mixer type to
DAC sampling rate (MHz) to
DAC interpolation mode (xN) to
DAC samples per clock cycle to
DAC mixer type to
ADC/DAC NCO mixer LO (GHz) to
Enable multi-tile sync to
If you are using a ZCU216 board, additionally set the DAC DUC mode parameter to
Full DUC Nyquist (0-Fs/2).
To build the FPGA bitstream design, right-click Build FPGA Bitstream and click Run to Selected Task.
IQ Data Capture
To capture IQ data in this loopback test, perform a full HDL Workflow Advisor build and wait until the FPGA bitstream has been compiled. Afterward, program the board and run this capture script.
The capture loop triggers a register to initiate data capture logic to move IQ data into the DMA. The loop then reads the frame of IQ data and formats it to display these plots. To stop the capture, close the MATLAB plot.
Change Converter Settings: LO Mixer
You can set the LO from MATLAB by using the System object script at run time. This example provides a script to show an example of how you can use the RFSoC System to alter the mixer tone of the DAC and ADC. Open and examine this MATLAB script file:
In this example, this script shifts the LO tone such that the DAC experiences a shift of 10 MHz relative to the ADC LO, with a center frequency of 800 MHz.
Connect to the target board.
rfobj = soc.RFDataConverter('zu49dr','192.168.1.101'); setup(rfobj)
Specify LO Value in MHz. All tiles and channels use this LO Value.
LO_VALUE = 800;
Create a shift of 10 MHz in the DAC RF NCO.
Configure frequency of the ADC RF NCO.
Disconnect the communication channel created between the
soc.RFDataConverter System object and the
rftool running on the SoC device.
After running this script, run the capture script again and examine the spectrum plot.
The tone, which was previously at 25 MHz, is now shifted by 10 MHz to 35 MHz.