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FM Broadcast Receiver

This example shows how to build an FM mono or stereo receiver using MATLAB® and Communications Toolbox™. You can either use captured signals, or receive signals in real time using the RTL-SDR Radio, ADALM-PLUTO Radio or USRP™ Radio.

Required Hardware and Software

To run this example using recorded data from a file, you need Communications Toolbox™.

To receive signals in real time, you also need one of these SDR devices and the corresponding software add-on:

  • RTL-SDR radio and the Communications Toolbox Support Package for RTL-SDR Radio add-on

  • ADALM-PLUTO radio and the Communications Toolbox Support Package for Analog Devices® ADALM-PLUTO Radio add-on

  • USRP radio and the Communications Toolbox Support Package for USRP® Radio add-on

For more information, see the Software Defined Radio (SDR) discovery page.

Background

FM broadcasting uses frequency modulation (FM) to provide high-fidelity sound transmission over broadcast radio channels. Pre-emphasis and de-emphasis filters are used to reduce the effect of noise on high audio frequencies. Stereo encoding enables simultaneous transmission of both left and right audio channels over the same FM channel [ 1 ].

Run the Example

To and run the example, you need to enter the following information:

  1. Reception duration in seconds

  2. Signal source (captured data, RTL-SDR radio, ADALM-PLUTO radio or USRP radio)

  3. FM channel frequency

The example plays the received audio over your computer's speakers.

NOTE: This example utilizes a center frequency that is outside the default PlutoSDR tuning range. To use your ADALM-PLUTO radio outside the qualified tuning range, at the MATLAB® command line, run configurePlutoRadio (Communications Toolbox Support Package for Analog Devices ADALM-Pluto Radio) using 'AD9364' as the input argument.

Receiver Structure

The FM Broadcast Demodulator Baseband System object™ converts the input sampling rate of the 228 kHz to 45.6 kHz, the sampling rate for your host computer's audio device. According to the FM broadcast standard in the United States, the de-emphasis lowpass filter time constant is set to 75 microseconds. This example processes the received mono signals. The demodulator can also process stereo signals.

To perform stereo decoding, the FM Broadcast Demodulator Baseband object uses a peaking filter which picks out the 19 kHz pilot tone from which the 38 kHz carrier is created. Using the resulting carrier signal, the FM Broadcast Demodulator Baseband block downconverts the L-R signal, centered at 38 kHz, to baseband. Afterwards, the L-R and L+R signals pass through a 75 microsecond de-emphasis filter. The FM Broadcast Demodulator Baseband block separates the L and R signals and converts them to the 45.6 kHz audio signal.

Example Code

The receiver asks for user input and initializes variables. Then, it calls the signal source and FM broadcast receiver in a loop. The loop also keeps track of the radio time using the frame duration and lost samples reported by the signal source.

The latency output of the signal source is an indication of when the samples were actually received and can be used to determine how close to real time the receiver is running. A latency value of 1 and a lost samples value of 0 indicates that the system is running in real time. A latency value of greater than one indicates that the receiver was not able to process the samples in real time. Latency is reported in terms of the number of frames. It can be between 1 and 128. If latency is greater than 128, then samples are lost.

%For the option to change default settings, set |cmdlineInput| to 1.
cmdlineInput = 0;
if cmdlineInput
    % Request user input from the command-line for application parameters
    userInput = helperFMUserInput;
else
    load('defaultinputsFM.mat');
end

% Calculate FM system parameters based on the user input
[fmRxParams,sigSrc] = helperFMConfig(userInput);

% Create FM broadcast receiver object and configure based on user input
fmBroadcastDemod = comm.FMBroadcastDemodulator(...
    'SampleRate', fmRxParams.FrontEndSampleRate, ...
    'FrequencyDeviation', fmRxParams.FrequencyDeviation, ...
    'FilterTimeConstant', fmRxParams.FilterTimeConstant, ...
    'AudioSampleRate', fmRxParams.AudioSampleRate, ...
    'Stereo', false);

% Create audio player
player = audioDeviceWriter('SampleRate',fmRxParams.AudioSampleRate);

% Initialize radio time
radioTime = 0;

% Main loop
while radioTime < userInput.Duration
  % Receive baseband samples (Signal Source)
  if fmRxParams.isSourceRadio
      if fmRxParams.isSourcePlutoSDR
          rcv = sigSrc();
          lost = 0;
          late = 1;
      elseif fmRxParams.isSourceUsrpRadio
          rcv= sigSrc();
          lost = 0;
      else
          [rcv,~,lost,late] = sigSrc();
      end
  else
    rcv = sigSrc();
    lost = 0;
    late = 1;
  end

  % Demodulate FM broadcast signals and play the decoded audio
  audioSig = fmBroadcastDemod(rcv);
  player(audioSig);

  % Update radio time. If there were lost samples, add those too.
  radioTime = radioTime + fmRxParams.FrontEndFrameTime + ...
    double(lost)/fmRxParams.FrontEndSampleRate;
end

% Release the audio and the signal source
release(sigSrc)
release(fmBroadcastDemod)
release(player)

Further Exploration

To further explore the example, you can vary the center frequency of the RTL-SDR radio, ADALM-PLUTO radio or USRP radio and listen to other radio stations.

You can set the Stereo property of the FM demodulator object to true to process the signals in stereo fashion and compare the sound quality.

You can explore following function for details of the system parameters:

You can further explore the FM signals using FMReceiverExampleApp user interface. This app allows you to select the signal source and change the center frequency of the RTL-SDR radio, ADALM-PLUTO radio or USRP radio. To launch the app, type FMReceiverExampleApp in the MATLAB Command Window. This user interface is shown in the following figure

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