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Super-heterodyne Receiver

Project Description

  • The purpose of this project is to simulate the basic components of an analog communication system using MATLAB programming. Specifically, an AM modulator and a corresponding super-heterodyne receiver will be simulated using radio-station generated signals.

Contents

  • Audio Signals : audio signals that used during testing
  • Screens : output figures
  • Source Code : MATLAB file

Project Requirements

  • MATLAB program recommended version 2021

Block Diagram

data frame

Result Figures

data frame data frame

Removing RF stage

%%%%%%%%%% comment this part if you want to demodulate without RF stage %%%%%%%%%%
% sum_signals_BPF = sum_signals;
band_pass_filter = fdesign.bandpass(F_stop1, F_pass1, F_pass2, F_stop2, A_stop1, A_pass, A_stop2, 15 * Fs);
band_pass_filter = design(band_pass_filter, 'equiripple');
sum_signals_BPF = filter(band_pass_filter, sum_signals);
SUM_SIGNALS_BPF = fftshift(fft(sum_signals_BPF));
f_MODULATED_SIGNAL = (-length(SUM_SIGNALS_BPF) / 2:1:length(SUM_SIGNALS_BPF) / 2 - 1)';
subplot(2, 1, 2)
plot(f_MODULATED_SIGNAL * Fs_carrier / length(SUM_SIGNALS_BPF), abs(SUM_SIGNALS_BPF), 'r')
title("RF stage after BPF for audio " + choose_signal)
xlabel("Frequency (Hz)")
ylabel("Magnitude")
grid on

Offset in Receiver Oscillator frequency

%%%%%%%%%% the receiver oscillator offset [0, 0.1k, 1k] %%%%%%%%%%
offset = 0;
IF = 25000 + offset;                                % If frequency 25 KHz

Run Program

  • by running code, user required to choose which audio he want to hear as in the following figure

data frame

Team members

  • Omr Amr Mahmoud Hafez
  • Mohamed Khaled Mohamed Alahmady

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