Spectrum of fm modulaton

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AbdAlla Hefny il 8 Apr 2017

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Risposto: santy vega il 28 Ago 2019

Is there a way to plot the spectrum of an fm modulated signal. I know that Fourier transform is not directly applicable for fm signals as they are not linear. So is there a direct method to do that [even for a tone modulation at least]?

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Answer 1

David Goodmanson il 9 Apr 2017

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https://it.mathworks.com/matlabcentral/answers/334334-spectrum-of-fm-modulaton#answer_262340

Modificato: David Goodmanson il 9 Apr 2017

Apri in MATLAB Online

Hello AbdAlla, The generation of a real fm signal is not a linear process, but there is no problem with finding the resulting spectrum by fft since the fft can find the frequency components of any signal. The fft works out best with modulation by a tone or the sum of a small number of tones, AND when the carrier and all the tones have an exact number of cycles in the time array.

(revised) Here is a small example:

F = 1e6;                 % sampling frequency
f0 = 20000;              % carrier
f1 = 200;                % modulating tone
beta = 1;                % modulation index  
% signal, spectrum
N = 1e6;
t = (0:N-1)*(1/F);       % delt = 1us
y = cos(2*pi*f0*t+beta*cos(2*pi*f1*t));
z = fftshift(fft(y))/N;
f = (-N/2:N/2-1)*(F/N);
% predicted sidebands for the positive frequencies only
n = 4;
sidamp = (1/2)*besselj(0:n,beta);
sidamp = [fliplr(sidamp(2:end)), sidamp];
sidf = (f0-n*f1):f1:(f0+n*f1);
figure(1)
plot (f,abs(z))
xlim([-2*f0 2*f0])
figure(2)
plot(f,abs(z),sidf,sidamp,'o')
xlim([f0-f1*10 f0+f1*10])            % sidebands at the pos frequencies

Fig 1 shows positive and negative frequencies. Most of the time people double the abs(amplitudes) and show positive frequencies only, in which case the sideband calculation does not have the factor of 1/2.

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venu dunde il 26 Mar 2018

Modificato: venu dunde il 26 Mar 2018

clear all;

clc;

close all;

Fs_fm = 200e3; %%%%%% sampling rate of FM signal bw = 100e3; %%% signal bandwidth

F_carrier = 98e6; %%%%% FM carrier

fc = 98e6; % Operating frequency fs = Fs_fm; % Waveform

[y_song,Fs_audio] = audioread('song.mp3');

%Fs_audio = 44100;

%y_fm = resample(y_song,Fs_fm,Fs_audio);

%%%%%%%%%%%%%%%%% %%%% time of simulations , sec %%%%%%%%%%%%%%%%%%

deltaT =40;

%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%% creating FM stereo signal %%%%%%%%%%%%%%%%%%%%%%%%%%%

audio_signal = y_song(1:deltaT*Fs_audio,:);

%rc = rcosine(Fs_audio,16*Fs_audio);

%audio_signal = filter(rc,1,randn(deltaT*Fs_audio,2));

audio_signal = resample(audio_signal, Fs_fm, Fs_audio);

t_vect = [0:length(audio_signal)-1]'/Fs_fm;

sum_ch= 0.5 *(audio_signal(:,1)+audio_signal(:,2));

diff_ch = 0.5 *(audio_signal(:,1)-audio_signal(:,2));

stereophonic_signal = sum_ch + 0.1*cos(2*pi*19e3*t_vect) + diff_ch.*cos(2*pi*38e3*t_vect);

CE_FM_radio_signal = exp(1j*2*pi*75e3*cumsum(stereophonic_signal/Fs_fm));

s_wav = CE_FM_radio_signal( 8.45e4:end);

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%% Source characterization %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

figure(1)

plot(fft(s_wav),Fs_fm,'b');

title('FM signal spectral density');

xlabel('Frequency KHz');

ylabel('Magnitude dB'); grid

figure(2)

fm_acor = abs(xcorr(s_wav));

plot(10*log10(fm_acor));

title('Autocorrelation Function');

xlabel('Autocorrelation Lags');

ylabel('magnitude');

grid

venu dunde il 26 Mar 2018

plot the frequency spectrum of FM signal ( which is almost real-time signal), i am facing problem at figure(1) plot(s_wav,Fs_fm,'b');title('FM signal spectral density');xlabel('Frequency KHz');ylabel('Magnitude dB');grid, figure-1

update the file (use any short .mp3 file, here i am unable to attach the .mp3 file) thank you,

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