Code-m file for Sampling

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Chetan Fadnis
Chetan Fadnis el 19 de Sept. de 2021
Respondida: Adel el 23 de Sept. de 2024
Write a MATLAB code to
1) Generate a band limited signal (at extremely high sampling rate to approximate it as a continuous signal)
2) Plot the signal in Time Domain.
3) Take the FFT of the signal and plot the magnitude and phase of the signal spectrum and show it is a bandlimited signal.
4) Generate an impulse train at an appropriate sampling rate using DFS and show that its FFT is again an impulse train.
5) Using the signal and impulse train generated in (1) and (4), produce sampled signal by multiplying the two and apply FFT.
6) Display the sampled signal and its spectrum.
7) Reconstruct the original signal from its sampled value using sinc (interpolation) filter and display the same.

Respuesta aceptada

VBBV
VBBV el 28 de En. de 2022
clear all
close all
% Creating modulating signal
fm=2; % message signal frequency (Hz)
n=50; % factor of sampling frequency
K=1000;
Ts=1/(n*fm); % sampling time
t=0:Ts:100-Ts; % time range
N=size(t,2);
Fs=1/Ts; % sampling frequency
dFs=Fs/N;
f=-Fs/2:dFs:Fs/2-dFs;
m=2*cos(2*pi*fm*t); % message signal
subplot(5,1,1);
plot(t,m);
xlabel('Time(in s)');
title('Modulating signal');
% Frequency Domain
M=fftshift(fft(m)); % FFT of the message signal
subplot(5,1,2)
plot(f,abs(M)/N);
xlabel('Frequency(in hertz)');
title('Magnitude response');
%sound(X)
% Pulse train generation
T=0.2; %sampling interval
F=1/T; % sapling frequency
h=zeros(1,length(t)); % initialize all values to zero
for k=-K:1:K
h=h+(1/T)*cos(2*pi*k*F*t);
end
h_a=T*h/(2*K+1); % scaling
subplot(5,1,3);
plot(t,h_a);
xlabel('Time(s)');
title('Pulse train');
% sampling
m_samp=m.*h_a;
N_samp=length(m_samp);
subplot(5,1,4);
plot(t,m_samp);% add the plot function
xlabel('Time(in s)');
title('Sampled value');
% Magnitude response of sampled signal
M_samp=fftshift(fft(m_samp));
subplot(5,1,5)
plot(f,abs(M_samp)/N_samp);
xlabel('Frequency(in hertz)');
title('Magnitude response')
You forgot to use plot function. Check with this
m_samp=m.*h_a;
N_samp=length(m_samp);
subplot(5,1,4);
plot(t,m_samp);% add the plot
  2 comentarios
VBBV
VBBV el 28 de En. de 2022
M_samp=fftshift(fft(m_samp));
H = sinc(M_samp)./N_samp;
G = filter(H,1,t);
plot(f,G)
Add this to reconstruct the sampled signal
Sushilkumar
Sushilkumar el 6 de Mayo de 2024
% Sampling Theorem
clc;
clear all;
t = -100:0.01:100;
T=30;
fm = 1/T;
x = cos(2*pi*fm*t);
subplot(2,2,1);
plot(t,x);
grid on;
xlabel('Time in seconds');
xlabel('x(t)');
title('Continuous time signal');
fs1 = 1.6*fm;
n1 = -5:1:5;
xn1 = cos(2*pi*n1*fm/fs1);
subplot(2,2,2);
stem(n1,xn1);
hold on;
plot(n1, xn1);
grid on;
xlabel('Time in seconds');
xlabel('x(t)');
title('Discrete time signal with fs1<2fm');
fs2 = 2*fm;
n2 = -5:1:5;
xn2 = cos(2*pi*n2*fm/fs2);
subplot(2,2,3);
stem(n2,xn2);
hold on;
plot(n2, xn2);
grid on;
xlabel('Time in seconds');
xlabel('x(t)');
title('Discrete time signal with fs2 = 2fm');
fs3 = 8*fm;
n3 = -20:1:20;
xn3 = cos (2*pi*n3*fm/fs3);
subplot(2,2,4);
stem(n3,xn3);
hold on;
plot(n3, xn3);
grid on;
xlabel('Time in seconds');
xlabel('x(t)');
title('Discrete time signal with fs1 > 2fm');
sampling

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Más respuestas (2)

Sulaymon Eshkabilov
Sulaymon Eshkabilov el 19 de Sept. de 2021
Could pl., show what you have done so far?
  1 comentario
Chetan Fadnis
Chetan Fadnis el 19 de Sept. de 2021
% Sampling and Reconstruction
clc
clear all
close all
% Creating modulating signal
fm=2; % message signal frequency (Hz)
n=50; % factor of sampling frequency
K=1000;
Ts=1/(n*fm); % sampling time
t=0:Ts:100-Ts; % time range
N=size(t,2);
Fs=1/Ts; % sampling frequency
dFs=Fs/N;
f=-Fs/2:dFs:Fs/2-dFs;
m=2*cos(2*pi*fm*t); % message signal
subplot(5,1,1);
plot(t,m);
xlabel('Time(in s)');
title('Modulating signal');
% Frequency Domain
M=fftshift(fft(m)); % FFT of the message signal
subplot(5,1,2)
plot(f,abs(M)/N);
xlabel('Frequency(in hertz)');
title('Magnitude response');
%sound(X)
% Pulse train generation
T=0.2; %sampling interval
F=1/T; % sapling frequency
h=zeros(1,length(t)); % initialize all values to zero
for k=-K:1:K
h=h+(1/T)*cos(2*pi*k*F*t);
end
h_a=T*h/(2*K+1); % scaling
subplot(5,1,3);
plot(t,h_a);
xlabel('Time(s)');
title('Pulse train');
% sampling
m_samp=m.*h_a;
N_samp=length(m_samp);
subplot(5,1,4);
xlabel('Time(in s)');
title('Sampled value');
% Magnitude response of sampled signal
M_samp=fftshift(fft(m_samp));
subplot(5,1,5)
plot(f,abs(M_samp)/N_samp);
xlabel('Frequency(in hertz)');
title('Magnitude response')
Finding difficulty in Reconstruction part

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Adel
Adel el 23 de Sept. de 2024
clear all
close all
% Creating modulating signal
fm=2; % message signal frequency (Hz)
n=50; % factor of sampling frequency
K=1000;
Ts=1/(n*fm); % sampling time
t=0:Ts:100-Ts; % time range
N=size(t,2);
Fs=1/Ts; % sampling frequency
dFs=Fs/N;
f=-Fs/2:dFs:Fs/2-dFs;
m=2*cos(2*pi*fm*t); % message signal
subplot(5,1,1);
plot(t,m);
xlabel('Time(in s)');
title('Modulating signal');
% Frequency Domain
M=fftshift(fft(m)); % FFT of the message signal
subplot(5,1,2)
plot(f,abs(M)/N);
xlabel('Frequency(in hertz)');
title('Magnitude response');
%sound(X)
% Pulse train generation
T=0.2; %sampling interval
F=1/T; % sapling frequency
h=zeros(1,length(t)); % initialize all values to zero
for k=-K:1:K
h=h+(1/T)*cos(2*pi*k*F*t);
end
h_a=T*h/(2*K+1); % scaling
subplot(5,1,3);
plot(t,h_a);
xlabel('Time(s)');
title('Pulse train');
% sampling
m_samp=m.*h_a;
N_samp=length(m_samp);
subplot(5,1,4);
plot(t,m_samp);% add the plot function
xlabel('Time(in s)');
title('Sampled value');
% Magnitude response of sampled signal
M_samp=fftshift(fft(m_samp));
subplot(5,1,5)
plot(f,abs(M_samp)/N_samp);
xlabel('Frequency(in hertz)');
title('Magnitude response')

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