I am trying to understand what happens when I try to reconstruct the spectrum of a signal with fewer samples. I tried 2 approaches. I resample the time domain signal based on the number of samples (N) I need and then took an FFT. In the second approach, I just did an N point FFT in which, as MATLAB says, the samples after N are ignored. Surprisingly, the second approach gives a good result. I don't understand why. For the ground truth, I simulate the time domain signal using a Gaussian-shaped frequency spectrum.
My MATLAB program is given below. You can change the value of N and see the results. Also you can change the interpolation method for the resampled signal case. I did all types of checks and I think the N point FFT performs better. However, one would think that the resampled signal should performed better when a FFT is applied.
clear;
close all;
n = 512;
[sig_a, sig_f] = DS_simulator(10^(Inf/20), 1, 5, 0.2, n, 7.5);
figure; plot((abs(sig_f).^2));
N = 256;
idx = 1:n;
idxq = linspace(min(idx), max(idx), N);
sig_resampled = interp1(idx, sig_a, idxq, 'cubic');
figure; plot(1:1:n, abs(sig_a)); hold on; plot(1:n/N:n, abs(sig_resampled), '*');
sig_resamp_doppler = 1/N .* abs(fftshift(fft(sig_resampled, N))).^2;
sig_doppler = 1/N .* abs(fftshift(fft(sig_a, N))).^2;
figure; plot(abs(sig_doppler)); hold on; plot(abs(sig_resamp_doppler));
The code of ground truth signal generation whose spectrum is a Gaussian shape with mean as mu and standard deviation as sigma
function [data, data_f] = DS_simulator(SNR, m0, mu, sigma, n, v_amb)
vel_axis = linspace(-v_amb, v_amb, n);
X = rand(1, n);
Theta = 2 .* pi * rand(1, n);
if sigma < 0.02
[~, idx1] = min(abs(vel_axis - mu));
S = dirac(vel_axis - vel_axis(idx1));
idx = S == Inf;
S(idx) = 1;
else
S = m0/sqrt(2*pi*sigma^2) * exp(-(vel_axis - mu).^2/(2*sigma^2));
end
N = sum(S) ./ (n .* SNR);
P = -(S + N) .* log(X);
data_f = sqrt(P);
data = ifft(fftshift(sqrt(n) .* sqrt(P) .* exp(1j .* Theta)));
end
