Try this:
xls = xlsread('signals.xls');
t = [0; xls(2:end,1)]*1E-6; % Time Vector (Set Initial ‘NaN’ To 0)
Fs = 1/mean(diff(t)); % Sampling Frequency
Fn = Fs/2; % Nyquist Frequency
y = xls(:,2:end); % Signal Matrix
ym = y - mean(y); % Subtract Column Means From All Columns (Eliminates D-C Offset Effect)
L = numel(t); % Signal Lengths
FTy = fft(ym)/L; % Fourier Transform (Scaled For Length)
Fv = linspace(0, 1, fix(L/2)+1)*Fn; % Frequency Vector
Iv = 1:numel(Fv); % Index Vector
figure
plot(Fv, abs(FTy(Iv,:))*2)
grid
sep = ones(numel(Fv),1) * (1:size(FTy,2)); % ‘Separation’ Matrix — Plots Each Record In Its Column Locatioln
Fm = ones(numel(size(FTy,2)),1) * Fv; % Frequency Matrix
figure
plot3(Fm, sep, abs(FTy(Iv,:))*2)
grid on
xlabel('Frequency (Hz)')
ylabel('Record (Column #)')
zlabel('Amplitude')
My code first subracts the mean from each column in order to eliminate the D-C offset at 0 Hz. It then simply calculates the fft of each column. The ‘Fv’ vector is a vector of the frequencies for a one-sided Fourier transform, and ‘Iv’ is the vector of indices corresponding to those frequencies, so that they are plotted correctly.
With 44 records, I added the second figure in order to make the Fourier transform of each record easier to see. The ‘sep’ matrix creates offsets for each record, and ‘Fm’ is the matrix of frequency vectors for each record (both required for plot3).
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