I'm currently studying the following book: "Fourier Transform Spectroscopy Instrumentation Engineering", by Vidi Saptari. My question is related to the code below, based on the code from the book, Appendix C. The code below computes the interferogram of 3 waves with wavenumbers [cm-1] 5000, 10000 and 15000, respectively, and than performs an FFT to retrieve the information. The unscaled output has a magnitude of 1600, instead of 1.

```
clear;
% Sampling clock signal generation
samp_period_nm = 632.8 / 4; % sampling period in nm. 632.8 is the HeNe laser's wavelength
samp_period = 1 * samp_period_nm * 10^-7; % sampling period in cm.
scan_dist = 0.1; % mirror scan distance in cm.
no_elements = floor(scan_dist/samp_period);
x_samp = 0:samp_period:samp_period*no_elements; %Vector of clock signals in cm
xn_samp = x_samp .* (1 + rand(1, length(x_samp)));
v1 = 5000;
v2 = 10000;
v3 = 15000;
arg = 4 * pi * x_samp;
y = cos(arg*v1) + cos(arg*v2) + cos(arg*v3) ;
total_data = 2^18;
no_zero_fills=[total_data - length(y)];
zero_fills=zeros(1, no_zero_fills);
%triangular apodization
n_y = length(y);
points = 1:1:n_y;
tri = 1 - 1/(n_y) * points(1:n_y);
y = y.*tri; %dot product of interferogram with triangular apodization function
y = [y zero_fills]; %zero filling
% FFT operation
fft_y = fft(y);
% fft_y = fft_y / n_y;
% fft_y = fft_y * samp_period;
fft_y(1) = [];
n_fft=length(fft_y);
spec_y = abs(fft_y(1:n_fft/2)); %spectrum generation
nyquist = 1 / (samp_period * 4);
freq = (1:n_fft/2)/(n_fft/2)*nyquist; %frequency scale generation
figure();
plot(freq, spec_y); % plot of spectrum vs wave number
xlabel('Wavenumber [cm-1]');
ylabel('Intesity [V]');
```

By multiplying the result of the fft (fft_y) with dt = samp_period, as suggested here, the peak is as 0.025.

Following the same link's second solution, by dividing fft_y by n_y (the length of y), the magnitude is 0.25.

Clearly, I'm doing something wrong. Any help is appreciated.

Thanks,