# Frequency response using FFT in MATLAB

Here is the scenario: using a spectrum analyzer i have the input values and the output values. the number of samples is `32000` and the sampling rate is `2000` samples/sec, and the input is a sine wave of `50 hz`, the input is current and the output is pressure in psi.

How do i calculate the frequency response from this data using MATLAB, using the FFT function in MATLAB.

i was able to generate a sine wave, that gives out the the magnitude and phase angles, here is the code that i used:

``````%FFT Analysis to calculate the frequency response for the raw data
%The FFT allows you to efficiently estimate component frequencies in data from a discrete set of values sampled at a fixed rate

% Sampling frequency(Hz)
Fs = 2000;

% Time vector of 16 second
t = 0:1/Fs:16-1;

% Create a sine wave of 50 Hz.
x = sin(2*pi*t*50);

% Use next highest power of 2 greater than or equal to length(x) to calculate FFT.
nfft = pow2(nextpow2(length(x)))

% Take fft, padding with zeros so that length(fftx) is equal to nfft
fftx = fft(x,nfft);

% Calculate the number of unique points
NumUniquePts = ceil((nfft+1)/2);

% FFT is symmetric, throw away second half
fftx = fftx(1:NumUniquePts);

% Take the magnitude of fft of x and scale the fft so that it is not a function of the length of x
mx = abs(fftx)/length(x);

% Take the square of the magnitude of fft of x.
mx = mx.^2;

% Since we dropped half the FFT, we multiply mx by 2 to keep the same energy.
% The DC component and Nyquist component, if it exists, are unique and should not be multiplied by 2.

if rem(nfft, 2) % odd nfft excludes Nyquist point
mx(2:end) = mx(2:end)*2;
else
mx(2:end -1) = mx(2:end -1)*2;
end

% This is an evenly spaced frequency vector with NumUniquePts points.
f = (0:NumUniquePts-1)*Fs/nfft;

% Generate the plot, title and labels.
subplot(211),plot(f,mx);
title('Power Spectrum of a 50Hz Sine Wave');
xlabel('Frequency (Hz)');
ylabel('Power');

% returns the phase angles, in radians, for each element of complex array fftx
phase = unwrap(angle(fftx));
PHA = phase*180/pi;
subplot(212),plot(f,PHA),title('frequency response');
xlabel('Frequency (Hz)')
ylabel('Phase (Degrees)')
grid on
``````

i took the frequency response from the phase plot at `90` degree phase angle, is this the right way to calculate the frequency response?

how do i compare this response to the values that is obtained from the analyzer? this is a cross check to see if the analyzer logic makes sense or not.

``````G = cpsd (output,input) / cpsd (input,input)
then take the `angle()` to obtain the phase difference between the input and the output.