# How do I calculate the transfer function of a filter in MATLAB?

I have to do some exercises in a Digital Signal Processing course and I have some problems.

I have a given file (signal.wav name the signal `x(n)` ) with some noise added and iIam asked to find some information from it. The noise added is `η(n) = sin8000πn`. So the signal I am processing is `s(n) = x(n) + η(n)`

In order to remove the noise, I apply a low-pass butterworth filter with `order = 2` and cutoff frequency = 2000hz.

I want to find the transfer function `H(s)` from the filter and the `H(z)` function. Well I know that I have to apply bilinear transformation but iIdont know how to do it with MATLAB.

Can anyone help me solve this?

Here is my code

``````[y, fs, nbits] = wavread('signal.wav');

% Playing the file
disp('-> Playing at the original sample rate...');
sound(y, fs);

fprintf('------------------------------------------\n');
% Sampling frequency
fprintf('-> Sample frequency is:      %f.\n', fs);

% Print the min and max values of the audio data.
fprintf('-> The maximum data value is %f.\n', max(y));
fprintf('-> The minimum data value is %f.\n', min(y));
fprintf('------------------------------------------\n');

order = 2;
sampling_freq = fs;
cut_off_freq = 2000;

[butter_a, butter_b] = butter(order,cut_off_freq/(sampling_freq/2));
%[butter_a, butter_b] = butter(order,cut_off_freq/(sampling_freq));

subplot(211), plot(y);
subplot(212), plot(filter(butter_a,butter_b,y));

sound(filter(butter_a,butter_b,y),fs);
``````
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ITYM transfer function (not "transport function") ? You might also be better off asking this in dsp.stackexchange.com since it's more DSP-related than programming-related. –  Paul R Sep 20 '11 at 13:38
Sorry i tried to translate from my native language. I meant transfer function. –  john_pots Sep 20 '11 at 13:40

You should use `freqs` to calculate the frequency response/transfer function of your analog filter (i.e., `H(s)`). So in this case, something like:

``````freqs(butter_b,butter_a,200);
``````

will plot the frequency and phase response for the filter at 200 frequency points. You can also provide a vector of points where it should be calculated (see the linked doc).

For the transfer function of the digital filter (i.e., `H(z)`), use `freqz`. So your syntax would be something like:

``````freqz(butter_b,butter_a,[],fs)
``````

which will again plot the frequency and phase responses as before. Again, make sure you read the linked documentation to understand and use it correctly.

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Thanks that's what i needed. I only changed 200 to 148864 cause it is the actual number of samples in the signal. Now i have another problem. The plot gives me frequencies x 10^4 so i see the cutoff at 2 x 10^4 = 20000hz instead of 2000hz. –  john_pots Sep 20 '11 at 15:46
ah, I see what the problem is. The output for `butter` in your code should be collected as `[b,a]` i.e., numerator coefficients first. You've reversed the order. Flip that and try this, you should get the cutoff at 2k Hz. –  yoda Sep 20 '11 at 16:28