Gauss-Markov process generation: how to filter a white noise sequence properly

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Hi all,
I'm trying to generate a first order Gauss-Markov process (https://en.wikipedia.org/wiki/Gauss%E2%80%93Markov_process).
From signal processing theory, it is known that this could be performed filtering a white gaussian noise properly (noise shaping filter).
This filter should have a transfer function equal to:
with the two parameters %sigma, %beta that have to be tuned and that will described completely the Gauss-Markov process.
fs = 100;
Nsamples = 2000;
rng('default');
gaussianNoise = randn(Nsample, 1);
whiteGaussianNoise = (gaussianNoise - mean(gaussianNoise)) / std(gaussianNoise);
beta = 0.01;
sigma = 0.1;
b = sqrt(2 * beta * sigma^2);
a = [1, beta];
gaussMarkov = filter(b,a,whiteGaussianNoise);
This is the code I used for the Gauss Markov synthetis. Unfortunately, something is wrong because it has a similar power spectral density and a similiar autocorrelation of the white noise. In the link provided above, the correct auocorrelation and psd are defined.
What's wrong with this code? Why I cannot generate a Gauss Markov process?
Thank you all.

Respuestas (1)

Adil
Adil el 9 de Sept. de 2022
Editada: Adil el 13 de Sept. de 2022
I'm not sure if that's the reason for your problem, but you're using a transfer function in the s-domain G(s) and it looks like the MATLAB filter function uses a transfer function in the z-domain G(z).
So maybe it will work after applying this method: Matched Z-transform method - Wikipedia
EDIT:
Ok, now I'm sure, just watch this video: https://www.youtube.com/watch?v=88tWmyBaKIQ and you will see that you can just use the bilinear transform and get (for your sampling frequency) the following parameters:
b = [((sqrt(2 * beta * sigma^2))*1/fs)/(beta*1/fs + 2), (sqrt(2 * beta * sigma^2)*1/fs)/(beta*1/fs + 2)];
a = [1,(beta*1/fs - 2)/(beta*1/fs + 2)];
  2 comentarios
Johnny Scalera
Johnny Scalera el 14 de Sept. de 2022
Thank you @Adil for your answer. I am taking into account your observation.
Using the bilinear transform described in the section 9.2 Converting S Domain to Z Domain of this page
I obtain this transfer function in the z domain
So my two vectors of coefficients are
k = sqrt(2*beta*sigma^2) / (beta+1)
b = [k, k]
a = [1, (beta-1) / (beta+1)]
Am I right? Why do you use different coefficients?
Adil
Adil el 14 de Sept. de 2022
Editada: Adil el 14 de Sept. de 2022
Hi Johnny,
I'm not sure why your source uses a different bilinear transform without dependency of dt, but as you suggested in your entry post: You can check the generated signal via its autocorrelation function, psd or Allan deviation plot.
So if I'm checking the gauss markov signal which was created with your parameters, then I can unfortunately see no exponentially time correlated autocorrelation plot, as expected.
But with the parameters which I posted above, I can see it.
[Rxx, lags] = xcorr(gaussMarkov);
figure();
plot(lags, Rxx);
This shape is what you would expect: https://www.researchgate.net/profile/Spiros_Pagiatakis/publication/232711015/figure/download/fig14/AS:668420496453664@1536375273795/Autocorrelation-function-of-the-first-order-Gauss-Markov-process.png
I calculated the coeffitients as described here: Bilinear transform - Wikipedia with s = (2 - 2z^(-1))/(dt + dtz^(-1))
I hope this helps

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