# Scale simulated time series to approach given Gaussian process

I am not sure if this question will be a little off-topic on this forum, that I will give it a try anyway

By using `MATLAB`, I'm on my way to generate a turbulent wind field. This wind field is generally a Gaussian process with all the time series having 0 mean value and unitary standard deviation. I will shortly introduce you to the problem:

1) Discretize the space in Y-Z plane in a certain number of points `Ny`, `Nz`;

2) Discretize the time scale (generally 600s) with a proper time sample, `dt = 0.15`;

3) Calculate distance among points;

4) Generate only positive frequency vector `f = (0:length(t)/2-1)*df`;

5) Generate power spectra

``````f_u = (f)*(xLu/Uhub);
f_v = (f)*(xLv/Uhub);
f_w = (f)*(xLw/Uhub);
% Define normalized power spectra
psd = zeros(length(f),3);
psd(:,1) = (4.*(sigma1^2).*(xLu/Uhub))./exp((5/3).*log(1 + 6.*f_u));
psd(:,2) = (4.*(sigma2^2).*(xLv/Uhub))./exp((5/3).*log(1 + 6.*f_v));
psd(:,3) = (4.*(sigma3^2).*(xLw/Uhub))./exp((5/3).*log(1 + 6.*f_w));
xLu = 340.2;
xLv = 113.4;
xLw = 27.72;
``````

6) Generate coherence matrix

``````nn_u = complex(normrnd(0,1,size(H_u)),normrnd(0,1,size(H_u)));
nn_v = complex(normrnd(0,1,size(H_v)),normrnd(0,1,size(H_v)));
nn_w = complex(normrnd(0,1,size(H_w)),normrnd(0,1,size(H_w)));

for ii = 2:numel(f)
Coh_u = exp(-a.*dist.*sqrt((f(ii)/Uhub).^2 + (0.12/Lc).^2)).*(df.*psd(ii,1)); % Coherence matrix
Coh_v = eye(N).*sqrt(df.*psd(ii,2));
Coh_w = eye(N).*sqrt(df.*psd(ii,3));
HH_u = chol(Coh_u,'lower'); % Cholesky factorization of the Coherence matrix for u-component
H_u(:,ii) = HH_u*nn_u(:,ii); % Computation of the FFT terms in x direction
H_v(:,ii) = Coh_v*nn_v(:,ii); % Computation of the FFT terms in y direction
H_w(:,ii) = Coh_w*nn_w(:,ii); % Computation of the FFT terms in z direction
end
``````

9) Generate time series

``````U = zeros(N,size(H_u,2)*2);
V = zeros(N,size(H_u,2)*2);
W = zeros(N,size(H_u,2)*2);

for ii = 1:N
tmp_u = fftshift(fft((H_u(ii,:)))); % FFT
tmp_v = fftshift(fft((H_v(ii,:))));
tmp_w = fftshift(fft((H_w(ii,:))));
U(ii,:) = [real(tmp_u) imag(tmp_u)];
V(ii,:) = [real(tmp_v) imag(tmp_v)];
W(ii,:) = [real(tmp_w) imag(tmp_w)];
end
``````

Now, after this consistent theorethical introduction, I can move towards the real matter: when calculating the standard deviations for eac time series (u,v,w components), they don't match the expected values

``````sigma1 = 1;
sigma2 = 0.8;
sigma3 = 0.5;
``````

because of several reasons:

• space discretization introducing smoothing effects
• time sample period
• power spectrum only within a short frequency range

Btw, I would like to, let's say, scale the time series in order they to match Gaussian variables with zero mean and a standard deviation.

Do you have any hint?

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