I am using matlab's wavelet fractional Brownian motion function in order to generate 1D point-like data of diffusion in the regions of sub-diffusion, super-diffusion and normal diffusion.
The problem I encounter with is that the time normalization/variance is weird.
For example for Hurst parameter equals
0.5 (regular Brownian motion) I get standard deviation which isn't unity (
>> std(diff(wfbm(0.5,1e6))) ans = 0.3955
Due to the above, I am not sure how to re-normalize all the 3 trajectories I create for the 3 diffusion cases (sub, super, normal).
I generated trajectories for
N pointlike particles of length
M=500; N=200; nd = zeros(M,N); sub = zeros(M,N); sup = zeros(M,N); Hsub = 0.25; Hsup = 0.75; for j=1:N nd(:,j) = wfbm(0.5, M, 15, 'db10'); sub(:,j) = wfbm(Hsub,M, 10, 'db10'); sup(:,j) = wfbm(Hsup,M, 10, 'db10'); end
Here is how function is implemented in matlab and generates the signal, however I am not sure how to modify it to have a proper brownian motion:
tmp = conv(randn(1,len+nbmax),ckbeta); tmp = cumsum(tmp); CA = wkeep(tmp,len,'c'); for j=0:nblev-1 CD = 2^(j/2)*4^(-s)*2^(-j*s)*randn(1,len); len = 2*len-nbmax; CA = idwt(CA,CD,fs1,gs1,len); end fBm = wkeep(CA,L,'c'); fBm = fBm-fBm(1);
I was trying to understand it from the paper which says it's possible to control the variance of fBm:
This is citation 7 from the snapshot above.