# Creating a matrix of Gaussian Wavelets at dyadic scales

I need to create a diagonal matrix containing the Fourier coefficients of the Gaussian wavelet function, but I'm unsure of what to do.

Currently I'm using this function to generate the Haar Wavelet matrix

http://www.mathworks.co.uk/matlabcentral/fileexchange/33625-haar-wavelet-transformation-matrix-implementation/content/ConstructHaarWaveletTransformationMatrix.m

and taking the rows at dyadic scales (2,4,8,16) as the transform:

M= 256
H = ConstructHaarWaveletTransformationMatrix(M);
fi = conj(dftmtx(M))/M;
H = fi*H;
H = H(4,:);
H = diag(H);

etc

How do I repeat this for Gaussian wavelets? Is there a built in Matlab function which will do this for me?

For reference I'm implementing the algorithm in section 4 of this paper:

http://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=04218361

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The link to the IEEE-paper is broken. Can you include that particular section as a figure? –  Schorsch Aug 29 '13 at 15:20
@Schorsch Hi, I've solved this particular problem, but the paper isn't really necessary to answer the question. It's 'Compressed Sensing for Wideband Cognitive Radios' Zhi Tian and Georgios Giannakis. –  Tom Kealy Aug 29 '13 at 15:23
You can answer your own question to help others in a similar situation. –  Schorsch Aug 29 '13 at 15:26

As far as i know, the Matlab Wavelet Toolbox only deal with wavelet operations and coefficients, increase or decrease resolution levels, and similar operations, but do not exposes the internal matrices serving to doing the transformations from signals and coefficients.

Hence i fear the answer to this question is no. Some time ago, i did this for some of the Hart Class wavelet, and i actually build the matrix from the scratch, and then i compared the coefficients obtained with the Built-in Matlab Wavelet Toolbox, hence ensuring your matrices are good enough for your algorithm. In my case, recursive parameter estimation for time varying models.

For the function ConstructHaarWaveletTransformationMatrix it is really simple to create the matrix, because the Hart Class could be really simple expressed as Kronecker products. The Gaussian Wavelet case as i fear should be done from the scratch too...

THe steps i suggest would be;

1. Although MATLAB dont include explicitely the matrices, you can use the Matlab built-in functions to recover the Gaussian Wavelets, and thus compose the matrix for your algorithm.

2. Build every column of the matrix with every Gaussian Wavelet, for every resolution levels you are requiring (the dyadic scales). Use the Matlab Wavelets toolbox for recover the shapes.

3. After this, compare the coefficients obtained by you, with the coefficients of the toolbox. This way you will correct the order of the Matrix row.

Numerically, being fj the signal projection over Vj (the PHI signals space, scaling functions) at resolution level j, and gj the signal projection over Wj (the PSI signals space, mother functions) at resolution level j, we can write:

f=fj0+sum_{j0}^{j1-1}{gj}

Hence, both fj0 and gj will induce two matrices, lets call them PHIj and PSIj matrices:

f=PHIj0*cj0+sum_{j0}^{j1-1}{PSIj*dj}

The PHIj columns contain the scaled and shifted scaling wavelet signal (one, for j0 only) for the approximation projection (the Vj0 space), and the PSIj columns contain the scaled and shifted mother wavelet signals (several, from j0 to j1-1) for the detail projection (onto the Wj0 to Wj1-1 spaces).

Hence, the Matrix you need is:

PHI=[PHIj0 PSIj0... PSIj1]

Thus you can express you original signal as:

f=PHI*C

where C is a vector of approximation and detail coefficients, for the levels:

C=[cj0' dj0'...dj1']'

The first part, for addressing the PHI build can be achieved by writing:

function PHI=MakePhi(l,str,Jmin,Jmax)
% [PHI]=MakePhi(l,str,Jmin,Jmax)
%
% Build full PHI Wavelet Matrix for obtaining wavelet coefficients
% (extract)
%FILTER
[LO_R,HI_R] = wfilters(str,'r');
lf=length(LO_R);

%PHI BUILD
PHI=[];
laux=l([end-Jmax end-Jmax:end]);
PHI=[PHI MakeWMatrix('a',str,laux)];

for j=Jmax:-1:Jmin
laux=l([end-j end-j:end]);
PHI=[PHI MakeWMatrix('d',str,laux)];
end

the wfilters is a MATLAB built in function, giving the required signal for the approximation and or detail wavelet signals.

The MakeWMatrix function is:

function M=MakeWMatrix(typestr,str,laux)
% M=MakeWMatrix(typestr,str,laux)
%
% Build Wavelet Matrix for obtaining wavelet coefficients
% for a single level vector.
% (extract)
[LO_R,HI_R] = wfilters(str,'r');
if typestr=='a'
F_R=LO_R';
else
F_R=HI_R';
end

la=length(laux);
lin=laux(2); lout=laux(3);
M=MakeCMatrix(F_R,lin,lout);

for i=3:la-1
lin=laux(i); lout=laux(i+1);
Mi=MakeCMatrix(LO_R',lin,lout);
M=Mi*M;
end

and finally the MakeCMatrix is:

function [M]=MakeCMatrix(F_R,lin,lout)
% Convolucion Matrix
% (extract)
lf=length(F_R);

M=[];
for i=1:lin
M(:,i)=[zeros(2*(i-1),1) ;F_R ;zeros(2*(lin-i),1)];
end

M=[zeros(1,lin); M ;zeros(1,lin)];

[ltot,lin]=size(M);

lmin=floor((ltot-lout)/2)+1;
lmax=floor((ltot-lout)/2)+lout;

M=M(lmin:lmax,:);

This last matrix should include some interpolation routine for having better general results in each case.

I expect this solve part of your problem.....

Hyp

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