NAME
Math::GSL::Wavelet  1D (Real) Wavelets
SYNOPSIS
use Math::GSL::Wavelet qw/:all/;
DESCRIPTION
gsl_wavelet_alloc($T, $k)

This function allocates and initializes a wavelet object of type $T, where $T must be one of the constants below. The parameter $k selects the specific member of the wavelet family.
gsl_wavelet_free($w)

This function frees the wavelet object $w.
gsl_wavelet_name
gsl_wavelet_workspace_alloc($n)

This function allocates a workspace for the discrete wavelet transform. To perform a onedimensional transform on $n elements, a workspace of size $n must be provided. For twodimensional transforms of $nby$n matrices it is sufficient to allocate a workspace of size $n, since the transform operates on individual rows and columns.
gsl_wavelet_workspace_free($work)

This function frees the allocated workspace work.
gsl_wavelet_transform
gsl_wavelet_transform_forward($w, $data, $stride, $n, $work)

This functions compute inplace forward discrete wavelet transforms of length $n with stride $stride on the array $data. The length of the transform $n is restricted to powers of two. For the forward transform, the elements of the original array are replaced by the discrete wavelet transform f_i > w_{j,k} in a packed triangular storage layout, where j is the index of the level j = 0 ... J1 and k is the index of the coefficient within each level, k = 0 ... (2^j)1. The total number of levels is J = \log_2(n). The output data has the following form,
(s_{1,0}, d_{0,0}, d_{1,0}, d_{1,1}, d_{2,0}, ..., d_{j,k}, ..., d_{J1,2^{J1}1})
where the first element is the smoothing coefficient s_{1,0}, followed by the detail coefficients d_{j,k} for each level j. The backward transform inverts these coefficients to obtain the original data. These functions return a status of $GSL_SUCCESS upon successful completion. $GSL_EINVAL is returned if $n is not an integer power of 2 or if insufficient workspace is provided.
gsl_wavelet_transform_inverse
This module also contains the following constants with their valid k value for the gsl_wavelet_alloc function :
This is the Daubechies wavelet family of maximum phase with k/2 vanishing moments. The implemented wavelets are k=4, 6, ..., 20, with k even.
This is the Haar wavelet. The only valid choice of k for the Haar wavelet is k=2.
This is the biorthogonal Bspline wavelet family of order (i,j). The implemented values of k = 100*i + j are 103, 105, 202, 204, 206, 208, 301, 303, 305 307, 309.
AUTHORS
Jonathan "Duke" Leto <jonathan@leto.net> and Thierry Moisan <thierry.moisan@gmail.com>
COPYRIGHT AND LICENSE
Copyright (C) 20082011 Jonathan "Duke" Leto and Thierry Moisan
This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.