Title :
Sublinear Recovery of Sparse Wavelet Signals
Author :
Maleh, R. ; Gilbert, A.C.
Author_Institution :
Univ. of Michigan, Ann Arbor
Abstract :
There are two main classes of decoding algorithms for "compressed sensing," those which run in time polynomial in the signal length and those which use sublinear resources. Most of the sublinear algorithms focus on signals which are compressible in either the Euclidean domain or the Fourier domain. Unfortunately, most practical signals are not sparse in either one of these domains. However, many are sparse (or nearly so) in the Haar wavelet system. We present a modified sublinear recovery algorithm which utilizes the recursive structure of Reed-Muller codes to recover a wavelet-sparse signal from a small set of pseudo-random measurements. We also discuss an implementation of the algorithm to illustrate proof-of-concept and empirical analysis.
Keywords :
Haar transforms; Reed-Muller codes; computational complexity; decoding; signal reconstruction; sparse matrices; wavelet transforms; Euclidean domain; Fourier domain; Haar wavelet system; Reed-Muller codes; compressed sensing decoding algorithm; pseudo-random measurement matrix; recursive structure; signal compression; signal reconstruction; sublinear sparse wavelet signal recovery; time polynomial; Algorithm design and analysis; Compressed sensing; Data compression; Decoding; Information analysis; Mathematics; Polynomials; Signal analysis; Wavelet coefficients; Wavelet domain; Haar; Reed Muller; sketch; sparse; sublinear recovery; wavelets;
Conference_Titel :
Data Compression Conference, 2008. DCC 2008
Conference_Location :
Snowbird, UT
Print_ISBN :
978-0-7695-3121-2
DOI :
10.1109/DCC.2008.86
