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Sunday, December 23, 2007

Compressed Sensing: MCA news and Sublinear Recovery of Sparse Wavelet Signals

Coming back from NIPS 07, Jort Gemmeke mentioned the following two items:

Morphological Component Analysis : an Adaptive Thresholding Strategy by Jerome Bobin, Jean-Luc Starck, Jalal Fadili, Yassir Moudden, and David Donoho, the abstract reads:
In a recent paper, a method called MCA (Morphological Component Analysis) has been proposed to separate the texture from the natural part in images. MCA relies on an iterative thresholding algorithm, using a threshold which decreases linearly towards zero along the iterations. This paper shows how the MCA convergence can be drastically improved using the mutual incoherence of the dictionaries associated to the different components. This modified MCA algorithm is then compared to Basis Pursuit, and experiments show that MCA and BP solutions are similar in terms of sparsity, as measured by l1 norm, but MCA is much faster and gives us the possibility to handle large scale data sets.
The MOM/matched filtering and thresholding bears some similarity with another paper mentioned in this entry from some of the same co-authors. I haven't looked at it deeper yet. Always on the same topic of Morphological Component Analysis, Jort also mentions the release of the MCA 802 C++ toolbox from Jalal Fadili's webpage.

Toward a dedicated Compressed Sensing based on the signal signature? It looks like Ray Maleh and Anna Gilbert are beginning to do that in Sublinear recovery of sparse wavelet signals. The abstract reads:
There are two main classes of decoding algorithms for “compressed sensing,” those which run time 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. Instead, they 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.

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