Abstract
We have previously shown that augmenting orthogonal matching pursuit (OMP) with an additional step in the identification stage of each pursuit iteration yields improved k-sparse reconstruction and denoising performance relative to baseline OMP. At each iteration a "path," or geodesic, is generated between the two dictionary atoms that are most correlated with the residual and from this path a new atom that has a greater correlation to the residual than either of the two bracketing atoms is selected. Here, we provide new computational results illustrating improvements in sparse coding and denoising on canonical datasets using both learned and structured dictionaries. Two methods of constructing a path are investigated for each dictionary type: the Euclidean geodesic formed by a linear combination of the two atoms and the 2-Wasserstein geodesic corresponding to the optimal transport map between the atoms. We prove here the existence of a higher-correlation atom in the Euclidean case under assumptions on the two bracketing atoms and introduce algorithmic modifications to improve the likelihood that the bracketing atoms meet those conditions. Although we demonstrate our augmentation on OMP alone, in general it may be applied to any reconstruction algorithm that relies on the selection and sorting of high-similarity atoms during an analysis or identification phase.
Highlights
A FREQUENT goal within signal/image processing is to reconstruct or compress the information contained in a signal by representing it as a linear combination of a set of reference signals
We will show a set of sufficient conditions under which there is guaranteed to be an improvement in reconstruction error using a linear path orthogonal matching pursuit
We test our method on two data sets: one canonical set of images and one comprised of short-wave infrared (SWIR) maritime imagery
Summary
A FREQUENT goal within signal/image processing is to reconstruct or compress the information contained in a signal by representing it as a linear combination of a set of reference signals. We introduced “path-based” augmentation of the matching pursuit algorithm in [12], [13] as a compromise between orthonormal bases and overcomplete dictionaries In essence, this augmentation can be applied to any reconstruction algorithm that relies on the selection and sorting of high-similarity atoms during an analysis or identification phase. We illustrate that augmenting MP with our path-based modification leads to better general image reconstruction and denoising performance relative to traditional orthogonal matching pursuit (OMP) on canonical datasets using both structured (DCT) and unstructured learned (kSVD) dictionaries. We provide a proof of the existence of an atom on the Euclidean geodesic that is maximally similar to the signal as long as certain assumptions regarding the endpoints of the geodesic are satisfied Based on these results, we modify the algorithm to increase the probability that said conditions will be satisfied during each analysis stage of the algorithm.
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