Matching Pursuit with Asymmetric Functions for Signal Decomposition and Parameterization

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2015 Jun 27

PMID 26115480

Citations 3

Authors

Tomasz Spustek

Wieslaw Wiktor Jedrzejczak

Katarzyna Joanna Blinowska

Affiliations

Soon will be listed here.

Abstract

The method of adaptive approximations by Matching Pursuit makes it possible to decompose signals into basic components (called atoms). The approach relies on fitting, in an iterative way, functions from a large predefined set (called dictionary) to an analyzed signal. Usually, symmetric functions coming from the Gabor family (sine modulated Gaussian) are used. However Gabor functions may not be optimal in describing waveforms present in physiological and medical signals. Many biomedical signals contain asymmetric components, usually with a steep rise and slower decay. For the decomposition of this kind of signal we introduce a dictionary of functions of various degrees of asymmetry--from symmetric Gabor atoms to highly asymmetric waveforms. The application of this enriched dictionary to Otoacoustic Emissions and Steady-State Visually Evoked Potentials demonstrated the advantages of the proposed method. The approach provides more sparse representation, allows for correct determination of the latencies of the components and removes the "energy leakage" effect generated by symmetric waveforms that do not sufficiently match the structures of the analyzed signal. Additionally, we introduced a time-frequency-amplitude distribution that is more adequate for representation of asymmetric atoms than the conventional time-frequency-energy distribution.

Citing Articles

Optimal Scale-Invariant Wavelet Representation and Filtering of Human Otoacoustic Emissions.

Moleti A J Assoc Res Otolaryngol. 2024; 25(4):329-340.

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Multivariate Matching Pursuit Decomposition and Normalized Gabor Entropy for Quantification of Preictal Trends in Epilepsy.

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Otoacoustic emissions from ears with spontaneous activity behave differently to those without: Stronger responses to tone bursts as well as to clicks.

Jedrzejczak W, Kochanek K, Skarzynski H PLoS One. 2018; 13(2):e0192930.

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