A novel time-frequency technique for multicomponent signal denoising

Author

Oberlin, Thomas ; Meignen, Sylvain ; McLaughlin, Steve

Author_Institution

Lab. Jean Kuntzmann, Univ. of Grenoble, Grenoble, France

fYear

2013

fDate

9-13 Sept. 2013

Firstpage

1

Lastpage

5

Abstract

Multicomponent signals, i.e. superpositions of modulated waves, arise in many physical or biological systems. Exploiting the particular structure of these signals, denoising methods based on time-frequency distributions often outperform standard techniques such as those based on diagonal estimation or sparsity approaches. Recently, a simple denoising technique based on local integration in scale of the wavelet transform was proposed. In spite of its behaviour being better compared to classical techniques for medium noise levels, it does not perform so well in other cases. We propose here a method to improve denoising behaviour based on a more accurate mode reconstruction technique. The method is detailed for time-frequency representation given by short-time Fourier and continuous wavelet transforms, with the emphasis placed on their differences.

Keywords

Fourier analysis; signal denoising; time-frequency analysis; wavelet transforms; biological systems; diagonal estimation; local integration; modulated waves; multicomponent signal denoising; physical systems; short-time Fourier; time-frequency distributions; time-frequency technique; wavelet transform; Approximation methods; Continuous wavelet transforms; Frequency modulation; Noise reduction; Signal to noise ratio; Time-frequency analysis; Time-frequency; denoising; multicomponent signals; ridge; synchrosqueezing;

fLanguage

English

Publisher

ieee

Conference_Titel

Signal Processing Conference (EUSIPCO), 2013 Proceedings of the 21st European

Conference_Location

Marrakech

Type

conf

Filename

6811607