English

Short-and-Sparse Deconvolution -- A Geometric Approach

Signal Processing 2019-10-02 v2 Machine Learning Image and Video Processing Optimization and Control Machine Learning

Abstract

Short-and-sparse deconvolution (SaSD) is the problem of extracting localized, recurring motifs in signals with spatial or temporal structure. Variants of this problem arise in applications such as image deblurring, microscopy, neural spike sorting, and more. The problem is challenging in both theory and practice, as natural optimization formulations are nonconvex. Moreover, practical deconvolution problems involve smooth motifs (kernels) whose spectra decay rapidly, resulting in poor conditioning and numerical challenges. This paper is motivated by recent theoretical advances, which characterize the optimization landscape of a particular nonconvex formulation of SaSD. This is used to derive a provableprovable algorithm which exactly solves certain non-practical instances of the SaSD problem. We leverage the key ideas from this theory (sphere constraints, data-driven initialization) to develop a practicalpractical algorithm, which performs well on data arising from a range of application areas. We highlight key additional challenges posed by the ill-conditioning of real SaSD problems, and suggest heuristics (acceleration, continuation, reweighting) to mitigate them. Experiments demonstrate both the performance and generality of the proposed method.

Keywords

Cite

@article{arxiv.1908.10959,
  title  = {Short-and-Sparse Deconvolution -- A Geometric Approach},
  author = {Yenson Lau and Qing Qu and Han-Wen Kuo and Pengcheng Zhou and Yuqian Zhang and John Wright},
  journal= {arXiv preprint arXiv:1908.10959},
  year   = {2019}
}

Comments

*YL and QQ contributed equally to this work; 30 figures, 45 pages; This version: added an experiment comparing with other methods, corrected typos and added references

R2 v1 2026-06-23T10:59:26.883Z