English

Weighed l1 on the simplex: Compressive sensing meets locality

Signal Processing 2024-08-05 v2 Information Theory Machine Learning math.IT Optimization and Control

Abstract

Sparse manifold learning algorithms combine techniques in manifold learning and sparse optimization to learn features that could be utilized for downstream tasks. The standard setting of compressive sensing can not be immediately applied to this setup. Due to the intrinsic geometric structure of data, dictionary atoms might be redundant and do not satisfy the restricted isometry property or coherence condition. In addition, manifold learning emphasizes learning local geometry which is not reflected in a standard 1\ell_1 minimization problem. We propose weighted 0\ell_0 and weighted 1\ell_1 metrics that encourage representation via neighborhood atoms suited for dictionary based manifold learning. Assuming that the data is generated from Delaunay triangulation, we show the equivalence of weighted 0\ell_0 and weighted 1\ell_1. We discuss an optimization program that learns the dictionaries and sparse coefficients and demonstrate the utility of our regularization on synthetic and real datasets.

Keywords

Cite

@article{arxiv.2104.13894,
  title  = {Weighed l1 on the simplex: Compressive sensing meets locality},
  author = {Abiy Tasissa and Pranay Tankala and Demba Ba},
  journal= {arXiv preprint arXiv:2104.13894},
  year   = {2024}
}

Comments

7 pages, 2 figures. The proof of theorem 1 in v1 does not hold true in general without additional assumptions. This version fixes this problem. For more details, we refer the interested reader to arXiv:2012.02134 which is the journal version of the workshop paper v1

R2 v1 2026-06-24T01:36:27.053Z