English

Almost-Optimal Local-Search Methods for Sparse Tensor PCA

Statistics Theory 2025-06-12 v1 Data Structures and Algorithms Machine Learning Statistics Theory

Abstract

Local-search methods are widely employed in statistical applications, yet interestingly, their theoretical foundations remain rather underexplored, compared to other classes of estimators such as low-degree polynomials and spectral methods. Of note, among the few existing results recent studies have revealed a significant "local-computational" gap in the context of a well-studied sparse tensor principal component analysis (PCA), where a broad class of local Markov chain methods exhibits a notable underperformance relative to other polynomial-time algorithms. In this work, we propose a series of local-search methods that provably "close" this gap to the best known polynomial-time procedures in multiple regimes of the model, including and going beyond the previously studied regimes in which the broad family of local Markov chain methods underperforms. Our framework includes: (1) standard greedy and randomized greedy algorithms applied to the (regularized) posterior of the model; and (2) novel random-threshold variants, in which the randomized greedy algorithm accepts a proposed transition if and only if the corresponding change in the Hamiltonian exceeds a random Gaussian threshold-rather that if and only if it is positive, as is customary. The introduction of the random thresholds enables a tight mathematical analysis of the randomized greedy algorithm's trajectory by crucially breaking the dependencies between the iterations, and could be of independent interest to the community.

Keywords

Cite

@article{arxiv.2506.09959,
  title  = {Almost-Optimal Local-Search Methods for Sparse Tensor PCA},
  author = {Max Lovig and Conor Sheehan and Konstantinos Tsirkas and Ilias Zadik},
  journal= {arXiv preprint arXiv:2506.09959},
  year   = {2025}
}
R2 v1 2026-07-01T03:11:43.394Z