English

Tridiagonal Maximum-Entropy Sampling and Tridiagonal Masks

Optimization and Control 2023-02-07 v2

Abstract

The NP-hard maximum-entropy sampling problem (MESP) seeks a maximum (log-)determinant principal submatrix, of a given order, from an input covariance matrix CC. We give an efficient dynamic-programming algorithm for MESP when CC (or its inverse) is tridiagonal and generalize it to the situation where the support graph of CC (or its inverse) is a spider graph with a constant number of legs (and beyond). We give a class of arrowhead covariance matrices CC for which a natural greedy algorithm solves MESP. A \emph{mask} MM for MESP is a correlation matrix with which we pre-process CC, by taking the Hadamard product MCM\circ C. Upper bounds on MESP with MCM\circ C give upper bounds on MESP with CC. Most upper-bounding methods are much faster to apply, when the input matrix is tridiagonal, so we consider tridiagonal masks MM (which yield tridiagonal MCM\circ C). We make a detailed analysis of such tridiagonal masks, and develop a combinatorial local-search based upper-bounding method that takes advantage of fast computations on tridiagonal matrices.

Keywords

Cite

@article{arxiv.2112.12814,
  title  = {Tridiagonal Maximum-Entropy Sampling and Tridiagonal Masks},
  author = {Hessa Al-Thani and Jon Lee},
  journal= {arXiv preprint arXiv:2112.12814},
  year   = {2023}
}
R2 v1 2026-06-24T08:30:20.652Z