English

Connecting Max-entropy With Computational Geometry, LP And SDP

Optimization and Control 2026-01-08 v1

Abstract

We consider the well-known max-(relative) entropy problem Θ\Theta(y) = infQ\llP DKL(Q P ) with Kullback-Leibler divergence on a domain Ω\Omega \subset R d , and with ''moment'' constraints h dQ = y, y \in R m . We show that when m \le d, Θ\Theta is the Cram{\'e}r transform of a function v that solves a simply related computational geometry problem. Also, and remarkably, to the canonical LP: min x\ge0 {c T x\,: A x = y}, with A \in R mxd , one may associate a max-entropy problem with a suitably chosen reference measure P on R d + and linear mapping h(x) = Ax, such that its associated perspective function ϵ\epsilon Θ\Theta(y/ϵ\epsilon) is the optimal value of the log-barrier formulation (with parameter ϵ\epsilon) of the dual LP (and so it converges to the LP optimal value as ϵ\epsilon \rightarrow 0). An analogous result also holds for the canonical SDP: min X 0 { C, X\,: A(X) = y }.

Keywords

Cite

@article{arxiv.2601.03759,
  title  = {Connecting Max-entropy With Computational Geometry, LP And SDP},
  author = {Jean B Lasserre},
  journal= {arXiv preprint arXiv:2601.03759},
  year   = {2026}
}
R2 v1 2026-07-01T08:54:02.777Z