English

A "joint+marginal" approach to parametric polynomial optimization

Optimization and Control 2009-05-18 v1

Abstract

Given a compact parameter set YRpY\subset R^p, we consider polynomial optimization problems (Py(P_y) on RnR^n whose description depends on the parameter y\inYy\inY. We assume that one can compute all moments of some probability measure ϕ\phi on YY, absolutely continuous with respect to the Lebesgue measure (e.g. YY is a box or a simplex and ϕ\phi is uniformly distributed). We then provide a hierarchy of semidefinite relaxations whose associated sequence of optimal solutions converges to the moment vector of a probability measure that encodes all information about all global optimal solutions x(y)x^*(y) of PyP_y. In particular, one may approximate as closely as desired any polynomial functional of the optimal solutions, like e.g. their ϕ\phi-mean. In addition, using this knowledge on moments, the measurable function yxk(y)y\mapsto x^*_k(y) of the kk-th coordinate of optimal solutions, can be estimated, e.g. by maximum entropy methods. Also, for a boolean variable xkx_k, one may approximate as closely as desired its persistency ϕ({y:xk(y)=1})\phi(\{y:x^*_k(y)=1\}), i.e. the probability that in an optimal solution x(y)x^*(y), the coordinate xk(y)x^*_k(y) takes the value 1. At last but not least, from an optimal solution of the dual semidefinite relaxations, one provides a sequence of polynomial (resp. piecewise polynomial) lower approximations with L1(ϕ)L_1(\phi) (resp. almost uniform) convergence to the optimal value function.

Keywords

Cite

@article{arxiv.0905.2497,
  title  = {A "joint+marginal" approach to parametric polynomial optimization},
  author = {Jean B. Lasserre},
  journal= {arXiv preprint arXiv:0905.2497},
  year   = {2009}
}
R2 v1 2026-06-21T13:02:36.023Z