English

Hardness and Approximation Results for $L_p$-Ball Constrained Homogeneous Polynomial Optimization Problems

Optimization and Control 2012-11-01 v1

Abstract

In this paper, we establish hardness and approximation results for various LpL_p-ball constrained homogeneous polynomial optimization problems, where p[2,]p \in [2,\infty]. Specifically, we prove that for any given d3d \ge 3 and p[2,]p \in [2,\infty], both the problem of optimizing a degree-dd homogeneous polynomial over the LpL_p-ball and the problem of optimizing a degree-dd multilinear form (regardless of its super-symmetry) over LpL_p-balls are NP-hard. On the other hand, we show that these problems can be approximated to within a factor of Ω((logn)(d2)/p/nd/21)\Omega((\log n)^{(d-2)/p} \big/ n^{d/2-1}) in deterministic polynomial time, where nn is the number of variables. We further show that with the help of randomization, the approximation guarantee can be improved to Ω((logn/n)d/21)\Omega((\log n/n)^{d/2-1}), which is independent of pp and is currently the best for the aforementioned problems. Our results unify and generalize those in the literature, which focus either on the quadratic case or the case where p2,p \in {2,\infty}. We believe that the wide array of tools used in this paper will have further applications in the study of polynomial optimization problems.

Keywords

Cite

@article{arxiv.1210.8284,
  title  = {Hardness and Approximation Results for $L_p$-Ball Constrained Homogeneous Polynomial Optimization Problems},
  author = {Ke Hou and Anthony Man-Cho So},
  journal= {arXiv preprint arXiv:1210.8284},
  year   = {2012}
}

Comments

37 pages

R2 v1 2026-06-21T22:30:44.442Z