English

A Computational Study of Perspective Cuts

Optimization and Control 2021-03-18 v1

Abstract

The benefits of cutting planes based on the perspective function are well known for many specific classes of mixed-integer nonlinear programs with on/off structures. However, we are not aware of any empirical studies that evaluate their applicability and computational impact over large, heterogeneous test sets in general-purpose solvers. This paper provides a detailed computational study of perspective cuts within a linear programming based branch-and-cut solver for general mixed-integer nonlinear programs. Within this study, we extend the applicability of perspective cuts from convex to nonconvex nonlinearities. This generalization is achieved by applying a perspective strengthening to valid linear inequalities which separate solutions of linear relaxations. The resulting method can be applied to any constraint where all variables appearing in nonlinear terms are semi-continuous and depend on at least one common indicator variable. Our computational experiments show that adding perspective cuts for convex constraints yields a consistent improvement of performance, and adding perspective cuts for nonconvex constraints reduces branch-and-bound tree sizes and strengthens the root node relaxation, but has no significant impact on the overall mean time.

Keywords

Cite

@article{arxiv.2103.09573,
  title  = {A Computational Study of Perspective Cuts},
  author = {Ksenia Bestuzheva and Ambros Gleixner and Stefan Vigerske},
  journal= {arXiv preprint arXiv:2103.09573},
  year   = {2021}
}
R2 v1 2026-06-24T00:16:12.232Z