Polyhedral approximation in mixed-integer convex optimization

Author(s)

Yamangil, Emre; Bent, Russell; Lubin, Miles C; Vielma Centeno, Juan Pablo

Abstract

Generalizing both mixed-integer linear optimization and convex optimization, mixed-integer convex optimization possesses broad modeling power but has seen relatively few advances in general-purpose solvers in recent years. In this paper, we intend to provide a broadly accessible introduction to our recent work in developing algorithms and software for this problem class. Our approach is based on constructing polyhedral outer approximations of the convex constraints, resulting in a global solution by solving a finite number of mixed-integer linear and continuous convex subproblems. The key advance we present is to strengthen the polyhedral approximations by constructing them in a higher-dimensional space. In order to automate this extended formulation we rely on the algebraic modeling technique of disciplined convex programming (DCP), and for generality and ease of implementation we use conic representations of the convex constraints. Although our framework requires a manual translation of existing models into DCP form, after performing this transformation on the MINLPLIB2 benchmark library we were able to solve a number of unsolved instances and on many other instances achieve superior performance compared with state-of-the-art solvers like Bonmin, SCIP, and Artelys Knitro.

Date issued

2017-09

URI

http://hdl.handle.net/1721.1/119247

Department

Sloan School of Management

Journal

Mathematical Programming

Publisher

Springer-Verlag

Citation

Lubin, Miles, Emre Yamangil, Russell Bent, and Juan Pablo Vielma. “Polyhedral Approximation in Mixed-Integer Convex Optimization.” Mathematical Programming 172, no. 1–2 (September 14, 2017): 139–168.

Version: Author's final manuscript

ISSN

0025-5610

1436-4646