ALSO-X and ALSO-X+: Better Convex Approximations for Chance Constrained Programs

• Published in: Operations research Vol. 70; no. 6; pp. 3581 - 3600
• Main Authors: Jiang, Nan, Xie, Weijun
• Format: Journal Article
• Language: English
• Published: Linthicum INFORMS 01.11.2022; Institute for Operations Research and the Management Sciences
• Subjects: Approximation; bilevel optimization; chance constraint; Constraints; Convex analysis; CVaR; Decision making; distributionally robust; Operations research; Optimization; Probability; Risk levels; Robustness (mathematics); Upper bounds
• ISSN: 0030-364X; 1526-5463
• DOI: 10.1287/opre.2021.2225

In a chance constrained program (CCP), decision makers seek the best decision whose probability of violating the uncertainty constraints is within the prespecified risk level. As a CCP is often nonconvex and is difficult to solve to optimality, much effort has been devoted to developing convex inner approximations for a CCP, among which the conditional value-at-risk ( CVaR ) has been known to be the best for more than a decade. This paper studies and generalizes the ALSO - X , originally proposed by A hmed, L uedtke, SO ng, and X ie in 2017 , for solving a CCP. We first show that the ALSO - X resembles a bilevel optimization, where the upper-level problem is to find the best objective function value and enforce the feasibility of a CCP for a given decision from the lower-level problem, and the lower-level problem is to minimize the expectation of constraint violations subject to the upper bound of the objective function value provided by the upper-level problem. This interpretation motivates us to prove that when uncertain constraints are convex in the decision variables, ALSO - X always outperforms the CVaR approximation. We further show (i) sufficient conditions under which ALSO - X can recover an optimal solution to a CCP; (ii) an equivalent bilinear programming formulation of a CCP, inspiring us to enhance ALSO - X with a convergent alternating minimization method ( ALSO - X + ); and (iii) an extension of ALSO - X and ALSO - X + to distributionally robust chance constrained programs (DRCCPs) under the ∞ − Wasserstein ambiguity set. Our numerical study demonstrates the effectiveness of the proposed methods. Funding: This work was supported by the Division of Civil, Mechanical and Manufacturing Innovation [Grant 2046426]. Supplemental Material: The e-companion is available at https://doi.org/10.1287/opre.2021.2225 .