Integer Programming for Classifying Orthogonal Arrays Article Swipe

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Integer programming Integer (computer science) Mathematics Combinatorics Isomorphism (crystallography) Orthogonal array Class (philosophy) Pruning Equivalence (formal languages) Set (abstract data type) Linear programming Discrete mathematics Algorithm Computer science Artificial intelligence Statistics Taguchi methods Programming language Crystallography Agronomy Biology Chemistry Crystal structure

Dursun A. Bulutoglu , Kenneth J. Ryan ·

YOU? · · 2015 · Open Access · · DOI: https://doi.org/10.48550/arxiv.1501.02281 · OA: W2736258942

Classifying orthogonal arrays is a well known important class of problems that asks for finding all non-isomorphic, non-negative integer solutions to a class of systems of constraints. Solved instances are scarce. We develop two new methods based on finding all non-isomorphic solutions of two novel integer linear programming formulations for classifying all non-isomorphic OA(N,k,s,t) given a set of all non-isomorphic OA(N,k-1,s,t). We also establish the concept of orthogonal design equivalence of OA(N,k,2,t) to reduce the number of integer linear programs (ILPs) whose all non-isomorphic solutions need to be enumerated by our methods. For each ILP, we determine the largest group of permutations that can be exploited with the branch-and-bound (B&B) with isomorphism pruning algorithm of Margot [Discrete Optim~4 (2007), 40-62] without losing isomorphism classes of OA(N,k,2,t). Our contributions brought the classifications of all non-isomorphic OA(160,k,2,4) for k=9,10 and OA(176,k,2,4) for k=5,6,7,8,9,10 within computational reach. These are the smallest s=2, t=4 cases for which classification results are not available in the literature.