Pattern-based ILP models for the one-dimensional cutting stock problem with setup cost

• Published in: Journal of combinatorial optimization Vol. 44; no. 1; pp. 557 - 582
• Main Authors: Martin, Mateus, Yanasse, Horacio Hideki, Salles-Neto, Luiz Leduíno
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.08.2022; Springer Nature B.V
• Subjects: Combinatorics; Convex and Discrete Geometry; Cutlery; Cutting equipment; Integer programming; Iterative methods; Knives; Linear programming; Machine tools; Mathematical Modeling and Industrial Mathematics; Mathematics; Mathematics and Statistics; Operations Research/Decision Theory; Optimization; Pareto optimum; Polynomials; Production costs; Theory of Computation; Upper bounds; Integer linear programming; Setup cost; Cutting and packing; Multi-objective optimization; Cutting stock problem
• ISSN: 1382-6905; 1573-2886
• DOI: 10.1007/s10878-022-00848-z

The one-dimensional cutting stock problem with setup cost (CSP-S) is a cutting problem that seeks a cutting plan with a minimum number of objects and a minimum number of different patterns. This problem gains relevance in manufacturing settings, where time consuming operations to set up the knives of the cutting machine for the new patterns increases production costs. In this paper, we aim at solving the bi-objective CSP-S that analyzes the trade-offs between the number of objects and the number of patterns. We first derive an upper bound on the maximum frequency of a pattern in the cutting plan. Then, we propose a pattern-based pseudo-polynomial integer linear programming (ILP) formulation for the CSP-S. To obtain the Pareto optimal frontier, this formulation is embedded into a straightforward framework which solves the problem of minimizing the number of objects subject to a limited number of patterns in an iterative manner. Since we are not aware of other approaches in the literature that have solved the bi-objective CSP-S exactly, we derive an ILP formulation based on Harjunkoski et al. (Comput Chem Eng 20:121–126, 1996. https://doi.org/10.1016/0098-1354(96)00031-2) into this framework to provide an alternative exact approach. The results of the computational experiments using a general-purpose ILP solver indicated that the approaches are proper for instances with solutions characterized by a moderate number of objects and a few patterns in the Pareto optimal frontier.