论文信息 - A computational study of using preprocessing and stronger formulations to solve large general fixed charge problems

A computational study of using preprocessing and stronger formulations to solve large general fixed charge problems

Abstract The application of traditional branch-and-bound (B&B) procedures to the standard formulation of the general fixed charge problem (GFCP) has not proven to be an acceptable approach to solving this well-known problem. It has been suggested by various authors that preprocessing the data and/or adding constraints to the GFCP might lead to improved B&B performance. In this paper, we present extensive computational results to test these hypotheses using the M PSX/MIP/370 package. The results demonstrate that while preprocessing the data is not always effective, simple constraints may be added to the problem allowing us to solve randomly generated GFCPs that are significantly larger than any previously reported in the literature. Results arc also presented which give insight into the effectiveness of a frequently used heuristic for the GFCP.

Patrick G. McKeown | Cliff T. Ragsdale

[1] P. McKeown. A branch‐and‐bound algorithm for solving fixed charge problems , 1981 .

[2] W. Walker. A Heuristic Adjacent Extreme Point Algorithm for the Fixed Charge Problem , 1976 .

[3] S. Selcuk Erenguc,et al. Improved penalties for fixed cost linear programs using Lagrangean relaxation , 1986 .

[4] Patrick McKeown. Technical Note - A Vertex Ranking Procedure for Solving the Linear Fixed-Charge Problem , 1975, Oper. Res..

[5] Laurence A. Wolsey,et al. Integer and Combinatorial Optimization , 1988 .

[6] Fred W. Glover,et al. A New Optimization Method for Large Scale Fixed Charge Transportation Problems , 1981, Oper. Res..

[7] D. I. Steinberg,et al. The fixed charge problem , 1970 .

[8] J. Kennington. The Fixed-Charge Transportation Problem: A Computational Study with a Branch-and-Bound Code , 1976 .

[9] J. Kennington,et al. A New Branch-and-Bound Algorithm for the Fixed-Charge Transportation Problem , 1976 .

[10] Hamdy A. Taha. Concave minimization over a convex polyhedron , 1973 .

[11] S. S. Erenguc,et al. The interactive fixed charge linear programming problem , 1986 .

[12] Gerald G. Brown,et al. Design and operation of a multicommodity production/distribution system using primal goal decomposition , 1987 .