A double-pivot simplex algorithm and its upper bounds of the iteration numbers
Abstract
In this paper, a double-pivot simplex method is proposed. Two upper bounds of iteration numbers are derived. Applying one of the bounds to some special linear programming (LP) problems, such as LP with a totally unimodular matrix and Markov Decision Problem (MDP) with a fixed discount rate, indicates that the double-pivot simplex method solves these problems in a strongly polynomial time. A variant of Klee-Minty cube is used to show that the estimated bounds of the iteration numbers are very tight. Numerical test on three variants of Klee-Minty cubes is performed for the problems with sizes as big as constraints and variables. Dantzig's simplex method cannot handle Klee-Minty cube problem with constraints because it needs about iterations. But the proposed algorithm performs extremely good for all three variants.
Cite
@article{arxiv.1910.10097,
title = {A double-pivot simplex algorithm and its upper bounds of the iteration numbers},
author = {Yaguang Yang},
journal= {arXiv preprint arXiv:1910.10097},
year = {2020}
}
Comments
22 pages, 4 figures