Exact and Approximation Algorithms for the Maximum Constraint Satisfaction Problem over the Point Algebra
We study the constraint satisfaction problem over the point algebra.
In this problem, an instance consists of a set of variables and a set of binary constraints of forms (x < y), (x <= y), (x \neq y) or (x = y). Then, the objective is to assign integers to variables so as to satisfy as many constraints as possible.This problem contains many important problems such as Correlation Clustering, Maximum Acyclic Subgraph, and Feedback Arc Set.
We first give an exact algorithm that runs in O^*(3^{\frac{log 5}{log 6}n}) time, which improves the previous best O^*(3^n) obtained by a standard dynamic programming.
Our algorithm combines the dynamic programming with the split-and-list technique. The split-and-list technique involves matrix products and we make use of sparsity of matrices to speed up the computation.
As for approximation, we give a 0.4586-approximation algorithm when the objective is maximizing the number of satisfied constraints, and give an O(log n log log n)-approximation algorithm when the objective is minimizing the number of unsatisfied constraints.
Constraint Satisfaction Problems
Point Algebra
Exact Algorithms
Approximation Algorithms
127-138
Regular Paper
Yoichi
Iwata
Yoichi Iwata
Yuichi
Yoshida
Yuichi Yoshida
10.4230/LIPIcs.STACS.2013.127
Creative Commons Attribution-NoDerivs 3.0 Unported license
https://creativecommons.org/licenses/by-nd/3.0/legalcode