A Polynomial-Time Approximation Algorithm for Complete Interval Minors

Abstract

As shown by Robertson and Seymour, deciding whether the complete graph Kt is a minor of an input graph G is a fixed parameter tractable problem when parameterized by t. From the approximation viewpoint, the gap to fill is quite large, as there is no PTAS for finding the largest complete minor unless P = NP, whereas a polytime O( n)-approximation algorithm was given by Alon, Lingas and Wahl\'en. We investigate the complexity of finding Kt as interval minor in ordered graphs (i.e. graphs with a linear order on the vertices, in which intervals are contracted to form minors). Our main result is a polytime f(t)-approximation algorithm, where f is triply exponential in t but independent of n. The algorithm is based on delayed decompositions and shows that ordered graphs without a Kt interval minor can be constructed via a bounded number of three operations: closure under substitutions, edge union, and concatenation of a stable set. As a byproduct, graphs avoiding Kt as an interval minor have bounded chromatic number.