A domination algorithm for \0,1\-instances of the travelling salesman problem

Abstract

We present an approximation algorithm for \0,1\-instances of the travelling salesman problem which performs well with respect to combinatorial dominance. More precisely, we give a polynomial-time algorithm which has domination ratio 1-n-1/29. In other words, given a \0,1\-edge-weighting of the complete graph Kn on n vertices, our algorithm outputs a Hamilton cycle H* of Kn with the following property: the proportion of Hamilton cycles of Kn whose weight is smaller than that of H* is at most n-1/29. Our analysis is based on a martingale approach. Previously, the best result in this direction was a polynomial-time algorithm with domination ratio 1/2-o(1) for arbitrary edge-weights. We also prove a hardness result showing that, if the Exponential Time Hypothesis holds, there exists a constant C such that n-1/29 cannot be replaced by (-( n)C) in the result above.