Complexity and algorithms for injective edge-coloring in graphs

Abstract

An injective k-edge-coloring of a graph G is an assignment of colors, i.e. integers in \1, … , k\, to the edges of G such that any two edges each incident with one distinct endpoint of a third edge, receive distinct colors. The problem of determining whether such a k-coloring exists is called k-INJECTIVE EDGE-COLORING. We show that 3-INJECTIVE EDGE-COLORING is NP-complete, even for triangle-free cubic graphs, planar subcubic graphs of arbitrarily large girth, and planar bipartite subcubic graphs of girth~6. 4-INJECTIVE EDGE-COLORING remains NP-complete for cubic graphs. For any k≥ 45, we show that k-INJECTIVE EDGE-COLORING remains NP-complete even for graphs of maximum degree at most 53k. In contrast with these negative results, we show that k is linear-time solvable on graphs of bounded treewidth. Moreover, we show that all planar bipartite subcubic graphs of girth at least~16 are injectively 3-edge-colorable. In addition, any graph of maximum degree at most k/2 is injectively k-edge-colorable.