Flipping Non-Crossing Spanning Trees

Abstract

For a set P of n points in general position in the plane, the flip graph F(P) has a vertex for each non-crossing spanning tree on P and an edge between any two spanning trees that can be transformed into each other by one edge flip. The diameter diam(F(P)) of this graph is subject of intensive study. For points in general position, it is between 3n/2-5 and 2n-4, with no improvement for 25 years. For points in convex position, it lies between 3n/2 - 5 and ≈1.95n, where the lower bound was conjectured to be tight up to an additive constant and the upper bound is a recent breakthrough improvement over several bounds of the form 2n-o(n). In this work, we provide new upper and lower bounds on diam(F(P)), mainly focusing on points in convex position. We show 14n/9 - O(1) diam(F(P)) 5n/3 - 3, by this disproving the conjectured upper bound of 3n/2 for convex position, and relevantly improving both the long-standing lower bound for general position and the recent new upper bound for convex position. We complement these by showing that if one of T,T' has at most two boundary edges, then dist(T,T') 2d/2 < 3n/2, where d = |T-T'| is the number of edges in one tree that are not in the other. To prove both the upper and the lower bound, we introduce a new powerful tool. Specifically, we convert the flip distance problem for given T,T' to the problem of a largest acyclic subset in an associated conflict graph H(T,T'). In fact, this method is powerful enough to give an equivalent formulation of the diameter of F(P) for points P in convex position up to lower-order terms. As such, conflict graphs are likely the key to a complete resolution of this and possibly also other reconfiguration problems.

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