On the Discrete Fr\'echet Distance in a Graph

Abstract

The Fr\'echet distance is a well-studied similarity measure between curves that is widely used throughout computer science. Motivated by applications where curves stem from paths and walks on an underlying graph (such as a road network), we define and study the Fr\'echet distance for paths and walks on graphs. When provided with a distance oracle of G with O(1) query time, the classical quadratic-time dynamic program can compute the Fr\'echet distance between two walks P and Q in a graph G in O(|P| · |Q|) time. We show that there are situations where the graph structure helps with computing Fr\'echet distance: when the graph G is planar, we apply existing (approximate) distance oracles to compute a (1+)-approximation of the Fr\'echet distance between any shortest path P and any walk Q in O(|G| |G| / + |P| + |Q| ) time. We generalise this result to near-shortest paths, i.e. -straight paths, as we show how to compute a (1+)-approximation between a -straight path P and any walk Q in O(|G| |G| / + |P| + |Q| ) time. Our algorithmic results hold for both the strong and the weak discrete Fr\'echet distance over the shortest path metric in G. Finally, we show that additional assumptions on the input, such as our assumption on path straightness, are indeed necessary to obtain truly subquadratic running time. We provide a conditional lower bound showing that the Fr\'echet distance, or even its 1.01-approximation, between arbitrary paths in a weighted planar graph cannot be computed in O((|P|·|Q|)1-δ) time for any δ > 0 unless the Orthogonal Vector Hypothesis fails. For walks, this lower bound holds even when G is planar, unit-weight and has O(1) vertices.