Parametric Shortest Paths in Planar Graphs

Abstract

We construct a family of planar graphs \Gn\n≥ 4, where Gn has n vertices including a source vertex s and a sink vertex t, and edge weights that change linearly with a parameter λ such that, as λ varies in (-∞,+∞), the piece-wise linear cost of the shortest path from s to t has n( n) pieces. This shows that lower bounds obtained earlier by Carstensen (1983) and Mulmuley \& Shah (2001) for general graphs also hold for planar graphs, thereby refuting a conjecture of Nikolova (2009). Gusfield (1980) and Dean (2009) showed that the number of pieces for every n-vertex graph with linear edge weights is n n + O(1). We generalize this result in two ways. (i) If the edge weights vary as a polynomial of degree at most d, then the number of pieces is n n + (α(n)+O(1))d, where α(n) is the slow growing inverse Ackermann function. (ii) If the edge weights are linear forms of three parameters, then the number of pieces, appropriately defined for R3, is n( n)2+O( n).