Parking functions for trees and mappings

Abstract

We apply the concept of parking functions to rooted labelled trees and functional digraphs of mappings (i.e., functions f : [n] [n]) by considering the nodes as parking spaces and the directed edges as one-way streets: Each driver has a preferred parking space and starting with this node he follows the edges in the graph until he either finds a free parking space or all reachable parking spaces are occupied. If all drivers are successful we speak about a parking function for the tree or mapping. We transfer well-known characterizations of parking functions to trees and mappings. Especially, this yields bounds and characterizations of the extremal cases for the number of parking functions with m drivers for a given tree T of size n. Via analytic combinatorics techniques we study the total number Fn,m and Mn,m of tree and mapping parking functions, respectively, i.e., the number of pairs (T,s) (or (f,s)), with T a size-n tree (or f : [n] [n] an n-mapping) and s ∈ [n]m a parking function for T (or for f) with m drivers, yielding exact and asymptotic results. We describe the phase change behaviour appearing at m=n2 for Fn,m and Mn,m, respectively, and relate it to previously studied combinatorial contexts. Moreover, we give a bijective proof of the occurring relation n Fn,m = Mn,m.