A parking function of length n is a sequence (b 1 , b 2 , . . . , b n ) of nonnegative integers for which there is a permutation π ∈ S n so that 0 ≤ b π(i) < i for all i. A well-known result about parking functions is that the polynomial P n (q), which enumerates the complements of parking functions by the sum of their terms, is the generating function for the number of connected graphs by the number of excess edges when evaluated at 1 + q. In this paper we extend this result to arbitrary connected graphs G. In general the polynomial that encodes information about subgraphs of G is the Tutte polynomial t G (x, y), which is the generating function for two parameters, namely the internal and external activities, associated with the spanning trees of G. We define G-multiparking functions, which generalize the G-parking functions that Postnikov and Shapiro introduced in the study of certain quotients of the polynomial ring. We construct a family of algorithmic bijections between the spanning forests of a graph G and the G-multiparking functions. In particular, the bijection induced by the breadth-first search leads to a new characterization of external activity, and hence a representation of Tutte polynomial by the reversed sum of G-multiparking functions.
There are several combinatorial objects that are known to be in bijection to the spanning trees of a graph G. These objects include G-parking functions, critical configurations of G, and descending traversals of G. In this paper, we extend the bijections to generalizations of all three objects.
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