Logarithmic terms in discrete heat kernel expansions in the quadrant

  • Andrew Elvey Price

    Université de Tours and Université d’Orléans, CNRS, Tours, France
  • Andreas Nessmann

    Université de Tours and Université d’Orléans, CNRS, Tours, France; Technische Universität Wien, Vienna, Austria
  • Kilian Raschel

    Université d’Angers, Angers, France
Logarithmic terms in discrete heat kernel expansions in the quadrant cover
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Abstract

In the context of lattice walk enumeration in cones, we consider the number of walks in the quarter plane with fixed starting and ending points, prescribed step-set, and given length. After renormalisation, this number may be interpreted as a discrete heat kernel in the quadrant. We propose a new method to compute complete asymptotic expansions of these numbers of walks as their length tends to infinity, based on two main ingredients: explicit expressions for the underlying generating functions in terms of elliptic Jacobi theta functions along with a duality known as Jacobi transformation. This duality allows us to pass from a classical Taylor expansion of the series to an expansion at the critical point of the model. We work through two examples. First, we present our approach on the well-known Kreweras model, which is algebraic, and show how to obtain a complete asymptotic expansion in this case. We then consider a more generic (so-called infinite group) model and find the associated complete asymptotic expansion. In this second case, we prove the existence of logarithmic terms in the asymptotic expansion, and we relate the coefficients appearing in the expansion to polyharmonic functions. To our knowledge, this is the first time that logarithmic terms have been observed in the asymptotics of a class of lattice walks confined to a quadrant.

Cite this article

Andrew Elvey Price, Andreas Nessmann, Kilian Raschel, Logarithmic terms in discrete heat kernel expansions in the quadrant. Ann. Inst. Henri Poincaré Comb. Phys. Interact. (2024), published online first

DOI 10.4171/AIHPD/199