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Greedy lattice paths with general weights

Yinshan Chang, Anqi Zheng

Abstract

Let $\{X_{v}:v\in\mathbb{Z}^d\}$ be i.i.d. random variables. Let $S(π)=\sum_{v\inπ}X_v$ be the weight of a self-avoiding lattice path $π$. Let \[M_n=\max\{S(π):π\text{ has length }n\text{ and starts from the origin}\}.\] We are interested in the asymptotics of $M_n$ as $n\to\infty$. This model is closely related to the first passage percolation when the weights $\{X_v:v\in\mathbb{Z}^d\}$ are non-positive and it is closely related to the last passage percolation when the weights $\{X_v,v\in\mathbb{Z}^d\}$ are non-negative. For general weights, this model could be viewed as an interpolation between first passage models and last passage models. Besides, this model is also closely related to a variant of the position of right-most particles of branching random walks. Under the two assumptions that $\existsα>0$, $E(X_0^{+})^d(\log^{+}X_0^{+})^{d+α}<+\infty$ and that $E[X_0^{-}]<+\infty$, we prove that there exists a finite real number $M$ such that $M_n/n$ converges to a deterministic constant $M$ in $L^{1}$ as $n$ tends to infinity. And under the stronger assumptions that $\existsα>0$, $E(X_0^{+})^d(\log^{+}X_0^{+})^{d+α}<+\infty$ and that $E[(X_0^{-})^4]<+\infty$, we prove that $M_n/n$ converges to the same constant $M$ almost surely as $n$ tends to infinity.

Greedy lattice paths with general weights

Abstract

Let be i.i.d. random variables. Let be the weight of a self-avoiding lattice path . Let We are interested in the asymptotics of as . This model is closely related to the first passage percolation when the weights are non-positive and it is closely related to the last passage percolation when the weights are non-negative. For general weights, this model could be viewed as an interpolation between first passage models and last passage models. Besides, this model is also closely related to a variant of the position of right-most particles of branching random walks. Under the two assumptions that , and that , we prove that there exists a finite real number such that converges to a deterministic constant in as tends to infinity. And under the stronger assumptions that , and that , we prove that converges to the same constant almost surely as tends to infinity.
Paper Structure (3 sections, 2 theorems, 49 equations)

This paper contains 3 sections, 2 theorems, 49 equations.

Key Result

Theorem 1.1

Let $x^{+}=\max(x,0)$, $x^{-}=\max(-x,0)$, $\log^{+}(x)=\max(\log x,0)$. Assume that there exists $\alpha>0$ such that and that $E(X_0^{-})<+\infty$. Then, there exists $M\in(-\infty,+\infty)$ such that If we further assume that $E((X_0^{-})^4)<+\infty$, then

Theorems & Definitions (7)

  • Theorem 1.1
  • Remark 1.1
  • Lemma 2.1
  • Remark 2.1
  • proof : Proof of Lemma \ref{['lem: key lemma']}
  • Conjecture 1
  • Conjecture 2