Convex bounds for last passage percolation with dependent identically distributed weights
Abstract
On the Z2 lattice, vertices are assigned random weights W(i,j). The point-to-point last passage percolation (LPP) time SM,N+1-M between (1,1) and (M,N+1-M) is the maximum total weight among all upward/right-oriented paths connecting the two. Point-to-line LPP time RN is the maximum of these maximal total weights over M. Asymptotic distributions and fluctuations of these LPP times have been studied for i.i.d. weights. The current study deals with identically distributed but not necessarily independent weights, and maximizes LPP times in the sense of increasing convex dominance. In particular, maximal expected LPP times are identified, in the class of all weight couplings with a given marginal distribution. For the case of mean-1 exponentially distributed weights, there is a coupling for which RN is the shifted exponential variable RN* = N W(1,1) + (N!), such that E[(RN)] E[(RN*)] for all couplings and all convex non-decreasing functions for which these expectations are well defined. In contrast to RN* N= W(1,1)+(N!) N, with variance 1 and mean diverging to ∞ like (N), RN N converges a.s. to 2 for the commonly studied i.i.d. weights. As for small LPP, expected LPP time is at least NE[W(1,1)], attained by assigning to each anti-diagonal identical weights. The minimal possible variance of RN is asymptotically zero for exponential weights.
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