On the local time of random processes in random scenery

Abstract

Random walks in random scenery are processes defined by Zn:=Σk=1nX1+...+Xk, where basically (Xk,k 1) and (y,y∈ Z) are two independent sequences of i.i.d. random variables. We assume here that X1 is -valued, centered and with finite moments of all orders. We also assume that 0 is -valued, centered and square integrable. In this case H. Kesten and F. Spitzer proved that (n-3/4Z[nt],t 0) converges in distribution as n ∞ toward some self-similar process (t,t 0) called Brownian motion in random scenery. In a previous paper, we established that P(Zn=0) behaves asymptotically like a constant times n-3/4, as n ∞. We extend here this local limit theorem: we give a precise asymptotic result for the probability for Z to return to zero simultaneously at several times. As a byproduct of our computations, we show that admits a bi-continuous version of its local time process which is locally H\"older continuous of order 1/4-δ and 1/6-δ, respectively in the time and space variables, for any δ>0. In particular, this gives a new proof of the fact, previously obtained by Khoshnevisan, that the level sets of have Hausdorff dimension a.s. equal to 1/4. We also get the convergence of every moment of the normalized local time of Z toward its continuous counterpart.