Spectral gap properties for linear random walks and Pareto's asymptotics for affine stochastic recursions

Abstract

Let V= Rd be the Euclidean d-dimensional space, μ (resp λ) a probability measure on the linear (resp affine) group G=G L (V) (resp H= (V)) and assume that μ is the projection of λ on G. We study asymptotic properties of the iterated convolutions μn *δ\v (resp λn*δ\v) if v∈ V, i.e asymptotics of the random walk on V defined by μ (resp λ), if the subsemigroup T⊂ G (resp.\ ⊂ H) generated by the support of μ (resp λ) is "large". We show spectral gap properties for the convolution operator defined by μ on spaces of homogeneous functions of degree s≥ 0 on V, which satisfy H\"older type conditions. As a consequence of our analysis we get precise asymptotics for the potential kernel \0∞ μk * δ\v, which imply its asymptotic homogeneity. Under natural conditions the H-space V is a λ-boundary; then we use the above results and radial Fourier Analysis on V \0\ to show that the unique λ-stationary measure on V is "homogeneous at infinity" with respect to dilations v→ t v (for t0), with a tail measure depending essentially of μ and . Our proofs are based on the simplicity of the dominant Lyapunov exponent for certain products of Markov-dependent random matrices, on the use of renewal theorems for "tame" Markov walks, and on the dynamical properties of a conditional λ-boundary dual to V.