Parametrised branching processes: a functional version of Kesten \& Stigum theorem

Abstract

Let (Zn,n≥ 0) be a supercritical Galton-Watson process whose offspring distribution μ has mean λ>1 and is such that ∫ x((x))+ dμ(x)<+∞. According to the famous Kesten \& Stigum theorem, (Zn/λn) converges almost surely, as n+∞. The limiting random variable has mean~1, and its distribution is characterised as the solution of a fixed point equation. In this paper, we consider a family of Galton-Watson processes (Zn(λ), n≥ 0) defined for~λ ranging in an interval I⊂ (1, ∞), and where we interpret λ as the time (when n is the generation). The number of children of an individual at time~λ is given by X(λ), where (X(λ))λ∈ I is a c\`adl\`ag integer-valued process which is assumed to be almost surely non-decreasing and such that E(X(λ))=λ >1 for all λ∈ I. This allows us to define Zn(λ) the number of elements in the nth generation at time λ. Set Wn(λ)= Zn(λ)/λn for all n≥ 0 and λ∈ I. We prove that, under some moment conditions on the process~X, the sequence of processes (Wn(λ), λ∈ I)n≥ 0 converges in probability as~n tends to infinity in the space of c\`adl\`ag processes equipped with the Skorokhod topology to a process, which we characterise as the solution of a fixed point equation.

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