A universal robust limit theorem for nonlinear L\'evy processes under sublinear expectation

Abstract

This article establishes a universal robust limit theorem under a sublinear expectation framework. Under moment and consistency conditions, we show that, for α ∈(1,2), the i.i.d. sequence \[ \ ( 1nΣi=1nXi,1nΣ i=1nYi,1[α]nΣi=1nZi) \ n=1∞ \] converges in distribution to L1, where Lt=( t,ηt,ζt), t∈ [0,1], is a multidimensional nonlinear L\'evy process with an uncertainty set as a set of L\'evy triplets. This nonlinear L\'evy process is characterized by a fully nonlinear and possibly degenerate partial integro-differential equation (PIDE) \[ \ array [c]l ∂tu(t,x,y,z)- (Fμ,q,Q)∈ \ ∫Rdδλu(t,x,y,z)Fμ(dλ). \\ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ . + Dyu(t,x,y,z),q+12tr[Dx2u(t,x,y,z)Q] \ =0,\\ u(0,x,y,z)=φ(x,y,z),\ \ ∀(t,x,y,z)∈ 0,1]× R3d, array . \] with δλu(t,x,y,z):=u(t,x,y,z+λ)-u(t,x,y,z)- Dzu(t,x,y,z),λ . To construct the limit process (Lt)t∈ 0,1], we develop a novel weak convergence approach based on the notions of tightness and weak compactness on a sublinear expectation space. We further prove a new type of L\'evy-Khintchine representation formula to characterize (Lt)t∈ [0,1]. As a byproduct, we also provide a probabilistic approach to prove the existence of the above fully nonlinear degenerate PIDE.