Monotone convex order for the McKean-Vlasov processes

Abstract

In this paper, we establish the monotone convex order between two R-valued McKean-Vlasov processes X=(Xt)t∈ [0, T] and Y=(Yt)t∈ [0, T] defined on a filtered probability space (, F, (Ft)t≥0, P) by align &dXt=b(t, Xt, μt)dt+σ(t, Xt, μt)dBt, X0∈ Lp(P)\; with\; p≥ 2,\\ &dYt=β(t, Yt, t)dt+θ(t, \,Yt, t)\,dBt, \, Y0∈ Lp(P), align where ∀\, t∈ [0, T],\: μt=P Xt-1, \:t=P Yt-1. If we make the convexity and monotony assumption (only) on b and |σ| and if b≤ β and |σ|≤ |θ|, then the monotone convex order for the initial random variable X0\,mcv Y0 can be propagated to the whole path of processes X and Y. That is, if we consider a non-decreasing convex functional F defined on the path space with polynomial growth, we have E\, F(X)≤ E\, F(Y); for a non-decreasing convex functional G defined on the product space involving the path space and its marginal distribution space, we have E\, G(X, (μt)t∈ [0, T])≤ E\, G(Y, (t)t∈ [0, T]) under appropriate conditions. The symmetric setting is also valid, that is, if Y0\,mcv X0 and |θ|≤ |σ|, then E\, F(Y)≤ E\, F(X) and E\, G(Y, (t)t∈ [0, T])≤ E\, G(X, (μt)t∈ [0, T]). The proof is based on several forward and backward dynamic programming principle and the convergence of the truncated Euler scheme of the McKean-Vlasov equation.