Martingale representation for degenerate diffusions

Abstract

Let (W,H,μ) be the classical Wiener space on d. Assume that X=(Xt) is a diffusion process satisfying the stochastic differential equation dXt=σ(t,X)dBt+b(t,X)dt, where σ:[0,1]× C([0,1],n) n d, b:[0,1]× C([0,1],n) n, B is an d-valued Brownian motion. We suppose that the weak uniqueness of this equation holds for any initial condition. We prove that any square integrable martingale M w.r.t. to the filtration (t(X),t∈ [0,1]) can be represented as Mt=E[M0]+∫0t Ps(X)αs(X).dBs where α(X) is an d-valued process adapted to (t(X),t∈ [0,1]), satisfying E∫0t(a(Xs)αs(X),αs(X))ds<∞, a=σσ and Ps(X) denotes a measurable version of the orthogonal projection from d to σ(Xs)(n). In particular, for any h∈ H, we have equation wick E[(δ h)|1(X)]=(∫01(Ps(X)hs,dBs)-∫01|Ps(X)hs|2ds)\,, equation where (δ h)=(∫01(hs,dBs)- |H|H2). This result gives a new development as an infinite series of the L2-functionals of the degenerate diffusions. We also give an adequate notion of "innovation process" associated to a degenerate diffusion which corresponds to the strong solution when the Brownian motion is replaced by an adapted perturbation of identity. This latter result gives the solution of the causal Monge-Amp\`ere equation.