Feynman-Kac formula under a finite entropy condition

Abstract

Motivated by entropic optimal transport, we investigate an extended notion of solution to the parabolic equation ( ∂t + b· ∇ + a/2 +V)g =0 with a final boundary condition. It is well-known that the viscosity solution g of this PDE is represented by the Feynman-Kac formula when the drift b, the diffusion matrix a and the scalar potential V are regular enough and not growing too fast. In this article, b and V are not assumed to be regular and their growth is controlled by a finite entropy condition, allowing for instance V to belong to some Kato class. We show that the Feynman-Kac formula represents a solution, in an extended sense, to the parabolic equation. This notion of solution is trajectorial and expressed with the semimartingale extension of the Markov generator b· ∇ + a/2. Our probabilistic approach relies on stochastic derivatives, semimartingales, Girsanov's theorem and the Hamilton-Jacobi-Bellman equation satisfied by g.