Neural Networks for Tamed Milstein Approximation of SDEs with Additive Symmetric Jump Noise Driven by a Poisson Random Measure

Abstract

This work aims to estimate the drift and diffusion functions in stochastic differential equations (SDEs) driven by a particular class of L\'evy processes with finite jump intensity, using neural networks. We propose a framework that integrates the Tamed-Milstein scheme with neural networks employed as non-parametric function approximators. Estimation is carried out in a non-parametric fashion for the drift function f: Z R, the diffusion coefficient g: Z R. The model of interest is given by \[ dX(t) = + f(X(t))\, dt + g(X(t))\, dWt + γ ∫Z z\, N(dt,dz), \] where Wt is a standard Brownian motion, and N(dt,dz) is a Poisson random measure on (R+ × Z, B (R+) Z, λ( v)), with λ, γ > 0, being the Lebesgue measure on R+, and v a finite measure on the measurable space (Z, Z). Neural networks are used as non-parametric function approximators, enabling the modeling of complex nonlinear dynamics without assuming restrictive functional forms. The proposed methodology constitutes a flexible alternative for inference in systems with state-dependent noise and discontinuities driven by L\'evy processes.