A partial Fourier transform method for a class of hypoelliptic Kolmogorov equations

Abstract

We consider hypoelliptic Kolmogorov equations in n+1 spatial dimensions, with n≥ 1, where the differential operator in the first n spatial variables featuring in the equation is second-order elliptic, and with respect to the (n+1)st spatial variable the equation contains a pure transport term only and is therefore first-order hyperbolic. If the two differential operators, in the first n and in the (n+1)st co-ordinate directions, do not commute, we benefit from hypoelliptic regularization in time, and the solution for t>0 is smooth even for a Dirac initial datum prescribed at t=0. We study specifically the case where the coefficients depend only on the first n variables. In that case, a Fourier transform in the last variable and standard central finite difference approximation in the other variables can be applied for the numerical solution. We prove second-order convergence in the spatial mesh size for the model hypoelliptic equation ∂ u∂ t + x ∂ u∂ y = ∂2 u∂ x2 subject to the initial condition u(x,y,0) = δ(x) δ(y), with (x,y) ∈ R ×R and t>0, proposed by Kolmogorov, and for an extension with n=2. We also demonstrate exponential convergence of an approximation of the inverse Fourier transform based on the trapezium rule. Lastly, we apply the method to a PDE arising in mathematical finance, which models the distribution of the hedging error under a mis-specified derivative pricing model.