Splitting algorithms for paraxial and Itô-Schrödinger models of wave propagation in random media
Abstract
This paper introduces a full discretization procedure to solve wave beam propagation in random media modeled by a paraxial wave equation or an Itô-Schrödinger stochastic partial differential equation. This method bears similarities with the phase screen method used routinely to solve such problems. The main axis of propagation is discretized by a centered splitting scheme with step Δz while the transverse variables are treated by a spectral method after appropriate spatial truncation. The originality of our approach is its theoretical validity even when the typical wavelength θ of the propagating signal satisfies θΔz. More precisely, we obtain a convergence of order Δz in mean-square sense while the errors on statistical moments are of order (Δz)2 as expected for standard centered splitting schemes. This is a surprising result as splitting schemes typically do not converge when Δz is not the smallest scale of the problem. The analysis is based on equations satisfied by statistical moments in the Itô-Schrödinger case and on integral (Duhamel) expansions for the paraxial model. Several numerical simulations illustrate and confirm the theoretical findings.
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