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Steepest-descent algorithm for simulating plasma-wave caustics via metaplectic geometrical optics

Sean M. Donnelly, Nicolas Lopez, I. Y. Dodin

2021Physical review. E45 citationsDOIOpen Access PDF

Abstract

The design and optimization of radiofrequency-wave systems for fusion applications is often performed using ray-tracing codes, which rely on the geometrical-optics (GO) approximation. However, GO fails at wave cutoffs and caustics. To accurately model the wave behavior in these regions, more advanced and computationally expensive "full-wave" simulations are typically used, but this is not strictly necessary. A new generalized formulation called metaplectic geometrical optics (MGO) has been proposed that reinstates GO near caustics. The MGO framework yields an integral representation of the wavefield that must be evaluated numerically in general. We present an algorithm for computing these integrals using Gauss-Freud quadrature along the steepest-descent contours. Benchmarking is performed on the standard Airy problem, for which the exact solution is known analytically. The numerical MGO solution provided by the new algorithm agrees remarkably well with the exact solution and significantly improves on previously derived analytical approximations of the MGO integral.

Topics & Concepts

Method of steepest descentGeometrical opticsGradient descentRay tracing (physics)Physical opticsAlgorithmQuadrature (astronomy)Representation (politics)MathematicsGaussian quadraturePhysicsMathematical analysisComputer scienceIntegral equationOpticsArtificial neural networkArtificial intelligenceNyström methodLawPoliticsPolitical scienceMagnetic confinement fusion researchLaser-Plasma Interactions and DiagnosticsParticle accelerators and beam dynamics
Steepest-descent algorithm for simulating plasma-wave caustics via metaplectic geometrical optics | Litcius