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Optimal uniform error estimates for moving <scp>least‐squares</scp> collocation with application to option pricing under jump‐diffusion processes

Mohammad Shirzadi, Mehdi Dehghan, Ali Foroush Bastani

2020Numerical Methods for Partial Differential Equations20 citationsDOI

Abstract

Abstract In this study, we derive optimal uniform error bounds for moving least‐squares (MLS) mesh‐free point collocation (also called finite point method ) when applied to solve second‐order elliptic partial integro‐differential equations (PIDEs). In the special case of elliptic partial differential equations (PDEs), we show that our estimate improves the results of Cheng and Cheng (Appl. Numer. Math. 58 (2008), no. 6, 884–898) both in terms of the used error norm (here the uniform norm and there the discrete vector norm) and the obtained order of convergence. We then present optimal convergence rate estimates for second‐order elliptic PIDEs. We proceed by some numerical experiments dealing with elliptic PDEs that confirm the obtained theoretical results. The article concludes with numerical approximation of the linear parabolic PIDE arising from European option pricing problem under Merton's and Kou's jump‐diffusion models. The presented computational results (including the computation of option Greeks) and comparisons with other competing approaches suggest that the MLS collocation scheme is an efficient and reliable numerical method to solve elliptic and parabolic PIDEs arising from applied areas such as financial engineering.

Topics & Concepts

MathematicsElliptic partial differential equationJump diffusionNorm (philosophy)Applied mathematicsPartial differential equationCollocation (remote sensing)Order (exchange)Numerical analysisJumpMathematical analysisComputer scienceLawEconomicsFinanceMachine learningPhysicsPolitical scienceQuantum mechanicsDifferential Equations and Numerical MethodsStochastic processes and financial applicationsDifferential Equations and Boundary Problems