scholarly journals Higher strong order methods for linear Itô SDEs on matrix Lie groups

2022 ◽  
Author(s):  
Michelle Muniz ◽  
Matthias Ehrhardt ◽  
Michael Günther ◽  
Renate Winkler
Keyword(s):  
Differential Equations ◽  
Strong Convergence ◽  
Lie Groups ◽  
General Procedure ◽  
Convergence Order ◽  
Financial Mathematics ◽  
Stochastic Version ◽  
Runge Kutta Method ◽  
Runge Kutta ◽  
Strong Order

AbstractIn this paper we present a general procedure for designing higher strong order methods for linear Itô stochastic differential equations on matrix Lie groups and illustrate this strategy with two novel schemes that have a strong convergence order of 1.5. Based on the Runge–Kutta–Munthe–Kaas (RKMK) method for ordinary differential equations on Lie groups, we present a stochastic version of this scheme and derive a condition such that the stochastic RKMK has the same strong convergence order as the underlying stochastic Runge–Kutta method. Further, we show how our higher order schemes can be applied in a mechanical engineering as well as in a financial mathematics setting.

scholarly journals The Euler–Maruyama scheme for SDEs with irregular drift: convergence rates via reduction to a quadrature problem.

2020 ◽  
Author(s):  
Andreas Neuenkirch ◽  
Michaela Szölgyenyi
Keyword(s):  
Brownian Motion ◽  
Differential Equations ◽  
Error Analysis ◽  
Strong Convergence ◽  
General Framework ◽  
Additive Noise ◽  
Convergence Rates ◽  
Convergence Order ◽  
Quadrature Problem ◽  
Weighted Quadrature

Abstract We study the strong convergence order of the Euler–Maruyama (EM) scheme for scalar stochastic differential equations with additive noise and irregular drift. We provide a general framework for the error analysis by reducing it to a weighted quadrature problem for irregular functions of Brownian motion. Assuming Sobolev–Slobodeckij-type regularity of order $\kappa \in (0,1)$ for the nonsmooth part of the drift, our analysis of the quadrature problem yields the convergence order $\min \{3/4,(1+\kappa )/2\}-\epsilon$ for the equidistant EM scheme (for arbitrarily small $\epsilon>0$). The cut-off of the convergence order at $3/4$ can be overcome by using a suitable nonequidistant discretization, which yields the strong convergence order of $(1+\kappa )/2-\epsilon$ for the corresponding EM scheme.

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