Tony Shardlow, Phillip Taylor
Published 2014-09-08Version 1
We consider one-step methods for integrating stochastic differential equations and prove pathwise convergence using ideas from rough path theory. In contrast to alternative theories of pathwise convergence, no knowledge is required of convergence in pth mean and the analysis starts from a pathwise bound on the sum of the truncation errors. We show how the theory is applied to the Euler-Maruyama method with fixed and adaptive time-stepping strategies. The assumption on the truncation errors suggests an error-control strategy and we implement this as an adaptive time-stepping Euler-Maruyama method using bounded diffusions. We prove the adaptive method converges and show some computational experiments.
Convergence of the Euler-Maruyama method for multidimensional SDEs with discontinuous drift and degenerate diffusion coefficient
The rate of Lp-convergence for the Euler-Maruyama method of the stochastic differential equations with Markovian switching
Longtime behaviors of $θ$-Euler-Maruyama method for stochastic functional differential equations
![QR code for arXiv:1409.2362 [math.NA]](http://oss.arxitics.com/images/favicon.svg)