Abstract
Modelling random dynamical systems in continuous time, diffusion processes are a powerful tool in many areas of science. Model parameters can be estimated from time-discretely observed processes using Markov chain Monte Carlo (MCMC) methods that introduce auxiliary data. These methods typically approximate the transition densities of the process numerically, both for calculating the posterior densities and proposing auxiliary data. Here, the Euler–Maruyama scheme is the standard approximation technique. However, the MCMC method is computationally expensive. Using higher-order approximations may accelerate it, but the specific implementation and benefit remain unclear. Hence, we investigate the utilization and usefulness of higher-order approximations in the example of the Milstein scheme. Our study demonstrates that the MCMC methods based on the Milstein approximation yield good estimation results. However, they are computationally more expensive and can be applied to multidimensional processes only with impractical restrictions. Moreover, the combination of the Milstein approximation and the well-known modified bridge proposal introduces additional numerical challenges.
Highlights
Diffusion processes are used in many areas of science as a powerful tool to model continuous-time dynamical systems that are subject to random fluctuations
We have demonstrated how to implement an algorithm for the parameter estimation of stochastic differential equation (SDE) from low-frequency data using the Milstein scheme to approximate the transition density of the underlying process
Our findings are rather discouraging: we found that this method can be applied to multidimensional processes only with impractical restrictions
Summary
Diffusion processes are used in many areas of science as a powerful tool to model continuous-time dynamical systems that are subject to random fluctuations. For parameter estimation from low-frequency observations, Markov chain Monte Carlo (MCMC) techniques have been developed that introduce imputed data points to reduce the time steps between data points This concept of Bayesian data imputation for the inference of diffusions has been used and developed further by many authors such as [3,4,5,6]. In [9], this closed form is used to estimate the parameters of a hyperbolic diffusion process from high-frequency financial data, but not in the context of Bayesian data augmentation For the latter, Elerian et al [3] propose the possible use of the Milstein scheme. The source code of our implementation and the simulation study is publicly available at https://github.com/fuchslab/ Inference_for_SDEs_with_the_Milstein_scheme
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