The content discusses the development of derivative-free extended Kalman filtering methods for state estimation in nonlinear stochastic systems. Two discretization schemes, Euler-Maruyama and Itô-Taylor, are compared for their effectiveness in handling highly nonlinear systems. The novel DF-EKF methods aim to maintain information about stochastic processes while ensuring stable estimation procedures. The article highlights the trade-offs between accuracy and computational demands associated with different discretization error control strategies. Additionally, the importance of numerical stability in derivative-free Bayesian filters is emphasized, leading to the development of stable square-root implementation methods.
The paper presents detailed derivations of continuous-discrete DF-EKF algorithms within both discretization schemes. The IT-1.5 DF-EKF method is shown to outperform the EM-0.5 DF-EKF in terms of accuracy due to its higher-order integration scheme. The discussion also touches upon the challenges posed by numerical instability in traditional implementations and proposes solutions through stable square-root techniques derived using Cholesky factorization and singular value decomposition.
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