Fangyuan Yu scite author profile

In this article we consider a Monte-Carlo-based method to filter partially observed diffusions observed at regular and discrete times. Given access only to Euler discretizations of the diffusion process, we present a new procedure which can return online estimates of the filtering distribution with no time-discretization bias and finite variance. Our approach is based upon a novel double application of the randomization methods of Rhee and Glynn (Operat. Res.63, 2015) along with the multilevel particle filter (MLPF) approach of Jasra et al. (SIAM J. Numer. Anal.55, 2017). A numerical comparison of our new approach with the MLPF, on a single processor, shows that similar errors are possible for a mild increase in computational cost. However, the new method scales strongly to arbitrarily many processors.

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Central limit theorems for coupled particle filters

Jasra

2020

Adv. Appl. Probab.

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In this article we prove new central limit theorems (CLTs) for several coupled particle filters (CPFs). CPFs are used for the sequential estimation of the difference of expectations with respect to filters which are in some sense close. Examples include the estimation of the filtering distribution associated to different parameters (finite difference estimation) and filters associated to partially observed discretized diffusion processes (PODDP) and the implementation of the multilevel Monte Carlo (MLMC) identity. We develop new theory for CPFs, and based upon several results, we propose a new CPF which approximates the maximal coupling (MCPF) of a pair of predictor distributions. In the context of ML estimation associated to PODDP with time-discretization $\Delta_l=2^{-l}$ , $l\in\{0,1,\dots\}$ , we show that the MCPF and the approach of Jasra, Ballesio, et al. (2018) have, under certain assumptions, an asymptotic variance that is bounded above by an expression that is of (almost) the order of $\Delta_l$ ( $\mathcal{O}(\Delta_l)$ ), uniformly in time. The $\mathcal{O}(\Delta_l)$ bound preserves the so-called forward rate of the diffusion in some scenarios, which is not the case for the CPF in Jasra et al. (2017).

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Multilevel Ensemble Kalman–Bucy Filters

Chada

Jasra

2022

SIAM/ASA J. Uncertainty Quantification

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In this article we consider the linear filtering problem in continuous time. We develop and apply multilevel Monte Carlo (MLMC) strategies for ensemble Kalman-Bucy filters (EnKBFs). These filters can be viewed as approximations of conditional McKean-Vlasov-type diffusion processes. They are also interpreted as the continuous-time analogue of the ensemble Kalman filter , which has proven to be successful due to its applicability and computational cost. We prove that an ideal version of our multilevel EnKBF can achieve a mean square error (MSE) of O( 2), > 0, with a cost of order O( −2 log( ) 2 ). In order to prove this result we provide a Monte Carlo convergence and approximation bounds associated to time-discretized EnKBFs. This implies a reduction in cost compared to the (single level) EnKBF which requires a cost of O( −3 ) to achieve an MSE of O( 2). We test our theory on a linear Ornstein-Uhlenbeck process, which we motivate through highdimensional examples of order ∼ O(10 4 ) and O(10 5 ), where we also numerically test an alternative deterministic counterpart of the EnKBF.

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Randomized Multilevel Monte Carlo for Embarrassingly Parallel Inference

Jasra

Law

Yu³

2022

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Fangyuan Yu

Multilevel particle filters for the non-linear filtering problem in continuous time

Unbiased filtering of a class of partially observed diffusions

Central limit theorems for coupled particle filters

Multilevel Ensemble Kalman–Bucy Filters

Randomized Multilevel Monte Carlo for Embarrassingly Parallel Inference

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