Simo Särkkä scite author profile

Filtering and smoothing methods are used to produce an accurate estimate of the state of a time-varying system based on multiple observational inputs (data). Interest in these methods has exploded in recent years, with numerous applications emerging in fields such as navigation, aerospace engineering, telecommunications and medicine. This compact, informal introduction for graduate students and advanced undergraduates presents the current state-of-the-art filtering and smoothing methods in a unified Bayesian framework. Readers learn what non-linear Kalman filters and particle filters are, how they are related, and their relative advantages and disadvantages. They also discover how state-of-the-art Bayesian parameter estimation methods can be combined with state-of-the-art filtering and smoothing algorithms. The book's practical and algorithmic approach assumes only modest mathematical prerequisites. Examples include Matlab computations, and the numerous end-of-chapter exercises include computational assignments. Matlab code is available for download at www.cambridge.org/sarkka, promoting hands-on work with the methods.

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Applied Stochastic Differential Equations

Särkkä

Solin

2019

267

279

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Recursive Noise Adaptive Kalman Filtering by Variational Bayesian Approximations

Särkkä¹,

Nummenmaa²

2009

IEEE Trans. Automat. Contr.

563

258

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Kalman filtering and smoothing solutions to temporal Gaussian process regression models

2010

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Hilbert space methods for reduced-rank Gaussian process regression

2019

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This paper proposes a novel scheme for reduced-rank Gaussian process regression. The method is based on an approximate series expansion of the covariance function in terms of an eigenfunction expansion of the Laplace operator in a compact subset of R d . On this approximate eigenbasis the eigenvalues of the covariance function can be expressed as simple functions of the spectral density of the Gaussian process, which allows the GP inference to be solved under a computational cost scaling as O(nm 2 ) (initial) and O(m 3 ) (hyperparameter learning) with m basis functions and n data points. The approach also allows for rigorous error analysis with Hilbert space theory, and we show that the approximation becomes exact when the size of the compact subset and the number of eigenfunctions go to infinity. The expansion generalizes to Hilbert spaces with an inner product which is defined as an integral over a specified input density. The method is compared to previously proposed methods theoretically and through empirical tests with simulated and real data.

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Simo Särkkä

Bayesian Filtering and Smoothing

Applied Stochastic Differential Equations

Recursive Noise Adaptive Kalman Filtering by Variational Bayesian Approximations

Kalman filtering and smoothing solutions to temporal Gaussian process regression models

Hilbert space methods for reduced-rank Gaussian process regression

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