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Convergence acceleration of ensemble Kalman inversion in nonlinear settings

Neil Chada, Xin T. Tong

2021Mathematics of Computation26 citationsDOIOpen Access PDF

Abstract

Many data-science problems can be formulated as an inverse problem, where the parameters are estimated by minimizing a proper loss function. When complicated black-box models are involved, derivative-free optimization tools are often needed. The ensemble Kalman filter (EnKF) is a particle-based derivative-free Bayesian algorithm originally designed for data assimilation. Recently, it has been applied to inverse problems for computational efficiency. The resulting algorithm, known as ensemble Kalman inversion (EKI), involves running an ensemble of particles with EnKF update rules so they can converge to a minimizer. In this article, we investigate EKI convergence in general nonlinear settings. To improve convergence speed and stability, we consider applying EKI with non-constant step-sizes and covariance inflation. We prove that EKI can hit critical points with finite steps in non-convex settings. We further prove that EKI converges to the global minimizer polynomially fast if the loss function is strongly convex. We verify the analysis presented with numerical experiments on two inverse problems.

Topics & Concepts

MathematicsEnsemble Kalman filterInverse problemKalman filterNonlinear systemApplied mathematicsData assimilationConvergence (economics)Mathematical optimizationInverseAlgorithmCovarianceExtended Kalman filterMathematical analysisGeometryEconomicsQuantum mechanicsPhysicsStatisticsEconomic growthMeteorologySoil Geostatistics and MappingGaussian Processes and Bayesian InferenceTarget Tracking and Data Fusion in Sensor Networks
Convergence acceleration of ensemble Kalman inversion in nonlinear settings | Litcius