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Robust importance sampling for bayesian model calibration with spatiotemporal data

Neal, Kyle D.; Schroeder, Benjamin B.; Mullins, Joshua; Subramanian, Abhinav; Mahadevan, Sankaran

This paper addresses two challenges in Bayesian calibration: (1) computational speed of existing sampling algorithms and (2) calibration with spatiotemporal responses. The commonly used Markov chain Monte Carlo (MCMC) approaches require many sequential model evaluations making the computational expense prohibitive. This paper proposes an efficient sampling algorithm: iterative importance sampling with genetic algorithm (IISGA). While iterative importance sampling enables computational efficiency, the genetic algorithm enables robustness by preventing sample degeneration and avoids getting stuck in multimodal search spaces. An inflated likelihood further enables robustness in high-dimensional parameter spaces by enlarging the target distribution. Spatiotemporal data complicate both surrogate modeling, which is necessary for expensive computational models, and the likelihood estimation. In this work, singular value decomposition is investigated for reducing the high-dimensional field data to a lower-dimensional space prior to Bayesian calibration. Then the likelihood is formulated and Bayesian inference is performed in the lower-dimension, latent space. An illustrative example is provided to demonstrate IISGA relative to existing sampling methods, and then IISGA is employed to calibrate a thermal battery model with 26 uncertain calibration parameters and spatiotemporal response data.