A Bayesian approach for the stochastic modeling error reduction of magnetic material identification of an electromagnetic device

Abstract: Magnetic material properties of an electromagnetic device can be recovered by solving an inverse problem where measurements are adequately interpreted by a mathematical forward model. The accuracy of these forward models dramatically affects the accuracy of the material properties recovered by the inverse problem. The more accurate the forward model is, the more accurate recovered data are. However, the more accurate 'fine' models demand a high computational time and memory storage. Alternatively, less accurat… Show more

“…Due to the random nature of the measurement noise, it is assumed to be normally white distributed with zero mean (μ n,k = 0) and a covariance of σ 2 n,k , i.e. (e n,k ∼ N (0, σ 2 n,k )) (Abdallh et al, 2012c). Similarly,…”

Advanced Magnetic Materials

“…Due to the random nature of the measurement noise, it is assumed to be normally white distributed with zero mean (μ n,k = 0) and a covariance of σ 2 n,k , i.e. (e n,k ∼ N (0, σ 2 n,k )) (Abdallh et al, 2012c). Similarly,…”

Advanced Magnetic Materials

“…Due to the random nature of the measurement noise, it is assumed to be normally white distributed with zero mean (µ n,k = 0) and a covariance of σ 2 n,k , i.e. (e n,k ∼N(0, σ 2 n,k )) (Abdallh et al, 2012c). Similarly,…”

Magnetic Material Characterization Using an Inverse Problem Approach

Review of methods for solving inverse problems in identifying permanent magnets of executive elements in dynamic devices