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Auteurs principaux: Fleig, Luisa, Liebsch, Melvin, Russenschuck, Stephan, Schöps, Sebastian
Format: Preprint
Publié: 2023
Sujets:
Accès en ligne:https://arxiv.org/abs/2306.12844
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author Fleig, Luisa
Liebsch, Melvin
Russenschuck, Stephan
Schöps, Sebastian
author_facet Fleig, Luisa
Liebsch, Melvin
Russenschuck, Stephan
Schöps, Sebastian
contents Accelerator magnets made from blocks of permanent magnets in a zero-clearance configuration are known as Halbach arrays. The objective of this work is the fusion of knowledge from different measurement sources (material and field) and domain knowledge (magnetostatics) to obtain an updated magnet model of a Halbach array. From Helmholtz-coil measurements of the magnetized blocks, a prior distribution of the magnetization is estimated. Measurements of the magnetic flux density are used to derive, by means of Bayesian inference, a posterior distribution. The method is validated on simulated data and applied to measurements of a dipole of the FASER detector. The updated magnet model of the FASER dipole describes the magnetic flux density one order of magnitude better than the prior magnet model.
format Preprint
id arxiv_https___arxiv_org_abs_2306_12844
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Combination of Measurement Data and Domain Knowledge for Simulation of Halbach Arrays with Bayesian Inference
Fleig, Luisa
Liebsch, Melvin
Russenschuck, Stephan
Schöps, Sebastian
Computational Engineering, Finance, and Science
35Q61, 65Z05, 65L60, 68W10, 60J20
Accelerator magnets made from blocks of permanent magnets in a zero-clearance configuration are known as Halbach arrays. The objective of this work is the fusion of knowledge from different measurement sources (material and field) and domain knowledge (magnetostatics) to obtain an updated magnet model of a Halbach array. From Helmholtz-coil measurements of the magnetized blocks, a prior distribution of the magnetization is estimated. Measurements of the magnetic flux density are used to derive, by means of Bayesian inference, a posterior distribution. The method is validated on simulated data and applied to measurements of a dipole of the FASER detector. The updated magnet model of the FASER dipole describes the magnetic flux density one order of magnitude better than the prior magnet model.
title Combination of Measurement Data and Domain Knowledge for Simulation of Halbach Arrays with Bayesian Inference
topic Computational Engineering, Finance, and Science
35Q61, 65Z05, 65L60, 68W10, 60J20
url https://arxiv.org/abs/2306.12844