Scott Bagwell scite author profile

SUMMARYWe propose a new computational framework for the treatment of acousto-magneto-mechanical coupling that arises in low-frequency electro-magneto-mechanical systems such as magnetic resonance imaging scanners. Our transient Newton-Raphson strategy involves the solution of a monolithic system obtained from the linearisation of the coupled system of equations. Moreover, this framework, in the case of excitation from static and harmonic current sources, allows us to propose a simple linearised system and rigorously motivate a single-step strategy for understanding the response of systems under different frequencies of excitation. Motivated by the need to solve industrial problems rapidly, we restrict ourselves to solving problems consisting of axisymmetric geometries and current sources. Our treatment also discusses in detail the computational requirements for the solution of these coupled problems on unbounded domains and the accurate discretisation of the fields using hp -finite elements. We include a set of academic and industrially relevant examples to benchmark and illustrate our approach.

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Solution of an industrially relevant coupled magneto–mechanical problem set on an axisymmetric domain

Ledger

Gil

Poya

et al. 2016

Applied Mathematical Modelling

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Transient solutions to nonlinear acousto‐magneto‐mechanical coupling for axisymmetric MRI scanner design

Bagwell

Ledger

Gil

et al. 2018

Numerical Meth Engineering

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Summary In this work, we simulate the coupled physics describing a magnetic resonance imaging (MRI) scanner by using a higher‐order finite element discretisation and a Newton‐Raphson algorithm. To apply the latter, a linearisation of the nonlinear system of equations is necessary, and we consider two alternative approaches. In the first approach, ie, the nonlinear approach, there is no approximation from a physical standpoint, and the linearisation is performed about the current solution. In the second approach, ie, the linearised approach, we realise that the MRI problem can be described by small dynamic fluctuations about a dominant static solution and linearise about the latter. The linearised approach permits solutions in the frequency domain and provides a computationally efficient way to solve this challenging problem, as it allows the tangent stiffness matrix to be inverted independently of time or frequency. We focus on transient solutions to the coupled system of equations and address the following two important questions: (i) how good is the agreement between the computationally efficient linearised approach compared with the intensive nonlinear approach and (ii) over what range of MRI operating conditions can the linearised approach be expected to provide acceptable results for outputs of interest in an industrial context for MRI scanner design? We include a set of academic and industrially relevant examples to benchmark and illustrate our approach.

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A High Order Finite Element Coupled Multi-Physics Approach To MRI Scanner Design

Bagwell¹

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Scott Bagwell

A linearisedhp-finite element framework for acousto-magneto-mechanical coupling in axisymmetric MRI scanners

Solution of an industrially relevant coupled magneto–mechanical problem set on an axisymmetric domain

Transient solutions to nonlinear acousto‐magneto‐mechanical coupling for axisymmetric MRI scanner design

A High Order Finite Element Coupled Multi-Physics Approach To MRI Scanner Design

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