The Monotonicity Principle for Magnetic Induction Tomography

TL;DR

This paper establishes a monotonic relationship between electrical resistivity and system response time constants in magnetic induction tomography, enabling noniterative, real-time imaging based on PDE analysis.

Contribution

It proves a new monotonic relation in MQS systems linking resistivity to response time constants using modal and eigenvalue analysis.

Findings

Monotonic relation between resistivity and response time constants.

Representation of induced current density via modal decomposition.

Analysis based on elliptic eigenvalue problem.

Abstract

The inverse problem treated in this article consists in reconstructing the electrical conductivity from the free response of the system in the magneto-quasi-stationary (MQS) limit. The MQS limit corresponds to a diffusion PDE. In this framework, a key role is played by the Monotonicity Principle, that is a monotone relation connecting the unknown material property to the (measured) free-response. MP is relevant as basis of noniterative and real-time imaging methods. Monotonicity Principles have been found in many different physical problems governed by PDEs of different nature. Despite its rather general nature, each different physical/mathematical context requires to discover the proper operator showing MP. For doing this, it is necessary to develop ad-hoc mathematical approaches tailored on the specific framework. In this article, we prove a monotonic relationship between the electrical resistivity and the time constants characterizing the free-response for MQS systems. The key result is the representation of the induced current density through a modal representation. The main result is based on the analysis of an elliptic eigenvalue problem, obtained from separation of variables.