Characterising small objects in the regime between the eddy current model and wave propagation

TL;DR

This paper develops a new asymptotic expansion for characterising small, permeable, highly conducting objects at frequencies beyond the eddy current limit, enhancing metal detection and object identification capabilities.

Contribution

It introduces a novel asymptotic expansion valid for small permeable objects at frequencies above the eddy current regime, enabling improved object characterisation.

Findings

Derived a new asymptotic expansion for permeable objects

Formulated polarizability tensor descriptions from transmission problems

Applicable to safety, archaeological, and forensic object detection

Abstract

Being able to characterise objects at low frequencies, but above the limiting frequency of the eddy current approximation of the Maxwell system, is important for improving current metal detection technologies. Importantly, the upper frequency limit of the eddy current model depends on the object topology and on its materials, with the maximum frequency being much smaller for certain geometries compared to others of the same size and materials. Additionally, the eddy current model breaks down at much smaller frequencies for highly magnetic conducting materials compared to non-permeable objects (with similar conductivities, sizes and shapes) and, hence, characterising small magnetic objects made of permeable materials using the eddy current at typical frequencies of operation for a metal detector is not always possible. To address this, we derive a new asymptotic expansion for permeable highly conducting objects that is valid for small objects and holds for frequencies just beyond the eddy current limit. The leading order term we derive leads to new forms of object characterisations in terms of polarizability tensor object descriptions where the coefficients can be obtained from solving vectorial transmission problems. We expect these new characterisations to be important when considering objects at greater stand-off distance from the coils, which is important for safety critical applications, such as the identification of landmines, unexploded ordnance and concealed weapons. We also expect our results to be important when characterising artefacts of archaeological and forensic significance at greater depths than the eddy current model allows and to have further applications parking sensors and improving the detection of hidden, out-of-sight, metallic objects.