The characterisation of small low conducting inclusions in an otherwise uniform background from low-frequency electrical field measurements has important applications in medical imaging using electrical impedance tomography as well as in geological imaging using electrical resistivity tomography. It is known that such objects can be characterised by a P\'oyla-Szeg\"o (polarizability) tensor. Such characterisations have attracted interest as they can provide object features in a machine learning classification algorithm and provide an alternative imaging solution. However, to be able train machine learning algorithms, large dictionaries are required and it is essential that the characterisations are accurate. In this work, we obtain accurate numerical approximations to the tensor coefficients, by applying an adaptive boundary element method. The goal being to provide a sequence of benchmark {computations} for the tensor coefficients to allow other software developers check the accuracy of their codes.
翻译:在低频电场测量中,低功率的小型低功率包含在本来统一的背景中,低频电场测量在医疗成像中使用电阻断层摄影以及地质成像中使用电阻断层摄影具有重要的应用性,众所周知,这些物体的特征可以用P\'oyla-Szeg\\'o(Polizity) aror( Polarization) 来定性。这些特征吸引了人们的兴趣,因为它们可以在机器学习分类算法中提供物体特征并提供替代成像解决方案。然而,为了能够培训机器学习算法,需要大型词典,而且必须使特征准确无误。在这项工作中,我们通过应用适应性边界要素方法,获得与数系数的准确数字近似度。目的是为多元系数提供基准{computs}的序列,以便其他软件开发者检查其代码的准确性。