English

Electrical impedance tomography-based pressure-sensing using conductive membrane

Analysis of PDEs 2014-09-15 v1

Abstract

This paper presents a mathematical framework for a flexible pressure-sensor model using electrical impedance tomography (EIT). When pressure is applied to a conductive membrane patch with clamped boundary, the pressure-induced surface deformation results in a change in the conductivity distribution. This change can be detected in the current-voltage data ({\it i.e.,} EIT data) measured on the boundary of the membrane patch. Hence, the corresponding inverse problem is to reconstruct the pressure distribution from the data. The 2D apparent conductivity (in terms of EIT data) corresponding to the surface deformation is anisotropic. Thus, we consider a constrained inverse problem by restricting the coefficient tensor to the range of the map from pressure to 2D-apparent conductivity. This paper provides theoretical grounds for the mathematical model of the inverse problem. We develop a reconstruction algorithm based on a careful sensitivity analysis. We demonstrate the performance of the reconstruction algorithm through numerical simulations to validate its feasibility for future experimental studies.

Keywords

Cite

@article{arxiv.1409.3650,
  title  = {Electrical impedance tomography-based pressure-sensing using conductive membrane},
  author = {Habib Ammari and Kyungkeun Kang and Kyounghun Lee and Jin Keun Seo},
  journal= {arXiv preprint arXiv:1409.3650},
  year   = {2014}
}

Comments

electrical impedance tomography, pressure sensing, conductive membrane, inverse problem, prescribed mean curvature equation

R2 v1 2026-06-22T05:55:05.603Z