Current density impedance imaging with PINNs
Abstract
In this paper, we introduce CDII-PINNs, a computationally efficient method for solving CDII using PINNs in the framework of Tikhonov regularization. This method constructs a physics-informed loss function by merging the regularized least-squares output functional with an underlying differential equation, which describes the relationship between the conductivity and voltage. A pair of neural networks representing the conductivity and voltage, respectively, are coupled by this loss function. Then, minimizing the loss function provides a reconstruction. A rigorous theoretical guarantee is provided. We give an error analysis for CDII-PINNs and establish a convergence rate, based on prior selected neural network parameters in terms of the number of samples. The numerical simulations demonstrate that CDII-PINNs are efficient, accurate and robust to noise levels ranging from to .
Keywords
Cite
@article{arxiv.2306.13881,
title = {Current density impedance imaging with PINNs},
author = {Chenguang Duan and Yuling Jiao and Xiliang Lu and Jerry Zhijian Yang},
journal= {arXiv preprint arXiv:2306.13881},
year = {2023}
}