电阻抗断层成像
灵敏度(控制系统)
迭代重建
电阻抗
无监督学习
人工智能
断层摄影术
电容层析成像
计算机科学
图像(数学)
计算机视觉
模式识别(心理学)
声学
电子工程
光学
工程类
物理
电气工程
电容
电极
量子力学
作者
Yuanbin Wu,Jianda Han,Xinhao Bai,Jianeng Lin,Ningbo Yu
标识
DOI:10.1109/tim.2025.3555752
摘要
Electrical impedance tomography (EIT) detects time-varying conductivity distribution and has grown to be a promising imaging modality in industrial and biomedical fields. However, current deep learning-based image reconstruction methods require a large number of voltage-conductivity samples for training. This paper proposes a sensitivity-guided unsupervised learning method for EIT image reconstruction (SULEIT). First, the voltage measurements are projected into voltage feature maps and a fully convolutional network is designed to nonlinearly reconstruct the conductivity distribution images. Subsequently, the reconstructed images are converted to the measurement domain through the EIT forward modeling. Moreover, the loss function consisting of the mean absolute error and a L1 regularization term is devised to evaluate the disparity between the measured and converted voltage measurements. By combining data-driven techniques with physical constraints, the neural network is enforced to learn the inherently nonlinear mapping from the voltage measurements to conductivity images. The proposed method enables the training of the neural network without the prior knowledge of the true conductivity distributions. Experiments show the proposed SULEIT method obtains higher correlation coefficient (CC) values and lower root mean square error (RMSE) values, which demonstrate its superior imaging quality to the alternative numerical and unsupervised learning methods.
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