人工神经网络
断层(地质)
计算机科学
人工智能
机器学习
地质学
地震学
作者
Jiaming Li,Xianbo Wang,Hao Chen,Zhi-Xin Yang
标识
DOI:10.1109/tii.2025.3547004
摘要
While deep-learning (DL) models have achieved significant achievements in fault diagnosis, their inherent opacity for human users often hinders practical applications in risk-sensitive scenarios. Fortunately, the advent of class activation mapping (CAM) significantly enhanced the transparency of DL models by illuminating the specific input areas that contribute more to the classification results. Nevertheless, CAM fails to enhance diagnostic accuracy and actively leverage interpretability due to its passively explanatory property for the trained models. To address this issue, in this article, a physically meaningful regularization (PMR) term is proposed by using gradient-weighted CAM, to guide the models in focusing on the same frequency bands of the input spectra and ignoring other parts of noisy and irrelevant signals. Based on the PMR term, a two-step back propagation training algorithm is accordingly designed to train the diagnostic models embedded with physical knowledge. Consequently, the obtained physical-knowledge-guided and interpretable DL models can offer not only strong interpretability but also a higher diagnostic accuracy for the noised test samples. Finally, the proposed diagnostic method is validated in two datasets containing multiple fault severity levels. The diagnostic results, along with the saliency analysis, substantiate the efficacy of the proposed method.
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