图卷积神经网络的可解释性方法

Phillip E. Pope, Soheil Kolouri, Mohammad Rostami, Charles E. Martin, Heiko Hoffmann
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引用次数: 326

摘要

随着图卷积神经网络(GCNNs)的应用越来越广泛,对可解释性的需求也随之而来。在本文中,我们介绍了gcnn的可解释性方法。我们开发了卷积神经网络三种突出的可解释性方法的图类似物:基于梯度的对比显著性图(CG),类激活映射(CAM)和激励反向传播(EB)及其变体,梯度加权的CAM (Grad-CAM)和对比EB (c-EB)。我们在视觉场景图和分子图两个应用领域展示了这些方法在分类问题上的概念证明。为了比较这些方法,我们确定了三个理想的解释属性:(1)它们对分类的重要性,通过遮挡的影响来衡量,(2)它们相对于不同类别的对比性,以及(3)它们在图上的稀疏性。我们将相应的定量度量称为保真度、对比性和稀疏性,并对每种方法进行评估。最后,我们分析了从解释中得到的显著子图,并报告了频繁出现的模式。
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Explainability Methods for Graph Convolutional Neural Networks
With the growing use of graph convolutional neural networks (GCNNs) comes the need for explainability. In this paper, we introduce explainability methods for GCNNs. We develop the graph analogues of three prominent explainability methods for convolutional neural networks: contrastive gradient-based (CG) saliency maps, Class Activation Mapping (CAM), and Excitation Back-Propagation (EB) and their variants, gradient-weighted CAM (Grad-CAM) and contrastive EB (c-EB). We show a proof-of-concept of these methods on classification problems in two application domains: visual scene graphs and molecular graphs. To compare the methods, we identify three desirable properties of explanations: (1) their importance to classification, as measured by the impact of occlusions, (2) their contrastivity with respect to different classes, and (3) their sparseness on a graph. We call the corresponding quantitative metrics fidelity, contrastivity, and sparsity and evaluate them for each method. Lastly, we analyze the salient subgraphs obtained from explanations and report frequently occurring patterns.
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