对抗性的机器学习阶段

Si Jiang, Sirui Lu, Dong-Ling Deng
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引用次数: 4

摘要

我们研究了机器学习方法对对抗性扰动的鲁棒性,重点是监督学习场景。我们发现基于深度神经网络的典型相位分类器非常容易受到对抗性扰动的影响:在原始的合法示例中添加少量精心制作的噪声将导致分类器在非常高的置信度下做出错误的预测。通过激活图的镜头,我们发现一些重要的潜在物理原理和对称性仍然需要充分捕捉到具有近乎完美性能的分类器。这就解释了为什么存在对抗性扰动来欺骗这些分类器。此外,我们发现,经过对抗性训练,分类器将变得更加符合物理定律,因此对某些类型的对抗性扰动更具鲁棒性。我们的研究结果为未来将机器学习技术应用于凝聚态物理的理论和实验研究提供了有价值的指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Adversarial machine learning phases of matter

We study the robustness of machine learning approaches to adversarial perturbations, with a focus on supervised learning scenarios. We find that typical phase classifiers based on deep neural networks are extremely vulnerable to adversarial perturbations: adding a tiny amount of carefully crafted noises into the original legitimate examples will cause the classifiers to make incorrect predictions at a notably high confidence level. Through the lens of activation maps, we find that some important underlying physical principles and symmetries remain to be adequately captured for classifiers with even near-perfect performance. This explains why adversarial perturbations exist for fooling these classifiers. In addition, we find that, after adversarial training the classifiers will become more consistent with physical laws and consequently more robust to certain kinds of adversarial perturbations. Our results provide valuable guidance for both theoretical and experimental future studies on applying machine learning techniques to condensed matter physics.

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