Adversarially Robust Learning with Tolerance

International Conference on Algorithmic Learning Theory Pub Date : 2022-03-02 DOI:10.48550/arXiv.2203.00849

H. Ashtiani, Vinayak Pathak, Ruth Urner

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引用次数: 5

Abstract

We initiate the study of tolerant adversarial PAC-learning with respect to metric perturbation sets. In adversarial PAC-learning, an adversary is allowed to replace a test point $x$ with an arbitrary point in a closed ball of radius $r$ centered at $x$. In the tolerant version, the error of the learner is compared with the best achievable error with respect to a slightly larger perturbation radius $(1+\gamma)r$. This simple tweak helps us bridge the gap between theory and practice and obtain the first PAC-type guarantees for algorithmic techniques that are popular in practice. Our first result concerns the widely-used ``perturb-and-smooth'' approach for adversarial learning. For perturbation sets with doubling dimension $d$, we show that a variant of these approaches PAC-learns any hypothesis class $\mathcal{H}$ with VC-dimension $v$ in the $\gamma$-tolerant adversarial setting with $O\left(\frac{v(1+1/\gamma)^{O(d)}}{\varepsilon}\right)$ samples. This is in contrast to the traditional (non-tolerant) setting in which, as we show, the perturb-and-smooth approach can provably fail. Our second result shows that one can PAC-learn the same class using $\widetilde{O}\left(\frac{d.v\log(1+1/\gamma)}{\varepsilon^2}\right)$ samples even in the agnostic setting. This result is based on a novel compression-based algorithm, and achieves a linear dependence on the doubling dimension as well as the VC-dimension. This is in contrast to the non-tolerant setting where there is no known sample complexity upper bound that depend polynomially on the VC-dimension.

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对抗性稳健学习与宽容

我们开始了关于度量摄动集的容忍对抗性pac学习的研究。在对抗性pac学习中，对手可以将测试点$x$替换为以$x$为中心的半径$r$的封闭球中的任意点。在容忍版本中，将学习器的误差与相对于稍大的扰动半径$(1+\gamma)r$的最佳可实现误差进行比较。这个简单的调整帮助我们弥合了理论和实践之间的差距，并为在实践中流行的算法技术获得了第一个pac类型的保证。我们的第一个结果涉及对抗性学习中广泛使用的“扰动-平滑”方法。对于具有双重维度$d$的扰动集，我们证明了这些方法的一种变体pac -学习在具有$O\left(\frac{v(1+1/\gamma)^{O(d)}}{\varepsilon}\right)$样本的$\gamma$容忍对抗设置中具有vc维$v$的任何假设类$\mathcal{H}$。这与传统的(非容忍的)设置形成对比，正如我们所展示的，在传统的设置中，扰动和平滑方法可能会失败。我们的第二个结果表明，即使在不可知论设置中，也可以使用$\widetilde{O}\left(\frac{d.v\log(1+1/\gamma)}{\varepsilon^2}\right)$样本来pac学习相同的类。该结果基于一种新颖的基于压缩的算法，实现了对加倍维和vc维的线性依赖。这与非容忍设置相反，其中没有已知的样本复杂性上界，多项式地依赖于vc维。

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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International Conference on Algorithmic Learning Theory

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