缩小差距：鲁棒性和标准通用性中的拉德马赫复杂性。

Proceedings of machine learning research Pub Date : 2024-01-01

Jiancong Xiao, Ruoyu Sun, Qi Long, Weijie J Su

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引用次数: 0

摘要

用对抗性示例训练深度神经网络（DNN）往往会导致对测试时对抗性数据的泛化效果不佳。本文通过拉德马赫复杂性的视角研究了这一问题，即所谓的对抗性鲁棒泛化（adversarially robust generalization）。在 Khim 和 Loh（2018 年）、Yin 等人（2019 年）的研究基础上，已有大量作品致力于解决这一问题，但要达到令人满意的界限仍是一个难以实现的目标。关于 DNN 的现有研究要么适用于替代损失而非稳健损失，要么产生的边界明显比标准边界宽松。在后一种情况下，边界对 DNNs 的宽度 m 或数据维度 d 有更高的依赖性，至少有 𝒪 ( m ) 或 𝒪 ( d ) 的额外系数。本文提出了 DNN 的对抗性拉德马赫复杂度上界，与 Bartlett 等人（2017）的研究中建立的标准设置中最著名的上界相匹配，对宽度和维度的依赖性为 𝒪 ( ln ( d m ) ) 。我们面临的核心挑战是计算对抗函数类的覆盖数。我们的目标是构建一个具有以下两个特性的新覆盖：1) 与对抗示例兼容，以及 2) 精度可与标准设置中使用的覆盖相媲美。为此，我们引入了一种新的覆盖数变体，称为统一覆盖数，它是为协调这两个特性而专门设计并经过验证的。因此，我们的方法有效地弥合了鲁棒性和标准泛函的拉德马赫复杂性之间的差距。

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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Bridging the Gap: Rademacher Complexity in Robust and Standard Generalization.

Training Deep Neural Networks (DNNs) with adversarial examples often results in poor generalization to test-time adversarial data. This paper investigates this issue, known as adversarially robust generalization, through the lens of Rademacher complexity. Building upon the studies by Khim and Loh (2018); Yin et al. (2019), numerous works have been dedicated to this problem, yet achieving a satisfactory bound remains an elusive goal. Existing works on DNNs either apply to a surrogate loss instead of the robust loss or yield bounds that are notably looser compared to their standard counterparts. In the latter case, the bounds have a higher dependency on the width $m$ of the DNNs or the dimension $d$ of the data, with an extra factor of at least $𝒪 (\sqrt{m})$ or $𝒪 (\sqrt{d})$ . This paper presents upper bounds for adversarial Rademacher complexity of DNNs that match the best-known upper bounds in standard settings, as established in the work of Bartlett et al. (2017), with the dependency on width and dimension being $𝒪 (ln (d m))$ . The central challenge addressed is calculating the covering number of adversarial function classes. We aim to construct a new cover that possesses two properties: 1) compatibility with adversarial examples, and 2) precision comparable to covers used in standard settings. To this end, we introduce a new variant of covering number called the uniform covering number, specifically designed and proven to reconcile these two properties. Consequently, our method effectively bridges the gap between Rademacher complexity in robust and standard generalization.

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Proceedings of machine learning research

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