Robustness and Generalization

A. Ben-Tal; A. Ben-Tal; A. C. Lozano; A. Globerson; A. Klivans; A. N. Kolmogorov; A. W. van der Vaart; A. Zakai; B. Cade; B. Schölkopf; B. Zou; C. Bhattacharyya; C. Caramanis; C. Cortes; C. McDiarmid; D. Bertsimas; D. Gamarnik; G. R. Lanckriet; H. Xu; H. Xu; H. Xu; H. Xu; H. Xu; Huan Xu; I. Steinwart; J. L. Doob; L. Devroye; L. Devroye; L. Devroye; M. Kearns; N. Alon; O. Bousquet; O. Bousquet; P. J. Huber; P. J. Rousseeuw; P. K. Shivaswamy; P. L. Bartlett; P. L. Bartlett; P. L. Bartlett; P. W. Glynn; R. Koenker; R. S. Sutton; R. Tibshirani; S. Ben-David; S. Kakade; S. Mukherjee; S. P. Meyn; S. Shalev-Shwartz; Shie Mannor; T. Cole; T. Evgeniou; T. Poggio; V. Koltchinskii; V. Koltchinskii; V. N. Vapnik; V. N. Vapnik; Y. Mansour; Y. Yu

Abstract

We derive generalization bounds for learning algorithms based on their robustness: the property that if a testing sample is "similar" to a training sample, then the testing error is close to the training error. This provides a novel approach, different from the complexity or stability arguments, to study generalization of learning algorithms. We further show that a weak notion of robustness is both sufficient and necessary for generalizability, which implies that robustness is a fundamental property for learning algorithms to work

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