Efficiently Learning Drifting Halfspaces with Massart Noise

Abstract

We study the problem of learning a drifting concept in the presence of Massart noise. In this framework, an online learner has access to a history of independent samples whose labels are noisy versions of a target concept that may change from round to round. The goal is to output, in each round, a hypothesis with small prediction error. We study the complexity of this learning problem for the fundamental class of margin-separable linear classifiers (halfspaces). On the positive side, we give a computationally efficient learner achieving error η+ O(Δ1/3/γ), where η upper bounds the Massart noise rate, Δ is the drift rate, and γ is the margin. Interestingly, in the realizable setting, an adaptation of our techniques yields an efficient learner with an improved error rate over prior work. On the lower-bound side, we provide formal evidence of an information-computation tradeoff, strongly suggesting that our algorithm's performance is essentially optimal. Specifically, while the information-theoretically optimal error scales with Δ1/2, we prove that Δ1/3-scaling is unavoidable for low-degree polynomial tests, even in the special case of random classification noise.