English

Fast rates with high probability in exp-concave statistical learning

Machine Learning 2016-10-17 v4

Abstract

We present an algorithm for the statistical learning setting with a bounded exp-concave loss in dd dimensions that obtains excess risk O(dlog(1/δ)/n)O(d \log(1/\delta)/n) with probability at least 1δ1 - \delta. The core technique is to boost the confidence of recent in-expectation O(d/n)O(d/n) excess risk bounds for empirical risk minimization (ERM), without sacrificing the rate, by leveraging a Bernstein condition which holds due to exp-concavity. We also show that with probability 1δ1 - \delta the standard ERM method obtains excess risk O(d(log(n)+log(1/δ))/n)O(d (\log(n) + \log(1/\delta))/n). We further show that a regret bound for any online learner in this setting translates to a high probability excess risk bound for the corresponding online-to-batch conversion of the online learner. Lastly, we present two high probability bounds for the exp-concave model selection aggregation problem that are quantile-adaptive in a certain sense. The first bound is a purely exponential weights type algorithm, obtains a nearly optimal rate, and has no explicit dependence on the Lipschitz continuity of the loss. The second bound requires Lipschitz continuity but obtains the optimal rate.

Keywords

Cite

@article{arxiv.1605.01288,
  title  = {Fast rates with high probability in exp-concave statistical learning},
  author = {Nishant A. Mehta},
  journal= {arXiv preprint arXiv:1605.01288},
  year   = {2016}
}

Comments

added results on model selection aggregation (Section 7)

R2 v1 2026-06-22T13:53:13.624Z