Robustness of Bayesian Pool-based Active Learning Against Prior Misspecification
Abstract
We study the robustness of active learning (AL) algorithms against prior misspecification: whether an algorithm achieves similar performance using a perturbed prior as compared to using the true prior. In both the average and worst cases of the maximum coverage setting, we prove that all -approximate algorithms are robust (i.e., near -approximate) if the utility is Lipschitz continuous in the prior. We further show that robustness may not be achieved if the utility is non-Lipschitz. This suggests we should use a Lipschitz utility for AL if robustness is required. For the minimum cost setting, we can also obtain a robustness result for approximate AL algorithms. Our results imply that many commonly used AL algorithms are robust against perturbed priors. We then propose the use of a mixture prior to alleviate the problem of prior misspecification. We analyze the robustness of the uniform mixture prior and show experimentally that it performs reasonably well in practice.
Keywords
Cite
@article{arxiv.1603.09050,
title = {Robustness of Bayesian Pool-based Active Learning Against Prior Misspecification},
author = {Nguyen Viet Cuong and Nan Ye and Wee Sun Lee},
journal= {arXiv preprint arXiv:1603.09050},
year = {2016}
}
Comments
This paper is published at AAAI Conference on Artificial Intelligence (AAAI 2016)