Heteroskedastic and Imbalanced Deep Learning with Adaptive Regularization
Abstract
Real-world large-scale datasets are heteroskedastic and imbalanced -- labels have varying levels of uncertainty and label distributions are long-tailed. Heteroskedasticity and imbalance challenge deep learning algorithms due to the difficulty of distinguishing among mislabeled, ambiguous, and rare examples. Addressing heteroskedasticity and imbalance simultaneously is under-explored. We propose a data-dependent regularization technique for heteroskedastic datasets that regularizes different regions of the input space differently. Inspired by the theoretical derivation of the optimal regularization strength in a one-dimensional nonparametric classification setting, our approach adaptively regularizes the data points in higher-uncertainty, lower-density regions more heavily. We test our method on several benchmark tasks, including a real-world heteroskedastic and imbalanced dataset, WebVision. Our experiments corroborate our theory and demonstrate a significant improvement over other methods in noise-robust deep learning.
Cite
@article{arxiv.2006.15766,
title = {Heteroskedastic and Imbalanced Deep Learning with Adaptive Regularization},
author = {Kaidi Cao and Yining Chen and Junwei Lu and Nikos Arechiga and Adrien Gaidon and Tengyu Ma},
journal= {arXiv preprint arXiv:2006.15766},
year = {2021}
}
Comments
to appear in ICLR 2021