Fairness Through Computationally-Bounded Awareness
Abstract
We study the problem of fair classification within the versatile framework of Dwork et al. [ITCS '12], which assumes the existence of a metric that measures similarity between pairs of individuals. Unlike earlier work, we do not assume that the entire metric is known to the learning algorithm; instead, the learner can query this *arbitrary* metric a bounded number of times. We propose a new notion of fairness called *metric multifairness* and show how to achieve this notion in our setting. Metric multifairness is parameterized by a similarity metric d on pairs of individuals to classify and a rich collection C of (possibly overlapping) "comparison sets" over pairs of individuals. At a high level, metric multifairness guarantees that *similar subpopulations are treated similarly*, as long as these subpopulations are identified within the class C.
Cite
Text
Kim et al. "Fairness Through Computationally-Bounded Awareness." Neural Information Processing Systems, 2018.Markdown
[Kim et al. "Fairness Through Computationally-Bounded Awareness." Neural Information Processing Systems, 2018.](https://mlanthology.org/neurips/2018/kim2018neurips-fairness/)BibTeX
@inproceedings{kim2018neurips-fairness,
title = {{Fairness Through Computationally-Bounded Awareness}},
author = {Kim, Michael and Reingold, Omer and Rothblum, Guy},
booktitle = {Neural Information Processing Systems},
year = {2018},
pages = {4842-4852},
url = {https://mlanthology.org/neurips/2018/kim2018neurips-fairness/}
}