English

Testing for Causal Fairness

Machine Learning 2025-02-19 v1

Abstract

Causality is widely used in fairness analysis to prevent discrimination on sensitive attributes, such as genders in career recruitment and races in crime prediction. However, the current data-based Potential Outcomes Framework (POF) often leads to untrustworthy fairness analysis results when handling high-dimensional data. To address this, we introduce a distribution-based POF that transform fairness analysis into Distributional Closeness Testing (DCT) by intervening on sensitive attributes. We define counterfactual closeness fairness as the null hypothesis of DCT, where a sensitive attribute is considered fair if its factual and counterfactual potential outcome distributions are sufficiently close. We introduce the Norm-Adaptive Maximum Mean Discrepancy Treatment Effect (N-TE) as a statistic for measuring distributional closeness and apply DCT using the empirical estimator of NTE, referred to Counterfactual Fairness-CLOseness Testing (CF-CLOT\textrm{CF-CLOT}). To ensure the trustworthiness of testing results, we establish the testing consistency of N-TE through rigorous theoretical analysis. CF-CLOT\textrm{CF-CLOT} demonstrates sensitivity in fairness analysis through the flexibility of the closeness parameter ϵ\epsilon. Unfair sensitive attributes have been successfully tested by CF-CLOT\textrm{CF-CLOT} in extensive experiments across various real-world scenarios, which validate the consistency of the testing.

Keywords

Cite

@article{arxiv.2502.12874,
  title  = {Testing for Causal Fairness},
  author = {Jiarun Fu and LiZhong Ding and Pengqi Li and Qiuning Wei and Yurong Cheng and Xu Chen},
  journal= {arXiv preprint arXiv:2502.12874},
  year   = {2025}
}
R2 v1 2026-06-28T21:48:46.183Z