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Autore principale: Song, Dogyoon
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.15161
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author Song, Dogyoon
author_facet Song, Dogyoon
contents In randomized experiments, regression adjustment can improve the precision of average treatment effect (ATE) estimation using covariates without requiring a correctly specified outcome model. Although well studied in low-dimensional settings, its behavior in high-dimensional regimes, where the number of covariates $p$ may exceed the number of observations $n$, remains underexplored. Moreover, existing analyses are largely asymptotic, providing limited guidance for finite-sample inference. We develop a design-based, non-asymptotic framework for analyzing the regression-adjusted ATE estimator under complete randomization. This yields finite-sample-valid confidence intervals with explicit, instance-adaptive widths, even when $p > n$. While these intervals rely on oracle (population-level) quantities, we also outline data-driven envelopes computable from observed data. Our approach hinges on a refined swap sensitivity analysis of an estimator: stochastic fluctuation is controlled via a variance-adaptive Doob martingale and Freedman's inequality, and design bias is bounded by Stein's method of exchangeable pairs. The analysis elucidates how covariate geometry governs concentration and bias of the adjusted estimator, suggesting when and how regression adjustment can be effective.
format Preprint
id arxiv_https___arxiv_org_abs_2511_15161
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Design-based finite-sample analysis for regression adjustment
Song, Dogyoon
Statistics Theory
Methodology
In randomized experiments, regression adjustment can improve the precision of average treatment effect (ATE) estimation using covariates without requiring a correctly specified outcome model. Although well studied in low-dimensional settings, its behavior in high-dimensional regimes, where the number of covariates $p$ may exceed the number of observations $n$, remains underexplored. Moreover, existing analyses are largely asymptotic, providing limited guidance for finite-sample inference. We develop a design-based, non-asymptotic framework for analyzing the regression-adjusted ATE estimator under complete randomization. This yields finite-sample-valid confidence intervals with explicit, instance-adaptive widths, even when $p > n$. While these intervals rely on oracle (population-level) quantities, we also outline data-driven envelopes computable from observed data. Our approach hinges on a refined swap sensitivity analysis of an estimator: stochastic fluctuation is controlled via a variance-adaptive Doob martingale and Freedman's inequality, and design bias is bounded by Stein's method of exchangeable pairs. The analysis elucidates how covariate geometry governs concentration and bias of the adjusted estimator, suggesting when and how regression adjustment can be effective.
title Design-based finite-sample analysis for regression adjustment
topic Statistics Theory
Methodology
url https://arxiv.org/abs/2511.15161