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Evaluating (weighted) dynamic treatment effects by double machine learning

Hugo Bodory, Martin Huber, Lukáš Lafférs

2022Econometrics Journal106 citationsDOI

Abstract

Summary We consider evaluating the causal effects of dynamic treatments, i.e., of mul-tiple treatment sequences in various periods, based on double machine learning to control for observed, time-varying covariates in a data-driven way under a selection-on-observables assumption. To this end, we make use of so-called Neyman-orthogonal score functions, which imply the robustness of treatment effect estimation to moderate (local) misspecifications of the dynamic outcome and treatment models. This robustness property permits approximating outcome and treatment models by double machine learning even under high-dimensional covariates. In addition to effect estimation for the total population, we consider weighted estimation that permits assessing dynamic treatment effects in specific subgroups, e.g., among those treated in the first treatment period. We demonstrate that the estimators are asymptotically normal and $\sqrt{n}$-consistent under specific regularity conditions and investigate their finite sample properties in a simulation study. Finally, we apply the methods to the Job Corps study.

Topics & Concepts

EstimatorCovariateRobustness (evolution)Outcome (game theory)MathematicsPopulationAverage treatment effectComputer scienceStatisticsEconometricsArtificial intelligenceApplied mathematicsMachine learningMathematical optimizationMathematical economicsMedicineEnvironmental healthBiochemistryGeneChemistryAdvanced Causal Inference TechniquesStatistical Methods and InferenceStatistical Methods and Bayesian Inference
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