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Orthogonal statistical learning

Dylan J. Foster, Vasilis Syrgkanis

2023The Annals of Statistics55 citationsDOIOpen Access PDF

Abstract

We provide nonasymptotic excess risk guarantees for statistical learning in a setting where the population risk with respect to which we evaluate the target parameter depends on an unknown nuisance parameter that must be estimated from data. We analyze a two-stage sample splitting meta-algorithm that takes as input arbitrary estimation algorithms for the target parameter and nuisance parameter. We show that if the population risk satisfies a condition called Neyman orthogonality, the impact of the nuisance estimation error on the excess risk bound achieved by the meta-algorithm is of second order. Our theorem is agnostic to the particular algorithms used for the target and nuisance and only makes an assumption on their individual performance. This enables the use of a plethora of existing results from machine learning to give new guarantees for learning with a nuisance component. Moreover, by focusing on excess risk rather than parameter estimation, we can provide rates under weaker assumptions than in previous works and accommodate settings in which the target parameter belongs to a complex nonparametric class. We provide conditions on the metric entropy of the nuisance and target classes such that oracle rates of the same order, as if we knew the nuisance parameter, are achieved.

Topics & Concepts

Empirical risk minimizationNuisance parameterPopulationNonparametric statisticsEstimation theoryMathematicsMetric (unit)OrthogonalityComputer scienceEstimatorMathematical optimizationAlgorithmEconometricsStatisticsDemographyEconomicsSociologyGeometryOperations managementStatistical Methods and InferenceAdvanced Causal Inference TechniquesStatistical Methods and Bayesian Inference
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