When is it worthwhile to jackknife? Breaking the quadratic barrier for Z-estimators
Abstract
Resampling methods are especially well-suited to inference with estimators that provide only "black-box'' access. Jackknife is a form of resampling, widely used for bias correction and variance estimation, that is well-understood under classical scaling where the sample size n grows for a fixed problem. We study its behavior in application to estimating functionals using high-dimensional Z-estimators, allowing both the sample size n and problem dimension d to diverge. We begin showing that the plug-in estimator based on the Z-estimate suffers from a quadratic breakdown: while it is n-consistent and asymptotically normal whenever n d2, it fails for a broad class of problems whenever n d2. We then show that under suitable regularity conditions, applying a jackknife correction yields an estimate that is n-consistent and asymptotically normal whenever n d3/2. This provides strong motivation for the use of jackknife in high-dimensional problems where the dimension is moderate relative to sample size. We illustrate consequences of our general theory for various specific Z-estimators, including non-linear functionals in linear models; generalized linear models; and the inverse propensity score weighting (IPW) estimate for the average treatment effect, among others.
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