Fast and Robust: Computationally Efficient Covariance Estimation for Sub-Weibull Vectors
Abstract
High-dimensional covariance estimation is notoriously sensitive to outliers. While statistically optimal estimators exist for general heavy-tailed distributions, they often rely on computationally expensive techniques like semidefinite programming or iterative M-estimation (O(d3)). In this work, we target the specific regime of Sub-Weibull distributions (characterized by stretched exponential tails (-tα)). We investigate a computationally efficient alternative: the Cross-Fitted Norm-Truncated Estimator. Unlike element-wise truncation, our approach preserves the spectral geometry while requiring O(Nd2) operations, which represents the theoretical lower bound for constructing a full covariance matrix. Although spherical truncation is geometrically suboptimal for anisotropic data, we prove that within the Sub-Weibull class, the exponential tail decay compensates for this mismatch. Leveraging weighted Hanson-Wright inequalities, we derive non-asymptotic error bounds showing that our estimator recovers the optimal sub-Gaussian rate O(r()/N) with high probability. This provides a scalable solution for high-dimensional data that exhibits tails heavier than Gaussian but lighter than polynomial decay.
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