Difference-based covariance matrix estimation in time series nonparametric regression with application to specification tests

Summary Long-run covariance matrix estimation is the building block of time series inference. The corresponding difference-based estimator, which avoids detrending, has attracted considerable interest due to its robustness to both smooth and abrupt structural breaks and its competitive finite sample...

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Bibliographic Details
Published in:Biometrika 2024-12, Vol.111 (4), p.1277-1292
Main Authors: Bai, Lujia, Wu, Weichi
Format: Article
Language:English
Subjects:
Asymptotic methods
Covariance matrix
Data analysis
Regression analysis
Regression coefficients
Stability tests
Structural stability
Time series
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Summary:Summary Long-run covariance matrix estimation is the building block of time series inference. The corresponding difference-based estimator, which avoids detrending, has attracted considerable interest due to its robustness to both smooth and abrupt structural breaks and its competitive finite sample performance. However, existing methods mainly focus on estimators for the univariate process, while their direct and multivariate extensions for most linear models are asymptotically biased. We propose a novel difference-based and debiased long-run covariance matrix estimator for functional linear models with time-varying regression coefficients, allowing time series nonstationarity, long-range dependence, state heteroscedasticity and combinations thereof. We apply the new estimator to (i) the structural stability test, overcoming the notorious nonmonotonic power phenomena caused by piecewise smooth alternatives for regression coefficients, and (ii) the nonparametric residual-based tests for long memory, improving the performance via the residual-free formula of the proposed estimator. The effectiveness of the proposed method is justified theoretically and demonstrated by superior performance in simulation studies, while its usefulness is elaborated via real data analysis. Our method is implemented in the R package mlrv.
ISSN:0006-3444
1464-3510
DOI:10.1093/biomet/asae013