An unknown signal plus white noise is observed at $n$ discrete time points. Within a large convex class of linear estimators of $\xi$, we choose the estimator $\hat{\xi}$ that minimizes estimated quadratic risk. By construction, $\hat{\xi}$ is nonlinear. This estimation is done after orthogonal transformation of the data to a reasonable coordinate system. The procedure adaptively tapers the coefficients of the transformed data. If the class of candidate estimators satisfies a uniform entropy condition, then $\hat{\xi}$ is asymptotically minimax in Pinsker’s sense over certain ellipsoids in the parameter space and shares one such asymptotic minimax property with the James–Stein estimator. We describe computational algorithms for $\hat{\xi}$ and construct confidence sets for the unknown signal. These confidence sets are centered at $\hat{\xi}$, have correct asymptotic coverage probability and have relatively small risk as set-valued estimators of $\xi$.

Publié le : 1998-10-14
Classification:  Adaptivity,  asymptotic minimax,  bootstrap,  bounded variation,  coverage probability isotonic regression,  orthogonal transformation,  signal recovery,  Stein’s unbiased estimator of risk,  tapering,  62H12,  62M10

@article{1024691359,
     author = {Beran, Rudolf and D\"umbgen, Lutz},
     title = {Modulation of estimators and confidence sets},
     journal = {Ann. Statist.},
     volume = {26},
     number = {3},
     year = {1998},
     pages = { 1826-1856},
     language = {en},
     url = {http://dml.mathdoc.fr/item/1024691359}
}

Beran, Rudolf; Dümbgen, Lutz. Modulation of estimators and confidence sets. Ann. Statist., Tome 26 (1998) no. 3, pp.  1826-1856. http://gdmltest.u-ga.fr/item/1024691359/