Minimax estimation via wavelet shrinkage
成果类型:
Article
署名作者:
Donoho, DL; Johnstone, IM
署名单位:
Stanford University
刊物名称:
ANNALS OF STATISTICS
ISSN/ISSBN:
0090-5364
发表日期:
1998
页码:
879-921
关键词:
Nonparametric regression
DENSITY-ESTIMATION
besov-spaces
orthonormal bases
decompositions
interpolation
models
RISK
CONVERGENCE
rates
摘要:
We attempt to recover an unknown function from noisy, sampled data. Using orthonormal bases of compactly supported wavelets, we develop a nonlinear method which works in the wavelet domain by simple nonlinear shrinkage of the empirical wavelet coefficient. The shrinkage can be tuned to be nearly minimax over any member of a wide range of Triebel- and Besov-type smoothness constraints and asymptotically minimax over Besov bodies with p less than or equal to q. Linear estimates cannot achieve even the minimax rates over Triebel and Besov classes with p < 2, so the method can significantly outperform every linear method (e.g., kernel, smoothing spline, sieve) in a minimax sense. Variants of our method based on simple threshold nonlinear estimators are nearly minimax. Our method possesses the interpretation of spatial adaptivity; it reconstructs using a kernel which may vary in shape and bandwidth from point to point, depending on the data. Least favorable distributions for certain of the Triebel and Besov scales generate objects with sparse wavelet transforms. Many real objects have similarly sparse transforms, which suggests that these minimax results are relevant for practical problems. Sequels to this paper, which was first drafted in November 1990, discuss practical implementation, spatial adaptation properties, universal near minimaxity and applications to inverse problems.