In this paper. we investigate the minimax properties of Stein block thresholding in any dimension d with a particular emphasis on d = 2. Towards this goal, we consider a frame coefficient space over which minimaxity is proved. The choice of this space is inspired by the characterization provided in [L. Borup, M. Nielsen, Frame decomposition of decomposition spaces, J. Fourier Anal. Appl. 13 (1) (2007) 39-70] of family of smoothness spaces on R(d), a subclass of so-called decomposition spaces [H.G. Feichtinger, Banach spaces of distributions defined by decomposition methods, II, Math. Nachr. 132 (1987) 207-237]. These smoothness spaces cover the classical case of Besov spaces, as well as smoothness spaces corresponding to curvelet-type constructions. Our main theoretical result investigates the minimax rates over these decomposition spaces, and shows that our block estimator can achieve the optimal minimax rate, or is at least nearly-minimax (up to a log factor) in the least favorable situation. Another contribution is that the minimax rates given here are stated for a noise sequence model in the transform coefficient domain satisfying some mild assumptions. This covers for instance the Gaussian case with frames where the noise is not white in the coefficient domain. The choice of the threshold parameter is theoretically discussed and its optimal value is stated for some noise models such as the (non-necessarily i.i.d.) Gaussian case. We provide a simple, fast and a practical procedure. We also report a comprehensive simulation study to support our theoretical findings. The practical performance of our Stein block denoising compares very favorably to the BLS-GSM state-of-the art denoising algorithm on a large set of test images. A toolbox is made available for download on the Internet to reproduce the results discussed in this paper.

• 出版日期2010-1
• 单位中国地震局