Title :
Relative optimization for blind deconvolution
Author :
Bronstein, Alexander M. ; Bronstein, Michael M. ; Zibulevsky, Michael
Author_Institution :
Dept. of Comput. Sci., Technion-Israel Inst. of Technol., Haifa, Israel
fDate :
6/1/2005 12:00:00 AM
Abstract :
We propose a relative optimization framework for quasi-maximum likelihood (QML) blind deconvolution and the relative Newton method as its particular instance. Special Hessian structure allows fast Newton system construction and solution, resulting in a fast-convergent algorithm with iteration complexity comparable to that of gradient methods. We also propose the use of rational infinite impulse response (IIR) restoration kernels, which constitute a richer family of filters than the traditionally used finite impulse response (FIR) kernels. We discuss different choices of nonlinear functions that are suitable for deconvolution of super- and sub-Gaussian sources and formulate the conditions under which the QML estimation is stable. Simulation results demonstrate the efficiency of the proposed methods.
Keywords :
Gaussian processes; IIR filters; Newton method; computational complexity; convergence of numerical methods; deconvolution; gradient methods; maximum likelihood estimation; nonlinear functions; optimisation; Hessian structure; fast-convergent algorithm; finite impulse response kernel; gradient method; infinite impulse response restoration kernel; iteration complexity; nonlinear function; quasimaximum likelihood blind deconvolution; relative Newton method; relative optimization; subGaussian source; superGaussian source; Deconvolution; Finite impulse response filter; IIR filters; Iterative algorithms; Kernel; Maximum likelihood estimation; Newton method; Nonlinear optics; Optical control; Optical filters; Blind deconvolution; Newton method; maximum likelihood; natural gradient;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2005.847822
