Open Access<title>Spatially adaptive 3D inverse for optical sectioning</title>
Author(s) -
Dmitriy Paliy,
Vladimir Katkovnik,
Karen Egiazarian
Publication year - 2006
Publication title -
proceedings of spie, the international society for optical engineering/proceedings of spie
Language(s) - English
Resource type - Conference proceedings
SCImago Journal Rank - 0.192
H-Index - 176
eISSN - 1996-756X
pISSN - 0277-786X
DOI - 10.1117/12.642696
Subject(s) - algorithm , computer science , inverse , inverse problem , point spread function , quadratic equation , image restoration , matrix (chemical analysis) , mathematics , artificial intelligence , computer vision , image (mathematics) , image processing , mathematical analysis , geometry , materials science , composite material
In this paper, we propose a novel nonparametric approach to reconstruction of three-dimensional (3D) objects from 2D blurred and noisy observations which is a problem of computational optical sectioning. This approach is based on an approximate image formation model which takes into account depth varying nature of blur described by a matrix of shift-invariant 2D point-spread functions (PSF) of an optical system. The proposed restoration scheme incorporates the matrix regularized inverse and matrix regularized Wiener inverse algorithms in combination with a novel spatially adaptive denoising. This technique is based on special statistical rules for selection of the adaptive size and shape neighbourhood used for the local polynomial approximation of the 2D image intensity. The simulations on a phantom 3D object show efficiency of the developed approach. The objective result evaluation is presented in terms of quadratic-error criteria.
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