Title :
Deconvolution for slowly time-varying systems 3D cases
Author :
Zenati, S. ; Boukrouche, A. ; Neveux, Ph
Author_Institution :
Dept. of Electron. & Telecommun., Univ. of Guelma, Guelma, Algeria
Abstract :
In the present work, we discuss an extension of the deconvolution techniques of Sekko [20] and Neveux [18] to 3D signals. The signals are assumed to be degraded by electronic linear systems, in which parameters are slowly time-varying such as sensors or other storage systems. For this purpose, Sekko & al. [20] developed a structure that has been adapted to time-varying systems [18] in order to produce an inverse filter with constant gain. This latter method was applied successfully to ordinary images [23]. The treatment of omnidirectional images requires working on the unit sphere. Therefore, the problem should be cast in 3D. In the 3D case, the deconvolution method [18] can be applied after some manipulations. The Heinz-Hopf fibration offers the possibility to consider that the sphere is similar to a torus. The advantage of this approach is that Kalman filtering can be applied and omnidirectional images projected on the sphere can be deconvolved.
Keywords :
Kalman filters; deconvolution; image processing; time-varying systems; 3D case; 3D signal; Heinz-Hopf fibration; Kalman filtering; constant gain; deconvolution technique; electronic linear system; inverse filter; omnidirectional image; ordinary image; sensor; storage system; time-varying system; unit sphere; Deconvolution; Filtering theory; Imaging; Kalman filters; Robustness; Time varying systems; Deconvolution; Kalman filter; invariant systems; omnidirectional images; time-varying; tridimensional deconvolution; uncertain systems;
Conference_Titel :
Image Processing Theory, Tools and Applications (IPTA), 2012 3rd International Conference on
Conference_Location :
Istanbul
Print_ISBN :
978-1-4673-2585-1
DOI :
10.1109/IPTA.2012.6469552
