Title :
GRADE: Gibbs reaction and diffusion equations
Author :
Zhu, Song Chun ; Mumford, David
Author_Institution :
Dept. of Comput. Sci., Stanford Univ., CA, USA
Abstract :
Recently there have been increasing interests in using nonlinear PDEs for applications in computer vision and image processing. In this paper, we propose a general statistical framework for designing a new class of PDEs. For a given application, a Markov random field model p(I) is learned according to the minimax entropy principle so that p(I) should characterize the ensemble of images in our application. P(I) is a Gibbs distribution whose energy terms can be divided into two categories. Subsequently the partial differential equations given by gradient descent on the Gibbs potential are essentially reaction-diffusion equations, where the energy terms in one category produce anisotropic diffusion while the inverted energy terms in the second category produce reaction associated with pattern formation. We call this new class of PDEs the Gibbs Reaction And Diffusion Equations-GRADE and we demonstrate experiments where GRADE are used for texture pattern formation, denoising, image enhancement, and clutter removal
Keywords :
Markov processes; computer vision; image enhancement; nonlinear differential equations; partial differential equations; GRADE; Gibbs distribution; Gibbs reaction and diffusion equations; Markov random field model; clutter removal; computer vision; denoising; image enhancement; image processing; minimax entropy principle; nonlinear PDEs; statistical framework; texture pattern formation; Application software; Computer vision; Differential equations; Entropy; Image processing; Markov random fields; Minimax techniques; Nonlinear equations; Partial differential equations; Pattern formation;
Conference_Titel :
Computer Vision, 1998. Sixth International Conference on
Conference_Location :
Bombay
Print_ISBN :
81-7319-221-9
DOI :
10.1109/ICCV.1998.710816
