Title :
Shape from Defocus via Diffusion
Author :
Favaro, Paolo ; Soatto, Stefano ; Burger, Martin ; Osher, Stanley J.
Author_Institution :
Heriot- Watt Univ., Edinburgh
fDate :
3/1/2008 12:00:00 AM
Abstract :
Defocus can be modeled as a diffusion process and represented mathematically using the heat equation, where image blur corresponds to the diffusion of heat. This analogy can be extended to nonplanar scenes by allowing a space-varying diffusion coefficient. The inverse problem of reconstructing 3D structure from blurred images corresponds to an "inverse diffusion" that is notoriously ill posed. We show how to bypass this problem by using the notion of relative blur. Given two images, within each neighborhood, the amount of diffusion necessary to transform the sharper image into the blurrier one depends on the depth of the scene. This can be used to devise a global algorithm to estimate the depth profile of the scene without recovering the deblurred image using only forward diffusion.
Keywords :
gradient methods; image restoration; inverse problems; partial differential equations; 3D structure reconstruction; defocus; depth cues; depth profile estimation; diffusion process; gradient method; heat diffusion; heat equation; image blur; image deblurring; image sharpening; inverse problem; iterative method; nonplanar scenes; partial differential equations; relative blur; shape recovery; space-varying diffusion coefficient; Depth cues; Gradient methods; Inverse problems; Iterative methods; Partial differential equations; Reconstruction; Shape; Sharpening and Deblurring; Algorithms; Artifacts; Artificial Intelligence; Diffusion; Image Enhancement; Image Interpretation, Computer-Assisted; Imaging, Three-Dimensional; Information Storage and Retrieval; Pattern Recognition, Automated; Reproducibility of Results; Sensitivity and Specificity;
Journal_Title :
Pattern Analysis and Machine Intelligence, IEEE Transactions on
DOI :
10.1109/TPAMI.2007.1175
