Flux maximizing geometric flows

Author

Vasilevskiy, Alexander ; Siddiqi, Kaleem

Author_Institution

Sch. of Comput. Sci., McGill Univ., Montreal, Que., Canada

Volume

1

fYear

2001

fDate

2001

Firstpage

149

Abstract

Several geometric active contour models have been proposed for segmentation in computer vision. The essential idea is to evolve a curve (in 2D) or a surface (in 3D) under constraints from image forces so that it clings to features of interest in an intensity image. Recent variations on this theme take into account properties of enclosed regions and allow for multiple curves or surfaces to be simultaneously represented. However, it is not clear how to apply these techniques to images of low contrast elongated structures, such as those of blood vessels. To address this problem we derive the gradient flow which maximizes the rate of increase of flux of an auxiliary vector field through a curve or surface. The calculation leads to a simple and elegant interpretation which is essentially parameter free. We illustrate its advantages with level-set based segmentations of 2D and 3D MRA images of blood vessels

Keywords

biomedical MRI; blood vessels; computer vision; image segmentation; MRA images; auxiliary vector field; blood vessels; computer vision; enclosed regions; flux maximizing geometric flows; geometric active contour models; gradient flow; multiple curves; segmentation; Active contours; Biomedical imaging; Blood flow; Blood vessels; Computer science; Computer vision; Image segmentation; Machine intelligence; Shape; Solid modeling;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer Vision, 2001. ICCV 2001. Proceedings. Eighth IEEE International Conference on

Conference_Location

Vancouver, BC

Print_ISBN

0-7695-1143-0

Type

conf

DOI

10.1109/ICCV.2001.937511

Filename

937511