Title :
A multistage, optimal active contour model
Author :
Wang, Mao ; Evans, Joyce ; Hassebrook, Laurence ; Knapp, Charles
Author_Institution :
Center for Biomed. Eng., Kentucky Univ., Lexington, KY, USA
fDate :
11/1/1996 12:00:00 AM
Abstract :
Energy-minimizing active contour models or snakes can be used in many applications such as edge detection, motion tracking, image matching, computer vision, and three-dimensional (3-D) reconstruction. We present a novel snake that is superior both in accuracy and convergence speed over previous snake algorithms. High performance is achieved by using spline representation and dividing the energy-minimization process into multiple stages. The first stage is designed to optimize the convergence speed in order to allow the snake to quickly approach the minimum-energy state. The second stage is devoted to snake refinement and to local minimization of energy, thereby driving the snake to a quasiminimum-energy state. The third stage uses the Bellman (1957) optimality principle to fine-tune the snake to the global minimum-energy state. This three-stage scheme is optimized for both accuracy and speed
Keywords :
computer vision; convergence of numerical methods; edge detection; image matching; image reconstruction; image representation; minimisation; motion estimation; splines (mathematics); 3D image reconstruction; Bellman optimality principle; accuracy; computer vision; convergence speed; edge detection; energy-minimization process; global minimum-energy state; image matching; local minimization; minimum-energy state; motion tracking; multistage active contour model; optimal active contour model; quasiminimum-energy state; snake algorithms; snake refinement; spline representation; three-dimensional reconstruction; Active contours; Application software; Computer vision; Convergence; Design optimization; Image edge detection; Image matching; Image reconstruction; Spline; Tracking;
Journal_Title :
Image Processing, IEEE Transactions on
