Title :
Reconstructing convex sets from support line measurements
Author :
Prince, Jerry L. ; Willsky, Alan S.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., MIT, Cambridge, MA, USA
fDate :
4/1/1990 12:00:00 AM
Abstract :
Algorithms are proposed for reconstructing convex sets given noisy support line measurements. It is observed that a set of measured support lines may not be consistent with any set in the plane. A theory of consistent support lines which serves as a basis for reconstruction algorithms that take the form of constrained optimization algorithms is developed. The formal statement of the problem and constraints reveals a rich geometry that makes it possible to include prior information about object position and boundary smoothness. The algorithms, which use explicit noise models and prior knowledge, are based on maximum-likelihood and maximum a posteriori estimation principles and are implemented using efficient linear and quadratic programming codes. Experimental results are presented. This research sets the stage for a more general approach to the incorporation of prior information concerning the estimation of object shape
Keywords :
computational geometry; linear programming; quadratic programming; boundary smoothness; computational geometry; consistent support lines; constrained optimization; convex sets; explicit noise models; linear programming; maximum a posteriori estimation principles; maximum-likelihood; object position; prior knowledge; quadratic programming; sets reconstruction; shape estimation; support line measurements; Computational geometry; Computed tomography; Constraint optimization; Constraint theory; Information geometry; Laboratories; Maximum likelihood estimation; Quadratic programming; Reconstruction algorithms; Shape;
Journal_Title :
Pattern Analysis and Machine Intelligence, IEEE Transactions on
