Title :
Neural networks for convex hull computation
Author :
Leung, Yee ; Zhang, Jiang-She ; Xu, Zong-Ben
Author_Institution :
Dept. of Geogr., Chinese Univ. of Hong Kong, Shatin, Hong Kong
fDate :
5/1/1997 12:00:00 AM
Abstract :
Computing convex hull is one of the central problems in various applications of computational geometry. In this paper, a convex hull computing neural network (CHCNN) is developed to solve the related problems in the N-dimensional spaces. The algorithm is based on a two-layered neural network, topologically similar to ART, with a newly developed adaptive training strategy called excited learning. The CHCNN provides a parallel online and real-time processing of data which, after training, yields two closely related approximations, one from within and one from outside, of the desired convex hull. It is shown that accuracy of the approximate convex hulls obtained is around O[K-1(N-1/)], where K is the number of neurons in the output layer of the CHCNN. When K is taken to be sufficiently large, the CHCNN can generate any accurate approximate convex hull. We also show that an upper bound exists such that the CHCNN will yield the precise convex hull when K is larger than or equal to this bound. A series of simulations and applications is provided to demonstrate the feasibility, effectiveness, and high efficiency of the proposed algorithm
Keywords :
ART neural nets; approximation theory; computational complexity; computational geometry; feedforward neural nets; learning (artificial intelligence); mathematics computing; parallel processing; real-time systems; ART like neural nets; adaptive training; computational geometry; convex hull; excited learning; multilayer neural networks; parallel processing; real-time system; upper bound; Artificial neural networks; Computational geometry; Computational modeling; Computer networks; Fasteners; Neural networks; Neurons; Parallel processing; Subspace constraints; Upper bound;
Journal_Title :
Neural Networks, IEEE Transactions on
