Title :
Turing equivalence of neural networks with second order connection weights
Author :
Chen, Hsiao-Hwa ; Lee, Young-Chul
Abstract :
In principle, a potentially infinitely large neural network (either in number of neurons or in the precision of a single neural activity) could possess an equivalent computational power to a Turing machine. The authors show such an equivalence of Turing machines to several explicitly constructed neural networks. It is proven that for any given Turing machine there exists a recurrent neural network with local, second-order, and uniformly connected weights (i.e., the weights connecting the second-order product of local `input neurons´ with their corresponding `output neurons´) which can simulate it. The numerical implementation and learning of such a neural Turing machine are also discussed
Keywords :
Turing machines; learning systems; neural nets; Turing equivalence; computational power; learning; neural activity precision; numerical implementation; recurrent neural network; second order connection weights; uniformly connected weights; Automata; Computational modeling; Computer networks; Laboratories; Magnetic heads; Neural networks; Neurons; Recurrent neural networks; Sun; Turing machines;
Conference_Titel :
Neural Networks, 1991., IJCNN-91-Seattle International Joint Conference on
Conference_Location :
Seattle, WA
Print_ISBN :
0-7803-0164-1
DOI :
10.1109/IJCNN.1991.155360
