Neural Network Dynamics without Minimizing Energy

Neural Network Dynamics without Minimizing Energy

Content-addressable memory (CAM) has been described by collective dynamics of neural networks and computing with attractors (equilibrium states). Studies of such neural network systems are typically based on the aspect of energy minimization. However, when the complexity and the dimension of neural...

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Main Authors: Mau-Hsiang Shih, Feng-Sheng Tsai
Format: Article
Language:English
Published: Hindawi Limited 2013-01-01
Series:Abstract and Applied Analysis
Online Access:http://dx.doi.org/10.1155/2013/496217
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spelling doaj-fd71aa1b67f44373a7b425b986ee91152020-11-25T00:12:07ZengHindawi LimitedAbstract and Applied Analysis1085-33751687-04092013-01-01201310.1155/2013/496217496217Neural Network Dynamics without Minimizing EnergyMau-Hsiang Shih0Feng-Sheng Tsai1Department of Mathematics, National Taiwan Normal University, 88 Section 4, Ting Chou Road, Taipei 11677, TaiwanDepartment of Mathematics, National Taiwan Normal University, 88 Section 4, Ting Chou Road, Taipei 11677, TaiwanContent-addressable memory (CAM) has been described by collective dynamics of neural networks and computing with attractors (equilibrium states). Studies of such neural network systems are typically based on the aspect of energy minimization. However, when the complexity and the dimension of neural network systems go up, the use of energy functions might have its own limitations to study CAM. Recently, we have proposed the decirculation process in neural network dynamics, suggesting a step toward the reshaping of network structure and the control of neural dynamics without minimizing energy. Armed with the decirculation process, a sort of decirculating maps and its structural properties are built here, dedicated to showing that circulation breaking taking place in the connections among many assemblies of neurons can collaborate harmoniously toward the completion of network structure that generates CAM.http://dx.doi.org/10.1155/2013/496217
collection DOAJ
language English
format Article
sources DOAJ
author Mau-Hsiang Shih
Feng-Sheng Tsai
spellingShingle Mau-Hsiang Shih
Feng-Sheng Tsai
Neural Network Dynamics without Minimizing Energy
Abstract and Applied Analysis
author_facet Mau-Hsiang Shih
Feng-Sheng Tsai
author_sort Mau-Hsiang Shih
title Neural Network Dynamics without Minimizing Energy
title_short Neural Network Dynamics without Minimizing Energy
title_full Neural Network Dynamics without Minimizing Energy
title_fullStr Neural Network Dynamics without Minimizing Energy
title_full_unstemmed Neural Network Dynamics without Minimizing Energy
title_sort neural network dynamics without minimizing energy
publisher Hindawi Limited
series Abstract and Applied Analysis
issn 1085-3375
1687-0409
publishDate 2013-01-01
description Content-addressable memory (CAM) has been described by collective dynamics of neural networks and computing with attractors (equilibrium states). Studies of such neural network systems are typically based on the aspect of energy minimization. However, when the complexity and the dimension of neural network systems go up, the use of energy functions might have its own limitations to study CAM. Recently, we have proposed the decirculation process in neural network dynamics, suggesting a step toward the reshaping of network structure and the control of neural dynamics without minimizing energy. Armed with the decirculation process, a sort of decirculating maps and its structural properties are built here, dedicated to showing that circulation breaking taking place in the connections among many assemblies of neurons can collaborate harmoniously toward the completion of network structure that generates CAM.
url http://dx.doi.org/10.1155/2013/496217
work_keys_str_mv AT mauhsiangshih neuralnetworkdynamicswithoutminimizingenergy
AT fengshengtsai neuralnetworkdynamicswithoutminimizingenergy
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