Your search keyword '"Infinite distributed time-varying delays"' showing total 3 results

1. A perspective on graph theory-based stability analysis of impulsive stochastic recurrent neural networks with time-varying delays

Author

M. Iswarya, R. Raja, G. Rajchakit, J. Cao, J. Alzabut, and C. Huang

Subjects

Recurrent neural networks (RNNs), Exponential stability, Graph theory, Young’s inequality, Discrete time-varying delays, Infinite distributed time-varying delays, Mathematics, QA1-939

Abstract

Abstract In this work, the exponential stability problem of impulsive recurrent neural networks is investigated; discrete time delay, continuously distributed delay and stochastic noise are simultaneously taken into consideration. In order to guarantee the exponential stability of our considered recurrent neural networks, two distinct types of sufficient conditions are derived on the basis of the Lyapunov functional and coefficient of our given system and also to construct a Lyapunov function for a large scale system a novel graph-theoretic approach is considered, which is derived by utilizing the Lyapunov functional as well as graph theory. In this approach a global Lyapunov functional is constructed which is more related to the topological structure of the given system. We present a numerical example and simulation figures to show the effectiveness of our proposed work.

Published

2019

2. A perspective on graph theory-based stability analysis of impulsive stochastic recurrent neural networks with time-varying delays.

Author

Iswarya, M., Raja, R., Rajchakit, G., Cao, J., Alzabut, J., and Huang, C.

Subjects

*RECURRENT neural networks, *TIME-varying networks, *LARGE scale systems, *EXPONENTIAL stability, *GRAPH theory, *STOCHASTIC analysis

Abstract

In this work, the exponential stability problem of impulsive recurrent neural networks is investigated; discrete time delay, continuously distributed delay and stochastic noise are simultaneously taken into consideration. In order to guarantee the exponential stability of our considered recurrent neural networks, two distinct types of sufficient conditions are derived on the basis of the Lyapunov functional and coefficient of our given system and also to construct a Lyapunov function for a large scale system a novel graph-theoretic approach is considered, which is derived by utilizing the Lyapunov functional as well as graph theory. In this approach a global Lyapunov functional is constructed which is more related to the topological structure of the given system. We present a numerical example and simulation figures to show the effectiveness of our proposed work. [ABSTRACT FROM AUTHOR]

Published

2019

3. A perspective on graph theory-based stability analysis of impulsive stochastic recurrent neural networks with time-varying delays

Author

Chuangxia Huang, M. Iswarya, Jehad Alzabut, Jinde Cao, Ramachandran Raja, and Grienggrai Rajchakit

Subjects

Lyapunov function, Stability (learning theory), 02 engineering and technology, Infinite distributed time-varying delays, Exponential stability, 01 natural sciences, symbols.namesake, Discrete time-varying delays, Control theory, ComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATION, 0202 electrical engineering, electronic engineering, information engineering, 0101 mathematics, Mathematics, Algebra and Number Theory, Young’s inequality, Basis (linear algebra), lcsh:Mathematics, Applied Mathematics, 010102 general mathematics, Graph theory, lcsh:QA1-939, Recurrent neural network, Discrete time and continuous time, Ordinary differential equation, symbols, 020201 artificial intelligence & image processing, Recurrent neural networks (RNNs), Analysis

Abstract

In this work, the exponential stability problem of impulsive recurrent neural networks is investigated; discrete time delay, continuously distributed delay and stochastic noise are simultaneously taken into consideration. In order to guarantee the exponential stability of our considered recurrent neural networks, two distinct types of sufficient conditions are derived on the basis of the Lyapunov functional and coefficient of our given system and also to construct a Lyapunov function for a large scale system a novel graph-theoretic approach is considered, which is derived by utilizing the Lyapunov functional as well as graph theory. In this approach a global Lyapunov functional is constructed which is more related to the topological structure of the given system. We present a numerical example and simulation figures to show the effectiveness of our proposed work.

Published

2019