Time-dependent neural networks with activation functions violating the standard Lipschitz condition

Nasser eddine Tatar; Sakthivel Rathinasamy

doi:10.1002/mma.8472

Time-dependent neural networks with activation functions violating the standard Lipschitz condition

Nasser eddine Tatar, Sakthivel Rathinasamy^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

A Hopfield neural network system with discrete (or variable delays) is considered in this paper. The standard assumption of Lipschitz continuity of the activation functions is dropped partially. Having in mind that this condition is needed not only for the uniqueness of solutions but also for the stability of the system, the present work improves the existing ones in the literature. The other feature here, which is in fact the main one, is the treatment of time-dependent activation functions. The time-independent case has been discussed by one of the authors in Tatar (2020). Unfortunately, it is not applicable to the present situation. Indeed, when applied, it will require a uniform boundedness condition. To overcome this difficulty, we provide here a new argument in addition to the introduction of some functionals.

Original language	English
Pages (from-to)	11659-11666
Number of pages	8
Journal	Mathematical Methods in the Applied Sciences
Volume	45
Issue number	17
DOIs	https://doi.org/10.1002/mma.8472
State	Published - 30 Nov 2022

Bibliographical note

Publisher Copyright:
© 2022 John Wiley & Sons, Ltd.

Keywords

Hopfield neural network
exponential stabilization
non-Lipschitz continuous activation functions

ASJC Scopus subject areas

General Mathematics
General Engineering

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10.1002/mma.8472

Cite this

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abstract = "A Hopfield neural network system with discrete (or variable delays) is considered in this paper. The standard assumption of Lipschitz continuity of the activation functions is dropped partially. Having in mind that this condition is needed not only for the uniqueness of solutions but also for the stability of the system, the present work improves the existing ones in the literature. The other feature here, which is in fact the main one, is the treatment of time-dependent activation functions. The time-independent case has been discussed by one of the authors in Tatar (2020). Unfortunately, it is not applicable to the present situation. Indeed, when applied, it will require a uniform boundedness condition. To overcome this difficulty, we provide here a new argument in addition to the introduction of some functionals.",

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T1 - Time-dependent neural networks with activation functions violating the standard Lipschitz condition

AU - Tatar, Nasser eddine

AU - Rathinasamy, Sakthivel

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N2 - A Hopfield neural network system with discrete (or variable delays) is considered in this paper. The standard assumption of Lipschitz continuity of the activation functions is dropped partially. Having in mind that this condition is needed not only for the uniqueness of solutions but also for the stability of the system, the present work improves the existing ones in the literature. The other feature here, which is in fact the main one, is the treatment of time-dependent activation functions. The time-independent case has been discussed by one of the authors in Tatar (2020). Unfortunately, it is not applicable to the present situation. Indeed, when applied, it will require a uniform boundedness condition. To overcome this difficulty, we provide here a new argument in addition to the introduction of some functionals.

AB - A Hopfield neural network system with discrete (or variable delays) is considered in this paper. The standard assumption of Lipschitz continuity of the activation functions is dropped partially. Having in mind that this condition is needed not only for the uniqueness of solutions but also for the stability of the system, the present work improves the existing ones in the literature. The other feature here, which is in fact the main one, is the treatment of time-dependent activation functions. The time-independent case has been discussed by one of the authors in Tatar (2020). Unfortunately, it is not applicable to the present situation. Indeed, when applied, it will require a uniform boundedness condition. To overcome this difficulty, we provide here a new argument in addition to the introduction of some functionals.

KW - Hopfield neural network

KW - exponential stabilization

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JF - Mathematical Methods in the Applied Sciences

IS - 17

ER -

Time-dependent neural networks with activation functions violating the standard Lipschitz condition

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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