First SN P visual cryptographic circuit with astrocyte control of structural plasticity for security applications

L. Olvera-Martinez; T. Jimenez-Borgonio; T. Frias-Carmona; M. Abarca-Rodriguez; C. Diaz-Rodriguez; M. Cedillo-Hernandez; M. Nakano-Miyatake; H. Perez-Meana

doi:10.1016/j.neucom.2021.05.057

First SN P visual cryptographic circuit with astrocyte control of structural plasticity for security applications

L. Olvera-Martinez, T. Jimenez-Borgonio, T. Frias-Carmona, M. Abarca-Rodriguez, C. Diaz-Rodriguez, M. Cedillo-Hernandez, M. Nakano-Miyatake, H. Perez-Meana

Escuela Superior de Ingeniería Mecánica y Eléctrica (ESIME), Unidad Culhuacán

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

5 Scopus citations

Abstract

Cryptographic algorithms have been widely used in all secure data transmissions due their capabilities to hide sensible information against eavesdroppers. Nevertheless, technological progress tends to develop new cryptographic methods based on non-classical computing paradigms. In this work, the first circuit of visual cryptography based on Spiking Neural P systems (VCSN P) is presented. The proposed circuit makes use of new biological behaviors in astrocytes, which are involved in processes of plasticity and pruning control in dendrites, that can be the beginning to new cryptographic algorithms based on SN P systems. To validate the SN P circuit, this was implemented on the Cyclone V field programmable gate array (FPGA) development kit. The results demonstrate that this new approach exploits the features of the SN P systems to improve the cryptographic algorithm.

Original language	English
Pages (from-to)	67-73
Number of pages	7
Journal	Neurocomputing
Volume	457
DOIs	https://doi.org/10.1016/j.neucom.2021.05.057
State	Published - 7 Oct 2021

Keywords

Astrocyte control
Plasticity
Spiking Neural P Systems
Visual cryptography

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10.1016/j.neucom.2021.05.057

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title = "First SN P visual cryptographic circuit with astrocyte control of structural plasticity for security applications",

abstract = "Cryptographic algorithms have been widely used in all secure data transmissions due their capabilities to hide sensible information against eavesdroppers. Nevertheless, technological progress tends to develop new cryptographic methods based on non-classical computing paradigms. In this work, the first circuit of visual cryptography based on Spiking Neural P systems (VCSN P) is presented. The proposed circuit makes use of new biological behaviors in astrocytes, which are involved in processes of plasticity and pruning control in dendrites, that can be the beginning to new cryptographic algorithms based on SN P systems. To validate the SN P circuit, this was implemented on the Cyclone V field programmable gate array (FPGA) development kit. The results demonstrate that this new approach exploits the features of the SN P systems to improve the cryptographic algorithm.",

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AU - Olvera-Martinez, L.

AU - Jimenez-Borgonio, T.

AU - Frias-Carmona, T.

AU - Abarca-Rodriguez, M.

AU - Diaz-Rodriguez, C.

AU - Cedillo-Hernandez, M.

AU - Nakano-Miyatake, M.

AU - Perez-Meana, H.

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AB - Cryptographic algorithms have been widely used in all secure data transmissions due their capabilities to hide sensible information against eavesdroppers. Nevertheless, technological progress tends to develop new cryptographic methods based on non-classical computing paradigms. In this work, the first circuit of visual cryptography based on Spiking Neural P systems (VCSN P) is presented. The proposed circuit makes use of new biological behaviors in astrocytes, which are involved in processes of plasticity and pruning control in dendrites, that can be the beginning to new cryptographic algorithms based on SN P systems. To validate the SN P circuit, this was implemented on the Cyclone V field programmable gate array (FPGA) development kit. The results demonstrate that this new approach exploits the features of the SN P systems to improve the cryptographic algorithm.

KW - Astrocyte control

KW - Plasticity

KW - Spiking Neural P Systems

KW - Visual cryptography

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JO - Neurocomputing

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First SN P visual cryptographic circuit with astrocyte control of structural plasticity for security applications

Abstract

Keywords

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