Dynamic analysis of the discrete fractional-order Rulkov neuron map

Dynamic analysis of the discrete fractional-order Rulkov neuron map

Human evolution is carried out by two genetic systems based on DNA and another based on the transmission of information through the functions of the nervous system. In computational neuroscience, mathematical neural models are used to describe the biological function of the brain. Discrete-time neur...

Full description

Saved in:
Bibliographic Details
Published in:Mathematical biosciences and engineering : MBE Vol. 20; no. 3; pp. 4760 - 4781
Main Authors: Vivekanandhan, Gayathri, Abdolmohammadi, Hamid Reza, Natiq, Hayder, Rajagopal, Karthikeyan, Jafari, Sajad, Namazi, Hamidreza
Format: Journal Article
Language:English
Published: United States AIMS Press 01-01-2023
Subjects:
Algorithms
bifurcation
Brain
discrete fractional-order
Humans
Neurons - physiology
Nonlinear Dynamics
rulkov neuron map
stability analysis
synchronization
Time Factors
Rulkov neuron map
synchronization
bifurcation
discrete fractional-order
stability analysis
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Human evolution is carried out by two genetic systems based on DNA and another based on the transmission of information through the functions of the nervous system. In computational neuroscience, mathematical neural models are used to describe the biological function of the brain. Discrete-time neural models have received particular attention due to their simple analysis and low computational costs. From the concept of neuroscience, discrete fractional order neuron models incorporate the memory in a dynamic model. This paper introduces the fractional order discrete Rulkov neuron map. The presented model is analyzed dynamically and also in terms of synchronization ability. First, the Rulkov neuron map is examined in terms of phase plane, bifurcation diagram, and Lyapunov exponent. The biological behaviors of the Rulkov neuron map, such as silence, bursting, and chaotic firing, also exist in its discrete fractional-order version. The bifurcation diagrams of the proposed model are investigated under the effect of the neuron model's parameters and the fractional order. The stability regions of the system are theoretically and numerically obtained, and it is shown that increasing the order of the fractional order decreases the stable areas. Finally, the synchronization behavior of two fractional-order models is investigated. The results represent that the fractional-order systems cannot reach complete synchronization.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1551-0018
DOI:10.3934/mbe.2023220