Response of Electrical Activity in an
Improved Neuron Model under Electromagnetic Radiation and Noise
Feibiao Zhan,Liu Shenquan
Electrical activities are ubiquitous
neuronal bioelectric phenomena, which have many different modes to encode the
expression of biological information, and constitute the whole process of
signal propagation between neurons. Therefore, we focus on the electrical
activities of neurons, which is also causing widespread concern among
neuroscientists. In this paper, we mainly investigate the electrical activities
of the Morris-Lecar (M-L) model with electromagnetic radiation or Gaussian
white noise, which can restore the authenticity of neurons in realistic neural
network. First, we explore dynamical response of the whole system with
electromagnetic induction (EMI) and Gaussian white noise. We find that there
are slight differences in the discharge behaviors via comparing the response of
original system with that of improved system, and electromagnetic induction can
transform bursting or spiking state to quiescent state and vice versa.
Furthermore, we research bursting transition mode and the corresponding periodic
solution mechanism for the isolated neuron model with electromagnetic induction
by using one-parameter and bi-parameters bifurcation analysis. Finally, we
analyze the effects of Gaussian white noise on the original system and coupled
system, which is conducive to understand the actual discharge properties of
realistic neurons.
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