AbstractIn this paper, we describe a numerical approach based on finite difference method to solve a mathematical model arising from a model of neuronal variability. The mathematical modelling of the determination of the expected time for generation of action potentials in nerve cells by random synaptic inputs in dendrites includes a general boundary-value problem for singularly perturbed differential–difference equation with small shifts. In the numerical treatment for such type of boundary-value problems, first we use Taylor approximation to tackle the terms containing small shifts which converts it to a boundary-value problem for singularly perturbed differential equation. A rigorous analysis is carried out to obtain priori estimates on ...
A novel approach for simulating potential propagation in neuronal branches with high accuracy is dev...
A stochastic model for single neuron's activity is constructed as the continuous limit of a birth-an...
Methods of comparing discrete and continuous cable models of single neurons and dynamical phenomena ...
AbstractIn this paper, we describe a numerical approach based on finite difference method to solve a...
AbstractThe objective of this paper is to present a numerical study of a class of boundary value pro...
AbstractIn this paper a finite difference method is presented for singularly perturbed differential-...
Introduction In this chapter we will discuss some practical and technical aspects of numerical meth...
We consider a simple neural field model in which the state variable is dendritic voltage, and in whi...
We consider a noisy leaky integrate-and-fire (NLIF) neuron model. The resulting nonlinear time-depen...
A High-order accurate finite difference scheme is derived for a non-linear soliton model of nerve si...
AbstractIn this article, numerical study for the fractional Cable equation which is fundamental equa...
In this article, numerical study for the fractional Cable equation which is fundamental equations fo...
In this work, we consider numerical solutions of the FitzHugh–Nagumo system of equations describing ...
In this paper there is presented a model of electrical signal propagation in neurons. The behaviors...
The Wright-Fisher model is an Itô stochastic differential equation that was originally introduced to...
A novel approach for simulating potential propagation in neuronal branches with high accuracy is dev...
A stochastic model for single neuron's activity is constructed as the continuous limit of a birth-an...
Methods of comparing discrete and continuous cable models of single neurons and dynamical phenomena ...
AbstractIn this paper, we describe a numerical approach based on finite difference method to solve a...
AbstractThe objective of this paper is to present a numerical study of a class of boundary value pro...
AbstractIn this paper a finite difference method is presented for singularly perturbed differential-...
Introduction In this chapter we will discuss some practical and technical aspects of numerical meth...
We consider a simple neural field model in which the state variable is dendritic voltage, and in whi...
We consider a noisy leaky integrate-and-fire (NLIF) neuron model. The resulting nonlinear time-depen...
A High-order accurate finite difference scheme is derived for a non-linear soliton model of nerve si...
AbstractIn this article, numerical study for the fractional Cable equation which is fundamental equa...
In this article, numerical study for the fractional Cable equation which is fundamental equations fo...
In this work, we consider numerical solutions of the FitzHugh–Nagumo system of equations describing ...
In this paper there is presented a model of electrical signal propagation in neurons. The behaviors...
The Wright-Fisher model is an Itô stochastic differential equation that was originally introduced to...
A novel approach for simulating potential propagation in neuronal branches with high accuracy is dev...
A stochastic model for single neuron's activity is constructed as the continuous limit of a birth-an...
Methods of comparing discrete and continuous cable models of single neurons and dynamical phenomena ...