Kapil K. Sharma scite author profile

We report here an effect in a four-level ladderlike system, which is in contrast to the usual quantum interference effects such as electromagnetically induced transperency ͑EIT͒ or coherent population trapping: we predict the occurrence of a narrow absorption peak within the EIT window when an EIT atomic system interacts with an additional driving rf field. The Doppler-free-central absorption appears when the three-photon resonance condition is satisfied. In the limit of the rf field strength ⍀ r f →0, the usual EIT profile is recovered.

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Numerical treatment of a mathematical model arising from a model of neuronal variability

Kadalbajoo

Sharma

2005

Journal of Mathematical Analysis and Applications

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In 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 the solution of the problem and its derivatives up to third order. Then a parameter uniform difference scheme is constructed to solve the boundary-value problem so obtained. A parameter uniform error estimate for the numerical scheme so constructed is established. Though the convergence of the difference scheme is almost linear but its beauty is that it converges independently of the singular perturbation parameter, i.e., the numerical scheme converges for each value of the singular perturbation parameter (however small it may be but remains positive). Several test examples are solved to demonstrate the efficiency of the numerical scheme presented in the paper and to show the effect of the small shift on the solution behavior.  2005 Elsevier Inc. All rights reserved.

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A parameter-uniform implicit difference scheme for solving time-dependent Burgers’ equations

Kadalbajoo

Sharma²,

Awasthi

2005

Applied Mathematics and Computation

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Kapil K. Sharma

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Numerical Analysis of Boundary-Value Problems for Singularly-Perturbed Differential-Difference Equations with Small Shifts of Mixed Type

Numerical analysis of singularly perturbed delay differential equations with layer behavior

Atomic coherence effects in four-level systems: Doppler-free absorption within an electromagnetically-induced-transparency window

Numerical treatment of a mathematical model arising from a model of neuronal variability

A parameter-uniform implicit difference scheme for solving time-dependent Burgers’ equations

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