This paper presents the use of the Exodus method to compute the potential distribution in a conducting prolate spheroidal shell. The transition probabilities for the Exodus method simulation were obtained from the finite-difference scheme transformation of the prolate spheroid Laplace equation. This method is independent of the random number generation from the computing facility and gives more accurate results than the fixed random walk Monte Carlo method. The results obtained matched perfectly with those obtained by using an exact solution and explicit finite-difference solution method
A new general stochastic-deterministic approach for a numerical solution of boundary value problems ...
This thesis works on a problem that involves calculating the total electrostatic interaction energy ...
In this paper, we present the Abramov approach for the numerical simulation of the whispering galler...
This paper presents a fixed random walk Monte Carlo method for computing potential distribution with...
In this paper, we implement the use of Exodus method to compute potential distribution in a conducti...
The Monte Carlo Methods have been applied with great success to the solution of electromagnetic prob...
The explicit finite-difference solution method for computing potential distribution within spheroida...
In the present paper, an algorithm for the numerical solution of the external Dirichlet generalized ...
AbstractIn this paper, we describe different methods of computing the eigenvalues associated with th...
The Dirichlet ordinary and generalized harmonic problems for some 3D finite domains are considered. ...
The internal potential of an inhomogeneous layered spheroid with a small ellipticity and general exp...
In engineering optimization, the key challenge is often how to properly model the electromagnetic pr...
AbstractWe present a new model for a variety of electric polarization effects on oblate and prolate ...
A series expansion is derived for the potential distribution, caused by a dipole source in a multila...
Abstract—This paper presents an alternative analysis of obtaining radiated electromagnetic (EM) fiel...
A new general stochastic-deterministic approach for a numerical solution of boundary value problems ...
This thesis works on a problem that involves calculating the total electrostatic interaction energy ...
In this paper, we present the Abramov approach for the numerical simulation of the whispering galler...
This paper presents a fixed random walk Monte Carlo method for computing potential distribution with...
In this paper, we implement the use of Exodus method to compute potential distribution in a conducti...
The Monte Carlo Methods have been applied with great success to the solution of electromagnetic prob...
The explicit finite-difference solution method for computing potential distribution within spheroida...
In the present paper, an algorithm for the numerical solution of the external Dirichlet generalized ...
AbstractIn this paper, we describe different methods of computing the eigenvalues associated with th...
The Dirichlet ordinary and generalized harmonic problems for some 3D finite domains are considered. ...
The internal potential of an inhomogeneous layered spheroid with a small ellipticity and general exp...
In engineering optimization, the key challenge is often how to properly model the electromagnetic pr...
AbstractWe present a new model for a variety of electric polarization effects on oblate and prolate ...
A series expansion is derived for the potential distribution, caused by a dipole source in a multila...
Abstract—This paper presents an alternative analysis of obtaining radiated electromagnetic (EM) fiel...
A new general stochastic-deterministic approach for a numerical solution of boundary value problems ...
This thesis works on a problem that involves calculating the total electrostatic interaction energy ...
In this paper, we present the Abramov approach for the numerical simulation of the whispering galler...