A 5th-order method for 1D-device solution

Author

Buscemi, F. ; Rudan, M. ; Piccinini, E. ; Brunetti, R.

Author_Institution

Dept. of Phys., Comput. Sci., & Math., Univ. of Modena & Reggio Emilia, Modena, Italy

fYear

2014

fDate

3-6 June 2014

Firstpage

1

Lastpage

4

Abstract

The so-called Numerov process provides a three-point interpolation with an ~η⁵ accuracy in grid´s size η, much better than the standard finite-difference scheme that keeps the ~η² terms. Such a substantial improvement is achieved with a negligible increase in computational cost. As the method is applicable to second-order differential equations in one dimension, it is an ideal tool for solving, e.g., the Poisson and Schrödinger equations in ballistic electron devices, where the longitudinal (that is, along the channel) problem is typically separated from the lateral one and solved over a uniform grid. Despite its advantage, the Numerov process has found limited applications, due to the difficulty of keeping the same precision in the boundary conditions. A method to work out the boundary conditions consistently with the rest of the scheme is presented, and applications are shown.

Keywords

Poisson equation; Schrodinger equation; differential equations; interpolation; 1D-device solution; 5th-order method; Numerov process; Poisson equations; Schrödinger equations; ballistic electron devices; boundary conditions; finite-difference scheme; longitudinal problem; second-order differential equations; three-point interpolation; uniform grid; Accuracy; Boundary conditions; Equations; Interpolation; Mathematical model; Wave functions;

fLanguage

English

Publisher

ieee

Conference_Titel

Computational Electronics (IWCE), 2014 International Workshop on

Conference_Location

Paris

Type

conf

DOI

10.1109/IWCE.2014.6865849

Filename

6865849