|
|
|
||
Last update: VEJCHOD (19.02.2007)
|
|
||
Last update: VEJCHOD/MFF.CUNI.CZ (03.04.2008)
Students will understand the mathematical modelling of the semiconductor devices and the box method. Students will get an overview about the techniques of the a posteriori error estimation for the elliptic and parabolic partial differential equations. |
|
||
Last update: T_KNM (17.05.2008)
Selberherr S.: Analysis and Simulation of Semiconductor Devices. Wien, Springer Verlag, l984. Markowich P.A.: The Stationary Semiconductor Equations. Wien, Springer Verlag, l986. Křížek M., Neittaanmaki P.: Finite Element Approximation of Variational Problems and Applications. Harlow, Longman, l990. Křížek M., Segeth K.: Numerické modelování problémů elektrotechniky. Praha, Karolinum, 2001. |
|
||
Last update: T_KNM (17.05.2008)
Lectures in a lecture hall. |
|
||
Last update: T_KNM (17.05.2008)
Examination according to the syllabus. |
|
||
Last update: T_KNM (17.05.2008)
The fundamental description of the electrostatic potential, density of elektrons, and density of holes in a semiconductor device by a system of three (in general nonlinear) partial differential equations of second order (van Roosbroeck system).
Overview of mathematical properties of the model and of principal classes of numerical methods for its solution.
A survey of approaches for a posteriori error estimation: explicit and implicit residual estimates, hierarchic estimates, estimates based on the adjoint and on the dual problem, estimates based on the postprocessing. |
|
||
Last update: T_KNM (17.05.2008)
Elementary knowledge of partial differential equations, functional analysis and the finite element method is assumed. This is a continuation of the lectures Numerical Simulation in Electrical Engineering 1 but exceptionally it is possible to register the part 2 without the part 1. |