Difference between revisions of "CEM"

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=== Course Description ===
 
=== Course Description ===
Introduction to fundamental ideas and techniques of finite element method and modelling in electromagnetics. Basics of electromagnetics, equations of static magnetic, electrostatic, eddy current and time-dependent problems, Helmholtz-equation, basic of finite element method, nodal and edge shape functions, boundary conditions, mesh operations. The course Random variables, expectation and conditional expectation, joint distributions, covariance, moment generating function, central limit theorem, weak and strong laws of large numbers, discrete time stochastic processes, stationarity, power spectral densities and the Wiener-Khinchine theorem, Gaussian processes, Poisson processes, Brownian motion. The course solves problems in selected areas such as fuel injection solenoid, eddy current brake, permanent magnet motor and an automobile cable harness analysis.
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Introduction to fundamentals and techniques of finite element method and modelling in electromagnetics. The course includes: basics of electromagnetics, equations of static magnetic, electrostatic, eddy current and time-dependent problems, Helmholtz-equation, basic of finite element method, nodal and edge shape functions, boundary conditions, mesh operations. The course participants meet the following automotive examples in practice, fuel injection solenoid, eddy current brake, permanent magnet motor and an automobile cable harness analysis.

Revision as of 20:11, 28 January 2019

Introduction to Computational Electromagnetics

Instructors

  • Dániel Marcsa (lecturer)
  • Lectures: Monday, 14:50 - 16:25 (D201), 16:30 - 17:15 (D105)
  • Office hours: by request

Teaching Assistants

  • -
  • Office hours: -.

Course Description

Introduction to fundamentals and techniques of finite element method and modelling in electromagnetics. The course includes: basics of electromagnetics, equations of static magnetic, electrostatic, eddy current and time-dependent problems, Helmholtz-equation, basic of finite element method, nodal and edge shape functions, boundary conditions, mesh operations. The course participants meet the following automotive examples in practice, fuel injection solenoid, eddy current brake, permanent magnet motor and an automobile cable harness analysis.

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