Electrical Engineering I

Dr. Cheng Yang, Winter Term, in English

Students learn to explain the fundamental formulas, relations, and methods of the theory of time-independent and time -dependent electromagnetic fields. They can explicate the principal behavior of electrostatic, magnetostatic, current density fields and quasistationary fields with regard to respective sources. They can characterize resistors, capacitors, and inductors from a circuit and field perspective. They can analyze electric networks and complex electromagnetic fields by means of superposition principle. The students are aware of applications for the theory of time-independent and time -dependent electromagnetic fields and are able to explicate these.

Specifically students learn to apply a variety of procedures in order to solve network equations for for general electric network problems. The students can assess the principal effects of given circuit and field sources in different networks or materials and analyze these quantitatively. They can deduce meaningful quantities for the characterization of electrostatic, magnetostatic, electrical flow fields and quasistationary fields (capacitances, inductances, resistances, power, energy, etc.) from given circuits and fields and dimension them for practical applications.