

Module code: FT08 

3V+1U (4 hours per week) 
5 
Semester: 2 
Mandatory course: yes 
Language of instruction:
German 
Assessment:
Written exam 100 min.
[updated 30.09.2020]

FT08 (P2420056, P2420057) Automotive Engineering, Bachelor, ASPO 01.10.2011
, semester 2, mandatory course
FT08 (P2420056, P2420057) Automotive Engineering, Bachelor, ASPO 01.10.2015
, semester 2, mandatory course
FT08 (P2420056, P2420057) Automotive Engineering, Bachelor, ASPO 01.04.2016
, semester 2, mandatory course
FT08 (P2420056, P2420057) Automotive Engineering, Bachelor, ASPO 01.10.2019
, semester 2, mandatory course

60 class hours (= 45 clock hours) over a 15week period. The total student study time is 150 hours (equivalent to 5 ECTS credits). There are therefore 105 hours available for class preparation and followup work and exam preparation.

Recommended prerequisites (modules):
None.

Recommended as prerequisite for:
FT20 Electric Vehicle Drive Systems FT24.2 Data Communication FT60
[updated 12.02.2020]

Module coordinator:
Prof. Dr. HansWerner Groh 
Lecturer: Prof. Dr. HansWerner Groh
[updated 12.02.2020]

Learning outcomes:
After successfully completing this course, students will be able to:  work confidently with the basic electrotechnical variables and describe resistors, capacitors, coils, diodes, transistors as well as their function and exemplary application.  apply different model descriptions of electrical components and networks in a problemadapted way and thus, be able to perform simple calculations by themselves.  analyze and calculate simple problems in electromagnetic fields and applications of the law of induction.  name, correctly apply and interpret basic electrical and electronic equations.  recognize and explain the interaction between electrical and magnetic circuits.  name an application of the theory in a vehicle and explain it.
[updated 30.09.2020]

Module content:
Basics Physical quantity and measurement systems, SI units Direct current: Electrical charge, current, source, voltage, electrical circuit; ohmic resistance: Temperature behavior, designs, standard series, interconnections, Kirchhoff´s mesh and point rule, current and voltage divider Electric field: Variables: Field strength, displacement density, fundamental laws; field calculation: Point, line, surface charge, superposition; potential, voltage, boundary layer behavior; capacitors; dielectric layers Magnetic field: Variables, fundamental laws, boundarylayer behavior; field calculation; Faraday´s law of induction, applications; self inductance, energy, moving charges; transformer, RL circuit, switching operations Alternating/threephase current theory: Periodic function, characteristics of the sinusoidal alternating quantity, mathematical; operations, basic bipoles R, L, C, power, pointer calculation, complex calculation, circuit calculation with image function: complex resistance, network calculation, symmetrical 3phase system, low and high pass Exercises: Sample calculations on the above topics
[updated 30.09.2020]

Teaching methods/Media:
Lecture and tutorials
[updated 30.09.2020]

Recommended or required reading:
 Gerd Hagmann: Grundlagen der Elektrotechnik, 16., durchges. u. korr. Aufl., AULAVerlag, Wiebelsheim, 2013, ISBN 9783891047798  Gerd Hagmann: Aufgabensammlung zu Grundlagen der Elektrotechnik, 16., durchges. u. korr. Aufl., AULAVerlag, Wiebelsheim, 2013, 9783891047712  Georg Bosse: Grundlagen der Elektrotechnik, Band I _ IV, VDIVerlag, Düsseldorf, 1996, ISBN 3184015734, ISBN 3184015475, 3184015742, 3184015750
[updated 30.09.2020]
