Digital Teaching
For further information on the online courses offered in the summer term 2021, please visit the website of the measurement and sensor technology group: [url=https://www.etit.tu-darmstadt.de/must/menu_teaching/index.en.jsp]Courses Measurement and Sensor Technology Technical University of Darmstadt (tu-darmstadt.de)[/url]
Lehrinhalte
Basic physical quantities, fundamental forces, stationary charges - electrostatics, Coulombs law, superposition, electrical field, electric flow, Gauss law, area charge density, electrical potential and difference of potential, capacitor and the term capacity, charging process, polarization, moving charge flow field, drift velocity, electrical current, Ohms law, electrical power, voltage- and current source, battery, impedance matching, power efficiency ratio, Kirchhoffs circuit laws, linear direct current circuits, the term magnetism, magnetic field, magnetic flux, electromagnet, electrodynamic principle Lorentz force, electric motor, cylindrical inductor and the term inductivity, Biot-Savart and Ampéres circuital law, magnetization, magnetic excitation and magnetic flux density, matter in magnetic field and explanation of hysteresis curve, Lenzs law, Faradays law, principle of a generator, harmonic alternating current, principles of alternating quantities, pointer diagrams, basic elements in alternating current circuits, power of alternating currents, impedance, transient processes in RC- and RL-elements, ODE of first order, complex variable domain, transformer, three-phase electric power, resonant circuit and mechanical analogy, two- and four-terminal network, measurement amplifier and control circuit, electric power and electromagnetic wave.
Literature
[list]
[*]Giancoli, Douglas C.: Physik Lehr- und Übungsbuch, Kapitel 21-32., 3. erweiterte Auflage, Pearson Studium Verlag, 2010 (primary literature, relevant excerpt < 15% according to UrhG Par 60a Abs. 1 of March 1st, 2018 is available for download via the teaching platform for registered students only).
[*]Purcell, Edward M.: Elektrizität und Magnetismus, 4. Auflage, Vieweg Verlag, 1989 (in-depth).
[*]Bergmann, Schaefer.: Lehrbuch der Experimentalphysik - Elektromagnetismus, Band 2, 9. Auflage, de Gruyter Verlag, 2006 (in-depth).
[/list]
[b]Lecture documents:[/b]
[list]
[*]Lecture notes with illustrations to download and write down in lecture via teaching platform,
[*]Recordings (picture and sound) of Visualizer via teaching platform after each lecture,
[*]Lecture slides with handwritten additions and sketches of the lecturer for download via teaching platform after each lecture.
[/list]
Voraussetzungen
Mathematics I, School knowledge of physics
Erwartete Teilnehmerzahl
600-1000
Further Grading Information
[b]Learning Outcomes[/b]
On successful completion of this module, students should be able to:
[list]
[*]analyze electric and magnetic fields, as well as the electric flux field, by utilizing Maxwells equations in integral form,
[*]calculate currents and voltages in DC and AC circuits,
[*]calculate transient switching events,
[*]illustrate the underlying principles of electrical machines (motor, generator, transformer),
[*]illustrate the basics of resonant circuits, measurement amplifiers and closed loop systems,
[*]calculate energy- and information transfer via electric lines and electromagnetic waves.
[/list]
Online-Angebote
Moodle
For further information on the online courses offered in the summer term 2021, please visit the website of the measurement and sensor technology group: [url=https://www.etit.tu-darmstadt.de/must/menu_teaching/index.en.jsp]Courses Measurement and Sensor Technology Technical University of Darmstadt (tu-darmstadt.de)[/url]
Lehrinhalte
Basic physical quantities, fundamental forces, stationary charges - electrostatics, Coulombs law, superposition, electrical field, electric flow, Gauss law, area charge density, electrical potential and difference of potential, capacitor and the term capacity, charging process, polarization, moving charge flow field, drift velocity, electrical current, Ohms law, electrical power, voltage- and current source, battery, impedance matching, power efficiency ratio, Kirchhoffs circuit laws, linear direct current circuits, the term magnetism, magnetic field, magnetic flux, electromagnet, electrodynamic principle Lorentz force, electric motor, cylindrical inductor and the term inductivity, Biot-Savart and Ampéres circuital law, magnetization, magnetic excitation and magnetic flux density, matter in magnetic field and explanation of hysteresis curve, Lenzs law, Faradays law, principle of a generator, harmonic alternating current, principles of alternating quantities, pointer diagrams, basic elements in alternating current circuits, power of alternating currents, impedance, transient processes in RC- and RL-elements, ODE of first order, complex variable domain, transformer, three-phase electric power, resonant circuit and mechanical analogy, two- and four-terminal network, measurement amplifier and control circuit, electric power and electromagnetic wave.
Literature
[list]
[*]Giancoli, Douglas C.: Physik Lehr- und Übungsbuch, Kapitel 21-32., 3. erweiterte Auflage, Pearson Studium Verlag, 2010 (primary literature, relevant excerpt < 15% according to UrhG Par 60a Abs. 1 of March 1st, 2018 is available for download via the teaching platform for registered students only).
[*]Purcell, Edward M.: Elektrizität und Magnetismus, 4. Auflage, Vieweg Verlag, 1989 (in-depth).
[*]Bergmann, Schaefer.: Lehrbuch der Experimentalphysik - Elektromagnetismus, Band 2, 9. Auflage, de Gruyter Verlag, 2006 (in-depth).
[/list]
[b]Lecture documents:[/b]
[list]
[*]Lecture notes with illustrations to download and write down in lecture via teaching platform,
[*]Recordings (picture and sound) of Visualizer via teaching platform after each lecture,
[*]Lecture slides with handwritten additions and sketches of the lecturer for download via teaching platform after each lecture.
[/list]
Voraussetzungen
Mathematics I, School knowledge of physics
Erwartete Teilnehmerzahl
600-1000
Further Grading Information
[b]Learning Outcomes[/b]
On successful completion of this module, students should be able to:
[list]
[*]analyze electric and magnetic fields, as well as the electric flux field, by utilizing Maxwells equations in integral form,
[*]calculate currents and voltages in DC and AC circuits,
[*]calculate transient switching events,
[*]illustrate the underlying principles of electrical machines (motor, generator, transformer),
[*]illustrate the basics of resonant circuits, measurement amplifiers and closed loop systems,
[*]calculate energy- and information transfer via electric lines and electromagnetic waves.
[/list]
Online-Angebote
Moodle
- Lehrende: Claas Hartmann
- Lehrende: Mario Kupnik
- Lehrende: Sonja Wismath
Semester: ST 2021