ECE 568
ECE 568 - Modeling and Control of Electromechanical Systems
Spring 2021
| Title | Rubric | Section | CRN | Type | Hours | Times | Days | Location | Instructor |
|---|---|---|---|---|---|---|---|---|---|
| Model & Cntrl Electromech Syst | ECE568 | R | 34004 | OLC | 4 | 1000 - 1120 | M W | Arijit Banerjee |
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Official Description
Fundamental electrical and mechanical laws for derivation of machine models; simplifying transformations of variables in electrical machines; power electronics for motor control; time-scale separation; feedback linearization and nonlinear control as applied to electrical machines. Typical electromechanical applications in actuators, robotics, and variable speed drives. Course Information: Prerequisite: ECE 431 and ECE 515.
Subject Area
- Power and Energy Systems
Course Director
Description
Fundamental electrical and mechanical laws for derivation of dynamic models of electrical machines; simplifying transformations for machine variables; power electronics for motor control; drive systems and basic control schemes; nonlinear control as applied to electrical machines, including feedback linearization and averaging techniques. Typical electromechanical applications in actuators, robotics, variable speed drive systems, electric and hybrid vehicles, and alternative energy systems.
Notes
Same as ME 565.
Topics
- Advanced electromechanics: analysis of electrical machines, electrostatic machines, electromechanical sensors, harmonic effects
- Examples of machines and their dynamic models: equations of dc machines, permanent magnet modeling, synchronous motors, Park's transformation, induction motors, general rotating transformations
- Models and circuits for electrical drives: Drive system models for electrical and mechanical terminals, power electronics for control of electrical machines, drive control objectives, dynamic examples, ac motor control methods including field-oriented control, models of vehicle loads, models of windmills and other loads
- Applied nonlinear system methods for drives: periodic system transformations, averaging theory, time-scale separation, variable-structure control applications, feedback linearization
Detailed Description and Outline
Topics:
- Advanced electromechanics: analysis of electrical machines, electrostatic machines, electromechanical sensors, harmonic effects
- Examples of machines and their dynamic models: equations of dc machines, permanent magnet modeling, synchronous motors, Park's transformation, induction motors, general rotating transformations
- Models and circuits for electrical drives: Drive system models for electrical and mechanical terminals, power electronics for control of electrical machines, drive control objectives, dynamic examples, ac motor control methods including field-oriented control, models of vehicle loads, models of windmills and other loads
- Applied nonlinear system methods for drives: periodic system transformations, averaging theory, time-scale separation, variable-structure control applications, feedback linearization
Same as ME 565.
Texts
Notes and current papers.
Recommended:
W. Leonhard, Control of Electrical drives, Springer-Verlag, 2001.
P. Krause, D. Wasynczuk, and S. D. Sudhoff, Analysis of Electric Machinery, IEEE Press, 2002.
Recommended:
W. Leonhard, Control of Electrical drives, Springer-Verlag, 2001.
P. Krause, D. Wasynczuk, and S. D. Sudhoff, Analysis of Electric Machinery, IEEE Press, 2002.
Last updated
2/13/2013