Description
Power Electronic System Design
Linking Differential Equations, Linear Algebra, and Implicit Functions
Authors: Wu Keng C., Wu Keng C.
Language: EnglishSubject for Power Electronic System Design:
Keywords
Capacitor; Current lagging; Current leading; Differential form; Inductor; Integral form; Voltage lagging; Voltage leading; Zero-crossing; Dissipative parasitic; Fourier analysis; RC network; RL network; Serial form; Current mirror; Differential pair; Diode equation; light-emitting diode (LED); Forward current; Forward voltage; Implicit function; Eigen value; Eigen vector; Eigen mode; Eigen configuration; Amplifier; Class-A; Class-B; Class-D; Direct coupled; Pulse width modulation; Window comparator; Current feedback; Feedback isolation; Phase plane; PID; State feedback; Voltage feedback; Close loop; Level control; Mode control; Multiple loop; Open loop; Single loop; State control; Zone control; Gain margin; Loop gain; Phase margin; Shunt mode; Type II amplifier; Type III amplifier
405 p. · 15x22.8 cm · Paperback
Description
/li>Contents
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1. Capacitor and Inductor2. First Order Circuits3. Current Source4. Second Order5. Gain Blocks6. Feedback Approaches7. Control Practices8. Linear Regulator9. Switch-mode DC/DC converters10. AC drives, rectification and inductive loads11. Rotation, Three Phase Synthesis, and Space Vector Concepts
- Outlines the physical meaning of differential forms and integral forms in designing circuits for power applications
- Delivers techniques to set up linear algebraic matrix representations of complex circuits
- Explores key approaches obtaining steady state and describes methods using implicit functions for close-loop representation
- Describes how to implement vector representation of rotational driving sources
- Supplemented by MATLAB implementations