| 3 |
Course content |
From Physics to Electrical Engineering- Lumped matter discipline
- Batteries, resistors, current sources and basic laws
- I-V characteristics and modeling physical systems
Basic Circuit Analysis Methods- KCL and KVL, voltage and current dividers
- Parallel and serial resistive circuits
- More complicated circuits
- Dependent sources, and the node method
- Superposition principle
- Thevenin and Norton method of solving linear circuits
- Circuits involving diode.
Analysis of Non-linear Circuits- Toy example of non-linear circuit and its analysis
- Incremental analysis
- Introduction to MOSFET Amplifiers
- Large and small signal analysis of MOSFETs
- MOSFET as a switch
Introduction to the Digital World- Voltage level and static discipline
- Boolean logic and combinational gates
- MOSFET devices and the S Model
- MOSFET as a switch; revisited
- The SR model of MOSFETs
- Non-linearities: A snapshot
Capacitors and Inductors- Behavior of capacitors, inductors and its linearity
- Basic RC and RLC circuits
- Modeling MOSFET anomalies using capacitors
- RLC circuit and its analysis
- Sinusoidal steady state analysis
- Introduction to passive filters
Operational Amplifier Abstraction- Introduction to Operational Amplifier
- Analysis of Operational amplifier circuits
- Op-Amp as active filters
- Introduction to active filter design
Transformers and Motors- AC Power circuit analysis
- Polyphase circuits
- Introduction to transformers
- Introduction to motors
|
| 4 |
Texts/References |
- Anant Agarwal and Jefferey H. Lang, “Foundations of Analog and Digital Electronics Circuits,” Morgan Kaufmann publishers, 2005
- Wlilliam H. Hayt, Jr., Jack E. Kemmerly and Steven M. Durbin, “Engineering Circuit Analysis,” Tata McGraw-Hill
- Theodore Wildi, “Electrical Machines, Drives and Power Systems,” Pearson, 6-th edition.
- V. Del. Toro, “Electrical Engineering Fundamentals,” Pearson publications, 2nd edition.
|