B.E. Electrical Engineering:Machine and Drive Dynamics

First Year: Semester I

Mathematics I
Engineering graphics
Computer Programming
Physics
Solid Mechanics
Communication Skills

First Year: Semester-II

Mathematics II
Manufacturing Process
Chemistry
Electrical and Electronic Science
Thermodynamics
Organizational Behavior


Second Year- Semester - I

Semiconductor Devices
Measurement Science and Techniques
Digital Electronic Circuits
Circuit Theory
Electromechanical Energy conversion
Electromagnetic Fields
Human Values, Ethics and IPR

Second Year- Semester – II

Numerical and Statistical Methods
Fluid Mechanics
Power Generation and Economics
Analog Electronic Circuits
Electrical and Electronic Measurements
Transmission and Distribution of Power
Environmental Studies

Third Year- Semester – I

Power Electronics
Asynchronous Machines
Switch gear and Protection
Microprocessors
Optimization Techniques
Engineering Economics
Summer Training (6 Weeks after 2nd year during summer vacation)


Third Year- Semester – II

Total Quality Management
Control Systems
Synchronous Machines
Power System Analysis
Flexible AC Transmission Systems


Fourth Year- Semester – I

High Voltage Engineering
Operation and Control of Power Systems
Electric Drives
Intelligent Algorithms in Power Systems


Fourth Year- Semester – II

Project Semester
Project
Industrial Training


Machine and Drive Dynamics

General: Volt-ampere and torque equations under stationary and rotating reference frames. Instantaneous symmetrical components and generalized operational equivalent circuits. Space vector concepts.

Modeling of D.C. Machines: Analysis under motoring and generating mode. Simulation for transient and dynamic conditions.

Modeling of Synchronous machines: Various Transformation Models, d-q transformations fixed to field structure-steady state and dynamic equations. Phasor diagram for cylindrical rotor and salient pole machines, electromagnetic and reluctance torque. Response under short circuit conditions.

Modeling of induction machines: Equations under stationary and rotating reference frames. Derivation of equivalent circuits. Correlation of inductances. Run up transients. Dynamics under load change, Speed reversal and braking. Unbalanced and asymmetrical Operation.

Modeling of Advanced Machines: Modeling and analysis of permanent magnet, Switched reluctance and stepper motors. Development of Computer Software using latest simulation tools to predict the behavior of different machines. Drive Dynamics: Dynamic modelling of AC and DC drive system using recent techniques.

Laboratory: Simulation of transient, steady state conditions of induction machine, DC machine and Synchronous machine, Performance characteristics of AC/ DC machines. Simulation using Matlab.