Department of Electrical Engineering LECTURE PLAN Course : ED 511 (Power Controller) Course Coordinator : Dr. R. K. Nema Session : July – Nov. 2019 Date Lect No Topic to be covered

18/07/19 L1 Introduction to Power Controller

23/07/19 L2 DC-DC Converters

25/07/19 L3 Buck Converter with Ideal Components-I

25/07/19 L4 Design of Buck Converter with Ideal Components-II

30/07/19 L5 Analysis of Boost Converter with Ideal Components-I

01/08/19 L6 Design of Boost Converter with Ideal Components-II

06/08/19 L7 Buck-Boost Converter with Ideal Components-I

08/08/19 L8 Design of Buck-Boost Converter with Ideal Components-II

08/08/19 L9 Analysis and Design of Sepic Converter with Ideal Components

13/02/19 L10 Analysis and Design of Cuk Converter with Ideal Components

15/08/19 Independence Day - HOLIDAY

20/08/19 L11 Mini Test

22/08/19 L12 Buck Converter with non-Ideal Components

22/08/19 L13 Boost & Buck-Boost Converters with non-Ideal Components

27/08/19 L14 Analysis and Design of DC-DC Converter under DCM

29/08/19 L15 Interleaved Converters

29/08/19 L19 Analysis of Isolated flyback Converter-I

03/09/19 L17 Design of Isolated flyback Converter-II

05/09/19 L18 Analysis of Isolated Forward Converter-I

05/09/19 L19 Analysis and Design of Push Pull Converter

10/09/19 Holiday- Muhharam

12/09/19 L20 Isolated Half Bridge/Full Bridge Converter

12/09/19 L21 Current Fed Converter 17/09/19 L22 Dynamic Modelling of DC/DC Converter -I

19/09/19 L23 Dynamic Modelling of DC/DC Converter -II

19/09/19 L24 Dynamic Modelling of DC/DC Converter -III

24/09/19

26/09/19 Mid Term Exam

26/09/19

01/10/19 L25 Controller Design

03/10/19 L26 Review of Semiconductor Switches

03/10/19 L27 Driver Circuits for Controlled Switches

08/10/19 Holiday-Dussehera

10/10/19 L28 Series –Parallel Operation and Heat Sink Design

10/10/19 L29 SOA and Loss Calculation

15/10/19 L30 Analysis of 1-ph/3-ph Bridge Converters

17/10/19 L31 Effect of Source Impedance and use of freewheeling diode

17/10/19 L32 Multi-Pulse & PWM Rectifiers

22/10/19 L33 1-ph VSI

24/10/19 L34 3-Ph VSI 180 degree mode of operation

24/10/19 L35 3-Ph VSI 120 degree mode of operation

29/10/19

31/10/19 MID SEMESTER BREAK

31/10/19

05/11/19 L36 3-Ph VSI 150 degree mode of operation

07/11/19 L37 Amplitude & harmonic control/reduction techniques,

07/11/19 L38 1- and 3- CSI Inverter.

12/11/19 L39 1- ac-ac regulator circuit.

14/11/19 L40 3- ac-ac regulator circuit-I

14/11/19 L41 3- ac-ac regulator circuit-II

Electrical Engineering Department M. Tech. (Electrical Drives)

Subject: Electrical Drives Subject Code: ED-512 Sem: I Lecture Topic to be covered No. 1. Introduction of electrical drives and applications of it. 2. Block diagram of electrical drives. Detail description of each block. 3. Dynamics of electrical drives. Speed- conventions of drives. 4. Equivalent values of drive parameter. 5. Measurement of moment of inertia, components of load torque. 6. Analysis of steady-state stability criteria. 7. Load equalisation using flywheel. 8. Closed Loop Control of Drives- Current Limit Control, Closed-Loop Torque Control, Closed-Loop Speed Control and Closed-Loop Speed Control. 9. Closed-loop speed control of multi-motor drives. Current and speed sensors. 10. Thermal model of motor for heating & cooling. Classes of motor duty. 11. Determination of motor rating with different duty cycles. 12. Review of DC motor. 13. Mini-Test 14. Speed-control methods (, field and resistance) of DC motor. 15. Braking of DC Motor 16. Transient analysis of DC motor and find out dynamic equivalent circuit of DC motor. 17. Single-phase and three-phase half-controlled and fully controlled rectifier circuits. 18. Analysis of Single-phase fully controlled rectifier for separately excited DC motor. 19. Analysis of Single-phase half-controlled rectifier for separately excited DC motor. 20. Analysis of three-phase fully and half controlled rectifier for separately excited DC motor. 21. Analysis of Single-phase fully controlled rectifier for series DC motor. 22. Advantages of Chopper Controlled Drives and brief Introduction of Chopper 23. Chopper Control of Separately Excited DC Motor- Motoring Mode and Regenerative Mode. 24. Analysis of chopper-controlled series DC motor. 25. Closed-loop speed control scheme for above and below base speed. 26. Minor Test 27. - Performance Analysis of Induction Motor 28. Operation of induction motor drives under unbalanced source voltage and single-phasing. 29. Analysis of induction motor fed from non-sinusoidal voltage supply. 30. Speed control of induction motor drives through voltage (AC voltage control and voltage source inverter). 31. Variable frequency control from voltage sources of an induction motor and voltage sources inverter (VSI). 32. Variable frequency control from current sources of an induction motor and current source inverter (CSI). 33. Control of induction . 34. Rotor Resistance Control- Conventional and Static Rotor Resistance Control 35. Slip power recovery- static scherbious and static kramer drive. 36. drive-Cylindrical-rotor motor 37. Synchronous motor drive- salient-pole motor. 38. Reluctant motor and permanent- motor. 39. Measures for Energy Conservation in Electrical Drives. 40. Contd.- Measures for Energy Conservation in Electrical Drives.

(Dr. Sushma Gupta) (Subject Coordinator)

Electrical Engineering Department M.Tech. I semester Lesson Plan Subject: Modeling and Analysis of Electrical Machines Subject Code: ED-513 Course Coordinator: Dr Pankaj Swarnkar and Dr Savita Nema Session: July- December 2019

Lecture No. Topic to be covered 1. Introduction to subject: Review of Conventional machine theory 2. Introduction to Generalized theory of machine (Assumption) 3. Rotational induced emf 4. Basic models for different rotating machines 5. Kron’s primitive machine 6. Voltage-current relation for Kron’s model 7. Power, torque relations for Kron’s model 8. Park’s Transformation 9. Kron’s Model for DC machine 10. Voltage-current relation for Kron’s model of DC Machine 11. Steady state analysis of DC generator 12. Transient analysis of DC generator 13. Generator operation with displaced brushes 14. Class Test 15. Generator operation on No load and with Load 16. Steady state analysis of DC Motor 17. Transient analysis of DC Motor 18. Sudden application of Inertial load on DC motor 19. Transfer function of DC motor and Generator 20. Kron’s model of and 21. Kron’s model for synchronous machine based on Park’s transformation 22. Voltage-current relation for Kron’s model of synchronous machine 23. Power- angle characteristic for synchronous machine-transient and steady state 24. Short circuit ratio and its effect on design and transient analysis 25. Effect of SCR on V.R. and stability 26. Sudden three phase sc at the synchronous generator terminals 27. Short Circuit armature current characteristics 28. Transient torque 29. D and Q axis equivalent circuits 30. Measurement of reactance and time constant using equivalent Circuit 31. Measurement of reactance and time constant using short circuit oscillogram 32. Kron’s model for Induction machine based on Park’s transformation 33. Torque- speed characteristic of induction machine using generalized approach 34. Single phasing and unbalanced operation of Induction motor 35. speed control of Induction motor

LECTURE PLAN Class : M. Tech. I Sem (ED) Course : ED531 (Power Quality) Course Coordinator : Dr. Suresh Kumar Gawre Session : July – Dec 2019 Lect No Topic to be covered L1- L3 Understanding Power quality, types of power quality disturbances,

L4-L6 Power quality indices, Characteristic curve and standards L7- L9 Causes and effects of power quality disturbances L10-L12 Monitoring of PQ disturbance , detection , feature extraction Methods L13-L15 Classification and decision making schemes for PQ analysis L16-L18 Harmonics Analysis, converter configuration and their contribution to supply harmonics, other sources of harmonics L19-L21 Radio interference, supply standards,

L22-L24 Elimination/suppression of harmonics, classical solutions & their drawbacks, L25-L27 Passive input filters, high power factor pre-regulator L28-L30 Switching control circuit, transformer connections, L31-L33 Elimination/suppression of harmonics using active power filters – topologies,

L34-L36 Control methods, PWM converter as a voltage source active filter, current source active filter,

L37-L39 Electro-magnetic compatibility, constant frequency control, constant tolerance band control, L40-L42 variable tolerance band control, discontinuous current control

Course Outcome: This course will provide concept of Power quality, its characterization, Monitoring of PQ disturbance, Power quality Analysis, classical and advanced solutions and mitigation techniques. PG students will learn theoretical as well as practical aspects of Power quality Analysis.

LECTURE PLAN

Departme July-Dec Electrical Engg. I Semester Session nt 2019 Name of Dr.PriyankaPaliwal Semester Odd Teacher Subject Reactive power control and FACTS Sub. Code ED-534 Electrical Course M. Tech. Branch Drives TIME SCHEDULE : Total expected periods: 32

Lecture Topic Covered No. 1. problems and needs, General introduction to FACT devices 2. Traditional Transmission line compensation and power flow control 3. Stability enhancement though dynamic compensation 4. Principle of shunt compensation, midpoint compensation, Introduction to shunt compensators 5. Variable impedance type compensators, Thyristor controlled reactor 6. Thyristor switched capacitor, conditions for transient free switching, waveforms 7. Functional control scheme of TCR and TSC 8. Fixed capacitor-TCR, TSC-TCR: waveforms and functional control scheme 9. Introduction to STATCOM, discussion on practical applications 10. STATCOM operating characteristics, Direct and indirect control of output voltage 11. Functional control scheme of STATCOM, transient response and losses 12. Introduction to series compensation 13. Effect of series compensation on voltage, stability and power oscillation damping 14. Different types of series compensators: variable impedance and switching converter type 15. TCSC: principle of operation, operating characteristics 16. Functional control scheme of TCSC, effect of TCSC on electromechanical oscillations damping 17. Mitigation of sub synchronous resonance through TCSC. 18. Introduction to switching converter type series compensator: SSSC 19. Principle of operation of SSSC, operating characteristic 20. Functional control scheme of SSSC 21. Principle of series-shunt compensation, Introduction to UPFC 22. Operating principle and characteristics of UPFC 23. Transmission control capabilities of UPFC 24. Independent real and reactive power control though UPFC 25. Basic control system for P and Q control, dynamic performance 26. Introduction to oscillation stability analysis and control 27. Linearized model of power system installed with FACTS based stabilizers 28. Analysis of damping torque contribution by FACTS based stabilizers in single- machine and multi machine infinite-bus power system 29. Design of FACTS based stabilizers 30. Selection of installation locations 31. Discussion on FACTS development and applications 32. Discussion on recent trends , application to renewable energy systems Teaching Plan: ED 553-Evolutionary Techniques

Total Lectures (17 July 2019 to 8 November 2019): 40

Lecture Topic 1. Introduction to Simulation mechanism and simulation tools 2. Introduction to optimization techniques 3. Simulation of linear electrical networks 4. Single objective and multi-objective optimization, constraints in optimization 5. Linear and non-linear problems 6. NP Hard problems, combinatorial optimization 7. Conventional optimization methods 8. Conventional optimization methods 9. Conventional optimization methods 10. Simulation of Conventional optimization methods 11. Gradient based optimization techniques 12. Simulation of Gradient based optimization techniques 13. Simulation of Gradient based optimization techniques 14. Simple genetic algorithm 15. Simulation of Simple genetic algorithm 16. Mini Test 17. Multi-objective genetic algorithm 18. Simulation of Multi-objective genetic algorithm 19. Simulation of Multi-objective genetic algorithm 20. Artificial Neural networks and its applications 21. Simulation of Artificial Neural networks 22. Fuzzy logic and its applications 23. Simulation of Fuzzy logic 24. Ant colony Optimization 25. Simulation of Ant colony Optimization 26. Particle swarm optimization 27. Simulation of Particle swarm optimization 28. Basic Simulated Annealing 29. Simulation of Basic Simulated Annealing 30. Basic Tabu Search method 31. Simulation of Basic Tabu Search method 32. Bacteria Foraging and fish schooling optimization 33. Simulation of Bacteria Foraging and fish schooling optimization 34. Bee flying optimization 35. Simulation of Bee flying optimization 36. Applications to Electrical systems 37. Applications to Electrical systems 38. Simulation of industrial system optimization 39. MATLAB interface with real time simulators and controllers such as dSPACE, FPGA, 40. MATLAB interface with real time simulators and controllers such as dSPACE, FPGA,