DEPATRMENT OF ELECTRICAL ENGINEERING of ... SCHEDULE...Starters and equivalent circuit effect of rotor resistance torque slip curves speed control by rotor resistance pole changing

DEPATRMENT OF ELECTRICAL ENGINEERING College of Technology & Engineering

Maharana Pratap University of Agriculture & Technology, Udaipur

Weekly Lecture Schedule

Course Title

Class

Venue

Lecturer

: Electrical Engineering-I (EE 100) :

: FirstYear B.E. (Electrical Engineering)

: Basic Science Department

: Guest Faculty Week

No. of Classes

Contents to be Covered

First Week

3

1. Introduction D.C. Networks(Unit-I)

2. Kirchoff’s law 3. Voltage and current division rule 4. Node voltage method 5. Mesh current method 6. Delta-star and star -delta transformation

Second Week

3

7. Source conversion 8. Solution of DC circuits by Thevenin's theorem 9. Solution of DC circuits by Norton’s theorem 10. Solution of DC circuits by Superposition theorem

Third Week

3

11. Solution of DC circuits by Maximum Power Transfer

theorem 12. Reciprocity theorem

Single Phase A.C.Ciruits (Unit-II)

1. Introduction 2. Important terms related to ac quantities 3. Average and effective values of sinusoidal and linear

periodic wave forms

Fourth Week

3

4. Single Phase EMF generation. 5. Solution of R-L-C series circuits 7. Solution of R-L-C parallel and series-parallel circuits. 8. Complex representation of impedances 9. Phasor diagram

Fifth Week

3

10. Instantaneous and average power, power factor, reactive &

apparent power 11. Series resonance.

Sixth Week

3

12. Parallel Resonance

Three Phase A.C. Circuits (Unit-III)

1. Introduction 2. Three phase EMF generation 3. Phase sequence 4. Delta and star-connection 6. Line and phase quantities 7. Solution of the 3- phase balanced circuits

Seventh Week

3

8. Measurement of power in three phase balanced circuits

Transformer(Unit –III)

1. Introduction 2. Faraday's laws of Electromagnetic induction

Eighth Week

3

3. Types of Induced EMF 4. Construction and principle of operation of single phase

transformer 5. EMF equation 6. Voltage and current relationship for ideal transformer 7. Phasor diagram for ideal transformer

Ninth Week

3

Electrical Measuring Instruments (Unit –IV)

1. Introduction 2. Type of measuring Instruments 3. D.C. PMMC instruments 4. Moving iron ammeters and voltmeter

Tenth Week

3

5. Dynamometer wattmeter 6. Induction type energy meter 7. Deflecting controlling & Damping Torque 8. Shunts and multipliers

Eleventh Week

3

Revision and Remedial Classes

Twelfth Week

3


Thirteenth Week

3


Fourteenth Week

3

University/GATE/IES old papers Practice

Total

42



Weekly Lecture Schedule Course Title : Electrical Measurements & Instruments (EE 212)

Class : Second Year B.E. (Electrical Engineering)

Venue : Room No: 211; Electrical Engineering Department

Lecturer : Jai Kumar Maherchandani

Week No. of

Classes Contents to be Covered

First Week

3 Scope, importance and Introduction of Subject Measurement of Resistances(Unit –II)

1. Classification of Resistances 2. Methods of Measurements of Medium Resistances

(i) Ammeter Voltmeter Method (ii) Substitution Method (iii) Wheatstone Bridge

3. Problems associated in measurement of Low Resistances 4. Construction of Low Resistances (Four Terminal Type) 5. Method of measurement of Low Resistances

(i) Kelvin’s Double Bridge 6. Problems Associated in measurement of High Resistances 7. Construction of High Resistances (Three Terminal Type) 8. Methods of measurement of High Resistances

(i) Price Guard Wire Method (ii) Loss of Charge Method

Second Week

3 A.C. Bridges (Unit-III) 1. Introduction (Four-arm AC Bridges) 2. Sources and Detectors 3. General Equation of Bridge Balance 4. Bridges used for measurement of inductances 5. Bridges used for measurement of capacitance 6. Quality and Dissipation Factor

Third Week

3 7. Measurement of Frequency 8. Sources of Errors in Bridge Circuits 9. Screening & Wagner Earthing Device 10. Numerical Problems on A.c. Bridges 11. Phasor Diagram

Fourth Week

3 Potentiometers (Unit-II) 1. Basic Potentiometer Circuit

2. Working of D.C. Potentiometer 3. Standardization and Applications of D.C. Potentiometer 4. Type of A.C. Potentiometer 5. Working of Polar Type A.C. Potentiometer 6. Working of Co-ordinate Type A.C. Potentiometer 7. Numerical Problems on A.C. Potentiometer

Fifth Week

3 Instrument Transformers (Unit-III) 1. Introduction 2. Use of Instrument Transformers 3. Important Definitions 4. Theory of Current Transformer

(i) Ratio Error (ii) Phase Angle Error

5. Causes of Errors 6. Methods of Reduction of Errors

Sixth Week

3 7. Theory of Potential Transformer (i) Ratio Error (ii) Phase Angle Error

8. Testing of Current Transformer 9. Testing of Potential Transformer

Magnetic Measurements (Unit-IV)

1. Introduction 2. Measurement of Flux Density 3. Determination of B-H Curve 4. Determination of Hysteresis Loop 5. Separation of Iron Losses

Seventh Week

3 6. Measurements of Iron Losses 7. Epstein Square 8. Lioyd-Fisher Square

Electronic Instruments (Unit-IV)

1. Introduction 2. Transistor Voltmeter (TVM) 3. FET input TVM 4. Balanced bridge TVM 5. Introduction of Digital Voltmeter

Eighth Week

3 1. Ramp type DVM 2. Integrating DVM 3. Measurement of time 4. Measurement of phase 5. Measurement of frequency 6. Introduction of Wave analyzers 6. Resonant Wave analyzer 7. Heterodyne Wave analyzer

Ninth Week

3 Galvanometers 1. D’Arsonaval Galvanometer 2. Dynamic Equation of Motion and its solution 3. Relative damping

Tenth Week

3 4. Ballistic Galvanometer 5. Logarithmic Decrement 6. Vibration Galvanometer

Measuring Instruments 1. Introduction of Analog Instruments 2. Classification of Analog Instruments 3. Moving Iron Instruments

a. Constructional Detail b. Torque Equation c. Scale Shape d. Errors e. Uses

Eleventh Week

3 4. Electrodynamometer Wattmeter a. Constructional Detail b. Torque Equation c. Scale Shape d. Errors e. Low pf Wattmeter

Twelfth Week

3 5. Induction Type Energy Meter a. Construction b. Theory c. Creep d. Compensation e. Errors

Thirteenth Week

3 Revision and Remedial Classes

Fourteenth Week


Fifteenth Week

3 University/GATE/IES old papers Practice

Total 45

LECTURE PLAN FOR EE 213 (ME/Ag/Mi) ELECTRICAL ENGINEERING-II Cr. Hrs. 3 (2 + 1)

Faculty : G.F.

S.No. Topics Lecture no. Total lecture Unit-I D.C. Machines:Introduction

Characteristics curves of d. c. generators and motors Application of motors for different uses starting and speed control of motors Revision

01 02 03 04 05

07

Unit-II

Transformers:Introduction Phasor diagram Equivalent circuits Regulation & efficiency and their determination Open circuit, short circuit and sumpners’s test. Revision

06 07 08 09 10

05

Unit-III

Induction motors: Introduction Poly-phase induction motors Starters and equivalent circuit effect of rotor resistance torque slip curves speed control by rotor resistance pole changing and cascading use in industry Single – phase induction motor starting methods Revision

11 12 13 14 15 16 17 18 19 20

10

Unit-IV

Alternators: Elementary idea of armature winding Calculation of induced e. m. f. Factors affecting generating e.m.f. Open circuit, short circuit and load characteristics. Voltage regulation and its determinations by synchronous impedance methods Synchronizing. Synchronous Motors: Methods of starting Power angle characteristics of cylindrical rotor machine operation of synchronizing motor as a condenser and as a reactor Application in Industries.

21 22 23 24 25 26 27 28 29 30 31

11

LECTURE PLAN FOR EE 214 (EC) NETWORK ANALYSIS Cr. Hrs. 2 (2 + 0)

Faculty: G.F.

Sn. Topics Lecture no. Total lecture Unit-i Itroduction

Network theorems: thevenin's, norton's, Reciprocity, superposition, compensation Miller's tellegen's and maximum power transfer theorems. Network with dependent sources. Transient analysis: impulse, step, ramp and Sinsuoidal response analysis of first order and second order circuits. Time domain & transform domain (frequency, laplace) analysis. Initial and final value theorems. Revision

01 02 03 04 05 06 07 08 09 10

10

Unit-ii

Linear network response to non-sinusoidal inputs: Complex periodic waves and their analysis by fourier analysis. Different kind of symmetry. Power in circuit. Coupling elements & coupled circuits: conductively coupled circuits. Inductively coupled circuits-mutual inductance, coefficient of coupling and mutual. Inductance between portions of same circuits and between parallel branches. Transformer equivalent. Inductively and conductively coupled circuits. Revision

11 12 13 14 15 16 17

07

Unit-iii

Two port networks: Two port; parameters and their interrelations – z parameters , Y-parameters, H-parameters, abcd parameters. Equivalence of two ports, Transformer equivalent, interconnection of two port network. Image parameters attenuation & phase shift in Symmetrical t and networks. Revision

18 19 20 21 22 23 24 25 26

09

Unit-iv

Network functions: Terminals and terminal pair, driving point impedance transfer functions Poles and zeros. Procedure of finding Network functions for general two terminal pair networks. Stability & causality. Network synthesis: hurwitz polynomial, positive real function, Rl & rc networks synthesis, Foster first & second form, cauer forms. Revision

27 28 29 30 31 32 33 34

08



Weekly Lecture Schedule Course Title : Electrical Machines-II (EE 313)

Class : Third Year B. Tech. (Electrical Engineering)

Venue : Room No: 213; Electrical Engineering Department

Lecturer : Jai Kumar Maherchandani

Week No. of


First Week

3 Scope, importance and Introduction of Subject Induction Motors (Unit –I)

1. Basic Concept and rule related to Electrical Machines 2. Development of Rotating Magnetic Field 3. Construction of Induction Motor 4. Basic principle of operation

Second Week

3 5. Induction Motor as generalized transformer 6. Phasor Diagram 7. Equivalent Circuits 8. No-load and Blocked rotor test

Third Week

3 9. Circle Diagram 10. Calculation of Performance 11. Torque-slip Characteristics 12. Effect of rotor resistances

Fourth Week

3 13. Operating characteristics of induction Motor 14. Speed Control of induction motor 15. Starting and braking 16. Cogging and crawling

Fifth Week

3 Single Phase Induction Motor (Unit-II) 1. Introduction 2. Basic Principle 3. Revolving Field Theory 4. Method of Starting 5. Equivalent Circuits 6. Induction Generators 7. Induction Regulators

Sixth Week

3 Synchronous Generator (Unit-II) 1. Constructional features 2. General equation of induced emf 3. Effect of distribution and chording 4. Armature reaction 5. Theory of cylindrical rotor machines

Seventh 3 6. Phasor diagrams

Week

7. OCC, SCC and ZPF characteristics 8. Saturation effects 9. Potier triangle 10. Regulation by synchronous impedance method

Eighth Week

3 11. Voltage regulation by MMF Method 12. Voltage regulation by ASA Method 13. Relative comparison 14. Theory of Salient pole machines 15. Blondel’s Two reaction theory 16. Phasor Diagram

Ninth Week

3 17. Determination of direct and quadrature axis reactance 18. Parallel operation of alternators 19. Synchronizing operation of infinite bus 20. Synchronizing Power

Tenth Week

3 21. Power-angle characteristics 22. Stability 23. Numerical Problems

Synchronous Motor (Unit-III)

1. Construction 2. Principle of operation 3. Equivalent Circuit

Eleventh Week

3 4. Phasor Diagram 5. Power Flow Equation 6. V Curves 7. Starting 8. Hunting and Damping

Twelfth Week

3 Commutator Motors (Unit-III) 1. Effect of injected EMF 2. Commuataor as frequency Changer 3. Single Phase Series Motor 4. Scharge Motor

Thirteenth Week

3 Fractional Horse Power Motors (Unit-IV) 1. Construction, principle of operation, elementary analysis,

characteristics and application of: (a) Universal Motors (b) Repulsion Motors (c) Hysteresis Motor

Fourteenth Week

3 (d) Brushless Motor (e) Linear Induction Motor (f) Stepper Motor

Fifteenth Week

3 Revision and Remedial Classes and University/GATE/IES old papers Practice

Total 45

LECTURE PLAN FOR EE 315 (EC) CONTROL SYSTEM ENGINEERING Cr. Hrs. 2 (2 + 0) Faculty: G.F.

Sn. Topics Lecture no. Total lecture Unit-i Introduction:-

Concepts of open loop and closed loop systems. Mathematical models for feedback systems. Examples and applications of open loop and closed loop systems. Brief idea of multi-variable control systems. Representation of physical systems: (electro-mechanical) by differential equations, Determination of transfer function by block diagram, reduction technique Signal flow graphs techniques. Revision

01 02 03 04 05 06 07 08 09

09

Unit-ii

System performance and stability:- Time domain and frequency domain specifications and their correlations. Time response analysis of first order systems. Second order systems. Transient response analysis steady state error and error constants. Revision

10-11 12-13-14 15-16 17-18-19

10

Unit-iii

Absolute and relative stability. Routh’s stability criterion. Root locus method of analysis. Polar plots, nyquist stability criterion. M and n locii, nichol’s chart. Frequency domain methods, bode plot, Design specification in frequency domain. Revision

20 21 22 23 24 25 26

07

Unit-iv

State variable analysis: Concept of state, State variables and state model. State models for linear continuous time systems. Diagonalization transfer functions. Solutions of state equations. Concept of controllability and observability. Elementary idea of compensating networks: lag, lead and lag-lead networks. Brief idea of proportional, derivative and integral controllers. Revision

27 28 29 30 31 32 33 34 35

09

EE 414 ELECTRIC ENERGY SYSTEMS THEORY

Cr. Hrs. 3 (3 + 0)

Faculty: Prof. R. R. Joshi

Sn. Topics Lecture no. Total lecture Unit-i Introduction:-

Fundamental concept of electric energy system theory; Electric supply systems; Economics of power transmission. Revision

01 02-03-04 05-06 07-08 09

09

Unit-ii

Load flow analysis: Static load flow equation, system variable and its solution, Bus admittance matrix, bus classification, Solution of load flow problem by gauss Siedal, Newton Rephson and fast decoupled method, Comparison of above method. Revision

10-11 12-13-14 15-16 17-18- 19

10

Unit-iii

The energy system in steady state-basic generator control loops, Mathematical modeling and description of various components of Automatic voltage regulator, Steady state and dynamic performance of AVR. Revision

20-21-22 23-24-25 26

07

Unit-iv

Automatic load-frequency control of single area system, mathematical modeling and description of various components of ALFC Steady state and dynamic performance of ALFC, Steady state, dynamic and transient stabilities, Equal area criterion, step by step method of solving swing equation. Revision

27-28 29-30 31-32 33-34 35-36 37

10




Course Title

Class

Venue

Lecturer

: Analysis of Power Electronic Converters (EPE 512)

: FirstYear M.Tech. ( Power Electronics)

: Electrical Department

: Guest Faculty Week

No. of Classes


First Week

2

Phase Controlled Converters (Unit-I)

1. Principle of Phase Control 2 Performance measures of single phase full converters with discontinuous load current for R, RL and RLE loads

Second Week

2

3 Single phase symmetrical and asymmetrical semi converters, 4 Performance measures of three-phase half wave converters with

discontinuous load current for R, RL and RLE loads

Third Week

2

5 Performance measures of three-phase full wave converters and

semi converters with discontinuous load current for different loads.

6 Effect of source inductance for single and three phase converters

Fourth Week

2

Choppers (Unit-II)

1. Introduction 2. Principle of operation 3. Control strategies 4. Step up Choppers 5. Brief explanation of type A , B and C Chopper

Fourth Week

2

6 Brief explanation of type D and E Chopper 7 Steady state analysis of type A Chopper-Minimum and

Maximum Currents, Ripple and average load current 8 Voltage commutated chopper

Fifth Week

2

9 Current and Load commutated chopper

Inverters(Unit-III)

1. Principle of Operation 2. Single-phase bridge inverters

Sixth Week

2

3 Three-phase bridge inverters 4 180 and 120 degree mode of conduction 5 Voltage control of three phase inverters-Sinusoidal PWM

Seventh Week

2

6 Third Harmonic PWM 7 60 degree PWM 8 Space Vector Modulation 9 Harmonic reductions

Eighth Week

2

10 Current source inverters

AC Voltage Controllers (Unit-IV)

1. Principle of On-Off Control 2. Principle of Phase control 3. Single Phase Bi-directional Controllers with Resistive Loads

Ninth Week

2

4 Single Phase Controllers with Inductive Loads 5 Three Phase full wave AC controllers

Tenth Week

2

6. AC Voltage Controller with PWM Control.

Cyclo-converters (Unit-V)

1. Single phase cycloconverters

Eleventh Week

2

2. Three phase Cyclo-converters 3. Reduction in Output Harmonics 4. Matrix Converter

Twelfth Week

2


Thirteenth Week

2


Fourteenth Week

2


Total

28

EPE 517 MODELING & ANALYSIS OF ELECTRICAL MACHINE

Cr. Hrs. 3 (3+0)


Sn. Topics Lecture no. Total lecture Unit-i Basic principle of Electrical Machines:

Introduction, Magnetically coupled circuit, Electromagnetic energy conversion, Machine winding and air gap EMF, winding inductance and voltage equations, Equation of transformation, Reference-Frame Theory. Revision

01 02-03-04 05-06-07- 08

08

Unit-ii

Fundamental of Electrical Drives: Introduction, Choice of Electrical Drives, Dynamics of Electrical Drives, Concept of Multi-quadrant operation, Components of load torques, Selection of motor power rating, Speed torque, speed control, Starting, Braking. Revision

10-11 12-13-14 15-16 17-18- 19

10

Unit-iii

Symmetrical induction machines: Introduction, voltage and torque equations in machine variables, Voltage and torque equations in arbitrary reference frame, analysis of steady state and dynamic operation.

20-21-22 23-24-25 26

07

Unit-iv

Synchronous machines: Introduction, voltage and torque equations in machine variables, Voltage equations in rotor reference frame, Analysis of steady state and dynamic operation Revision

27-28 29-30 31-32 33

10

LECTURE PLAN FOR EPE 532 MODERN CONTROL TECHNIQUES IN ELECTRIC DRIVES


Sno. Topics Lecture no. Total lecture Vector Control of Induction Motor:

Principles of vector control, Direct vector control, Derivation of indirect vector control, Implementation-block diagram; Estimation of flux, flux weakening operation.

01-02 03 04 05-06

06

Sensorless Vector Control of Induction Motor: Slip and speed estimation at low performance, Rotor angle and flux linkage estimation at high performance-rotor speed estimation scheme-estimators using rotor slot harmonics, Model reference adaptive systems, Extended Kalamn filter, injection of auxiliary signal on salient rotor.

07 08-09 10 11 12

06

Control of Synchronous Motor Drives: Synchronous motor and its characteristics- Control strategies-Constant torque angle control- power factor control, Constant flux control, flux weakening operation, Load commutated inverter fed synchronous motor drive, motoring and regeneration, phasor diagrams

13 14 15 16 17

05.

Control of Switched Reluctance Motor Drives: SRM Structure-Stator Excitation- Techniques of sensor less operation-convertor topologies- SRM Waveforms-SRM drive design factors- Torque controlled SRM-Torque Ripple-Instantaneous Torque control – Using current controllers-flux controllers.

18 19 20 21 22

05.

Control of BLDC Motor Drives: Principle of operation of BLDC Machine, Sensing and logic switching scheme, BLDM as Variable Speed Synchronous motor-methods of reducing Torque pulsations - Three-phase full wave Brushless dc motor -Sinusoidal type of Brushless dc motor – Current controlled Brushless dc motor Servo drive.

23 24-25 26-27 28

07

LECTURE PLAN FOR EPE-514 ANN & Fuzzy logic Cr. Hrs. 3 (3+0)

Faculty : G.F.

S.No. Topics Lecture no. Total lecture Unit-I Neural Network: Introduction-biological neurons

Artificial models-learning, adaptation Neural network's learning rules Types of neural networks-single layer, multiplayer-feed forward, Feedback networks; back propagation learning and training-Hopfield network. Revision

01 02 03 04-05 06-07

07

Unit-II

Neural Networks in Control:Neural network for non-linear systems Schemes of neuro control System identification forward model Inverse model-indirect learning Neural network control applications-case studies

06-07 08-09 10-11 12-13 14-15

10

Unit-III

Neural Network in Control:Structure of fuzzy logic controller Fuzzification models,data base Rule base,inference engine Defuzzification module. Non-linear fuzzy control PID like FLC Sliding mode FLC Surgeno FLC Adaptive fuzzy control Fuzzy control applications-case studies.

16 17 18-19 20 21-22 23 24 25 26 27

11

Unit-IV

Analysis of Neural Networks:Analysis of Neural Network for liner and non-liner systems. Analysis of neuro -fuzzy systems. Application of neural networks Fuzzy Logic:Fuzzy sets Fuzzy operation-fuzzy arithmetic-fuzzy relations Fuzzy relational equations-fuzzy measure Fuzzy functions-approximate reasoning Fuzzy propositions-fuzzy quantifiers-if-then rules. Adaptive Fuzzy control: Introduction, Design & performance evaluation, Performance monitor, Main approaches to design. FKBC design parameters: Structure of FKBC Fuzzification and defuzzification module, Rule based choice of variable and contents of rules Derivation of rule data based, choice of membership function and scaling factors

28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 447

17




Course Title : Electrical Measurements & Instruments (EE 212)

Class : Second Year B.E. (Computer Science Engineering)

Venue : Computer Science Department

Lecturer : Guest Faculty

Week No. of Classes Contents to be Covered

First Week 3 Galvanometers(Unit-I)_ 1. D’Arsonaval Galvanometer 2. Dynamic Equation of Motion and its solution 3. Relative damping 4. Ballistic Galvanometer 5. Logarithmic Decrement 6. Vibration Galvanometer

Second Week 3 Measuring Instruments(Unit-I) 1. Introduction of Analog Instruments 2. Classification of Analog Instruments 3. Moving Iron Instruments 4. Electrodynamometer Wattmeter

Third Week 3 5. Induction Type Energy Meter A.C. Bridges (Unit-III)

1. Introduction (Four-arm AC Bridges) 2. Sources and Detectors 3. General Equation of Bridge Balance 4. Bridges used for measurement of inductances 5. Bridges used for measurement of capacitance 6. Quality and Dissipation Factor

Fourth Week 3 7. Measurement of Frequency 8. Sources of Errors in Bridge Circuits 9. Screening & Wagner Earthing Device 10. Numerical Problems 11. Phasor Diagram

Fifth Week 3 Instrument Transformers (Unit-III) 1. Introduction 2. Use of Instrument Transformers 3. Important Definitions 4. Theory of Current Transformer 5. Causes of Errors 6. Methods of Reduction of Errors

Sixth Week 3 7. Theory of Potential Transformer 8. Testing of Current Transformer 9. Testing of Potential Transformer

Measurement of Resistances(Unit –II)

1. Classification of Resistances 2. Methods of Measurements of Medium Resistances 3. Problems associated in measurement of Low Resistances

Seventh Week

3

4. Construction of Low Resistances (Four Terminal Type) 5. Method of measurement of Low Resistances 6. Problems Associated in measurement of High Resistances 7. Construction of High Resistances (Three Terminal Type) 8. Methods of measurement of High Resistances

Potentiometers (Unit-II)

1. Basic Potentiometer Circuit 2. Working of D.C. Potentiometer 3. Standardization and Applications of D.C. Potentiometer

Eighth Week 3 4. Type of A.C. Potentiometer 5. Working of Polar Type A.C. Potentiometer 6. Working of Co-ordinate Type A.C. Potentiometer

Magnetic Measurements (Unit-IV)

1. Introduction 2. Measurement of Flux Density 3. Determination of B-H Curve 4. Determination of Hysteresis Loop 5. Separation of Iron Losses

Ninth Week 3 6. Measurements of Iron Losses 7. Epstein Square 8. Lioyd-Fisher Square

Electronic Instruments (Unit-IV) 1. Introduction 2. Transistor Voltmeter (TVM) 3. FET input TVM 4. Balanced bridge TVM

Tenth Week 3 Introduction of Digital Voltmeter

1. Ramp type DVM 2. Integrating DVM 3. Measurement of time 4. Measurement of phase 5. Measurement of frequency 6. Introduction of Wave analyzers 6. Resonant Wave analyzer 7. Heterodyne Wave analyzer

Eleventh Week 3 Revision and Remedial Classes

Twelfth Week 3 Revision and Remedial Classes

Thirteenth Week


Fourteenth Week

3 University/GATE/IES old papers Practice

Total 42




Course Title : Computer Architecture and Industrial Control(EE 315)

Class : Third Year B.E. (Electrical Engineering)

Venue : Electrical Department

Lecturer : Guest Faculty

Week No. of


First Week 3 Microprocessor Architecture(

Unit-I):

1. Inter 8085 Architecture 2. Buses, Registers and status flag 3. Opcode & operands 4. Pin configuration 5. Instruction cycle

Second Week 3 6. Fetch Operation, 7. Machine Cycle & State 8. Instruction & Data Flow 9. Timing Diagram For-Opcode Fetch, Memory Read 10. Timing Diagram For -Write, I/O Read And Write 11. Instruction & Data Formats

Third Week 3 12. Addressing modes, Instruction set 13. Stack & subroutines 14. Data Transfer Schemes 15. Programming the 8085 16. Programming techniques-looping, counting, indexing,

counters and time delays, subroutines.

Fourth Week 3 Programming the 8085(Unit-II)1. Interrupts Of 8085,

:

2. Debugging Of Programs. 3. Modular & Structured Programming, Macro, Micro

Programming. 4. Micro Controllers-Introduction & Applications

Fifth Week 3 5. Computer Memories-Tape, Disk And Floppy Disk Storage,

6. Semiconductor Memories Systems, 7. Bubble Memories- CCD Memory. 8. Input –Output Devices- VDU, Graphic Display,

Magnetic Tape Unit, Printers, Mouse, Plotters & Digitiser.

Sixth Week 3 Programmable logic controller (Unit-III)

1. Principles Of Operation 2. Architecture Of Programmable Controller 3. Programming The Programmable Controller

Seventh Week 3 4. Programming The Programmable Controller

5. Software Configurations 6. Applications

Eighth Week 3 1. Fundamental Requirements Of Distributed Process

Control System

Distributed Digital Control( Unit-IV)

2. System Architecture 3. Distributed Control System 4. Configuration 5. Popular Distributed Control System

Ninth Week 3 1. Introduction

Industrial Control Applications

2. Cement Plant 3. Thermal Power Plant 4. Water Treatment Plant 5. Steel Plant.

Tenth Week


Eleventh Week


Twelveth Week 3 University/GATE/IES old papers Practice

Total 36




Course Title : Advanced Semiconductor Devices (EPE 513)

Class : FirstYear M.Tech. ( Power Electronics)

Venue : Electrical Department Lecturer : Guest Faculty

Week

No. of Classes


First Week

3

Power Switching Devices(Unit I)

SCR 1. Structure and Construction 2. Working and operations 3. Switching and Static Characteristics 4. Ratings 5. Triggering Circuits 6. Protection Circuits 7. Commutation Circuits, 8. PSPICE Models &Testing 9. Gate Drive Requirements and Applications

Second Week

3

GTO

1. Structure and Construction 2. Working and operations 3. Switching and Static Characteristics 4. Ratings 5. Triggering Circuits 6. Protection Circuits 7. Commutation Circuits, 8. PSPICE Models &Testing 9. Gate Drive Requirements and Applications

Third Week

3

MOSFETS


Fourth Week

3

BJT


Fifth Week

3

IGBT


Sixth Week

3

MCTs and Static Induction Devices 1. Structure and Construction 2. Working and operations 3. Switching and Static Characteristics 4. Ratings 5. Triggering Circuits 6. Protection Circuits 7. Commutation Circuits, 8. PSPICE Models &Testing 9. Gate Drive Requirements and Applications

Seventh Week

3

1. Trigger Techniques 2. Optical Isolators 3. Protection Circuits 4. Isolation Transformers

Eighth Week

3

5. Future Trends in Power Devices 6. Comparison Testing of Switches 7. General Power Semiconductor Switch Requirements.

Ninth Week

3


Tenth Week

3


Eleventh Week

3


Total

33

Documents

DEPATRMENT OF ELECTRICAL ENGINEERING of ... SCHEDULE...Starters and equivalent circuit effect of rotor resistance torque slip curves speed control by rotor resistance pole changing