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1 CURRICULUM B. Tech. Electrical Engineering 3 rd 8 th Semester July 2018 admissions on wards APPROVED BY BOARD OF STUDIES (BOS) 7 th MEETING, November 03, 2020 Department of Electrical Engineering Dr B R AMBEDKAR NATIONAL INSTITUTE OF TECHNOLOGY, JALANDHAR Phone: 0181-2690301, 02 (Ext. 2101, 2104), Fax: 0181-2690932 Website: www.nitj.ac.in

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Page 1: B. Tech. Electrical Engineering

1

CURRICULUM

B. Tech. Electrical Engineering

3rd

– 8th

Semester July 2018 admissions on wards

APPROVED BY

BOARD OF STUDIES (BOS) 7th MEETING, November 03, 2020

Department of Electrical Engineering

Dr B R AMBEDKAR NATIONAL INSTITUTE OF TECHNOLOGY, JALANDHAR

Phone: 0181-2690301, 02 (Ext. 2101, 2104), Fax: 0181-2690932 Website: www.nitj.ac.in

Page 2: B. Tech. Electrical Engineering

2

About NIT Jalandhar

Dr B. R. Ambedkar National Institute of Technology Jalandhar was established in the year

1987 as Regional Engineering College and was given the status of National Institute of

Technology (Deemed University) by the Government of India on October 17, 2002 under the

aegis of Ministry of Human Resource Development, New Delhi. Now the Ministry of Human

Resource Development, Government of India has declared the Institute as ―Institute of

National Importance under the act of Parliament-2007.

Institute Vision

To build a rich intellectual potential embedded with interdisciplinary knowledge, human

values and professional ethics among the youth, aspirant of becoming engineers and

technologists, so that they contribute to society and create a niche for a successful career.

Institute Mission

To become a leading and unique institution of higher learning, offering state-of-the-art

education, research and training in engineering and technology to students who are able

and eager to become change agents for the industrial and economic progress of the nation.

To nurture and sustain an academic ambience conducive to the development and growth of

committed professionals for sustainable development of the nation and to accomplish its

integration into the global economy.

Page 3: B. Tech. Electrical Engineering

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Department of Electrical Engineering

The Department of Electrical Engineering commenced its Bachelor of Technology (B. Tech)

degree program in 2013. Electrical Engineering is a well-diversified discipline. Many areas of

specialization namely Control Systems, Power System, High Voltage, Electric Drives etc.

have grown by leaps and bounds and have emerged as full-fledged disciplines in

themselves. Training students in all these areas is an uphill and challenging task. Therefore,

every effort has been made while developing curricula to ensure full cognizance of all value

elements among students. A holistic approach has been adopted while framing curriculum,

updating infrastructural facilities and improving coaching methods. The teaching scheme has

been enriched by the valuable inputs of experts of respective fields from prestigious

institutions / organizations such as IIT Roorkee and IIT Delhi, R&D organizations like CSIO

and leading industries of the region. The Department is consolidating its efforts to promote

industrial research and consultancy in appropriate areas of Electrical Engineering.

Department Vision

To excel in the field of Electrical Engineering education, research and innovation with

interdisciplinary approach responsive to the needs of industry and sustainable development

of society while emphasizing on human values and professional ethics.

Department Mission

To create and disseminate knowledge through research, quality education and creative

inquiry.

To orient the education and research towards latest developments through close

interaction with industry, other institutions of higher learning and research organizations.

To train the students in problem solving and soft skills, inculcating leadership and team-

work qualities, human values and ethical professionalism.

Page 4: B. Tech. Electrical Engineering

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PREFACE

With rapidly changing industrial scenario and technological advances that have taken place

in microelectronics, telecommunications and computer technologies, the field of Electrical

Engineering (EE) has also been revolutionized. This needs up-gradation and updating the

existing academic programmes, so that trained human resource is competent to meet the

requirements of today's industries. Accordingly the Department of Electrical Engineering has

proposed flexible curriculum as per directions of NIT council stipulated under the credit

based system. It was really challenging to evolve a common programme for this discipline

that meets the need of national and international industries and research establishments.

However, with the rich experience of experts, the task of development of a flexible

curriculum could be possible. The suggested curriculum is based on philosophy presented

by the Dean (Academic Programmes) during the Senate meeting of the institute. The

suggested curriculum is in conformity with IIT/AICTE norms with emphasis on analysis and

design. On graduation the student should be acceptable to national and international

industry or academic / research establishments. The programme has to be forward looking

in context of the rapid changing scenario of science and technology which provides a proper

balance in teaching of basic sciences, social sciences and management, engineering

sciences and technical arts, technologies and their applications. Core subjects have been

selected to cover all those, which are essential to training in EE discipline. The curriculum

presents flexibility that the new programmes started with reasonable sources can be

managed with a scope of further updating as the resource position improves. The above

features have been achieved by offering a number of departmental and open elective

courses. I take this opportunity to express my deep appreciation to members of the Senate

for their valuable suggestions and critical comments in finalizing the curriculum. It is hoped

that the curriculum compiled in form of the booklet will be of immense help to the students

and the faculty in smooth offering the under graduate programme in Electrical Engineering. I

thank all the members of curriculum committee and the faculty of EE Department for help

and cooperation rendered in bringing out this booklet in time.

Dr Dilbag Singh Head Department of Electrical Engineering Dr B R Ambedkar National Institute of Technology Jalandhar (Punjab)-144011 INDIA

Page 5: B. Tech. Electrical Engineering

5

Programme Outcomes (POs) of B. Tech. Programme

1. Ability to apply knowledge of mathematics, science and electrical engineering to solution of complex problems.

2. Ability to conduct experiments and researches, perform analysis and interpret data for real time complex engineering problems.

3. Ability to identify, formulate, investigate and synthesis of information to solve multipart engineering problems.

4. Ability to design solutions for complex system, component or process within a defined specification that meet specified needs with appropriate consideration for public health and safety, cultural, societal and environmental considerations.

5. Ability to use appropriate techniques, skills and modern engineering tools, software and hardware necessary for complex engineering practice with an understanding of their limitations.

6. Ability to articulate ideas, communicate effectively, in writing and verbally, on complex engineering activities with the engineering community and with society at large.

7. Ability to analyse the impact of global and contemporary issues, the role of engineers on society, including, health, safety, legal and cultural issues, and the consequent responsibilities relevant to professional engineering.

8. Ability to execute responsibility in professional and ethical manner.

9. Ability to function effectively as an individual, and as a member or leader in diverse teams.

10. Ability to understand the impact of professional engineering solutions in societal and environmental contexts and demonstrate knowledge of sustainable development.

11. Ability to recognize the need for, and have the preparation and ability to engage in independent and life-long learning in the broadest context of technological change.

12. Ability to demonstrate understanding of engineering concepts and management principles to manage projects in multidisciplinary environments.

Programme Educational Objectives (PEO)

The Programme Educational Objectives are:

1. The graduate should become as good professional (Teacher/ Researcher/ Engineer/ Entrepreneur) by acquiring strong knowledge in the principles and practices of Electrical Engineering.

2. The graduate will continue to learn and to adapt in the world of constantly evolving technology.

3. The complete engineer with professional and social ethics in-line with human values and work with values that meet the diversified needs of industry, academia and research.

Page 6: B. Tech. Electrical Engineering

6

Course Outcomes of B. Tech. Programme

After completing the course, the students will:

1. Develop good engineering knowledge and problem analysis skills of various courses related to Electrical Engineering.

2. Exposed to practical issues related to Electrical Engineering.

3. Attain good knowledge of soft skills to analyses the performance of various Electrical Systems.

4. Learn to make and deliver presentations through seminar activity and will be passing through a process of project/thesis work where they will make design, fabrication and test of the project work and then write a report.

5. Learn to work ethically which is beneficial to the society.

Development of curriculum: Overview

As per the NIT council (9th meeting) the following choices may be made available to the students at the end of the first year.

• Normal pace – total 4 years (8 semesters): One major degree.

• Major +Minor Degree- Total 04 years, 06 minor courses (18 credits) in addition to essential Major Program Credits

Basic Structure of Flexible Curriculum of EE Department

Sl.

No

Course Category Number of

Courses

Number of Credits

1 Common Institute Core Courses (CIC) 63

2 Programme Core(PC)- Theory & Lab. 33 90

3 Programme Elective (PE) 06 18

Total credits for PC & PE limited to 100

4 Open Electives (OE) (from other dept.) 03 09

5 Minor Electives (MI) (For Minor Degree) 06 18

Total 180

(Excluding MI)

Page 7: B. Tech. Electrical Engineering

7

First Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Category

1. CYCI-102 Applied Chemistry-B 3 1 0 4 4 CIC

2. MACI-101 Applied Mathematics-I 3 1 0 4 4 CIC

3. ICCI-101 Basic of Electrical Science

3 0 1 4 4 CIC

4. HMCI-102 English Communication & Report Writing

3 0 0 3 3 CIC

5. IPCI-101 Introduction to Manufacturing

2 0 0 2 2 CIC

6. IPCI-102 Product Realization through Manufacturing Laboratory

0 0 4 2 4 CIC

7. HMCI-103 English Communication Lab

0 0 2 1 2 CIC

8. CYCI-103 Applied Chemistry-B Lab

0 0 2 1 2 CIC

9. CYCI-104 Environmental Science and Technology

3 0 0 3 3 CIC

10. Introduction Programme

-

TOTAL 24 28

Second Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Category

1. PHCI-103 Applied Physics-B 3 1 0 4 4 CIC

2. MECI-101 Elements of Mechanical Engineering

3 0 1 4 4 CIC

3. CSCI-101 Computer Programming

3 0 0 3 3 CIC

4. MACI-102 Applied Mathematics-II 3 1 0 4 4 CIC

5. HMCI-101 Management, Principles & Practices

3 0 0 3 3 CIC

6. MECI-102 Engineering Graphics & CADD

1 0 4 3 5 CIC

7. PHCI-104 Applied Physics-B Lab 0 0 2 1 2 CIC

8. CSCI-102 Computer Programming Lab

0 0 2 1 2 CIC

9. NCC/NSO/NSS -

TOTAL 23 27

Page 8: B. Tech. Electrical Engineering

8

Third Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Category

1. EEPC-201 Circuit Theory 3 1 0 4 4 PC

2. ICPC-251 Electrical Measurements and Measuring Instruments

3 1 0 4 4 PC

3. ECPC-251 Electronic Devices and Analog Integrated Circuits

3 0 0 3 3 PC

4. EEPC-203 EMF Theory 3 1 0 4 4 PC

5. ECPC-254 Digital Electronics 3 0 0 3 3 PC

6. ICPC-271 Electrical Measurements Laboratory

0 0 2 1 2 PC

7. EEPC-225 Circuit Theory Laboratory 0 0 2 1 2 PC

TOTAL 20 22

Fourth Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Category

1. EEPC-202 Electrical Machines -I 3 1 0 4 4 PC

2. EEPC-204 Instrumentation 3 0 0 3 3 PC

3. EEPC-206 Generation of Electric Power

3 1 0 4 4 PC

4. MACI-206 Numerical Methods 3 1 0 4 4 CIC

5. HMCI-201 Economics for Engineers 3 0 0 3 3 CIC

6. EEXX-250 Professional Ethics & Holistic Wellbeing

2 0 0 Non

credit 2

7. EEPC-222 Electrical Machines Laboratory-I

0 0 2 1 2 PC

8. EEPC-224 Instrumentation Laboratory 0 0 2 1 2 PC

TOTAL 20 24

Page 9: B. Tech. Electrical Engineering

9

Fifth Semester

Sr. No.

Course Code

Course Title L T P Credits Contact Hours

Type

1. EEPC-301 Microprocessors and Interfacing 3 0 0 3 3 PC

2. EEPC-303 Control System Engineering 3 1 0 4 4 PC

3. EEPC-305 Power Electronics 3 1 0 4 4 PC

4. EEPC-307 Electrical Machines-II 3 1 0 4 4

PC

5. EEPC-309 Transmission and Distribution of

Electric Power

3 1 0 4 4 PC

6. EEPE-3XX Program Elective-I 3 0 0 3 3 PE1

7. EEPC-321 Microprocessors and Interfacing Laboratory

0 0 2 1 2 PC

8. EEPC-323 Control System Engineering Laboratory

0 0 2 1 2 PC

9. EEPC-325 Electrical Machines Laboratory-II 0 0 2 1 2 PC

10. EECI-300 Minor Project 0 0 2 - 2 CIC

TOTAL 25 30

Sixth Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Type

1. EEPC-302 Power System Analysis 3 1 0 4 4 PC

2. EEPC-304 Digital Signal Processing 3 1 0 4 4 PC

3. ICPC-352 PLC, DCS, SCADA 3 0 0 3 3 PC

4. CSPC-213 Data Structure & Algorithms 3 0 0 3 3 PC

5. EEPE-3XX Program Elective-II 3 0 0 3 3 PE2

6. EEPE-3XX Program Elective -III 3 0 0 3 3 PE3

7. IDOE-3XX Open Elective-I 3 0 0 3 3 OE1

8. EEPC-322 Power System Laboratory 0 0 2 1 2 PC

9. EEPC-324 Digital Signal Processing Laboratory

0 0 2 1 2 PC

10. EECI - 300 Minor Project

0 0 2 2 2 CIC

TOTAL 27 29

Page 10: B. Tech. Electrical Engineering

10

Seventh Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Type

1. EEPC-401 Switchgear and Protection 3 1 0 4 4

PC

2. EEPC-403 Power System Operation

and Control

3 0 0 3 3 PC

3. EEPE-4XX Program Elective -IV 3 0 0 3 3 PE4

4. EEPE-4XX Program Elective -V 3 0 0 3 3 PE5

5. IDOE-4XX Open Elective -II 3 0 0 3 3 OE2

6. EEPC-421 Power System Operation and Control Laboratory

0 0 2 1 2 PC

7. EECI-400 Major Project - - 4 - 4 CIC

8. EECI-350 Summer Training* - - - 2 - CIC

TOTAL 19 22

Eighth Semester

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Type

1. EEPC-402 Electric Drives & Control 3 1 0 4 4 PC

2. EEPC-404 Flexible AC Transmission System

3 0 0 3 3 PC

3. EEPC-406 Utilization of Electrical Energy

and Electric Traction 3 0 0 3 3 PC

4. EEPE-4XX Program Elective -VI 3 0 0 3 3 PE6

5. IDOE-4XX Open Elective -III 3 0 0 3 3 OE3

6. EEPC-426 Electric Drives & Control Laboratory

0 0 2 1 2 PC

7. EECI-400 Major Project - - 8 4 8 CIC

8. EECI-420 Industrial Lectures 1 CIC

TOTAL 22 26

Page 11: B. Tech. Electrical Engineering

11

Sem. Course Category Number Credits Total Credits

III CIC - -

20 PC 7 20

PE - -

OE - -

IV CIC 2 7

20 PC 5 13

PE - -

OE - -

V CIC 1 -

25 PC 8 22

PE 1 3

OE - -

VI CIC 1 2

27 PC 6 16

PE 2 6

OE 1 3

VII CIC 2 2

19 PC 3 8

PE 2 6

OE 1 3

VIII CIC 2 5

22 PC 4 11

PE 1 3

OE 1 3

Total Credits (III to VIII Sem) 133

Total No of PC 33 90

133 Total No of PE 6 18

Total No of OE 3 9

Total Credits for CIC 8 16

Credits of Ist yr 17 47 47

Total Credits

180

*Excluding minor elective

Page 12: B. Tech. Electrical Engineering

12

LIST OF DEPARTMENTAL ELECTIVES

S. No Semester Course Code Course Title L-T-P-C

1. 5th Semester EEPE-351 Operation Research 3-0-0-3

2. 5th Semester EEPE-353 Renewable Energy 3-0-0-3

3. 5th Semester EEPE-355 Computer Networks 3-0-0-3

4. 5th Semester EEPE-357 System Modelling and Reliability 3-0-0-3

5. 5th Semester EEPE -359 Data Acquisition and Telemetry 3-0-0-3

6. 6th Semester EEPE-352 High Voltage Engineering 3-0-0-3

7. 6th Semester EEPE-354 Soft Computing 3-0-0-3

8. 6th Semester EEPE-356 Power System Deregulation 3-0-0-3

9. 6th Semester EEPE-358 Smart Grid 3-0-0-3

10. 6th Semester EEPE -360 Energy Audit and Management 3-0-0-3

11. 6th Semester EEPE -362 Electrical Safety 3-0-0-3

12. 6th Semester EEPE -364 Embedded Systems 3-0-0-3

13. 6th Semester EEPE-366 Biomedical Instrumentation 3-0-0-3

14. 6th Semester EEPE-368 Power station automation 3-0-0-3

15. 6th Semester EEPE-370 Artificial Intelligence 3-0-0-3

16. 7th Semester EEPE-451 Control System Design 3-0-0-3

17. 7th Semester EEPE-453 Power Plant Engineering 3-0-0-3

18. 7th Semester EEPE-455 Modern Control System 3-0-0-3

19. 7th Semester EEPE-457 Smart Sensors and Sensor Networking

3-0-0-3

20. 7th Semester EEPE-459 High Voltage Transmission System

3-0-0-3

21. 8th Semester EEPE-452 Discrete Control Systems 3-0-0-3

22. 8th Semester EEPE-454 Distributed Generation 3-0-0-3

23. 8th Semester EEPE-456 Nonlinear Control System 3-0-0-3

24. 8th Semester EEPE-458 Brain Computer Interfacing 3-0-0-3

25. 8th Semester EEPE-460 Electric Machine Design 3-0-0-3

Page 13: B. Tech. Electrical Engineering

13

LIST OF OPEN ELECTIVES (OE)

S. No. Course Code Course Title L-T-P-C

1. EEOE-380 Elements of Control Engineering 3-0-0-3

2. EEOE-381 Sensors and Transducers 3-0-0-3

3. EEOE-382 Electronic Instrumentation and Measurements 3-0-0-3

4. EEOE-383 Virtual Instrumentation 3-0-0-3

5. EEOE-384 Non-conventional Energy Sources 3-0-0-3

6. EEOE-385 Digital Signal Processing 3-0-0-3

7. EEOE-386 Smart Materials and Structures 3-0-0-3

8. EEOE-387 Intellectual Property Rights 3-0-0-3

9. EEOE-480 Computer Networks 3-0-0-3

10. EEOE-481 Brain Computer Interface 3-0-0-3

11. EEOE-482 Biomedical Measurements 3-0-0-3

12. EEOE-483 Physiological Control Systems 3-0-0-3

13. EEOE-484 Testing and Calibration 3-0-0-3

14. EEOE-485 Elements of Electrical Engineering 3-0-0-3

15. EEOE-486 Optimization Techniques 3-0-0-3

16. EEOE-487 Computer Control of Industrial Process 3-0-0-3

17. EEOE-488 Machine Learning 3-0-0-3

18. EEOE-489 Industrial Measurements 3-0-0-3

19. EEOE-490 Smart Sensor and Wireless sensor Networks 3-0-0-3

20. EEOE-491 Internet of Things System Design 3-0-0-3

Page 14: B. Tech. Electrical Engineering

14

LIST OF MINOR ELECTIVES (MI)

S.No. Semester Course Code Course Title

1. 3rd Semester EEMI201 Circuit Theory

2. 4th Semester EEMI202 Electric Machine

3. 5th Semester EEMI301 Control System Engineering

4. 6th Semester EEMI302 Power System Analysis

5. 7th Semester EEMI401 Power System Operation and Control

6. 8th Semester EEMI402 Electrical Drives and Control

MI Minor Elective PC: Program Core CIC: Common Institute Core PE : Program Elective OE: Open Elective

Sr. No.

Course Code

Course Title L T P Credits Contact

Hours

Type

1. EEMI201 Circuit Theory 3 0 0 3 3 MI

2. EEMI202 Electric Machine 3 0 0 3 3 MI

3. EEMI301 Control System Engineering 3 0 0 3 3 MI

4. EEMI302 Power System Analysis 3 0 0 3 3 MI

5. EEMI401 Power System Operation and Control

3 0 0 3 3 MI

6. EEMI402 Electrical Drives and Control 3 0 0 3 3 MI

Total 18 18

The matter is to be placed before the Institute Senate for final approval. The meeting ended with vote of thanks to the Chair.

(Dr Dilbag Singh) Chairman, Board of Studies

Department of Electrical Engineering

Page 15: B. Tech. Electrical Engineering

15

3rd SEMESTER

EEPC-201 Circuit Theory [3 1 0 4] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

On successful completion of this course the student will be able to:

1. Analyse AC electrical circuits using basic laws and theorems of electrical circuits

2. Obtain the transient response of RC, RL and RLC circuits using Laplace transform

3. Solve two-port networks and Apply graph theory

4. Design analog filter and Synthesize networks

Network Analysis Techniques: Reciprocity Theorem, Milliman’s Theorem, Telegen’s

Theorem and Maximum Power Transfer Theorem – Applications of Network Theorems to

network analysis both with AC and DC inputs and magnetic coupling.

Applications of Laplace Transform: Introduction, some basic theorems, solutions of Linear

Differential Equations for electric network-problems, partial fraction expansion-Heaviside’s

Expansion Theorem, The convolution Integral-evaluation; Application of Laplace Transform

analysis of electrical circuits – Linear time invariant first and second order circuits. Zero

input response, Zero state response and complete response. Impulse response of first and

second order circuits, time varying circuits, Introduction to Fourier Transform.

Network Functions: Ports and terminal pairs, network functions, Poles and zeros,

necessary conditions for driving point functions and transfer functions, Time-domain

behaviour from pole-zero plot.

Two Port Networks: Introduction, Characterization of linear time invariant two port

networks, Z-, Y-, h- and transmission parameters, Interrelationship between these

parameters, Interconnection of Two-port networks, Image parameters; Attenuation and

phase shift in symmetrical T- and - networks.

Filters and Active Networks: Classifications of filters, Filter networks, pass band and stop

band types, Constant k-low pass and high pass filters, Characteristics impedance and cut off

frequency, m-derived filters.

Graph Theory and Network Equations: Introduction, graph of a network, trees, co-trees

and loops, incidence matrix, Cut-set matrix, Tie-set matrix and loop currents, Analysis of

networks using graph theory, duality, and general network transformations.

Network Synthesis: Introduction, Hurwitz polynomials, positive real functions, driving point

and transfer impedance function, LC-network, synthesis of dissipative network, Two-terminal

Page 16: B. Tech. Electrical Engineering

16

R-L network, Two-terminal R-C networks, Synthesis of R-L and R-C networks by Cauer and

Foster – methods.

Textbooks

1. Alexander, Charles K., and Matthew Sadiku, “Fundamentals of electric circuits”, McGraw Hill Education.

2. Van-Valkenburg M E, “Network Analysis”, Prentice Hall, New Delhi 3. Sudhakar, A, “Circuits and Networks”, Tata McGraw-Hill 4. Hayt, W., “Engineering Circuit Analysis”, Tata McGraw-Hill

5. Bell D A, “Electric Circuit,” Oxford University press

6. Van-Valkenburg M E, “Introduction to Modern Network Synthesis”, Wiley and Sons

7. Suresh Kumar,“ Introduction to Modern Network Synthesis”, Dorling Kindsley

Page 17: B. Tech. Electrical Engineering

17

ICPC- 251 Electrical Measurement and Measuring Instruments [3 1 0 4] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand working of general instrument system, types of error, calibration etc.

2. Measurement of various electrical quantities and parameters

3. Understand the principle and working of various electrical instruments and devices

Analog Measuring Instruments: Classification of analog instruments, operating forces in

indicating instruments, T/W ratio, pointers and scales. Working principle, theory, construction

and salient features of electromechanical indicating / registering instrument viz. PMMC,

Electrodynamometer, Moving iron, Rectifier type, Induction type for the measurement of dc

and ac voltage, current, power, energy (1-phase induction type wattmeter), power factor

(single phase Electrodynamometer), Volt ohmmeter or multimeter.

Measurement of Resistances: Classification of resistances, measurement of medium

resistance, Measurement of low resistance (Kelvin double bridge, Ammeter -Voltmeter) and

Measurement of high resistance including loss of charge method and Mega ohm bridge

method.

AC Bridges: General theory of ac bridge, Measurement of self-inductance, Measurement of

capacitance, Measurement of mutual inductance, Measurement of frequency, Sources of

error in ac bridges and their minimization.

Potentiometer: Introduction to basic principle, Laboratory type Crompton’s potentiometer,

Dual range potentiometer, Volt ratio box, application of dc potentiometer, self-balancing

potentiometer.

Magnetic Measurement: Working principle and theory of Ballistic galvanometer,

Measurement of flux density, Determination of B-H curve, hysteresis loop, Ewing Double bar

permeameter, Hopkinson permeameter, separation of iron losses by wattmeter and Bridge

methods.

Instrument Transformers: Theory and construction of current and potential transformers,

transformation ratio and phase angle errors and their minimization, effects of pf, secondary

burden and frequency.

Cathode Ray Oscilloscope: Principle and working of CRO, Block diagram presentation of

CRO and brief description of various elements of CRO – CRT, horizontal Deflecting system,

Vertical deflecting system, CRO screen, Measurement of voltage, frequency and phase

angle using CRO, CRO probes.

Textbooks

1. Cooper W D, “Electronic Instrumentation and Measurement Techniques”, Prentice Hall, New Delhi

2. Bell David A, “Electronic Instrumentation and Measurements”, Prentice Hall, Inc, New Delhi

Page 18: B. Tech. Electrical Engineering

18

3. Reissland Martin V, “Electrical Measurements Fundamentals, Concepts,

Applications”, New Age International.

4. Doebelin Ernest O, “Measurement Systems: Application and Design”, Tata McGraw

Hill Ltd., New Delhi.

5. Wolf S and Smith R F M, “Student Reference Manual for Electronic Instrumentation

Laboratories”, Prentice Hall, New Delhi.

Page 19: B. Tech. Electrical Engineering

19

ECPC-251 Electronic Devices and Analog Integrated Circuits [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

On successful completion of this course the student will be able to:

1. Knowledge of various solid state devices e.g. diodes, BJTs, FETs and their applications in electronic circuits

2. Knowledge of various feedback configurations of power and multistage amplifiers and ability to analyze their performances

3. Knowledge of op-amps and their applications and ability to analyze op-amp based circuits

4. Familiarization with various specialized ICs such as 555 timer, PLL, etc and their applications.

Semiconductors Diodes and Applications: Review of p-n junction diode and special

purpose diodes - Zener diode, Tunnel diode, Varactor diode, Photo diode; Clippers-single

and two level, clampers, their analysis with ideal and practical diodes.

Bipolar Junction Transistor: Transistors-construction, operation, characteristics,

parameters, Transistor as an amplifier at low frequency, Hybrid model and re model of BJT,

Analysis of amplifier using Hybrid model and re model, Amplifier types-CE,CB,CC. DC

operating point, Biasing circuits-fixed bias, emitter bias, voltage divider bias, bias

stabilization.

Field-Effect Transistor: The junction FET - construction, operation, characteristics,

parameters, JFET as an amplifier, FET as a VVR and MOSFET- construction, operation,

characteristics, parameters, introduction to CMOS.

Power and Multistage Amplifiers: Power Amplifiers, Types, analysis of Class A, B, C, AB;

Multistage Amplifiers, Types of multistage couplings. Feedback Amplifier and Oscillators:

Feedback concept, Analysis of various configurations of feedback in amplifiers, Criterion for

oscillation and Oscillator based on RC and LC feedback circuits, crystal oscillator.

Op-amps and Applications: Op-amp- analysis, Ideal op-amp building blocks, Open loop

op-amp configurations, Practical op-amp- Offset voltage, Input bias and offset current

analysis and compensation, CMRR, Block diagram representations and analysis of

configurations using negative feedback, Voltage-series and Voltage–shunt feedback

amplifier, Applications of op-amp- Summing, Scaling and Averaging amplifiers, Differential

amplifier, Instrumentation amplifiers, V to I and I to V converters, Differentiator and

integrator, Sample and hold circuits, Schmitt trigger.

Specialized ICs: 555 Timer-Monostable multivibrator, astable multivibrator, PLLs

Page 20: B. Tech. Electrical Engineering

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Textbooks:

1. Jacob Millman, Christos C Halkias and Satyabratajit, “Electronic Devices and Circuits” Tata McGraw- Hill, New Delhi (2008).

2. Boylestad Nashelsky, “Electronic Devices and Circuit Theory”, Pearson Education, 8th edition, 7th Indian Reprint (2004).

3. Ramakant A Gayakwad, “Op-amps and Linear Integrated Circuits”, Pearson Education, 4th edition, New Delhi (2002).

4. Adel S Sedra, and Kenneth C Smith, “Microelectronic Circuits”, Oxford University Press, New York, 4th edition (1997).

5. Ben J Streetman and Sanjay Banerjee, “Solid State Electronic Devices”, PHI 5th edition (2004).

Page 21: B. Tech. Electrical Engineering

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EEPC-203 EMF Theory [3 1 0 4] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. To impart knowledge on the concepts and the computation of Electro-magnetic field

which is essential for understanding the working principle, design and analysis of

Electrical machines and Systems.

2. The ability to compute the voltage, current impedance, and power along two-

conductor transmission lines using the solution of the wave equation and with the

Smith chart.

3. To understand Maxwell equations for solving the problem of electromagnetic filed

theory.

Electrostatics: Review of the fundamental postulates of Electrostatics in free space,

Coulomb's Law, Gauss's Law and applications, Electric potential, Conductors and Dielectrics

in static Electric Field, Electric flux density, boundary conditions for electrostatic fields,

Capacitance and capacitors, Electrostatic energy and Forces, Poisson's and Laplace's

Equations, Uniqueness of Electrostatic solutions, method of images.

Magneto statics: Review of the fundamental postulates of magneto statics in free space,

vector magnetic potential, Biot-Savart Law and applications, magnetic Dipole, Magnetic field

intensity and relative permeability, boundary conditions for Magneto static fields, magnetic

forces and torques.

Time varying fields and Maxwell's Equations: Introduction, Faraday's law of

Electromagnetic

Plane Electromagnetic Waves: Introduction, Plane waves in lossless media, plane waves

in lossy media, Group velocity, Flow of Electromagnetic Power and the poynting Vector,

Normal Incidence at a plane conducting boundary, Normal incidence at a plane dielectric

boundary.

Transmission lines: Introduction, transmission line parameters, transmission line

equations, input impedance, SWR, and Power, smith chart, microstrip transmission lines.

Waveguides: Introduction, rectangular waveguides, TM and TE modes, wave propagation

in the guide, power transmission and attenuation, waveguide current and mode excitation,

wave guide resonators.

Electromagnetic Interference and Compatibility: Introduction, source and characteristic

of EMI, control techniques.

Text Books

1. Hayt W H and J A Buck, “Engineering Electromagnetics”, Tata McGraw Hill Publishing

2. Edminister J A, “Schaum’s outline of theory and problems of Electromagnetics”, Tata McGraw Hill Publishing Co., New Delhi

Page 22: B. Tech. Electrical Engineering

22

3. Kraus J D, “Electromagnetics”, McGraw Hill, New York 4. Sadiku M N O, “Elements of Electromagnetics”, Oxford University Press 5. Jordon E C and K G Balmain, “Electromagnetic waves and radiating systems”,

Prentice Hall, New Delhi

Page 23: B. Tech. Electrical Engineering

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ECPC-254 Digital Electronics [3 0 0 3] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Knowledge of various number systems and ability to perform number conversions

2. Ability to identify, analyse and design combinational and sequential circuits

3. Knowledge of digital logic families

4. Knowledge about ADCs/DACs, memories and programmable logic devices.

Number Systems And Boolean Algebra: Review of Number systems, Radix conversion,

Complements 9’s &10’s, Subtraction using 1’s & 2’s complements, Binary codes, Error

detecting and Correcting codes, Theorems of Boolean algebra, Canonical forms, Logic

gates.

Combinational Circuits: Representation of logic functions, Simplification using Karnaugh

map, Tabulation method, Implementation of combinational logic using standard logic gates,

Multiplexers and Demultiplexers, Encoders and Decoders, Code Converters, Adders,

Subtractors, Parity Checker and Magnitude Comparator.

Sequential Circuits: Flip flops - SR, JK, D and T flip flops - Level triggering and edge

triggering, Excitation tables - Counters - Asynchronous and synchronous type Modulo

counters, design with state equation state diagram, Shift registers, type of registers, circuit

diagrams.

Digital Logic Families: Introduction to bipolar Logic families: TTL, ECL and MOS Logic

families: NMOS, PMOS, CMOS, Details of TTL logic family and its subfamilies.

D/A And A/D Converters: Weighted resistor type D/A Converter, Binary ladder D/A

converter, D/A accuracy and resolution, Parallel A/D Converter, counter type A/D converter,

Successive approximation A/D converter, Single and Dual slope A/D converter.

Semiconductor Memories: Memory organization, characteristics of memories, Sequential

memories, ROM, RAM and PLDs-PLA & PAL.

Text Books

1. Mano M. Morris, “Digital Design”, 3rd edition, Pearson Education 2006.

2. Jain R. P. “Modern Digital Electronics”, 3rd edition, Tata McGraw-Hill 2003.

3. Malvino and Leach “Digital principles and Applications”, 5th edition, Tata McGraw

Hill, 2003.

4. James W. Bignell and Robert Donovan, “Digital Electronics”, 5th edition, Delmar

Publishers, 2007.

5. Flecther “An Engineering Approach to Digital Design”, 1st edition, PHI, 2009.

6. Tocci Ronald J. “Digital Systems-Principles and Applications” 10th edition, PHI, 2009.

Page 24: B. Tech. Electrical Engineering

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EEPC-271 Electrical Measurement Laboratory [0 0 2 1] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand the procedure to measure unknown resistance, inductance and

capacitance using bridge circuits

2. Gain knowledge to calibrate electrical instruments Implement and verify different

3. Understand measurement schemes for measuring of electrical and non-electrical

parameters

List of Experiments 1. To measure amplitude and frequency of the signal using CRO (Y-t mode) 2. To measure frequency of an unknown signal and phase angle between two

signals obtaining Lissajous pattern using a CRO 3. Measurement of medium resistance with the help of a Wheatstone Bridge 4. Measurement of low resistance with the help of a Kelvin Double Bridge 5. Measurement of high resistance using a Meggar 6. Measurement of capacitance and inductance by Maxwell’s Bridge 7. Measurement of capacitance by Schering Bridge 8. Measurement of frequency by Wein’s Bridge 9. To study potentiometer and to plot EMF Vs. Displacement characteristics of a

potentiometer 10. To plot calibration curve for PMMC, Moving Iron and Electrodynamometer

type of voltmeters 11. To measure power consumed by a 3-phase load and to find its power factor

using 2-Wattmeter method 12. To plot calibration curve for a single phase energy meter 13. To find Q-factor of the coil using series resonance method and verify it using

LCR-Q meter 14. To draw a B-H loop of toroidal specimen by the Fluxmeter 15. To measure iron losses in the magnetic specimen using Wattmeter method

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 25: B. Tech. Electrical Engineering

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EEPC-225 Circuit Theory Laboratory [0 0 2 1] PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand various principles and theorems and practical application to analog

circuits

2. Fabricate basic forms of various filters and their configurations. Where after they get

familiarized with basic frequency responses of these filters

3. Realize active filters and develop their frequency response

List of Experiments

1. To study resonance in circuits 2. To Verify Telegen’s theorem 3. To verify Thevenin’s Theorem and Norton Theorem for a given network 4. To verify maximum power transfer theorem and reciprocity theorem 5. To evaluate two-port parameters for a TTPN 6. To verify working of inter-connected two TTPNs 7. To evaluate transmission parameters of a ladder network 8. To plot current locus of R-L and R-C series circuits 9. a) To observe the response of a RLC circuit to a.c. input. b) Determining the phase shift between the applied voltage and current using

Lissajous figures.

10. To find the Q of a coil by a series resonance method and verify it using Q meter.

11. a) To draw the characteristics of output voltage of a coupled circuit b) Determination of self and mutual inductances of a coupled circuit

12. To convert a four terminal network into a three terminal network (i.e. equivalent T network)

13. To design, fabricate and to obtain characteristics of a low pass T type filter 14. To design, fabricate and to obtain characteristics of a high pass T type filter 15. To design, fabricate and to obtain characteristics of a band pass T type filter 16. To design, fabricate and to obtain characteristics of a composite low pass

filter 17. To design, fabricate and to obtain characteristics of a composite high pass

filter 18. To design, fabricate and to obtain characteristics of a composite band pass

filter 19. To obtain the response of a given network to step and impulse inputs and to

verify the result 20. To obtain the impulse response and frequency response of a zero hold circuit 21. To study an active filter and to obtain characteristics in respect of Butterworth

filter 22. To study Chebyshev filter and to realize it in both active and passive form

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 26: B. Tech. Electrical Engineering

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4th SEMESTER

EEPC-202 Electrical Machines- I [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course, the student will be able to:

1. Learn the fundamental principles of Magnetic Circuits, Electro-mechanical energy conversion.

2. Learn about the construction and working principle of DC machines, AC Machines, transformers, synchronous machines and induction machines.

3. Learn the procedure for selecting machines for different applications.

Principle of Electromechanical Energy Conversion: Principle of energy conversion,

singly and doubly excited magnetic system, Dynamic equations.

DC Generators: EMF equation, classification of DC generators, various characteristics,

parallel operation of DC Generators, Tests on Generators, Losses and Efficiency.

DC Motors: Construction and principle of operation, armature winding, torque equation,

characteristics of DC motors and their applications, Braking and speed control, Brushless

DC machines.

Transformers: Construction and working principle, type of single-phase transformer,

concept of ideal transformer, emf equation, transformer on load, phasor diagram on no load

and on load, equivalent circuit, OC and SC tests, Regulation and efficiency, Pulse

transformer. Low, intermediate and high frequency response, Three Phase Transformers,

Auto Transformer: Principle of operation, advantages, phasor diagram, equivalent circuit.

Three Phase Induction Motors: Construction and principle of operation, slip-torque

equation, characteristics, phasor diagram at standstill and on load, equivalent circuit, No

load and blocked rotor tests, methods of speed control, applications.

Speciality Motors: Construction and principle of operation, Double revolving field theory,

types of single-phase induction motor, equivalent circuit, phasor diagram, characteristics,

hysteresis motor, reluctance motor, universal motor and their characteristics, applications.

Text Books

1. Hubert C I, Electric Machines: Theory, Operating Applications, and Controls”,

Pearson Education

2. Nagrath I J and Kothari D P, “Electric Machines”, Tata McGraw Hill

3. Say M G “Alternating Current Machines”, ELBS

4. Mcpherson George, Laramore R D, “Introduction to Electric Machines and Transformers”, John Wiley and Sons

5. Fitzegerald A F, Kingsley C and Umans S D, “Electrical Machinery”, Tata- McGraw Hill

Page 27: B. Tech. Electrical Engineering

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EEPC-204 Instrumentation [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn about various transducers and their working principles. 2. Learn different Op-amp based filters used for signal conditioning before data

acquisition. 3. Learn the working principle of telemetry system used for transmission of acquired

data. 4. Learn about various display devices.

Introduction: Generalized Measurement systems, Transduction principles, Classification of

transducers, General transducers characteristics, Criteria for transducer selection.

Transducers: Resistive, Inductive, Capacitive, Elastic andOther types-Principles of

operation, construction, theory, advantages, disadvantages and applications

Signal Conditioning: Concept of signal conditioning, Applications of AC/DC bridges in

instrumentation, Op-amp circuits used in instrumentation, Instrumentation amplifiers, Signal

filtering, averaging, correlation, interference, grounding, and shielding.

Data Transmission Systems: Definition, generalized block diagram of Telemetry system,

classification of Telemetry system the working principle, block diagram, construction, salient

features and applications of the following Telemetry systems: DC voltage, current and

position telemetry system (Landline Telemetry system), Radio frequency amplitude

modulated and frequency modulated telemetry system – theory related to amplitude and

frequency modulation techniques, Pulse telemetry systems, Modem based telemetry

system.

Display Systems: Construction, principle of operation and salient features of various kinds

of display devices such as LED, LCD, single and multi-digit LED 7-segmental display system

(study of BCD to 7 segment code converter / decoder),to design LED Dot Matrix (3 x 5)

numeric display system and LCD 7-segmental numeric display system.

Recorders: The working principle, construction, operation and salient features of X-t strip

chart recorder, X-Y strip chart recorder.

Textbooks

1. Murty D V S, “Transducers & Instrumentation”, PHI, New Delhi 2. Bell David A, “Electronic Instrumentation and Measurement”, PHI, Inc, New Delhi 3. Kalsi H S, “Electronic Instrumentation”, Tata McGraw Hill 4. Patranabis D, “Sensors and Transducers”, PHI, New Delhi 5. Doebelin Ernest O,”Measurement Systems: Application and Design”, Tata McGraw

Hill 6. Tocci Ronald J, “Digital Systems Principles and Applications”, PHI, New Delhi

Page 28: B. Tech. Electrical Engineering

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7. Mani and Rangan, “Instrumentation Devices and Systems”, Tata McGraw Hill, New Delhi

Page 29: B. Tech. Electrical Engineering

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EEPC-206 Generation of Electric Power [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn about various sources of energy and the types of power plants that harness these sources of energy.

2. Learn key components of hydroelectric power plant and its working. 3. Learn working of Steam, Gas and Nuclear power plant. 4. Learn about economic operation of power plants.

Introduction: Energy sources and their availability, Principle types of power plants, their

special features and application, present status and future trends.

Hydro Electric Power Plants: Essentials, Classifications, Hydroelectric survey,

Hydrograph, Flow durations curve, Mass curve, Storage capacity, Site selection, Plant

layout, Various components, Types of turbines, Governor and speed regulation, Pumped

storage, Small scale hydro-electric plants.

Steam Power Plant: General developing trends, Essentials, Plant layout, Coal –Its storage,

Preparation, Handling, Feeding and burning, Ash handling, dust collection, High pressure

boilers and steam turbines, super heaters, economizers, Pre-heaters etc., Fuel

efficiency/heat balance.

Gas Turbine Power Plants: Field of use, Components, Plant layout, Comparison with

steam power plants, combined steam and gas power plants.

Nuclear Power Plants: Nuclear fuels, Nuclear energy, Main components of nuclear power

plant, Nuclear reactors types and applications, Radiation shielding, Radioactive and waste

disposal safety aspect.

Performance and operation of Power Plants: Selection of type of generation,

Performance and operating characteristics of power plants, Economic Scheduling principles,

Load curves, Effect of load on power plant design, Methods to meet variable load, Load

forecasting, electric tariffs. Theory of peak load pricing, Theory of issues of real time pricing

comparison of public supply and private generating units, Power factor improvement.

Textbooks

1. Deshpande MV, Power Plant Engineering, Tata McGraw Hill

2. Gupta, B. R. Generation of electrical energy. S. Chand Publishing

3. Wood AJ, and Wallenberg BF, Power Generation and Control, John Wiley

4. Pansini AJ, Guide to Electric Power Generation, CRC Press

5. Grigsby LL, Electrical Power Generation Transmission and Distribution, CRC Press

6. Singh SN, Electric Power Generation Transmission and Distribution, Prentice Hall of

India

Page 30: B. Tech. Electrical Engineering

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MACI-206 Numerical Methods [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

CO5

Course Outcomes: The course will make the students able:

1. To attain knowledge of finding the roots of algebraic and transcendental equations which is a problem of great importance in applied mathematics by various numerical methods?

2. To understand direct and iterative methods for solving linear system of equations. 3. To attain knowledge of Eigen value problems and several methods of finding the

inverse of matrix which require less of computational labour and can be easily extended to matrices of higher order.

4. To understand interpolation, numerical differentiation and integration using basic concepts of finite differences.

5. To apply various numerical methods for solving ordinary differential equations where solutions cannot be obtained using available analytical methods and even to solve ordinary differential equations which have analytical solutions with greater ease.

6. To understand finite difference methods for boundary value problems and for elliptic, parabolic and hyperbolic partial differential equations which arise in description of physical processes in applied sciences and engineering?

Roots of algebraic and transcendental equations, Bisection Method, Regula – Falsi method,

Newton –Raphson method, Bairstow’s method and Graeffe’s root squaring method.

Solution of simultaneous algebraic equations, matrix inversion and Eigen-value problems,

train gularisation method, Jacobi’s and Gauss-Siedel iteration method, partition method for

matrix inversion, power method for largest Eigen-values and Jacobi’s method for finding all

Eigen-values.

Finite differences, interpolation and numerical differentiation, forward, backward and central

differences, Newton’s forward, backward and divided difference interpolation formulas,

Lagrange’s interpolation formula, Stirling’s and Bessel’s central difference interpolation

formulas, numerical differentiations using Newton’s forward and backward difference

formulas and Numerical differentiations using Stirling’s and Bessel’s central difference

interpolation formulas.

Numerical integration, Trapezoidal rule, Simpson’s one-third rule and numerical double

integration using Trapezoidal rule and Simpson’s one-third rule.

Page 31: B. Tech. Electrical Engineering

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Taylor’s series method, Euler’s and modified Euler’s methods, Runge-Kutta fourth order

methods for ordinary differential equations, simultaneous first order differential equations

and second order differential equations.

Boundary value problems, finite difference methods for boundary value problems. Partial

differential equations, finite difference methods for elliptic, Parabolic and hyperbolic

equations.

Textbooks

1. Sastry SS, Introductionary Methods of Numerical Analysis, Prentice Hall of India 2. Chapra SC and Canale RP, Numerical Methods for Engineers, McGraw Hill Book

Company 3. Grewal, BS, “Numerical Methods”, Khanna Publishers

Page 32: B. Tech. Electrical Engineering

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HMCI-201 Economics for Engineers [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Objectives

1. To gain knowledge about different micro and macro aspects of economics.

2. To understand the complex relationships and intricacies of different economic

variables.

3. To understand the micro and macro implications of economic policies and decisions.

Course Contents

Basic Economic concepts, Decision making under risk and uncertainty. Concept of utility,

demand and supply, elasticity of demand and supply, Demand forecasting. Production

function in short and long run: law of diminishing marginal returns, isoquant-isocost

approach. Economies of scale. Shapes of different cost curves in short and long run. Price-

output determination in perfect competition, monopoly, monopolistic competition and

oligopoly. Macroeconomics: national income, business cycle, fiscal policy, monetary policy,

price indices, inflation, theories of international trade.

Course Outcomes

1. The students will able to understand different terms and concepts of economics.

2. The students will gain proficiency in understanding the changes in economic

environment and their impact both at micro and macro levels.

Textbooks

1. Carl E Case, Ray C Fair and Sharon E Oster (2017), Principles of Economics,

Pearson

2. John Sloman, Dean Garratt and Alison Wride (2014), Economics, 9th edition,

Pearson.

3. Christopher R Thomas, S Charles Maurice and Sumit Sarkar (2010), Managerial

Economics, 9th edition, McGraw Hill Publication.

4. H L Ahuja (2017), Managerial Economics, 9th edition, S Chand Publishing.

Page 33: B. Tech. Electrical Engineering

33

EEXX-250 Professional Ethics & Holistic Wellbeing [2 0 0 2]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes:

1. Develop an understanding for ethics and their importance.

2. Learn about ethical decision making.

3. Learn the significance of team work and professional code of conduct.

Course Introduction to Ethics: Understand the requirements, expectations and evaluation

procedure for the course, Develop an understanding of the terms “ethics”, “morals”, “ethical

dilemma,” and the value of the study of ethics as it applies to both personal and professional

choices.

Ethical Theories & Decision Making – Personal Ethics: Understand the basis of personal

ethics including character development, individual norms and values, religion (Divine

Command Theory) societal norms and values, Discuss the implications of morality vs.

legality, professional codes, and ethical relativism as these apply to ethical decision making,

Begin developing a model for making ethical decisions.

Professional Codes of Conduct: Identify the benefits and effective components of

professional codes of conduct in the justice administration system, Application of ethical

values and process to decisions regarding conduct.

Group Work – Professional Presentations: Demonstrate team work, presentation skills,

and an understanding of ethical theories and the Code of Conduct through a group

presentation on the Code of Conduct and its application to a scenario or dilemma.

Text Books:

1. Code of Ethics and Professional Conduct, College of Occupational Therapists;

Revised edition edition, ISBN-10: 1905944209

2. Richard D. Parsons , “The Ethics of Professional Practice,” ISBN-13: 978-0205308781

Page 34: B. Tech. Electrical Engineering

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EECP-222 Electrical Machines - I Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Perform various configuration test on electrical single phase AC transformer

2. Understand the working of single phase and three phase electrical motors along with their construction

3. Acquire knowledge about the functioning of DC motor and generator

List of experiments

1. To perform Ratio, Polarity and the Load Test on a Single Phase Transformer 2. To perform Open Circuit and Short Circuit Test on a Single Phase Transformer

and hence determine its Equivalent Circuit Parameters 3. To perform Parallel Operation on two Single Phase Transformers 4. Speed Control of a DC Shunt Motor 5. To obtain Magnetization characteristics of (i) a separately excited DC Generator

(ii) a Shunt Generator 6. To obtain the load characteristics of (i) a DC Shunt Motor (ii) a DC Cumulative

Compound Generator 7. To perform no-load test and blocked rotor test on a three-phase induction motor

and hence determine its equivalent circuit parameters 8. To perform load test on a three-phase induction motor and obtain its various

performance characteristics 9. To perform the retardation test on a three phase induction motor and obtain its

moments of inertia 10. To perform no-load and blocked-rotor test on a single phase induction motor and

hence determine its equivalent circuit parameters 11. To study dc shunt motor starters. 12. To perform reversal and speed control of Induction motor. 13. Identification of different windings of a dc compound motor.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 35: B. Tech. Electrical Engineering

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EEPC-224 Instrumentation Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand the mechanism of measurement of physical quantities using transducers.

2. Understand the working of data acquisition system.

3. Learn about various display devices.

List of experiments

1. To measure displacement using an LVDT (linear variable differential transformer). 2. To measure the temperature using thermocouple and to plot variation of temperature

with the voltage. 3. To measure the force using a full bridge strain gauge based transducer. 4. To measure the strain of a deflecting beam with the help of a strain gauge. 5. To measure speed-using proximity type sensor. 6. To measure temperature using a thermistor and to plot variation of resistance with

temperature. 7. To study the recording of different signals from sensors on a magnetic tape

recorders. 8. To study the acquisition data from strain gauge transducer using a data acquisition

system. 9. To study the acquisition of data from inductive transducer using a data acquisition

system. 10. To measure the vibrations of system using a piezoelectric crystal. 11. To study the performance of an LCD, LED, BCD to 7-segment display. 12. To measure a load using a load cell. 13. To study the characteristics of a given bourdon tube.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 36: B. Tech. Electrical Engineering

36

5th SEMESTER

EEPC-301 Microprocessors and Interfacing [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand the architecture of 8-bit, 16-bit & Pentium microprocessors 2. Program the 8085 microprocessor & comprehend the basic concepts about the

peripherals and interfacing devices 3. Develop microprocessor based systems for real time applications

Introduction to 8-Bit Microprocessor: General 8-bit Microprocessor and its architecture –

Intel 8085 Microprocessor, Pin Configuration, CPU Architecture, Registers, ALU Control

Unit, Stack.

Microprocessor Instruction Set (INTEL 8085): Complete instruction set of INTEL 8085,

instruction format, types of instructions, various addressing modes, Timing diagrams – T-

states, machine cycles, instruction cycle.

Assembly Language Programming: Programming of Microprocessors using 8085

instructions, use of Arithmetic, logical, Data transfer, stack and I/O instructions in

programming, Interrupt in 8085.

Peripherals and Interfacing for 8085 Microprocessors: Memory interfacing, I/O

interfacing – memory mapped and peripheral mapped I/O, Data transfer schemes –

Programmed, Interrupt driven and Direct memory Access (DMA) data transfers, Block

diagram representation, Control word formats, modes and Simple programming of 8255A

PPI, 8254 Programmable Interval Timer, Interfacing of Data converters (A/D & D/A), Serial

I/O and data communication

Introduction to 8086 Microprocessors: Architecture of 8086, block diagram, register set,

flags, Queuing, concept of segmentation, Pin description, operating modes, addressing

modes and interrupts.

Pentium Microprocessors: Introduction to Pentium processors

Textbooks:

1. Gaonkar R S, “Microprocessor architecture, programming and application with 8085”, Wiley

2. Ram B, “Fundamentals of Microprocessors and Microcomputers”, Dhanpat Rai and Sons

1. Liu Yu-Cheng, “Microcomputer Systems”, The 8086/8088 family,” Prentice Hall.

2. Mathur AP, “Introduction to Microprocessors”, Tata McGraw Hill. 3. Ray AK and Bhurchandi KM. “Advanced Microprocessor and peripherals:

Architecture programming and interfacing”, Tata McGraw Hill.

Page 37: B. Tech. Electrical Engineering

37

EEPC-303 Control System Engineering [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn the representation of systems, their transfer function models 2. Find the time response of systems subjected to test inputs and the associated steady

state/dynamic errors 3. Analyse the concept of stability in time domain and frequency domain 4. Learn basics of compensation 5. Use of various control components

Introductory Concepts: Plant, Systems, Servomechanism, regulating systems,

disturbances, Open loop control system, closed loop control systems, linear and non-linear

systems, time variant and invariant, continuous and sampled-data control systems, Block

diagrams, some illustrative examples.

Modelling: Formulation of equation of linear electrical, mechanical, thermal, pneumatic

hydraulic system, electrical, mechanical analogies. Use of Laplace transforms, Transfer

function, concepts of state variable modelling. Block diagram representation, signal flow

graphs and associated algebra, characteristics equation.

Time Domain Analysis: Typical test – input signals, Transient response of the first and

second order systems. Time domain specifications, Dominant closed loop poles of higher

order systems. Steady state error and coefficients, pole-zero location and stability, Routh-

Hurwitz Criterion.

Root Locus Technique: The extreme points of the root loci for positive gain. Asymptotes to

the loci, Breakaway points, intersection with imaginary axis, location of roots with given gain

and sketch of the root locus plot.

Frequency Domain Analysis: Closed loop frequency response, Bode plots, stability and

loop transfer function. Frequency response specifications, Relative stability, Relation

between time and frequency response for second order systems. Log. Magnitude versus

Phase angle plot, Nyquist criterion for stability.

Compensation: Necessity of compensation, series and parallel compensation,

compensating networks, applications of lag and lead-compensation.

Control Components: Error detectors – potentiometers and synchros, servo motors, AC

and DC techno generators, Magnetic amplifiers.

Textbooks:

1. Ogata K, “Modern Control Engineering”, Prentice Hall

Page 38: B. Tech. Electrical Engineering

38

2. Nagrath IJ and Gopal M, “Control System Engineering”, Wiley Eastern 3. Kuo B C, “Automatic Control System”, Prentice Hall 4. Dorf R C and Bishop RH, “Modern Control System”, Addison-Wesley, Pearson 5. Stephanopoulos G, “Chemical Process Control”, Prentice Hall of India 6. Norman S. Nise, “Control Systems Engineering”

Page 39: B. Tech. Electrical Engineering

39

EEPC-305 Power Electronics [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn about various switching devices.

2. Learn the basic principle and design of phase controlled converters.

3. Learn about DC-DC and AC-AC converters.

4. Learn PWM based inverters.

Power Semi-Conductor Devices: Study of switching devices, Frame, Driver and Snubber

circuit of SCR, TRIAC,BJT, IGBT, MOSFET, Turn-on and turn-off characteristics, switching

losses, Commutation circuits for SCR.

Phase-Controlled Converters: 2-pulse, 3-pulse and 6-pulse converters, Effect of source

inductance, performance parameters, Reactive power control of converters, Dual converters,

Battery charger.

DC to DC Converter: Step-down and step-up chopper, Time ratio control and current limit

control, Buck, boost, buck boost converter, concept of Resonant switching, SMPS.

Inverters: Single phase and three phase (both 1200 mode and 1800 mode) inverters, PWM

techniques: Sinusoidal PWM, modified sinusoidal PWM, multiple PWM,

AC to AC Converters: Single phase AC voltage controllers, Multi-stage sequence control,

single and three phase cyclo-converters,

Textbooks:

1. Bimbra PS, “Power Electronics” Khanna Publishers. 2. Mohan N, Undeland TM, Robbins WP, “Power Electronics: Converters, Applications

and Design,” John Wiley. 3. Rashid MH, “Power Electronics: Circuits, Devices and Applications,” Pearson

Education. 4. Krein PT, “Elements of Power Electronics,” Oxford University Press. 5. Ahmed A, “Power Electronics for Technology”, Pearson Education.

Page 40: B. Tech. Electrical Engineering

40

EEPC-307 Electrical Machines-II [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn construction of Polyphase synchronous machine.

2. Develop equivalent circuit model and phasor diagram for synchronous machine

3. Understand parallel operation of synchronous generators and methods of

synchronization.

Polyphase Synchronous Machines: Constructional features. Polyphase Distributed AC

Windings: Types, Distribution, coil span and winding factors. Excitation systems, emf

equation and harmonic elimination.

Synchronous Generator: Interaction between excitation flux and armature mmf, equivalent

circuit model and phasor diagram for cylindrical rotor machine. Salient pole machines: two

reaction theory, equivalent circuit model and phasor diagram. Power angle equations and

characteristics. Voltage regulation and effect of AVR.

Multi Machine Operation: Synchronizing methods, Parallel operation and load sharing,

active and reactive power control, operation on infinite busbar. Analysis under sudden short

circuit. Transient parameters. Motoring mode, Transition from motoring to generating mode,

Phasor diagram, steady state operating characteristic, V-curves, starting, synchronous

condenser, hunting –damper winding effects, speed control including solid state control.

Testing of Synchronous Machines: Stability considerations, Brushless generators, Single

Phase generators.

Text Books:

1. Nagrath IJ and Kothari DP, “Electric Machines,” Tata McGraw Hill 2. Bimbhra PS, “Electrical Machinery”, Khanna Publishers 3. Sarma MS and Pathak M, “Electrical Machines,” Cengage Learning India 4. Say, MG, “Alternating Current Machines”, ELBS. 5. Hubert CI, “Electric Machines: Theory, Operation, Applications, Adjustment, and

Control,” Pearson Education India

Page 41: B. Tech. Electrical Engineering

41

EEPC-309 Transmission and Distribution of Electric Power [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand different configurations of distribution system.

2. Learn about constructional and operational aspects of transmission lines and

underground cables.

3. Learn mathematical modelling of transmission lines.

Introduction: Generation, Transmission and Distribution, Various supply systems,

Comparison based on copper Efficiency.

Distribution System: Primary and secondary distribution systems, Radial, ring-main and

network distribution systems, Distribution Voltage, Choice of conductor size for distributors,

Distribution sub stations – types and location, main equipment in distribution sub-station,

Supporting structures for distribution lines, Voltage drop and power loss calculations.

Over Head Transmission Lines: Overhead and Underground – transmission, conductor,

materials, solid stranded, ACSR, hollow and bundle conductors, different types of supporting

structures and tower for OH-lines, Transmission line parameters – calculation of inductance

and capacitance of single and double circuit transmission lines, 3-Phase with stranded and

bundle conductors, Generalized ABCD – constants, Transposition of OH-conductors.

Performance of Transmission Lines: Short transmission lines – voltage drop, regulation

and efficiency calculations. Medium transmission Lines – Nominal – T and -solution for

voltage drop, regulation and efficiency. Long Transmission Lines – current and voltage

relations, ABCD – constants, charging current and Ferranti effect.

Mechanical Design of Overhead Lines: Sag and stress calculations, Wind and Ice loads

stringing chart and Sag Templates, elementary idea about conductor vibrations.

Insulators of Overhead Lines: Insulator materials, types of insulators, Voltage distribution

over an insulator string, string efficiency, equalizing voltage drops across insulators of a

string.

Underground Cables: Insulating materials, types of LV and HV – Cable, 3-core solid, oil

filled and gas pressure cables, grading of cables, sheath and dielectric loss in cables,

elementary idea about cable breakdown, thermal considerations and current rating of

cables, cable laying and jointing.

Text Books:

1. Wadhwa CL, “Electric Power Systems”, Wiley Eastern

2. Ashfaq, Hussain, "Electrical power systems", CBS Publications. 3. Nagrath, IJ and Kothari DP, “Modern Power System Analysis”, Tata McGraw Hill

Page 42: B. Tech. Electrical Engineering

42

4. Cottan H and Barber H, “Transmission and Distribution of Electric Energy”, B I Publishing

5. Stevenson WD, “Elements of Power System Analysis”, McGraw Hill 6. Elgerd O I, “Electric Energy System – An Introduction”, Tata McGraw Hill

EEPE-3XX Program Elective-I [3 0 0 3]

Refer Page No. 72 to Page No. 77

Page 43: B. Tech. Electrical Engineering

43

EEPC-321 Microprocessors and Interfacing Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Program 8085 Microprocessors using assembly language 2. Interface peripheral devices such as PPI, Timer, ADC/ DAC with microprocessor 3. Learn implementation of microprocessor based applications such as of Stepper Motor

Controller, Traffic Light Controller, PID controller and Data Acquisition System 4. Analyse, comprehend, design and simulate microprocessor based systems used for

control and monitoring

At least 8 experiments are to be performed out of the following list:

1 a) Familiarization with the 8085 kit (trainer kit)

b) To execute at least 8 programs on the above kit.

2 a) Familiarization with the 8085 kit (trainer-cum-development)

b) To execute at least 5 program on the above kit.

3. Study of 8155 card 4. Study of 8212 card 5. Study of 8255 card 6. Study of 8253 card 7. Study of 8251 card 8. Study of latch, buffer, decade, RAM study card. 9. Study of 8257/8237 DMA control study card. 10. Study of DC motor study card. 11. Study of traffic control study card. 12. Study of A to D and D/A converter. 13. Familiarization with 8086 trainer kit

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 44: B. Tech. Electrical Engineering

44

EEPC-323 Control System Engineering Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

Course Outcomes:

On successful completion of this course the student will be able to:

1. Use potentiometer and syncro as error detectors

2. Characterize servo motors

3. Derive transfer function

4. Study the open loop and closed loop speed control of AC servo motor

5. Study of PID control action

At least 8 experiments are to be performed out of the following list: 1. To study the characteristics of potentiometer and to use it as an error detector in a

control system 2. To study the synchro Transmitter-Receiver set and to use it as an error detector 3. To study the Speed – Torque characteristics of an AC Servo Motor 4. To study the Speed – Torque characteristics of an DC Servo Motor 5. To study the various electro-mechanical transducers i.e. resistance, capacitance,

inductive transducers 6. To study a LVDT (AC-AC, DC-DC) as a transducer and its processing circuits 7. To study the characteristics of a thermocouple, a thermistor and a RTD 8. To study photo-conductive cell, semi-conductor photodiode and a silicon photo

voltaic cell 9. To study a silicon phototransistor and obtain response of photo conductive cell 10. To study the variations of time lag by changing the time constant using control

engineering trainer 11. To simulate a third order differential equations using an analog computer and

calculate time response specifications 12. To obtain the transfer function of a D.C. motor – D.C. Generator set using Transfer

Function Trainer 13. To study the speed control of an A.C. Servo Motor using a closed loop and an open

loop systems 14. (i)To study the operation of a position sensor and study the conversion of position in

to voltage (ii) To study the PI control action and show its usefulness for minimizing steady

state error

15. To measure Force / Displacement using Strain Gauge in a wheat stone bridge

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 45: B. Tech. Electrical Engineering

45

EEPC-325 Electrical Machines -II Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Perform various test on synchronous machine used for its characterization.

2. Learn the procedure of synchronization of three phase alternator with the grid.

3. Learn operational aspects of synchronous generator at different load conditions.

4. Learn about Automatic Voltage Regulator (AVR).

At least 8 experiments are to be performed out of the following list:

1. No-load short-circuit and ZPF tests on a synchronous machine. Determination of

voltage regulation at specified load by i) EMF ii) MMF iii) Potier’s method iv) ASA

methods and comparison of results.

2. Load-angle characteristic and comparison with theoretically predicted results.

3. V-curves and inverted V-curves of synchronous machines. Comparison with

predicted characteristics.

4. Synchronization of three phase alternator with infinite bus bar. Study of variation of

excitation and mechanical power input on performance.

5. Slip-test, short circuit and lagging current tests on a salient pole machine and

determination of armature parameters. Estimation of voltage regulation at specified

loads using Blondel‟s method. Comparison with results from load test.

6. Sudden short circuit test and determination of Xd, Xd‟, Xd‟‟ and machine time

constants.

7. Determination of XI, X2, X0 by fault simulation methods.

8. Study of Automatic Voltage Regulators (AVR) and switch over from grid to stand

alone mode.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 46: B. Tech. Electrical Engineering

46

EECI-300 Minor Project [0 0 2 2]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: After completion of this course, the students would be able to:

1. Identify projects related to broad area of Electrical Engineering.

2. Design, model, simulate and fabricate a prototype.

3. Prepare the project report.

The Minor Project is aimed at training the students in the broad area of Electrical

Engineering to analyse a problem and propose a possible economic solution. The project

may be analytical, computational, and experimental or combination of them based on the

latest developments in the relevant areas. It essentially will consist of objectives of study,

scope of work, critical literature review and preliminary work done and it may be extend for

the next semester (minor project) and major project in Seventh and Eighth Semester. All the

students are required to implement a research paper already published. During the project

period, every student has to present the progress of their works before the duly constituted

committee of internal teachers of the department. The assessment by the committee

members are a part of Mid Term Evaluation. A report of the project in the form of hard copy

must be submitted in the office before the final evaluation by the External Examiners.

Page 47: B. Tech. Electrical Engineering

47

6TH SEMESTER

EEPC-302 Power System Analysis [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand per unit system, Z-bus and Y-bus representations.

2. Learn how to carry out power flow analysis.

3. Learn to carry out fault analysis.

4. Understand stability issues of power system

Introduction: Need of system planning and operational studies, basic components of

power system, Introduction to restructuring, Single line diagram, per phase and per unit

analysis, Generator, transformer, transmission line and load representation for different

power system studies, Primitive network – construction of Y-bus using inspection and

singular transformation methods, Z-bus.

Power flow analysis: Importance of power flow analysis in planning and operation of power

systems, statement of power flow problem, classification of buses, development of power

flow model in complex variables form, iterative solution using Gauss-Seidel method, Q-limit

check for voltage controlled buses, power flow model in polar form, iterative solution using

Newton-Raphson method.

Fault analysis of balanced faults: Importance of short circuit analysis, assumptions in fault

analysis, analysis using Thevenin’s theorem, Z-bus building algorithm, fault analysis using Z-

bus, computations of short circuit capacity, post fault voltage and currents.

Fault analysis of unbalanced faults: Introduction to symmetrical components, sequence

impedances, sequence circuits of synchronous machine, transformer and transmission lines,

sequence networks analysis of single line to ground, line to line and double line to ground

faults using Thevenin’s theorem and Z-bus matrix.

Stability analysis: Importance of stability analysis in power system planning and operation-

classification of power system stability, angle and voltage stability, Single Machine Infinite

Bus (SMIB) system: Development of swing equation, equal area criterion, determination of

critical clearing angle and time, solution of swing equation by modified Euler method and

Runge-Kutta fourth order method.

Textbooks:

1. Saadat, Hadi. “Power system analysis” McGraw-Hill. 2. Glover, J. Duncan, Mulukutla S. Sarma, and Thomas Overbye, “Power system

analysis & design” Cengage Learning. 3. Wadhwa CL, “Electrical Power Systems”, New Age International Publication 4. Kothari DP and Nagrath IJ, “Modern Power System Analysis”, Tata McGraw Hill 5. Elgerd OI, “Electric Energy Systems Theory: An Introduction”, Tata McGraw Hill

Page 48: B. Tech. Electrical Engineering

48

6. Gainger JJ and Steveson WD “Power System Analysis”, McGraw Hill 7. Kundur P, “Power System Stability and Control”, McGraw Hill 8. Kimbark EW, “Power System Stability, Vol. I : Elements of Stability Calculations”,

Johns Wiley & Sons.

Page 49: B. Tech. Electrical Engineering

49

EEPC-304 Digital Signal Processing [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

Course Outcomes: On successful completion of this course the student will be able to:

1. Represent continuous and discrete systems 2. Apply Z-transform, FT, DFT, FFT and their computation 3. Learn the finite word length effects in signal processing 4. Design digital filters 5. Learn fundamentals of digital signal processors

Introduction: Classification of systems: Continuous, discrete, linear, causal, stable,

dynamic, recursive, time variance; classification of signals: continuous and discrete, energy

and power; mathematical representation of signals; spectral density; sampling techniques,

quantization, quantization error, Nyquist rate, aliasing effect. Digital Signal representation.

Discrete Time System Analysis: Z-transform and its properties, inverse Z-transforms;

difference equation – Solution by Z-transform, application to discrete systems - Stability

analysis, frequency response – Convolution – Fourier transform of discrete sequence –

Discrete Fourier series.

Discrete Fourier Transform & Computation: DFT properties, magnitude and phase

representation - Computation of DFT using FFT algorithm – DIT & DIF - FFT using radix 2 –

Butterfly structure.

Design of Digital Filters: FIR & IIR filter realization – Parallel & cascade forms. FIR design:

Windowing Techniques – Need and choice of windows – Linear phase characteristics. IIR

design: Pole-zero placement, Impulse-invariant, matched z-transform and bilinear

transformation methods.

Digital Signal Processors: Introduction – Architecture – Features – Addressing Formats –

Functional modes - Introduction to Commercial Processors.

Textbooks:

1. Ambardar A, “Digital signal processing - A modern introduction,” Cengage Learning 2. Proakis JG and Manolakis DG, “Digital signal processing,” Pearson Education India 3. Ifeacher EC and Jerris BW, “Digital signal processing - A practical approach,”

Pearson Education 4. Lyons RG, “Understanding Digital Signal Processing,” Pearson Education 5. Chen CT, “Digital signal processing - Spectral computation and filter design,” Oxford

University

Page 50: B. Tech. Electrical Engineering

50

ICPC-352 PLC, DCS and SCADA [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn hardware, architecture and software for PLC and SCADA 2. Learn PLC and SCADA programming for selected industrial processes 3. Study DCS architecture and industrial automation 4. Learn various industrial data communication protocols

Computer Based Control: Implementing control system using computer or microprocessor;

computer based controller: hardware configuration and software requirements.

Distributed Control System: Meaning and necessity of distributed control; hardware

components of DCS; DCS software.

Introduction Programmable Logic Controller (PLC): PLC versus microprocessor/

microcontroller/ computer, advantages and disadvantages of PLC, architecture and physical

forms of PLC.

Basic PLC functions: Registers: holding, input and output registers; Timers and timer

functions; counters and counter functions

Intermediate PLC functions: Arithmetic functions: addition, subtraction, multiplication,

division and other arithmetic functions; Number comparison and conversion.

Data Handling Functions of PLC: Skip function and applications; master control relay

function and applications; jump with non-return and return; data table, register and other

move functions.

Bit Functions of PLC: Digital bit functions and applications; sequencer functions and

applications.

Advanced Functions of PLC: Analog input and output functions, analog input and output

modules, analog signal processing in PLC; PID control function, network communication

function.

PLC programming: PLC programming languages, ladder programming, mnemonic

programming and high level language programming.

SCADA: Supervisory control versus distributed control; Layout and parts of SCADA system,

detailed block schematic of SCADA system; Functions of SCADA system: data acquisition,

monitoring, control, data collection and storage, data processing and calculation, report

generation; MTU: functions, single and dual computer configurations of MTU; RTU:

functions, architecture / layout; MTU-RTU communication and RTU-field device

communication.

Page 51: B. Tech. Electrical Engineering

51

Textbooks:

1. Johnson CD, “Process Control Instrumentation Technology,” Prentice Hall

2. Chemsmond CJ, “Basic Control System Technology,” Viva Books 3. Webb JW and Reis RA, “ Programmable Logic Controllers” Prentice-Hall India 4. Hackworth JR and Hackworth FD, “ Programmable Logic Controllers,” Pearson

Edition 5. Boyer SA, “Supervisory Control and Data Acquisition (SCADA), International Society

of Automation

Page 52: B. Tech. Electrical Engineering

52

CSPC-231 Data Structure and Algorithms [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

CO6

Course Outcomes:

On successful completion of this course the student will be able to:

1. Define basic static and dynamic data structures and relevant standard algorithms for them: stack, queue, dynamically linked lists, trees, graphs, heap, priority queue, hash tables, sorting algorithms, min-max algorithm,

2. Demonstrate advantages and disadvantages of specific algorithms and data structures,

3. Select basic data structures and algorithms for autonomous realization of simple programs or program parts

4. Determine and demonstrate bugs in program, recognize needed basic operations with data structures

5. Formulate new solutions for programing problems or improve existing code using learned algorithms and data structures

6. Evaluate algorithms and data structures in terms of time and memory complexity of basic operations.

Introduction: Basic Terminology, Elementary Data Organization, Structure operations.

Arrays: Array Definition, Representation and Analysis, Single and Multidimensional Arrays,

address calculation, application of arrays, Character String in C++, Character string

operation, Array as Parameters, Ordered List, Sparse Matrices and Vectors.

Stacks: Array Representation and Implementation of stack, Operations on Stacks: Push &

Pop, Array Representation of Stack, Linked Representation of Stack, Operations Associated

with Stacks, and Application of stack: Conversion of Infix to prefix and Postfix Expressions,

Evaluation of postfix expression using stack.

Recursion: Recursive definition and processes, recursion in C, example of recursion, Tower

of Hanoi Problem, simulating recursion, Backtracking, recursive algorithms, principles of

recursion, tail recursion, removal of recursion.

Queues: Array and linked representation and implementation of queues, Operations on

Queue: Create, Add, Delete, Full and Empty, Circular queues, D-queues and Priority

Queues.

Linked list: Representation and Implementation of Singly Linked Lists, Two-way Header

List, Traversing and Searching of Linked List, Overflow and Underflow, Insertion and

deletion to/from Linked Lists, Insertion and deletion Algorithms, Doubly linked list, Linked List

in Array, Polynomial representation and addition, Generalized linked list, Garbage Collection

and Compaction.

Page 53: B. Tech. Electrical Engineering

53

Trees: Basic terminology, Binary Trees, Binary tree representation, algebraic Expressions,

Complete Binary Tree, Extended Binary Trees, Array and Linked Representation of Binary

trees, Traversing Binary trees.

Searching and Hashing: Sequential search, binary search, comparison and analysis, Hash

Table, Hash Functions, Collision Resolution Strategies, Hash Table Implementation.

Sorting: Insertion Sort, Bubble Sorting, Quick Sort, Two Way Merge Sort, Heap Sort,

Sorting on Different Keys, Practical consideration for Internal Sorting.

Graphs: Terminology & Representations, Graphs & Multi-graphs, Directed Graphs,

Sequential Representations of Graphs, Adjacency Matrices, Traversal, Connected

Component and Spanning Trees, Minimum Cost Spanning Trees.

Textbooks:

1. Horowitz and Sahani, “Fundamentals of data Structures”, Galgotia Publication Pvt.

Ltd., New Delhi.

2. R. Kruse etal, “Data Structures and Program Design in C”, Pearson Education Asia,

Delhi-2002

3. A. M. Tenenbaum, “Data Structures using C & C++”, Prentice-Hall of India Pvt. Ltd.,

New Delhi.

1. Bruno R Preiss, “Data Structures and Algorithms with Object Oriented Design Pattern

in C++”, Jhon Wiley & Sons, Inc.

2. GilbergForozan , “Data Structure – A pseudo code approach with C++”, Cengage

Learning, New Delhi.

EEPE-3XX Program Elective-II [3 0 0 3]

Refer Page No. 78 to Page No.90

EEPE-3XX Program Elective –III [3 0 0 3]

Refer Page No. 78 to Page No.90

IDOE-3XX Open Elective-I [3 0 0 3]

Page 54: B. Tech. Electrical Engineering

54

EEPC-322 Power System Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand load flow algorithms.

2. Understand IEEE 14 and IEEE30 bus system

3. Simulate symmetrical three phase faults

4. Simulate single-area and two-area frequency control

At least 8 experiments are to be performed out of the following list:

1. To develop a computer program to solve the set of non-linear load flow equations using G-S load flow algorithm.

2. To develop a software program to obtain real and reactive power flows, bus voltage magnitude and angles by using N – R method.

3. To become proficient in the usage of software in solving load flow problems using Fast decoupled load flow method.

4. Program to read and print out the power system load flow data of 5 BUS – IEE 14 Bus and IEEE 30 Bus systems.

5. To develop a computer program to carry out simulation study of a symmetrical three phase short circuit on a given power system.

6. To develop a program to transient stability of a given power system. 7. To develop a program for solving economic dispatch problem without transmission

losses for a given load condition using direct method and Lambda-iteration method. 8. To develop a Simulink model of single-area and two-area load frequency control of

power system. 9. To develop a computer program to obtain the building algorithm for bus impedance

matrix of the given power system. 10. To measure ABCD parameters of a transmission line and calculate its efficiency at

various loads. 11. To plot the trip time characteristics of over voltage relay (microprocessor based) on

testing kit. 12. To plot the trip time characteristics of under voltage relay (microprocessor based) on

testing kit. 13. To plot the characteristics of an over current relay (Inverse Type CDG) for plug setting of

2.5A and 5A and TMS of 0.6 and 1.0. 14. To study the Negative phase sequence protection scheme on testing kit. 15. To find the string efficiency without the guard ring, with guard ring. 16. To measure zero sequence components of line current in a 3-phase, 4 wire system. 17. To measure (PPS and NPS) sequence components of supply voltage by segregating

networks and verify graphically. 18. To measure earth resistance with the help of digital earth resistance tester.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 55: B. Tech. Electrical Engineering

55

EEPC-324 Digital Signal Processing Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course, the student will be able to:

1. Characterize sampled systems in time and frequency domain 2. Design basic IIR digital filters (using the bilinear transformation) 3. Program digital signal processing algorithms in C and MATLAB, including the design,

implementation, and real-time operation of digital filters, and applications of the fast Fourier transform

At least 8 experiments are to be performed out of the following list:

1. Plotting discrete signals: Plot δ[n-3], u[n-3], r[n-3], sinc(n/4) and 4(0.8)n cos(0.2nπ)u[n] over the range -10 ≤ n ≤ 10.

2. Signal measures: Let x[n] = r[n] – r[n-5] – 5u[n-10]. (a) Sketch x[n], x[n+2], x[-n], xe[n], and xo[n].

(b) Find the signal energy in x[n].

(c) Is x[n] absolutely summable? Square summable?

(d) Sketch the periodic extension of x[n] with period N = 7 and find its signal power.

3. Random distributions: Generate about 500 points each of a uniform and Gaussian

random signal.

(a) Plot their first 100 values.

(b) Plot their histograms using 20 bins.

(c) Compute their mean and variance.

4. The central limit theorem: Demonstrate the central limit theorem by generating five

realizations of a uniformly distributed random signal and plotting the histogram of the

individual signals and their sum.

5. Signal-to-Noise Ratio: For a noisy signal x(t) = s(t)+An(t) with a signal component s(t)

and noise component An(t), the signal to noise ratio (SNR) is the ratio of signal power

and noise power 𝐴2𝜎𝑛2 and defined as dB. We can adjust the

SNR by varying the noise amplitude A. Use the result to generate the noisy sinusoid with

SNR of 18 dB.

6. Signal Averaging: Using coherent signal averaging extract the signals from the noise

given below.

(a) Sample x = sin(40πt) at 1000Hz for 0.2s to obtain the discrete signal x[n].

(b) Generate 16 runs (realizations) of a noisy signal by adding uniformly distributed

random noise (with zero mean) to x[n] and average the results.

(c) Repeat part (b) for 64 runs and compare results.

(d) Does averaging improve the quality of the noisy signal?

2

s 22

2

log10n

s

ASNR

Page 56: B. Tech. Electrical Engineering

56

7. Discrete system response: Consider the second oreder system y[n]-0.64y[n-2] =

x[n]+2x[n-1] with zero initial conditions and x[n]=20(0.8)nu[n].

(a) Find its response using dlsim and filter and compare the results.

(b) Is this system BIBO stable?

8. Smoothing effects of a moving average filter: Consider a 20-point moving average filter

y[n] = 1/20{x[n]+x[n-1]+............x[n-19]}. It is also called a smoothing filter because it

tends to smooth out the rapid variations in a signal, To confirm this try the following;

(a) Generate 200 samples of 1Hz sine wave sampled at 40 Hz.

(b) Add some noise to generate a noisy signal.

(c) Filter the noisy signal through the 20-point MA filter.

(d) Plot each signal to display the effects of noise and smoothing.

9. Convolution and convolution indices: An input is applied to an FIR filter

whose impulse response is given by . Find the response y[n] and sketch

all three signals using the same axis limits.

10. Approximating analytical convolution: The impulse response of a digital filter is described

by h[n] = (0.4)nu[n]. Evaluate and plot the response y[n] of this filter to the input x[n] =

(0.8)nu[n] over the range 0≤n≤20.

11. System response to sinusoidal inputs: We claim that the response of LTI system to a

sinusoidal input is a sinusoid at the input frequency. Justify the statement using an input

x[n] = cos(0.2πn) to a digital filter whose impulse response is described by

.

12. Convolution and filtering: The difference equation describing the digital filter of the

previous example may be written as y[n]=x[n]+2x[n-1]+................+8x[n-7].Use this to find

the response to x[n] = cos(0.2πn) and compare with the previous example.

13. Deconvolution: Given and 𝑥[𝑛] = {3↑, 3,2,2} identify h[n].

14. Circular convolution: Consider two periodic signals described over one period by

𝑥𝑝[𝑛] = {1↑, 2, −1,0,2,3} ℎ𝑝[𝑛] = {2

↑, 1,0,−1,−2,−3}. Find their periodic convolutions.

15. Let 𝑥𝑝[𝑛] = {1↑, 2, −1,0,2,3}andℎ𝑝[𝑛] = {2

↑, 1,0, −1,−2,−3}.

(a) Find the periodic convolution y1[n] using one period of x and h.

(b) Find the periodic convolution y5[n] using 5 periods of x and h.

(c) How is the period of y5[n] related to that of y1[n] ?

(d) How are the convolution values of y5[n] and y1[n] related?

16. Let 𝑥𝑝[𝑛] = {1↑, 2, −1,0,2}andℎ𝑝[𝑛] = {2

↑, 1,0,−1,−2,−3}. Find their regular convolution

using zero padding and periodic convolution.

17. Autocorrelation and cross-correlation: Consider the sequences x[n] = n, 0≤n≤8 and h[n] =

n, 0≤n≤3.

(a) Evaluate and plot rxx[n] and rhh[n] and find where they attain their maximum.

(b) Evaluate and plot rxh[n] and rhx[n].

}3,1,2{][

nx

}3,2,2,1{][

nh

}8,7,6,5,4,3,2,1{][

nh

}2,6,13,19,21,17,9,3{][

ny

Page 57: B. Tech. Electrical Engineering

57

(c) Evaluate and plot the correlation of h[n] and h[n-4] and find where it attains a

maximum.

18. Signals buried in noise: Generate two noisy signals by adding noise to a 20Hz sinusoid

sampled at ts=0.01s for 2s.

(a) Verify the presence of the signal by correlating the two noisy signals.

(b) Estimate the frequency of the signal from the FFT spectrum of the correlation.

19. Convolution by FFT: Use FFT to find

(a) The periodic convolution of 𝑥𝑝[𝑛] = {1↑, 2, −1,0,2,3}andℎ𝑝[𝑛] = {2

↑, 1,0,−1,−2,−3}.

(b) The regular convolution of 𝑥𝑝[𝑛] = {1↑, 2, −1,0,2}andℎ𝑝[𝑛] = {2

↑, 1,0,−1,−2,−3}.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 58: B. Tech. Electrical Engineering

58

EECI-300 Minor Project [0 0 2 2]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Identify projects relevant to Instrumentation and Control systems.

2. Design, model, simulate and fabricate a prototype.

3. Prepare the project report

It is the continuation of Minor Project started in the previous semester. During this period,

every student has to present the progress of their works before the duly constituted

committee of internal teachers of the department. The assessment by the committee

members are a part of Mid Term Evaluation. The students are advised to extend it as their

major project in Seventh and Eighth Semester. A report of the project in the form of hard

copy must be submitted in the office before the final evaluation by the External Examiners.

Page 59: B. Tech. Electrical Engineering

59

7TH SEMESTER

EEPC-401 Switchgear and Protection [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Understand the working of circuit breakers 2. Understand the mechanism of working of relays 3. Understand different protection schemes

Relays: Principle and operation of Electromagnetic and Induction type Relays, Relay

settings, Directional, Distance, Differential, Overcurrent and Earth-fault Relays, Static

Relays, Numerical Relays/IEDs, Device Numbers.

Generator Protection: Protection of generators against stator faults, Rotor faults,

Overvoltage and Over-speed protection, Protection against Motoring and vibration,

Generator Management Relays.

Transformer Protection: Differential Protection, Protection CTs and Accuracy class,

Buchholtz relay, Transformer Management Relays.

Neutral Grounding: Grounded and Ungrounded Neutral Systems, Effects of Ungrounded

Neutral on system Performance, Methods of Neutral Grounding and Grounding Practices.

Over-voltage Protection: Causes of overvoltage, Lightning phenomena, Klydonograph and

magnetic Link, Protection of Transmission lines against Direct Lightning Strokes, Protection

of station and substation from Direct Strokes, Protection against Travelling Waves, Peterson

Coil, Insulation Coordination, Basic Impulse Insulation Level (BIIL).

Circuit Breakers: Fault Clearing time of a circuit breaker, Arc Voltage, Arc Interruption,

Restriking Phenomenon, Restriking Voltage and Recovery voltages, Current Chopping and

Resistance Switching, Interruption of capacitive current, Circuit breaker rating Fuse, H.R.C.

fuse, Isolators, Description and Operation of following types of circuit breakers: Oil Circuit

breakers, Air Blast Circuit Breakers, Vacuum and SF6 circuit breaker, Comparative merits

and demerits.

Textbooks:

1. Badari Ram, D.N Viswakarma “Power System Protection and Switchgear”, TMH

Publications

2. C.L.Wadhwa “Electrical Power Systems”, New Age international (P) Limited,

3. Horowitz, Stanley H., and Arun G. Phadke. “Power system relaying” Vol. 22. John

Wiley & Sons.

4. Sunil S Rao “Switchgear and Protection”, Khanna Publlishers

5. Paithankar and S.R. Bhide “Fundamentals of Power System Protection”,PHI.

6. C R Mason “Art & Science of Protective Relaying”, Wiley Eastern Ltd.

7. B.L.Soni, Gupta, Bhatnagar, Chakrabarthy “A Text book on Power System

Engineering”, Dhanpat Rai & Co.

Page 60: B. Tech. Electrical Engineering

60

EEPC-403 Power System Operation and Control [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: On successful completion of this course the student will be able to:

1. Learn about Hydro-Thermal scheduling

2. Modelling of Turbines, Generators in steady state and transient state

3. Learn about, how to control the load frequency

Introduction: General characteristics of modern power systems, evolution, structure, power

system control, operating states of a power system and control strategies, economic load

dispatch, function and applications, price based unit commitment problem.

Hydro-thermal Scheduling: Optimal scheduling of Hydro-thermal System, Hydroelectric

power plant models, scheduling problems, Short-term hydro-thermal scheduling problem.

Modelling of Turbine, Generator and Automatic Controllers: Modelling of Turbines: First

order Turbine model, Block Diagram representation of Steam Turbines and Approximate

Linear Models. Modelling of Generator (Steady State and Transient Models), Simplified

Network Model of a Synchronous Machine (Classical Model).

Modelling of Governor: Mathematical Modelling of Speed Governing System, Derivation of

small signal transfer function. Modelling of Excitation System, Fundamental Characteristics

of an Excitation system, Transfer function, Block Diagram Representation of IEEE Type-1

Model, Power system stabilizer.

Load Frequency Control: Single area control – Block diagram representation of an isolated

power system – Steady state analysis – Dynamic response – Uncontrolled case, Load

frequency control of 2-area system – uncontrolled case and controlled case, tie-line bias

control, Proportional plus Integral control of single area and its block diagram representation,

steady state response – Load Frequency Control and Economic dispatch control.

Reactive Power Control: Overview of Reactive Power control – Reactive Power

compensation in transmission systems – advantages and disadvantages of different types of

compensating equipment for transmission systems; load compensation – Specifications of

load compensator, Uncompensated and compensated transmission lines: shunt and Series

Compensation.

Textbooks:

1. Wood, Allen J., Bruce F. Wollenberg, and Gerald B. Sheblé “Power generation,

operation, and control” John Wiley & Sons.

2. C.L.Wadhwa “Electrical Power Systems” , Newage International

3. I.J.Nagrath & D.P.Kothari “Modern Power System Analysis” Tata M Graw

4. J.Duncan Glover and M.S.Sarma “Power System Analysis and Design”., Thompson,

5. O.I.Elgerd “Electric Energy systems Theory”, Tata Mc Graw-hill Pub. Company Ltd.,

6. Grainger and Stevenson “Power System Analysis”, Tata McGraw Hill.

7. Hadi Saadat “Power System Analysis” TMH

Page 61: B. Tech. Electrical Engineering

61

EEPE-4XX Program Elective-IV [3 0 0 3]

Refer Page No. 91 to Page No. 96

EEPE-4XX Program Elective-V [3 0 0 3]

Refer Page No. 91 to Page No. 96

IDOE-4XX Open Elective –II [3 0 0 3]

Page 62: B. Tech. Electrical Engineering

62

EEPC-421 Power System Operation and Control Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: At the end of the laboratory course the student would be able to:

1. Solve hydrothermal scheduling problem in the power system.

2. Develop small scale model of alternator, excitation and governing systems

3. Design frequency and voltage controller for multi area power system

4. Understand reactive power compensation in power systems.

At least 8 experiments are to be performed out of the following list:

1. To develop a computer program to solve Price Based Unit Commitment problem for

three and ten generator systems.

2. To develop a software program to solve hydro-thermal scheduling problem in a single

area power system.

3. To develop a software program to solve dynamic hydro-thermal scheduling problem

in the multi area power system.

4. To develop a Simulink model for Turbine, Generator and Automatic Controllers.

5. To develop a Simulink model for Speed Governing System.

6. To develop a software program for stability analysis of single area frequency control.

7. To develop a Simulink model for load frequency control of a single area power

system.

8. To develop a Simulink model for load frequency control of two area power systems

using tie-line bias control mechanism.

9. To develop a computer program to model series and shunt compensation in the

power system.

10. To analyse the power flow results of the power system with uncompensated and

compensated transmission lines.

11. To develop a computer program for optimal placement of shunts capacitors in the

power system.

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 63: B. Tech. Electrical Engineering

63

EECI-400 Major Project [0 0 4 0]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Identify projects related to broad area of Electrical Engineering.

2. Design, model, simulate and fabricate a prototype.

3. Prepare the project report.

The Project is aimed at training the students to analyse any problem in the field of Electrical

Engineering independently. The project may be analytical, computational and experimental

or combination of them based on the latest developments in the relevant areas. It should

consist of objectives of study, scope of work, critical literature review and preliminary work

done pertaining to the seminar undertaken in 7th & 8th Semesters. All the students are

required to implement a research paper already published. During the project period, every

student has to present the progress of their works before the duly constituted committee of

internal teachers of the department. The assessment by the committee members are a part

of Mid Term Evaluation. A report of the project in the form of hard copy must be submitted in

the office before the final evaluation by the External Examiners.

Page 64: B. Tech. Electrical Engineering

64

EECI-350 Summer Training [0 0 0 2]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Gain exposure to industrial environment and latest technology trends.

2. Understand organizational hierarchy.

3. Enhance technical and managerial skills

The main objective of the Industrial/Vocational Training is to experience and understand real

life situations in industrial organizations and their related environments and accelerating the

learning process of how student’s knowledge could be used in a realistic way. In addition to

that, industrial training also makes one understand the formal and informal relationships in

an industrial organization so as to promote favourable human relations and teamwork.

Besides, it provides the exposure to practice and apply the acquired knowledge “hands – on”

in the working environment. Industrial training also provides a systematic introduction to the

ways of industry and developing talent and attitudes, so that one can understand how

Human Resource Development works. Moreover, students can gain hands-on experience

that is related to the students majoring so that the student can relate to and widen the skills

that have been learnt while being in university. Industrial training also exposes the students

to the real career world and accustoms them to an organizational structure, business

operation and administrative functions. Furthermore, students implement what they have

learned and learn more throughout this training. Besides, students can also gain experience

to select the optimal solution in handling a situation. During industrial training students can

learn the accepted safety practices in the industry. Students can also develop a sense of

responsibility towards society.

Page 65: B. Tech. Electrical Engineering

65

8TH SEMESTER

EEPC-402 Electric Drive & Control [3 1 0 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: After completion of this course, the students would be able to:

1. Develop basic understanding of requirement and working of drives.

2. Learn different aspects of control of electric drives.

3. Understand operational aspects of DC drives.

4. Understand operational aspects of AC drives.

Introduction: Electric drives, Requirement of electric drives, fundamental torque equation,

speed torque converter and multi quadrant operation, equivalent values of drive parameters,

concept of load torque, calculation of time and energy loss in transient operation, steady

state stability and load equalization

Control of Electric Drive: Closed loop control of drives, current limit control, closed loop

torque control, closed loop speed control, closed loop speed control of multi motor drives,

phase locked loop controller (PLL), closed loop position control.

DC Drives: Single-phase half controlled and fully controlled converter fed dc motor drives,

operation of dc drives with continuous armature current, voltage and current waveforms;

Concept of energy utilization and effect of free-wheeling diode; Operation of drive under

discontinuous current, expression for speed-torque characteristic, Chopper controlled dc

drives, motoring operation of chopper fed separately excited dc motor, Chopper controlled of

Series motor, steady state analysis of drive with time-ratio control.

AC Drives: Variable voltage, rotor resistance and slip power recovery control of induction

motors, torque-speed characteristic sunder different control schemes; Variable frequency

control of induction motor, analysis of induction machine under constant V/f operation,

Inverter fed AC Drives, Voltage source inverter fed induction motor drive in open loop,

frequency and voltage control in PWMVSI; Current source inverter Control, advantage of

CSI fed drives, scalar control, vector control, sensor-less control.

Brushless DC Drive: Self- control, CSI with load commutation, low speed commutation,

inverter control strategies and performance.

Switched Reluctance Motor Drive System: Construction, principle of operation,

advantages, disadvantages, characteristics, closed loop control, applications.

Textbooks:

1. Dubey G. K., “Fundamentals of Electric Drives”, 2nd Ed., Narosa Publishing House 2. Bose B. K., “Power Electronics and Variable Frequency Drives”, IEEE Press,

Standard Publisher Distributors. 3. Pillai S. K., “A First Course in Electric Drives”, 2nd Ed., New Age International Private

Limited.

Page 66: B. Tech. Electrical Engineering

66

4. Sen P. C., “Thyristor DC Drives”, John Wiley and Sons. 5. Dubey G. K., “Power Semiconductor Controlled Drives”, Prentice Hall International

Edition. 6. Murphy J. M. D. and Turnbull F. G., “Power Electronics Control of AC Motors”,

Peragmon Press.

Page 67: B. Tech. Electrical Engineering

67

EEPC-404 Flexible AC Transmission System [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: After completion of this course, the students would be able to:

1. Develop an understanding about FACT devices.

2. Understand principle of compensation.

3. Understand stability issues.

Fundamentals of ac power transmission: Transmission problems and needs - emergence

of FACTS-FACTS control considerations - FACTS controllers

Principles of shunt compensation: Variable Impedance type & switching converter type -

Static Synchronous Compensator (STATCOM) configuration - characteristics and control

Static Series Compensators: Principles of static series compensation using GCSC, TCSC

and TSSC: applications -Static Synchronous Series Compensator (SSSC)

Static Voltage and Phase Angle Regulators: Principles of operation-Steady state model

and characteristics of a static voltage regulators and phase shifters - power circuit

configurations

UPFC: Principles of operation and characteristics - independent active and reactive power

flow control - comparison of UPFC with the controlled series compensators and phase

shifters

Stability Analysis: Modeling of FACTS devices, optimization of FACTS, transient and

dynamic stability enhancement

Textbooks:

1. Hingorani, L.Gyugyi, ‘Concepts and Technology of Flexible AC Transmission

System’, IEEE Press, New York, 2000 ISBN –078033 4588.

2. Mohan Mathur R. and Rajiv K.Varma, ‘Thyristor - based FACTS controllers for

Electrical transmission systems’, IEEE press, Wiley Inter science

3. Padiyar K.R., ‘FACTS controllers for Transmission and Distribution systems’ New

Age International Publishers.

4. Song, Y.H. and Allan T. Johns, ‘Flexible AC Transmission Systems (FACTS)’,

Institution of Electrical Engineers Press, London

5. Enrique Acha, Claudio R.Fuerte-Esqivel, Hugo Ambriz-Perez, Cesar Angeles-

Camacho ‘FACTS –Modeling and simulation in Power Networks’ John Wiley & Sons

Page 68: B. Tech. Electrical Engineering

68

EEPC-406 Utilization of Electrical Energy and Electric Traction [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: After completion of this course, the students would be able to:

1. Learn different aspects of illumination

2. Learn electric heating and welding

3. Learn different aspects of traction and refrigeration.

Illumination Engineering: Nature of light, definitions, units, basics laws of illumination,

determination of luminous flux, Light sources and their characteristics, Photometry-

Photovoltaic & photo emissive cell, incandescence and fluorescence, sources of light-

filament lam, halogen lamp, discharge lamp, fluorescent lamp, incandescent lamp, arc lamp

and their applications, Direct lighting and mixed reflection, reflection factor, transmission

factor, refractors, Flood lighting and calculations, street lighting, exterior and interior lighting,

Design of choke and capacitor.

Electric Heating & Welding: Advantages of electric heating, resistance heating, types of

furnaces, types of heating materials, temperature control of furnaces, variable voltage

supply, design of heating element, arc furnace, induction heating, dielectric heating,

microwave oven, Electric Welding, Resistance Welding, Electric arc welding

Electric Traction: Introduction, general features, track specification, arrangement of

locomotive drives, transmission of power from motor to driving wheel. Mechanics of train

movement, speed-time curves, tractive effort for acceleration and propulsion, power and

energy output from driving axis.

Traction motors – DC shunt motors, DC series motor, AC series motor, three phase

induction motor, series and parallel operation with unequal and equal wheel diameters,

effect of sudden change in supply voltage, temporary interruption of supply, tractive effort

and horse power, DC series motor control, AC series motor control, three phase induction

motor control, Multiple unit control, Braking of electric motors, recent trends in solid state

speed control methods.

Refrigeration and Air-Conditioning: Control of temperature - basic wiring diagram - simple

heat load and motor calculations. Air-conditioning - function of complete air conditioning

system - type of compressor motor and fan motor-wiring diagram for a typical air

conditioning unit.

Textbooks:

1. H. Partab, “Art And Science Of Utilisation Of Electrical Energy”, Danpath rai and co.

2. S. C. Tripathy, “Electric Energy Utilisation and Conservation”, Tata McGraw Hill,

3. W. F. Stocker and J. W. Jones, “Refrigeration & Air Conditioning”, McGraw Hill,

Page 69: B. Tech. Electrical Engineering

69

4. C. L. Wadhwa, “Generation, Distribution and Utilization of Electrical Energy”, New

Age

5. N. V. Suryanarayana, “Utilisation of Electric Power”, Wiley Eastern Ltd.,

6. M. Prasad, “Refrigeration and Air Conditioning”, Wiley Eastern Ltd

EEPE-4XX Program Elective –VI [3 0 0 3]

Refer Page No. 98 to Page No. 102

IDOE-4XX Open Elective –III [3 0 0 3]

Page 70: B. Tech. Electrical Engineering

70

EEPC-426 Electric Drives & Control Laboratory [0 0 2 1]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcomes: After completion of this lab, the students would be able to:

1. Understand operational aspects of power electronic devices

2. Understand different aspects of controlling AC machines

3. Understand different aspects of controlling DC machines

At least 8 experiments are to be performed out of the following list:

1) To study characteristics of different types of power semiconductor devices like SCR, TRIAC, DIAC, MOSFET, IGBT.

2) To study different firing schemes for SCRs.

3) To study the base drive circuit for MOSFET.

4) To study different configurations of a single-phase controlled rectifier for a resistive, inductive, and capacitive load.

5) To study different configurations of three-phase controlled rectifiers for a resistive, inductive, and capacitive load.

6) To study different types (Type A, B, C, D, E) of chopper circuits.

7) To study DC-DC Step-Down (Buck), Step-Up (Boost) Converter.

8) To study DC-DC converter using PWM (Pulse Width Modulation) and PFM (Pulse Frequency Modulation) methods.

9) To study three-phase inverter with R and RL load and FFT analysis.

10) To study the principle of Variable Frequency Drive (VFD) for asynchronous motor.

11) To study Sinusoidal Pulse Width Modulated (SPWM) inverter with the asynchronous motor as load.

12) To study relationship between Control Voltage, Modulation Index, frequency and Inverter Output Voltage in SVM Inverter and V/f control of Induction Motor with SVM Inverter.

13) To study closed loop speed control (PI control) of BLDC motor with Hall sensor feedback.

14) To Understanding effect of Gain factor and Integral Factor in closed loop control of BLDC motor.

15) To study the four-quadrant operation of separately excited DC machine.

16) To study scalar (v/f) control of PMSM motor.

17) To study vector control of PMSM motor using rotor position sensor feedbacks (sensored).

The list of experiments given above is only suggestive. The Instructor may add new

experiments as per the requirement of the course.

Page 71: B. Tech. Electrical Engineering

71

EECI-400 Major Project [0 0 4 4]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Identify projects related to broad area of Electrical Engineering.

2. Design, model, simulate and fabricate a prototype.

3. Prepare the project report.

The Project is aimed at training the students to analyze any problem in the field of Electrical

Engineering independently. The project may be analytical, computational and experimental

or combination of them based on the latest developments in the relevant areas. It should

consist of objectives of study, scope of work, critical literature review and preliminary work

done pertaining to the seminar undertaken in 7th & 8th Semesters. All the students are

required to implement a research paper already published. During the project period, every

student has to present the progress of their works before the duly constituted committee of

internal teachers of the department. The assessment by the committee members are a part

of Mid Term Evaluation. A report of the project in the form of hard copy must be submitted in

the office before the final evaluation by the External Examiners.

EECI-420 Industrial Lectures [0 0 0 1]

A minimum of 2-5 lectures of two hours duration by Industry/Academic/R&D experts will be

arranged by the Department. The evaluation methodology will be based on objective type

questioning at the end of each lecture.

Page 72: B. Tech. Electrical Engineering

72

LIST OF DEPARTMENTAL ELECTIVES (FOR BATCH 2012 ONWARDS)

5th Semester

EEPE-351 Operations Research [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Understand linear optimization and transportation models

2. Understand and apply dynamic programming technique to the optimization

3. Write the model and Perform simulation

Section Nature and development of Operations Research: some mathematical

preliminaries, OR and managerial decision making, OR applications in industrial and non-

industrial fields.

Linear Optimization Models: formulation of linear programming problem, graphical

solution, sensitivity analysis in graphical solution, comparison of graphical and simplex

algorithm, simplex algorithm, computational procedure in simplex, penalty method, two

phase method, degeneracy, duality and its concept, application of LP model to product mix

and production scheduling problems.

The transportation model: solution methods, balanced and unbalanced problems, Vogel’s

approximation method, degeneracy in transportation problems. Assignment problem,

methods for solving assignment problems. The traveling sales man problem. Numerical on

transportation, assignment and traveling salesman method. Computer algorithms for solution

to LP problems.

Dynamic programming problems: model formulation, computational procedures, solution

in different stages. Decision making under conditions of risk, assumed certainty.

Waiting line models: queuing systems and concepts, various types of queuing situations,

single server queues with poison arrivals and exponential service times, finite queue length

model, industrial applications of queuing theory.

Simulation: advantages and limitations of the simulation technique: generation of random

numbers, Monte Carlo simulation, computer-aided simulation, applications in maintenance

and inventory management.

Textbooks:

1. Taha HA, “Operations Research - An Introduction”, Prentice Hall

2. Hillier, FS, “Operations Research”, CBS Publishers & Distributors

3. Wagner HM, “Principles of Operations Research”, Prentice Hall

4. Mustafi CK, “Operations Research”, New Age International

Page 73: B. Tech. Electrical Engineering

73

EEPE-353 Renewable Energy Resources [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Understand the need for harvesting renewable sources of energy.

2. Operational aspects of solar, wind and hydro power plant.

3. Learn about other sources of energy like biomass, geothermal and Ocean.

Introduction: Energy Sources and their availability, renewable energy sources, Prospects of

renewable energy sources, application of non-conventional and renewal energy sources.

Environmental Aspects of Electric Energy Generation: Introduction Thermal pollution,

Atmospheric pollution, Effects of Hydroelectric projects, Nuclear power generation and

environment, Green House Gas Effects, Global Environmental awareness, Energy options

for Indian Economy.

Solar Energy: Solar radiation estimation, Basic Principle of Solar Energy physical Principal

of the conversion of solar radiation into heat, Collectors, Solar Energy storage system, solar

thermal electric conversion, solar electric Power Plant & applications.

Wind Energy: Basic Principle of wind energy conversion, nature & Power of wind, site

selection, wind energy conversion SYSTEM. Scheme for Electric Generation, Generator

Control load control, Inter connected SYSTEM & applications.

Small Hydro Power: General description, classification of schemes, siting and economic

considerations, system components: weir/intake channel, desilting tank, forbay, spillway,

penstock, turbine, generator, governor, control.

Biomass Energy: Biomass conversion technologies bio mass generation, classification of

Bio Gas Plants material used in Bio Gas Plants., Selection of site & applications.

Geothermal Energy: Sources of Geothermal energy Estimation of Geothermal Power,

Geothermal Power Plants, Geothermal energy in India and Prospects.

Ocean Energy: Ocean thermal electric conversion, site selection, Power Plant, Prospects of

ocean energy in India, tidal Power tidal Power Plant, Prospects in India.

MHD & Hydrogen Energy: Basic Principle MHD SYSTEM, advantages, Power OUTPUT of

MHD Generation, future Prospects. Principle and classification of fuel cell energy, hydrogen

as alternative fuel for Generation of Electrical Energy & applications.

Fuel Cell: Fuel Cell, Management of Fuel, Thermonic power generation, water Resource

Electricity deviend scenario storage and handling,

Textbooks:

1. D.P Kothari, K.C. Singla, Rakesh Ranjan “Renewable Energy Sources and Emerging

Technologies” PHI Publications.

2. G.D. Rai “NON-Conventional energy Sources” Khanna Publications.

Page 74: B. Tech. Electrical Engineering

74

3. Abbari, “Renewal energy sources and their environmental aspects”: PHI 4. Dr. S.L. Uppal “Electric Power” Khanna Publications 5. Jain &Bala Subramanyam “Power Plant Engineering”

Page 75: B. Tech. Electrical Engineering

75

EEPE-355 Computer Networks [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Understand the TCP/IP protocols.

2. Learn about Ethernet technology.

3. Learn about wireless technology and the protocol for data transmission.

Introduction: Uses of Computer Networks, Network Hardware and Software, OSI, TCP/IP

Reference Models, Networking Terminology, Internet Evolution.

Ethernet Technology: IEEE Standard, Switched Ethernet, fast Ethernet, Gigabit Ethernet,

Logical link control Retrospectives on Ethernet.

ATM Networks: Introduction, Reference Model, Routing and Addressing, ATM Signalling,

ATM Switching Overview,ATM Traffic Management& Congestion, SS7.

Wireless Networks: Introduction, Wireless LANs, IEEE 802.11 Standard, Physical Layer,

MAC sub Layer, 802.11 Frame Structure and Services, ad-hoc networks: Introduction,

Proactive and Reactive protocols-AODV, DSR and TORA, performance issues- Quality of

Service (QoS)

Bluetooth Technology, Bluetooth Architecture and Applications, Protocol Stack, Radio

layer, Baseband Layer, L2CAP Layer, Frame Structure.

Broad Band Wireless Networks: IEEE 802.16 Standard, Comparison of 802.11 with

802.16, 802.16 Protocol Stack, 802.16 Physical Layer, 802.16 MAC sub Layer Protocol,

802.16 Frame Structure and Services.

Sensor Networks: Introduction, topology and Applications

Textbooks:

1. Tananbum AS, “Computer Networks, ”Pearson Education 2. Forouzan BA, “Data Communication and Networking,” Tata McGraw Hill 3. Peterson LN and Davie BS, “Computer Networks: A system approach,” Elsevier 4. Walrand J and Varaiya P, “High Performance Communication Networks,” Morgan

Kauffman 5. Vasseure JP, Picavet M and Demeester P, “Network Recovery Protection and

Restoration of Optical, SONET-SDH, IP and MPLS,” Elsevier 6. Stalling William, “Wireless communication and networks,” Pearson Education

Page 76: B. Tech. Electrical Engineering

76

EEPE-357 System Modeling and Reliability [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: After completion of this course, the students would be able to:

1. Understand the methods used for the modelling of a system.

2. Learn about the probability theory and its application in system identification

3. Perform simulation studies and understand system reliability

System Models and Studies: Concept of a system, system Environment, stochastic

Activities, continuous and discrete systems, systems modelling, types of models, Principles

used in Modelling, system Analysis & design.

System Representation: Introduction, Block diagram presentation, Standard Block –

Diagram, Signal flow graphs, Determination of overall system response using Block diagram

and Signal flow for the various inputs. System Equations: Introduction, Electric circuits and

components, Basic linear algebra, state concept, Mechanical Translation system, analogous

circuits, Mechanical rotational system.

Probability concepts in simulation: Stochastic variables, discrete probability functions,

continuous probability functions, Measures of probability. Functions, numerical evaluation of

continuous probability functions, Estimation of mean variances, and Correlation, Random

number generator and Properties of Random Numbers.

System Simulation: Step in simulation study, techniques of simulation, comparison of

simulation and analytical methods, Experimental Nature of simulation, types of system

simulation, Numerical computation Technique for continuous models, Numerical

computation technique for Discrete models, Distributed lag models, Real Time Simulation,

Selection of Simulation Software, Simulation Packages, Trends in simulation software.

Introduction to system Reliability: Reliability, MTTF, MTBF, failure data analysis, hazard

rate, System reliability using: - series configuration, parallel configuration, mixed

configuration, Markov model, fault tree analysis. Reliability improvement and maintainability.

Case studies using soft computing algorithm.

Textbooks:

1. Nagrath IJ and Gopal M, “System Modeling and Analysis,” Tata McGraw-Hill.

2. Srinath LS, “Reliability Engineering,” East West Press Reference Books.

3. Gorden G, “System Simulation,” Prentice Hall.

4. Law AM and Kelton WD, “Simulation Modeling and Analysis,” Tata McGraw-Hill.

5. Banks J, Carson JS, Nelson BL and Nicol DM, “Discrete Event System Simulation,”

Prentice Hall.

Page 77: B. Tech. Electrical Engineering

77

EEPE-359 Data Acquisition and Telemetry [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand the functionality of different components and configuration of data acquisition system

2. Understand the working and functionality of the Data Logger 3. Gain knowledge on different telemetry systems working principle, design

techniques, signal transmission method, media and salient features 4. Gain knowledge on digital communication techniques and applications of single and

multiple channel digital telemetry systems.

Data Acquisition System: Definition and generalized block diagram of data acquisition

system (DAQ), Classification of DAQ, working principle block diagram, construction and

salient features of the following data acquisition systems: Analog data acquisition system

using time division multiplexing, Analog data acquisition system using frequency division

multiplexing, Digital data acquisition system with different configurations and Data logger.

Analog Communication Techniques: Analog communication techniques: analog

modulation of AC carrier; amplitude modulation of AM wave and frequency spectrum,

frequency modulation and frequency spectrum of FM wave, Phase modulation and

frequency spectrum of PM wave. Analog modulation of pulse carrier; basis of PAM, PFM.

Digital Communication Techniques: Digital modulation of pulse carrier, basis of PCM,

DCPM; Digital modulation of AC carrier, ASK, FSK, PSK, error detection and correction

methods, error control techniques.

Telemetry: Introduction, signal formation, conversion and transmission, general block

diagram of telemetry system , classification of telemetry system, signal transmission media:

Wires and cables, Power line carrier communication, terrestrial and satellite radio links,

optical fiber communication, Multiplexing – TDM, FDM and WDM.

Telemetry Systems: Direct voltage and current telemetry system, AM and FM telemetry system, Multi-channel PAM and PWM telemetry system, single and multi-channel digital telemetry system, modem based telemetry system, short range radio telemetry and satellite telemetry system, fibre optics telemetry system. Text Books

1. Karp HR (Ed.), “Basics of Data Communication,” McGraw-Hill 2. Tomasi W, “Fundamentals of Electronic Communication Systems,” Prentice Hall 3. Gruenberg EL, “Handbook of Telemetry and Remote Control,” McGraw-Hill 4. Ginzberg, Lekhtman and Malov, “Fundamentals of Automation and Remote Control,”

Mir Publishers 5. Rangan CS, Sharma GR and Mani VSV, “Instrumentation Devices and Systems,”

Tata McGraw-Hill

Page 78: B. Tech. Electrical Engineering

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6th Semester

EEPE-352 High Voltage Engineering [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand the phenomenon of breakdown of gases under high voltage.

2. Learn about solid and liquid dielectrics and their properties.

3. Learn the methods to develop high voltage and its measurement.

Breakdown in Gases: insulating media, Ionization processes, Electron avalanche,

Townsend’s criterion for breakdown, streamer theory of breakdown, Gaseous discharge in

uniform field, Paschen’s law, Breakdown in non-uniform field, corona discharges, effect of

polarity on corona & breakdown voltage. Corona in transmission lines, Empirical formulae for

corona loss, Methods of reducing corona loss.

Dielectrics Liquid Dielectrics: conduction & breakdown in pure liquids and commercial

liquids, Methods for determination of breakdown strength. Factors affecting dielectric

strength of liquids

Solid Dielectrics: -Breakdown mechanism, Intrinsic breakdown, Electromechanical

breakdown, thermal breakdown, breakdown of solid dielectric in practice, Breakdown due to

treeing & tracking, breakdown due to the internal discharges.

Generation of high voltages: Generation of high D.C. voltages, half wave & full wave

rectifier circuits, Voltage doublers and multiplier circuits Van De Graff generators, Electro-

static Generators, Generation of high alternating voltages, cascade transformers, Resonant

transformer, Generation of impulse voltages, Standard impulse wave shapes, Analysis of

model, Multistage Impulse generator, Marx circuit, Tripping & control of Impulse generators.

Measurement of high Voltages: Measurement of high AC and DC voltages by micro

ammeter, Resistance and potential divider, series Impedance voltmeter, series

capacitance voltmeter capacitance potential dividers & capacitance voltage transformers,

Resistance potential dividers, Generating voltmeters, Electrostatic voltmeter, Spark gap for

measurement of high D.C., A.C. & impulse voltages, Potential divider for impulse voltage

measurements, CRO for impulse voltage measurements.

High Voltage Testing of Electrical Apparatus: Test on insulators, Dry & wet flash Over

tests & withstand tests, Impulse flash over & withstand voltage test, High voltage tests on

cables Impulse testing of transformers. Non-Destructive Testing: Measurement of dielectric

constant & loss factor, High voltage Schering Bridge, Partial Discharge Measurements.

Textbooks:

1. M.S. Naidu &V.Kamraju“High Voltage Engineering”, TMH Pbs.

2. KuffelE “High Voltage: Engineering fundamentals”; Butterworth-Heineman,

Page 79: B. Tech. Electrical Engineering

79

3. RavindraArora,“High voltage Insulation Engineering”, New Age International.

4. Dr.R.S.Jha“High Voltage Engineering” Dhanpat Rai & Sons.

5. Wadhawa, C.L. “High Voltage Engineering” Wiley Eastern Ltd, New Age Ltd,

6. R.D. Begamudre“Extra High Voltage A.C. Transmission Engineering” Wiley Eastern

Limited.

Page 80: B. Tech. Electrical Engineering

80

EEPE-354 Soft Computing [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand different topologies of Neural Networks.

2. Learn about fuzzy logic and support vector technique.

3. Learn the basics of genetic algorithm.

Introduction: History of development in neural networks, neural network characteristics,

Artificial neural network technology, Model of a neuron, topology, learning, types of learning,

supervised, unsupervised and reinforcement learning.

Supervised Learning: Basic hop field model, the perceptron, linear reparability, Basic

learning laws, Hebb’s rule, Delta rule, Widroff and Huff LMS learning rule, correlation

learning rule, In star and out star learning rules. Unsupervised learning, competitive learning,

K mean clustering algorithm, Kolwner’s feature maps.

Radial Basis Function: Basic learning laws in RBF network, recurrent networks, recurrent

back propagation, Real time recurrent learning algorithm.

Counter Propagation Networks: Introduction to counter propagation networks, CMAC

networks, ART networks, Application of neural networks, pattern recognition, optimization,

associative memories, vector quantization, control.

Fuzzy Logic: Basic concepts of fuzzy logic, Fuzzy logic crisp set, Linguistic variable,

Membership functions, Operation of fuzzy set, Fuzzy IF-THEN rules, Variable inference

techniques, Defuzzification techniques, Basic fuzzy inference algorithm, Application of fuzzy

logic, Fuzzy system design, Implementation of fuzzy system, Useful tools supporting design.

Support Vector Machines: Introduction, Support Vector classification, Support Vector

regression, applications.

Basics of Genetic Algorithms: Evolution of Genetic and Evolutionary Algorithms,

Applications.

Text Books

1. Berkin R and Trubatch, “Fuzzy System Design Principles, ”Prentice Hall. 2. Kosko B, “Nueral Networks and Fuzzy Logic,” Prentice Hall. 3. Haykin S, “Neural Networks,” Pearson Education. 4. Cristianini N and Taylor JS, “An Introduction to Support Vector Machines (and other

Kernel – based learning methods),” Cambridge University Press. 5. Anderson JA, “An Introduction to Neural Networks,” Prentice Hall. 6. Jang JRS, Sun CT and Mizutani E, “Neuro-Fuzzy and Soft Computing – A

Computational Approach to Learning and Machine Intelligence,” Pearson Education. 7. Sivanandam S and Deepa SN, “Principles of Soft Computing,” Wiley India.

Page 81: B. Tech. Electrical Engineering

81

EEPE-356 Power System Deregulation [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand deregulation of electricity supply industry.

2. Understand pricing issues in power sector.

3. Learn the relation between reliability and deregulation.

Deregulation of the Electricity Supply Industry: Background of deregulation and the

current situation, Benefits from a competitive Electricity Market, After effects of Deregulation.

Power System Operation in Competitive Environment: Role of Independent System

operator, Operational Planning activities of ISO, operational planning activities of Genco.

Transmission open Access and Pricing Issues: Power Wheeling, Transmission Open

Access, Cost component in Transmission, Pricing of Power Transmissions, Security

Management in Deregulated environment, Congestion management in Deregulation.

Reliability and Deregulation: Reliability Analysis, Optimal Power Flow as a Basic Tool, Unit

Commitment, Formation of Power Pools.

Textbooks:

1. Lei Lee Lal, “Power System Restructuring and Deregulation”. UK: John Wiley and Sons,

2. Kankar Bhattacharya, Math H.J.Bollen and Jaap E. Daalder, “Operation of Restructured Power Systems”. USA: Kluwer Academic Publishers, 2001.

3. Md Shahidehpour and Muwaffaq Alomoush,“Restructured Electrical Power Systems”. Marcel Dekker, Inc.

4. S.S. Rao, “Switch Gear Protection and Power System Analysis”. Khanna Publications

Page 82: B. Tech. Electrical Engineering

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EEPE-358 Smart Grid [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand the meaning and the architecture of smart grid.

2. Learn the techniques for the analysis of smart grid

3. Learn control and communication aspect of smart grid.

Introduction: Smart Grid, Working definitions of Smart Grid and Associated Concepts –

Smart Grid Functions-Traditional Power Grid and Smart Grid –New Technologies for Smart

Grid –Advantages –Indian Smart Grid –Key Challenges for Smart Grid.

Smart Grid Architecture: Components and Architecture of Smart Grid Design –Review of

the proposed architectures for Smart Grid. The fundamental components of Smart Grid

designs –Transmission Automation –Distribution Automation –Renewable Integration

Tools and Techniques for Smart Grid: Computational Techniques –Static and Dynamic

Optimization Techniques –Computational Intelligence Techniques –Evolutionary Algorithms

–Artificial Intelligence techniques.

Distribution Generation Technologies: Introduction to Renewable Energy Technologies –

Micro grids –Storage Technologies –Electric Vehicles and plug –in hybrids –Environmental

impact and Climate Change –Economic Issues.

Communication Technologies and Smart Grid: Introduction to Communication

Technology –Synchro Phasor Measurement Units (PMUs) –Wide Area Measurement

Systems (WAMS).

Control of Smart Power Grid System: Load Frequency Control (LFC) in Micro Grid

System –Voltage Control in Micro Grid System –Reactive Power Control in Smart Grid. Case

Studies and Test beds for the Smart Grids.

Textbooks:

1. James Momoh, “Smart Grid Fundamentals of Design and Analysis”, Wiley-IEEE

Press.

2. Stuart Borlase, “Smart Grids, Infrastructure, Technology and Solutions”, CRC Press.

3. Gil Masters, “Renewable and Efficient Electric Power System”, Wiley-IEEE Press.

4. A.G. Phadke and J.S. Thorp, “Synchronized Phasor Measurements and their

Application”, Springer Edition.

5. T. Ackermann, “Wind Power in Power Systems”, Hoboken, NJ, USA, John Wiley.

Page 83: B. Tech. Electrical Engineering

83

EEPE-360 Energy Audit and Management [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Understand prevailing energy scenario.

2. Learn about energy conversion process.

3. Learn energy and financial management and its audit.

Energy Scenario: Commercial and Non-commercial energy, primary energy resources,

commercial energy production, final energy consumption, Indian energy scenario, Sectorial

energy consumption (domestic, industrial and other sectors), energy needs of growing

economy, energy intensity, long term energy scenario, energy pricing, Energy security,

energy conservation and its importance, energy strategy for the future, Energy Conservation

Act 2001 and its features.

Basics of Energy its various forms and conservation: Electricity basics – Direct Current

and Alternative Currents, electricity tariff, Thermal Basics-fuels, thermal energy contents of

fuel, temperature and pressure, heat capacity, sensible and latent heat, evaporation,

condensation, steam, moist air and humidity and heat transfer.

Evaluation of thermal performance: calculation of heat loss – heat gain, estimation of

annual heating & cooling loads, factors that influence thermal performance, analysis of

existing buildings setting up an energy management programme and use management –

electricity saving techniques.

Energy Management & Audit: Definition, energy audit, need, types of energy audit. Energy

management (audit) approach-understanding energy costs, 3.1 Bench marking, energy

performance, matching energy use to requirement, maximizing system efficiencies,

optimizing the input energy requirements, fuel and energy substitution, energy audit

instruments and metering

Financial Management: Investment-need, appraisal and criteria, financial analysis

techniques simple payback period, return on investment, net present value, internal rate of

return, cash flows, risk and sensitivity analysis; financing options, energy performance

contracts and role of Energy Service Companies (ESCOs)

Energy Monitoring and Targeting: Defining monitoring & targeting, elements of monitoring

& targeting, data and information-analysis, techniques – energy consumption, production,

cumulative sum of differences (CUSUM). Energy Management Information Systems (EMIS)

Energy Efficiency.

Thermal Utilities and systems: Energy efficiency in thermal utilities like boilers, furnaces,

pumps and fans , compressors, cogeneration (steam and gas turbines), heat exchangers

,lighting system, Motors belts and drives, refrigeration system.

Heat Recovery and Co-generation: Heat recovery from ventilation, air co-generation of

heat and electricity, heat recovery and bottoming cycles.

Page 84: B. Tech. Electrical Engineering

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Textbooks:

1. W. F. Kenny, “Energy Conservation In Process Industry”. 2. AmlanChakrabarti, “Energy Engineering and Management”, Prentice hall 3. CB Smith, “Energy Management Principles” , Pergamon Press, New York 4. Hand outs New Delhi, Bureau of energy efficiency 5. W. C. Turner, “Energy Management Hand Book”.John Wiley and sons

Page 85: B. Tech. Electrical Engineering

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EEPE-362 Electrical Safety [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Understand the Indian electricity rules and their significance.

2. Understand the safety standard in residential, commercial, and agricultural area

3. Learn about electrical safety installation, testing and commission

4. Understand about electrical safety in distribution system

Indian Electricity Rules and Acts: ground clearances and section clearances – standards

on electrical safety - safe limits of current, voltage – earthling of system neutral – Rules

regarding first aid and firefighting facility.

Electrical safety standard in residential, commercial, and agricultural Installations:

Wiring and fitting, Domestic appliances, water tap giving shock, shock from wet wall, fan

firing shock, multi-storied building, Temporary installations, Agricultural pump Installation,

Do’s and Don’ts for safety in the use of domestic electrical appliances.

Safety during Installation, Testing and Commissioning: Preliminary preparations, safe

sequence, risk of plant and equipment, safety documentation, field quality and safety,

personal protective equipment, safety clearance notice, safety precautions, safeguards for

operators, safety.

Electrical Safety in Hazardous Areas: Hazardous zones, class 0,1 and 2, spark,

flashovers and corona discharge and functional requirements, Specifications of electrical

plants, equipments for hazardous locations, Classification of equipment enclosure for

various hazardous gases and vapours, classification of equipment/enclosure for hazardous

locations.

Electrical Safety in Distribution System: Total quality control and management,

Importance of high load factor, Disadvantages of low power factor, Causes of low P.F.,

power factor improvement, equipments, Importance of P.F. improvement.

Textbooks:

1. Rao, S. and Saluja, H.L., “Electrical Safety, Fire Safety Engineering and Safety

Management”, Khanna Publishers, 1988.

2. Pradeep Chaturvedi, “Energy Management Policy, Planning and Utilization”, Concept

Publishing Company, 1997.

3. Nagrath, I.J. and Kothari, D.P., “Power System Engineering”, Tata McGraw Hill,

1998.

4. Gupta, B.R., “Power System Analysis and Design”, S.Chand and Sons, 2003.

5. Wadhwa, C.L., “Electric Power Systems”, New Age International, 2004

Page 86: B. Tech. Electrical Engineering

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EEPE-364 Embedded Systems [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Learn the architecture of microcontroller 8051 and its programming in C.

2. Learn interfacing aspects of 8051.

3. Learn the architecture of processors like PIC and ARM

Introduction &Architecture of 8051 Microcontroller: Review of architecture and

instruction set of 8085 microprocessor. Overview of 8051 architecture. CISC & RISC

processors.

8051 Instructions: Addressing modes, data transfer arithmetic and logical instructions. Bit

instructions, jump, loop and call instructions. Time delay using instructions.

Programming of 8051 Microcontroller: Input/output port programming, Timer/counter

programming for different modes. Serial communication and programming for different

modes.

Programming of interrupts and priority of interrupts; power down mode programming;

programming in C language.

Interfacing to 8051 Microcontroller: Interfacing of 7 segment display, LCD and

keyboard.Interfacing of DC motor, stepper motor and relay. Interfacing of ADC, DAC and

sensors.

Advanced Topics: On board buses for embedded systems-I2C & SPI; real time tasks and

types, real time systems, real time operating systems. Hardware software co-design,

embedded product development lifecycle management. Introduction to PIC and ARM

microcontrollers.

Text Books

1. Mazidi MA, Mazidi JG and Mchinlay RD, “The 8051 Microcontroller and Embedded

Systems using assembly and C,” Pearson Education

2. Das LB, “Embedded Systems: An integrated approach,” Pearson Education

3. Morton TD, “Embedded Microcontrollers,” Pearson Education 4. Valvano JW, “Embedded Microcomputers Systems: Real Time Interfacing,” Cengage

Learning India 5. Ram B, “Advanced Microprocessors and Interfacing,” Tata McGraw-Hill 6. Rajkamal, “Microcontrollers: Architecture, Programming, Interfacing and System

Design,” Pearson Education 7. Ray AK and Bhurchavdi KM, “Advanced Microprocessors and Peripherals:

Architecture, Programming and Interfacing,” Tata McGraw-Hill

Page 87: B. Tech. Electrical Engineering

87

EEPE-366 Biomedical Instrumentation [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Know the human anatomy and physiological signal Measurements.

2. Learn about the techniques used for measurement of Blood flow, blood pressure,

respiration rate and body temperature.

3. Analyze the recording of ECG, EEG, EMG and ERG signals.

4. Understand the concept of assisting and therapeutic devices

Introduction: Cells and their structure, action events of nerve; the origin of bio-potentials,

Introduction to the physiology of cardiac, nervous and muscular and respiratory systems.

Different types of transducers and their selection for biomedical applications.

Biopotential Electrodes: Signal acquisition; electrode theory, electrodes for biophysical

sensing; electrode-electrolyte interface; electrode-skin interface and motion artifact; Different

types of electrodes Hydrogen Calomel, Ag-AgCl, pH, Disposable electrodes, selection

criteria of electrodes surface electrodes; electrical safety.

Measurement of Bioelectrical Activities: The electro-conduction system of the heart; the

ECG waveform; the standard lead system; Electrocardiography, Electromyography,

Electroencephalograph and their interpretation.

Non-electrical Measurements: Measurement of Blood Pressure, Blood flow, Cardiac

output and Cardiac rate, Heart Sounds, Respiratory System Measurements, Measurement

of pH value of blood, ESR measurements.

Therapeutic Aids: Stimulators, Defibrillators, Cardiac Pacemakers, Diathermy.

Advances in Radiological Imaging: Introduction to Computed Tomography, Magnetic

Resonance Imaging, Angiography, Nuclear Medicine, Ultrasound.

Textbooks:

1. Rao C R and Guha S K, “Principles of Medical Electronics and Biomedical

Instrumentation”, Universities Press (India) Limited (2001).

2. Cromwell L, Weibell F J and Pfeiffer E A, “Biomedical Instrumentation and

Measurements”, 2nd ed., New Delhi: Pearson Education India (2003).

3. Carr Joseph J. and Brown John M., “Introduction to Biomedical Equipment

Technology”, 4th Ed., New Delhi: Pearson Education India (2001).

4. Webster John G (Ed.), “Medical Instrumentation, Application and Design”, 3rd ed.,

Singapore: John Wiley & Sons (Asia) Pte. Ltd. (2003).

5. Khandpur R S, “Handbook on Biomedical Instrumentation”, TMH, 13th reprint, New

Delhi (2000).

Page 88: B. Tech. Electrical Engineering

88

EEPE-368 Power station automation [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: After completion of this course, the students would be able to:

1. Understand fundamentals of power station and substation automation

2. Program PLC for various applications for substation automation system

3. Identify and select appropriate PLC and SCADA system for substation automation

4. Understand communication system and standards used in substation automation

system

Introduction: Historical development of power system automation, Fundamentals of

electrical protection, development of protective relays, numeric (microprocessor-based

relays), Remote terminal unit, PLC, SCADA and other intelligent devices, Networking media

and Communication Standards.

Substation Automation: Types of power system automation architecture, Automation of HV

substations, automation of MV substations. Main functions of Substation Automation

Systems: Control Function, Monitoring Function, Alarming Function, Measurement Function,

Setting and Monitoring of Protective Relays, Control and Monitoring of the Auxiliary Power

System and Voltage Regulation.

Introduction to PLC Programming and SCADA Systems: PLC architecture, modular and

micro PLCs, PLC Hardware, Input-Output modules, CPU Module, PLC scan cycle,

Introduction to ladder diagrams, hard wired relay logic, ladder logic symbols Boolean logic

programming examples, timers, counters, Registers, Programming of arithmetic instructions,

programming of analog inputs and outputs, requirement and background, SCADA

programming, SCADA master station.

Communication in Power System Automation: Basics of data communication, The OSI

model, Media access control principles, CSMA/CD Ethernet MAC, Full duplex Ethernet,

Communication protocols, Mode bus and Mode bus TCP/IP, Profibus, TCP/IP, DNP3.

IEC 61850 Standard for Substation Automation: Logical Nodes (LN), Logical Device (LD),

Intelligent Electronic Devices (IEDs), Process level functions, Bay level functions, Station

Level Functions, Station Bus and Process Bus.

Textbooks:

1. Turan Gonen, Electric Power Distribution Engg., Mc-Graw Hill,1986.

2. James A Momoh, Electric Power Distribution, Automation, Protection and Control,

CRC press.

3. AS. PABLA, Electric Power Distribution, TMH, 2000.

4. Padilla, Evelio. Substation automation systems: design and implementation. John

Wiley & Sons, 2015.

Page 89: B. Tech. Electrical Engineering

89

5. John Webb, Ronald Reis - Programmable Logic Controllers, PHI, 2003.

6. Klaus-Peter and Others – Substation Automation Handbook, Utility Automation

Consulting Lohmann, ISBN 3-85758-951-5.

7. Hackworth JR and Hackworth FD, “ Programmable Logic Controllers,” Pearson

Edition

8. Boyer SA, “Supervisory Control and Data Acquisition (SCADA), International Society

of Automation

Page 90: B. Tech. Electrical Engineering

90

EEPE-370 Artificial Intelligence [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course, the student will be able to:

1. Learn the fundamentals of artificial intelligence followed by Fuzzy Rule Base

2. Learn fundamentals of neural networks and their applications

3. Learn about human language technologies

4. Understand Bayesian and Deep Learning for machine vision and signal processing;

explore pattern recognition applications

Artificial intelligence fundamentals: Advanced search, Constraint satisfaction problems,

Knowledge representation and reasoning, Non-standard logics, Uncertain and probabilistic

reasoning (Bayesian networks, fuzzy sets), Foundations of semantic web: semantic

networks and description logics., Rules systems: use and efficient implementation, Planning

systems.

Machine learning

Computational learning tasks for predictions, learning as function approximation,

generalization concept, Linear models and Nearest-Neighbors (learning algorithms and

properties, regularization), Neural Networks (MLP and deep models, SOM), Probabilistic

graphical models, Principles of learning processes: elements of statistical learning theory,

model validation, Support Vector Machines and kernel-based models, Introduction to

applications and advanced models.

Human language technologies: Formal and statistical approaches to NLP, Statistical

methods: Language Model, Hidden Markov Model, Viterbi Algorithm, Generative vs

Discriminative Models, Linguistic essentials (tokenization, morphology, PoS, collocations,

etc.), Parsing (constituency and dependency parsing), Processing Pipelines, Lexical

semantics: corpora, thesauri, gazetteers, Distributional Semantics: Word embeddings,

Character embeddings, Deep Learning for natural language, Applications: Entity recognition,

Entity linking, classification, summarization, Opinion mining, Sentiment Analysis, Question

answering, Language inference, Dialogic interfaces, Statistical Machine Translation, NLP

libraries: NLTK, Theano, Tensorflow.

Intelligent Systems for Pattern Recognition: Signal processing and time-series analysis,

Image processing, filters and visual feature detectors, Bayesian learning and deep learning

for machine vision and signal processing, Neural network models for pattern recognition on

non-vectorial data (physiological data, sensor streams, etc), Kernel and adaptive methods

for relational data, Pattern recognition applications: machine vision, bio-informatics, robotics,

medical imaging, etc., ML and deep learning libraries overview: e.g. scikit-learn, Keras,

Theano.

Text Books

1. Berkin R and Trubatch, “Fuzzy System Design Principles, ”Prentice Hall 2. Kosko B, “Nueral Networks and Fuzzy Logic,” Prentice Hall 3. Haykin S, “Neural Networks,” Pearson Education

Page 91: B. Tech. Electrical Engineering

91

7th Semester

EEPE-451 Control System Design [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

CO5

Course Outcome: After completion of this course, the students would be able to:

1. Analyze systems using transfer function and state space models

2. Design controllers and compensators using conventional techniques

3. Design using frequency response method

4. State space design

5. Perform process identification and PID tuning for the same

Introduction: The feedback concept and modelling, Transfer Function and stability, concept

of Block diagram representation and reduction, Signal Flow graph, Types of control system

design.

Root Locus Analysis and Design: Root locus for feedback control systems, root locus

construction, Design concepts, relation between root locus and time domain, compensation,

Pole placement, Frequency response and forced sinusoidal response, Bode plots, Nyquist

plot, gain margin and phase margin, Frequency response Design, PID – compensation.

State Space Modelling and Design: State feedback and pole placement, Limitations of

state feedback, tracking problems, Observer design, control law using observer, Observer

T.F., Reduced order observer design, Trade-offs in state feedback and observers.

Advanced State Space Methods: Design via optimal control techniques, the linear

quadratic regulator problem, properties of LQR design, optimal observer – Kalman Filter,

Robustness, robust stability, root T.F. recovery (LTR), uncertainty modelling.

Digital Control: Preview, computer processing, A/D and D/A conversion, Discrete time

signals, Sample and hold circuits, Z-transformation and properties, inverse Z-transform,

sampling, reconstruction of signals from samples, stability and Bilinear transformation, state

space description of discrete – time systems, response and stability, controllability and

observability, Direct digital design, some examples, Decoupling.

Textbooks:

1. Stefani RT, Savant CJ, Shahian Balram and Hostetter G H, “Design of feedback

controls systems,” Oxford University Press.

2. Goodwin CG, Graebe SF and Salgado M E, “Control System Design,” Pearson

Education

3. Gopal M, “Control Systems: Principles and Design,” Tata McGraw-Hill

4. Chen CT, “Linear System Theory and Design,” Rinehart and Winston Press

5. Ogata K, “Discrete Time Control Systems,” Prentice Hall

6. Kuo BC, “Digital Control Systems,” Oxford University Press

Page 92: B. Tech. Electrical Engineering

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EEPE-453 Power Plant Engineering [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Understand functions of the components of power plant.

2. Understand the working of nuclear, thermal and oil based power plants.

3. Evaluate the design layout and working of hydro electric power plants.

4. Evaluate economic feasibility and its implications on power generating units.

Introduction: Conventional & Non-Conventional Sources of Energy and their availability in

India. Different Types of Power Plants, Choice of Type of Power Generation, Power Plants in

India.

Thermal Power Generation: Operating Principle, Site selection, Coal to Electricity, General

Layout of Thermal Power Plant, Brief description of different parts/systems and their

functions, Advantages and Limitations.

Hydro Power Generation: Hydrology – Hydrographs, Flow Duration Curve, Mass Curve;

Principle of working, Classification, Site selection; Different components & their functions;

Types of Dams; Types, Characteristics & Selection of Hydro-Turbines; Specific Speed of

Hydro-Turbines; Power Output Equation; Turbine Governing; Draft Tube; Bearings; Water

Hammer & Surge Tank, Cavitation, General arrangement and Operation of Hydro-electric

Power Plant, Mini & Micro Hydro Power Plants, Pumped Storage Power Plants; Advantages

of Hydro-electric Power Plants; Hydro Power in India & future trends.

Diesel & Nuclear Power Generation: Applications of Diesel Engine, Advantages &

disadvantages, Types of Diesel Plants, General Layout, Combustion in CI Engines,

Performance Characteristics, Supercharging, Layout of a Diesel Engine Power plant,

Principle of Nuclear Energy, Nuclear Power Plant Components & their Functions; Nuclear

Fuels, Radioactivity, Nuclear Reaction & Classification.

Gas Power Generation: Operating Principle; Classification – Open Cycle, Closed Cycle,

Combined Cycle; Fuels for Gas Turbine Power Plants; Different Components and their

functions; Gas Turbine Characteristics, Cycle Efficiency, Operational Aspects, Advantages

and Limitations.

Power Plant Economics: Various Terms and definitions, load curves, cost of electricity

generation, performance and operating characteristics, combined operation of power plants,

load division.

Textbooks:

1. P. K. Nag, Power Plant Engineering, II Edition, TMH.

2. G. D. Rai, An Introduction to Power Plant Technology, Khanna Publishers

3. Rajput,A Text Book of Power Plant Engineering, Laxmi Publications

4. P. C. Sharma, Power Plant Engineering, Pub S. K. Kataria & Sons

Page 93: B. Tech. Electrical Engineering

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5. Arora and S. Domkundwar. A Course in Power Plant Engineering, Dhanpat Rai,

1988

6. Elanchezhian, Power plant Engg , I.K. International Pub

7. Ramalingam, Power plant Engineering, Scietech Publishers

Page 94: B. Tech. Electrical Engineering

94

EEPE-455 Modern Control System [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Design state variable systems and analyze non-linear systems

2. Analyze the stability of the non-linear systems

3. Understand the concepts on design of optimal controller

4. Analyze system by phase plane method

State Space Analysis of Continuous System: Review of state variable representation of

continuous system, conversion of state variable models to transfer function and vice-versa,

solution of state equations and state transition matrix, controllability and observability, design

of state observer and controller.

Analysis of Discrete System: Discrete system and discrete time signals, state variable

model and transfer function model of discrete system, conversion of state variable model to

transfer function model and vice-versa, modelling of sample-hold circuit, solution of state

difference equations, steady state accuracy, stability on the z-plane and Jury stability

criterion, bilinear transformation, Routh Hurwitz criterion on rth planes.

Stability: Lyapunov’s stability theorems for continuous and discrete systems, methods for

generating Lyapunov function for continuous and discrete system, Popov’s criterion.

Non-linear System: Types of non linearities, phenomena related to non - linear systems.

Analysis of non-linear systems-Linearization method, second order non-linear system on the

phase plane, types of phase portraits, singular points, system analysis by phase-plane

method, describing function and its application to system analysis.

Optimal Control: Introduction, formation of optimal control problem, calculus of variations

minimization of functions, constrained optimization. Pontryagin’s Minimum Maximum

Principle, Linear Quadratic Problem-Hamilton Jacobi equation, Riccati equation and its

solution.

Adaptive Control: Introduction, modal reference adaptive control systems, controller

structure, self-tuning regulators.

Textbooks:

1. Gopal M, “Digital Control and State Variable Methods,” Tata McGraw-Hill

2. Kirk DE, “Optimal Control Theory: An Introduction,” Prentice Hall

3. Khalil HK, “Non-linear Systems”, Prentice Hall

4. Astron KJ, “Adaptive Control”, Dover Publications

5. Kuo BC, “Digital Control Systems,” Oxford University Press

6. Ogata K, “Modern Control Engineering,” Prentice Hall

7. Houpis CH and Lamont GB, “Digital Control Systems: Theory, Hardware, Software,”

McGraw-Hill

Page 95: B. Tech. Electrical Engineering

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EEPE-457 Smart Sensors and Sensor Networking [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Learn the basics and the architecture of smart sensors.

2. Learn fabrication technique of smart sensor.

3. Interfacing of smart sensor over wired and wireless network.

Review of Basic Concepts: Measurement system, transducers, sensors and actuators;

signal conditioners; data communications and networking.

Basics of Smart Sensors: Definition and architecture of smart sensor; different levels of

integration in small sensors, differences between smart, intelligent and network sensors;

advantages of smart sensors ;smart actuators and transmitters.

Smart Sensor Technologies: IC Technologies: thick film, thin film and monolithic IC

technologies; Micro-machining processes: materials for micro-machining, wafer bonding,

bulk and surface micromachining, other micro-machining techniques.

Examples of Smart Sensors: Principles, characteristics and constructional details of typical

smart sensors for temperature, humidity, pressure and vibrations.

Basics of Sensor and Actuator Networking: Field-level, controller-level and enterprise-

level networks; Sensor and actuator network (SAN): Network topologies; seven-layer OSI

model of communication system.

Wired Network Protocols: RS-422, RS-485, HART and Foundation Fieldbus protocols,

comparison with Ethernet (IEEE – 802.3) protocol.

Wireless Network Protocols: Need and advantages of wireless sensor and actuator

network (WSAN); Zigbee (IEEE – 802.15.4) protocol, Merits of Zigbee over WiFi (IEEE –

802.11) and Bluetooth for sensor and actuator networking.

IEEE Standard 1451: Introduction to IEEE Standard 1451: “Smart Transducer Interface for

Sensors and Actuators”; highlights of parts 1451.1, 1451.2, 1451.3, 1451.4 and 1451.5 of

the Standard.

Textbooks:

1. Patranabis D, “Sensors and Transducers,” Prentice Hall

2. Frank Randy, “Understanding Smart Sensors,” Artech House

1. Callaway EH, “Wireless Sensor Networks : Architecture and Protocols,” CRC Press

2. Anand MMS, “Electronic Instruments and Instrumentation Techniques,” Prentice Hall

3. William S, “Data and Computer Communications,” Pearson Education

4. IEEE Standard 1451, “Smart Transducer Interface for Sensor and Actuators,” IEEE

Press

Page 96: B. Tech. Electrical Engineering

96

EEPE-459 High Voltage Transmission System [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcome: On successful completion of this course the student will be able to:

1. Learn the development of HVDC system.

2. Learn the working of converters used in HVDC system

3. Understand the operational expects of EHVAC system with its limitations.

4. Learn about harmonics and filters.

Basic Concepts: Historical development of HVDC, Limitations and advantages of EHVAC

and DC transmission, classification of DC links, Applications, Ground Return, Economic

factors, future of HVDC transmission.

Converter Operation (Normal and Abnormal): 6-pulse and 12- pulse rectifiers and

inverters; Equivalent circuits of rectifier and inverter, relations between ac and dc quantities.

EHVAC Transmission System: Sequence impedance calculation, calculation of

transmission line parameters and sequence impedances for lines with ground returns, lines

with bundle conductors and ground returns, sequence networks for various three phase

transformer connections.

Reactive Power Compensation: Basic concepts of reactive power compensation,

principles of series and shunt compensation; Improvement of system performance due to

reactive power compensation.

HVDC Transmission System: Brief history of HVDC transmission system, comparison with

EHVAC transmission, analysis of converter circuits for HVDC transmission, HVDC control

system: CIA, CC and CEA control, analysis of faults in HVDC converters, basic concepts of

multi-terminal HVDC system.

Selection of HVDC Converter, six pulse Converters, cascade converters, basic principle of

HVDC protection. Analysis of 3-phase.Bridge Converter, 3-phase.Bridge inverter, HVDC link

and Converter control, characteristics, Analysis of HVDC link performance.

Converter Fault & Protection: Converter faults – protection against over current and over

voltage in converter station – surge arresters – smoothing reactors – DC breakers –Audible

noise-space charge field-corona effects on DC lines-Radio interference.

Harmonics and Filters: Characteristic and non-characteristic harmonics, input harmonics,

output harmonics, problems due to harmonics, ac and dc filters.

Textbooks:

1. K.R.Padiyar “HVDC Power Transmission Systems: Technology and system

Interactions”, New Age International (P) Limited.

2. S.Rao “EHVAC and HVDC Transmission Engineering and Practice”

Page 97: B. Tech. Electrical Engineering

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3. Begamudre R. D., “Extra High Voltage AC Transmission Engineering”, 3rd Ed., New

Age International Private Limited

4. J.Arrillaga “HVDC Transmission” 5. E. W. Kimbark “Direct Current Transmission”, John Wiley & Sons. 6. E. Uhlmann “Power Transmission by Direct Current”, B.S. Publications 7. Ulmann E., “Power Transmission by Direct Current”, Springer- Verlag.

Page 98: B. Tech. Electrical Engineering

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8th Semester

EEPE-452 Discrete Control Systems [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

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CO3

Course Outcome: On successful completion of this course the student will be able to:

1. Learn the benefits of digital control and its implementation.

2. Learn the modelling of discrete time systems.

3. Learn the procedure of designing digital controllers and their implementation.

Computer Controlled System: Configuration of the basic digital control scheme, general

sampled data system variables, signal classifications, why use digital control system,

Advantages, disadvantages, examples of discrete data and digital control systems.

Signal Processing in Digital Control: Sampling process, Frequency domain analysis, ideal

samples, Shanon’s sampling theorem, generation and solution of process, linear difference

equations, data reconstruction process, frequency domain characteristics.

Discrete System Modelling: Determination of the transform, mapping between s and z

domains, transform of system equations, open loop Hybrid sampled Data Control Systems,

open loop discrete Input Data Control System, closed loop sampled data control system,

modified transform method, response between sampling instants, stability on the z-plane

and Jury’s stability test, steady state error analysis for stable systems.

State Variable Analysis of Digital Control Systems: State descriptions of digital

processors, conversion of state variable models to transfer functions, conversion of transfer

functions to canonical state variable models, first comparison form, second companion form,

Jordon Canonical form, state description of sampled continuous time plants, solution of state

difference equations, closed form solution, state transition matrix, Cayley Hamilton

Technique, concept of controllability and observability, loss of controllability and observability

due to sampling.

Design of Digital Control: Digital PI, PD and PID Controller, Position and velocity forms,

state regulator design, design of state observers, dead beat control by state feedback and

dead beat

Textbooks:

1. Kuo BC, “Digital Control Systems,” Oxford University Press

2. Ogata K, “Discrete Control Systems,” Prentice Hall

1. Houpis CM, Lamount GB, “Digital Control Systems-Theory, Hardware, Software,”

McGraw-Hill

2. Gopal M, “Digital Control and State Variables Methods,” Tata McGraw-Hill

3. Deshpande PB and Ash RH, “Computer Process Control,” ISA Publication

4. George VI and Kurian CP, “Digital Control Systems,” Cengage Learning India

Page 99: B. Tech. Electrical Engineering

99

EEPE-454 Distributed Generation [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: After the completion of the course student will be able to

1. Understand the fundamentals of distributed generation

2. Identify different storage mediums used for distributed generation

3. Categorize various types of distributed generation systems

4. Analyse the problems of grid integration of distributed generation systems

Introduction: Conventional power generation: advantages and disadvantages, Energy

crises, Nonconventional energy (NCE) resources: basics of Solar PV, Wind Energy systems,

Fuel Cells, micro turbines, biomass, and tidal sources.

Distributed Generations (DG): Concept of distributed generations, topologies, selection of

sources, regulatory standards/ framework, Standards for interconnecting Distributed

resources to electric power systems: IEEE 1547. Energy storage elements: Batteries, ultra-

capacitors, flywheels, Superconducting magnetic energy storage.

Microgrids: Concept and definition of microgrid, microgrid drivers and benefits, review of

sources of Microgrids, typical structure and configuration of a Microgrid, AC and DC

Microgrids, Power Electronic interfaces in DC and AC Microgrids.

Impact of Grid Integration: Requirements for grid interconnection, limits on operational

parameters: voltage, frequency, THD Impact of grid integration with NCE sources on existing

power system: reliability, stability and power quality issues.

Textbooks:

1 D. N. Gaonkar, Distributed Generation, In-Tech publications.

2 Magdi S. Mahmoud, Fouad M. AL-Sunni, Control and Optimization of Distributed

Generation Systems, Springer International Publishing

Page 100: B. Tech. Electrical Engineering

100

EEPE-456 Nonlinear Control System [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

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CO4

Course Outcomes: After the completion of the course student will be able to:

1. Understand the difference in the performance of linear and nonlinear system.

2. Learn the tools used for the analysis of nonlinear system.

3. Understand stability theory for nonlinear system.

4. Learn the control techniques used to design controllers for nonlinear system.

Introduction: Introduction to nonlinear Models and Nonlinear Phenomena – Pendulum

equation, Mass-spring system, Negative resistance oscillator, Artificial Neural Netwrok,

Adaptive control. Common nonlinearirties.

Nonlinear System Analysis: Construction of phase portrait, Phase plane analysis – Phase

Prtrait, Singular points, Symmetry in phase plane Prtrait. Phase plane analysis for linear and

nonlinear systems, Limit cycle. Describing function analysis.

Stability Theory: Nonliear systems and equilibrium points, Concept of stability, Linearizatin

and local stability, Lyaponov’s Direct method, System analysis based on Lyapunov’s direct

method, Control design based on Lyapunov’s Direct method. Stability for non-autonomous

systems. Barbalat’s Lemma.

Nonlinear Control System Design: Feedback linearization – Input sate linearization, input-

output linearization. Sliding Mode control – Design of sliding surface, Continuous

approximaition of switching control law. Adaptive control of linear and nonlinear systems,

Robustness of adaptive contorl system.

Textbooks:

1. Slotine, J. J. E., & Li, W. (1991). Applied nonlinear control, Englewood Cliffs, NJ:

Prentice hall.

2. Khalil, H. K. (2002). Nonlinear systems (Vol. 3). Upper Saddle River, NJ: Prentice

hall.

Page 101: B. Tech. Electrical Engineering

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EEPE-458 Brain Computer Interfacing [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

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Course Outcomes: On successful completion of this course, the student will be able to:

1. Review various physiological signals

2. Learn Interfacing of various physiological signals with external world

3. Familiarize with associated research directions

An Introduction to Human Computer Interfacing: Introduction to Human-computer

Interaction, The nature of human-computer interaction.

Methodology for Designing User-computer Interfaces:- conceptual, semantic, syntactic,

and lexical levels of the design of an interactive system. Interaction Tasks, Techniques, and

Devices: Design of novel interaction techniques, Modes of human-computer communication,

Voice, Gesture and Eye movement. P300 based communication, Thought Translation device

(TTD), Graz-HCI research, μ-rhythm synchronization and desynchronization.

BCI Techniques: General Signal processing and machine learning tool for HCI analysis,

Spectral filtering, spatial filtering, PCA, ICA, AR modeling, CWT, DWT Classification

Techniques: Bayesian Analysis, LDA (Linear Discriminant Analysis) SVM (Support Vector

Machine) ANN (Artificial Neural Network)

User Interface Software: Languages and tools for specifying and interfaces, Dialogue

independence, UIMS (user interface management system) approach .BCI2000: A general

purpose software platform for HCI research.

Applications of HCI: HCI for Communication and motor control, combining HCI and Virtual

reality: Scouting Virtual worlds.

Textbooks:

1. Dornhege G, Millan JDR, Hinterberger T, Mcfarland DJ and Muller KR, “Toward

Brain-Computer interfacing,” MIT Press

2. Rangayyan RM, “Biomedical Signal Analysis: a case study Approach,” Wiley India

3. Tompkins WJ (Ed.), “Biomedical signal Processing,” Prentice Hall

4. Berger TW, Chapin JK et.al., “Brain-Computer Interfaces-An International

Assessment of Research and Development trends,” Springer Science

5. Bronzino JD (Ed.), “The Biomedical Engineering Handbook,” CRC Press

Page 102: B. Tech. Electrical Engineering

102

EEPE-460 Electrical Machine Design [3 0 0 3]

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1

CO2

CO3

CO4

Course Outcomes: On successful completion of this course, the student will be able to:

1. Understand and learn the procedure to design the DC machine with specified rating.

2. Learn the procedure to design the transformer, induction machine.

3. Learn the procedure to design synchronous machine.

4. Learn different aspects of machine design using computers.

DC Machine design- Main dimensions, output equation, specific electrical loading, specific

magnetic loading, torque developed, choice of number of poles, Armature reaction-mmf

distribution, shape of mmf wave, saturation and brush shifting, methods to reduce armature

reaction. Commutation-commutator design. Magnetic circuit- mmf, reluctance, slot and

ventilating ducts, apparent and real flux, flux density in teeth, calculations Field coil Armature

winding- types, lap and wave, numbering, number of slots, equalizer connections, symmetry

of commutator winding, layout Starters.

Transformer Design: Output equation, design of core, yoke and windings, overall

dimensions, computation of no load current, voltage regulation and design of cooling

systems.

Induction Motor Design- Main dimensions, output equation, specific electrical loading,

specific magnetic loading, air gap, winding-layout, Calculation of magnetizing current, no

laod current. Leakage reactance calculations- specific slot permeance, significance, semi-

closed rectangular slot, inductance calculations, rotor bar current calculation, semi-closed

round slot, reactance/slot and slot reactance per phase. Eddy current loss ratio, Rotor bar

currents- slip ring induction motor, squirrel cage induction motor, current distribution, cage

rotor resistance, transformation ratio, rms value of rotor bar current, ring current, copper

losses, equivalent cage resistance.

Synchronous Motor Design- Main dimensions. Harmonic calculations- pitch factor,

distribution factor, winding factor, mmf wave, armature reaction, design considerations to

reduce harmonics, Cooling design- cooling system, cooling media, calculations, AC

Windings- three phase windings, single layer windings, doube layer windings, fractional slot

winding.

Computer aided design: Philosophy of computer aided design, advantages and limitations.

Computer aided design approaches analysis, synthesis and hybrid methods. Concept of

optimization and its general procedure. Flow charts for design of transformer, dc machines,

three phase induction and synchronous machines.

Textbooks:

1. Balbir Singh, Electrical Machine Design, Vikas Publishing House, New Delhi.

2. M.G. Say, “Performance and Design of A.C. Machines”, CBS Publishers.

Page 103: B. Tech. Electrical Engineering

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3. A.K. Sawhney, Electrical Machine Design”, Dhanpat Rai and sons

4. Murthy,Vishnu “Computer aided design for electric machines” BSP Hyderabad

5. S.K. Sen, “Principle of electrical machines design” Oxford and IBH.

6. Ghosh, Samarjeet. “Electrical Machines” Pearson Education