TE Electrical Engg Syllabus Rev 2019C1 1 Syllabus Mumbai University by munotes
Page 2
Copy to : -
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(AAMS),
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Department (CAD),
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(FAD) (VAD), Record Section,
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Vidyanagari,
They are requested to treat this as action taken report on the concerned
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Page 3
AC- 29/6/2021
Item No. - 6.4
UNIVERSITY OF MUMBAI
Bachelor of Engineering
in
Electrical Engineering
Third Year with Effect from AY 2021 -22
(REV- 2019 ‘C’ Scheme) from Academic Year 2019 – 20
Under
FACULTY OF SCIENCE & TECHNOLOGY
(As per AICTE guidelines with effect from the academic year
2019 –2020 )
Page 4
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Date:29/6/2021
Dr. S. K. Ukarande Dr Anuradha Muzumdar
Associate Dean , Faculty of Science and Technology Dean, Faculty of Science and Technology
University of Mumbai Unive rsity of Mumbai
Sr. No. Heading Particulars
1 Title of the Course Third Year in Bachelor of Electrical Engineering
2 Eligibility for Admission
After Passing Second Year Enginee ring as per the
Ordinance 0.6243
3 Passing Mar ks 40%
4 Ordinances /
Regulations ( if any) Ordinance 0.6243
5 No. of Years / Semesters 8 semesters
6 Level Under Graduation
7 Pattern Semester
8 Status Revised
9 To be implemented from
Academic Year With effect from Academic Ye ar: 2021 -2022
AC: 29/6/2021
Item No. -6.4
UNIVERSITY OF MUMBAI
Syllabus for Approv al
Page 5
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Preamble
To meet the challenge of ensuring excellence in engineering education, the issue of quality needs to be
addressed, debated and taken forward in a systematic manner. Accreditation is the principal means of
quality assurance in hi gher education. The major emphasis of accreditation process is to measure the
outcomes of the program that is being accredited. In line with this Faculty of Science and Technology
(in particular Engineering) of University of Mumbai has taken a lead in inco rporating philosophy of
outcome based education in the process of curriculum development.
Faculty resolved that course objectives and course outcomes are to be clearly defined for each course,
so that all faculty members in affiliated institutes understand the depth and approach of course to be
taught, which will enhance learner’s learning process. Choice based Credit and grading system enables
a much -required shift in focus from teacher -centric to learner -centric education since the workload
estimated is b ased on the investment of time in learning and not in teaching. It also focuses on
continuous evaluation which will enhance the quality of education. Credit assignment for courses is
based on 15 weeks teaching learning process, however content of courses i s to be taught in 13 weeks
and remaining 2 weeks to be utilized for revision, guest lectures, coverage of content beyond syllabus
etc.
There was a concern that the earlier revised curriculum more focused on providing information and
knowledge across variou s domains of the said program, which led to heavily loading of students in
terms of direct contact hours. In this regard, faculty of science and technology resolved that to minimize
the burden of contact hours, total credits of entire program will be of 17 0, wherein focus is not only on
providing knowledge but also on building skills, attitude and self learning. Therefore in the present
curriculum skill based laboratories and mini projects are made mandatory across all disciplines of
engineering in second a nd third year of programs, which will definitely facilitate self learning of
students. The overall credits and approach of curriculum proposed in the present revision is in line with
AICTE model curriculum.
The present curriculum will be implemented for Third Year of Enginee ring from the academic year
2021 -22. Subsequently this will be carried forward for Final Year Engineering in the academic year
2022 -23.
Dr. S. K. Ukarande Dr Anuradha Muzumdar
Associate Dean Dean
Faculty of Science and Technology Faculty of Science and Technology
University of Mumbai University of Mumbai
Page 6
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Incorporation and Implementation of Online Contents from
NPTEL/ Swayam Platform
The curriculum revision is mainly focused on knowl edge component, skill based activities and project
based activities. Self learning opportunities are provided to learners. In the revision process this time
in particular Revised syllabus of ‘C ‘ scheme wherever possible additional resource links of platfo rms
such as NPTEL, Swayam are appropriately provided. In an earlier revision of curriculum in the year
2012 and 2016 in Revised scheme ‘A' and ‘B' respectively, efforts were made to use online contents
more appropriately as additional learning materials to enhance learning of students.
In the current revision based on the recommendation of AICTE model curriculum overall credits are
reduced to 171, to provide opportunity of self learning to learner. Learners are now getting sufficient
time for self learning either through online courses or additional projects for enhancing their
knowledge and skill sets.
The Principals/ HoD’s/ Faculties of all the institute are required to motivate and encourage learners to
use additional online resources available on platfo rms such as NPTEL/ Swayam. Learners can be
advised to take up online courses, on successful completion they are required to submit certification
for the same. This will definitely help learners to facilitate their enhanced learning based on their
interest .
Dr. S. K. Ukarande Dr Anuradha Muzumdar
Associate Dean Dean
Faculty of Science and Technology Faculty of Science and Technology
University of Mumbai University of Mumbai
Page 7
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Preface By BoS
The o utcome based course curriculum for the undergraduate degree in Electrical Engineering in
Rev.2019 ‘C’ scheme has been chalked out through the thoughtful discussions and deliberations of
academic and industry experts. While devising the syllabus content fra mework, the correct balance
between the fundamental / core topics with appropriate mix of topics from the state of the art
technologies in electrical and allied domains is attempted. With the increased Industry -Institute
interaction and internship programs , students are encouraged to explore the opportunity to improve
communication skills, problem solving skill and good team management. These skills shall surely help
them to meet the future challenges in their career.
The new course curriculum will also g ive ample opportunity to the students to work in cross discipline
domains to gain the hands on experience through the project based learning facilitated through the
various skill based labs, Mini projects, Course projects , Major projects etc. The increas ed number of
department and institute level electives shall facilitate students with the truly choice based learning
and skilling in a particular domains.
On behalf of the Board of Studies (BoS) in Electrical Engineering of the University of Mumbai, we
seek the active participation from all the stake holders of the engineering education to meet the set
outcomes and o bjectives for the U ndergraduate Program in Electrical Engineering .
Board of Studies in Electrical Engineering
Dr. Sushil S. Thale : Chai rman
Dr. B. R. Patil : Member
Dr. S. R. Deore : Member
Dr. B. B. Pimple : Member
Dr. Nandkishor Kinhekar : Member
Page 8
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Program Structure for Third Year Electrical Engineering
(Semester V & VI)
University Of Mumbai
(With Effect from 2021 -2022 )
Semester V
Course
Code Course Name Teaching Scheme
(Contact Hours) Credits Assigned
Theory Pract. Theory Pract. Total
EEC501 Electrical AC
Machines II 3 -- 3 -- 3
EEC502 Electrical Power
System II 3 -- 3 3
EEC503 Control System 3 -- 3 -- 3
EEC504 Electroma gnetic
Field and Wave 3 -- 3 -- 3
EEDO501X Department Optional
Course – 1 3 -- 3 -- 3
EEL501 Electrical AC
Machines Lab II -- 2 -- 1 1
EEL502 Simulation Lab II -- 2 -- 1 1
EEL503 Control System Lab -- 2 -- 1 1
EEL504 Professional
Communication and
Ethics-II -- 2*+2 -- 2 2
EEM501 Mini Project – 2 A -- 4$ -- 2 2
Total 15 14 15 07 22
Course
Code Course Name Examination Scheme
Theory
Term
Work Prac
/
Oral Total Internal Assessment End
Sem
Exam Exam.
Duration
(in Hrs) Test1 Test2 Avg
EEC501 Electrical AC
Machines -II 20 20 20 80 3 -- -- 100
EEC502 Electrical Power
System -II 20 20 20 80 3 -- -- 100
EEC503 Control System 20 20 20 80 3 -- -- 100
EEC504 Electromagnetic
Field and Wave 20 20 20 80 3 -- -- 100
EEDO501X Department Optional
Course – 1 20 20 20 80 3 -- -- 100
EEL501 Electrical AC
Machines Lab -II -- -- -- -- -- 25 25 50
EEL502 Simulation Lab -II -- -- -- -- -- 25 25 50
EEL503 Control System Lab -- -- -- -- -- 25 25 50
EEL504 Professional
Communication and
Ethics -II -- -- -- -- -- 25 25 50
EEM501 Mini Project – 2A -- -- -- -- -- 25 25 50
Total -- -- 100 400 -- 125 125 750
* Theory class to be conducted for full class
$ indicates work load of Learner (Not Faculty), for Mini Project ; Faculty Load : 1 hour per week per four
groups
Page 9
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Semester VI
Course
Code Course Name Teaching Scheme (Contact
Hours) Credits Assigned
Theory Pract./ Tut. Theory Pract. Total
EEC601 Power System
Protection &
Switchgear 3 -- 3 -- 3
EEC602 Microcontroller
Applications 3 -- 3 3
EEC603 Control Sy stem
Design 3 -- 3 -- 3
EEC604 Signals and Systems 3 -- 3 -- 3
EEDO601X Department
Optional Course – 2 3 -- 3 -- 3
EEL601 Power System
Protection &
Switchgear Lab -- 2 -- 1 1
EEL602 Microcontroller
Applications Lab -- 2 -- 1 1
EEL603 Control System
Design Lab -- 2 -- 1 1
EEL604 SBL-III: Industrial
Automation Lab -- 4 -- 2 2
EEM601 Mini Project – 2 B -- 4$ -- 2 2
Total 15 14 15 07 22
Course
Code Course Name Examination Scheme
Theory
Term
Work Prac
/
Oral Total Internal Assessment End
Sem
Exam Exam.
Duration
(in Hrs) Test1 Test2 Avg
EEC601 Power System
Protection &
Switchgear 20 20 20 80 3 -- -- 100
EEC602 Microcontroller
Applications 20 20 20 80 3 -- -- 100
EEC603 Control System
Design 20 20 20 80 3 -- -- 100
EEC604 Signals and Systems 20 20 20 80 3 -- -- 100
EEDO601X Department
Optional Course – 2 20 20 20 80 3 -- -- 100
EEL601 Power System
Protection &
Switchgear Lab -- -- -- -- -- 25 25 50
EEL602 Microcontroller
Applications Lab -- -- -- -- -- 25 25 50
EEL603 Control Syst em
Design Lab -- -- -- -- -- 25 -- 25
EEL604 SBL-III: Industrial
Automation Lab -- -- -- -- -- 25 25 50
EEM601 Mini Project – 2 B -- -- -- -- -- 25 25 50
Total -- -- 100 400 -- 125 100 725
$ indicates work load of Learner (Not Faculty), for Mini Proje ct; Faculty Load : 1 hour per week per
four groups
Page 10
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Department Optional Courses
Sem. V: Department Optional Course – 1
EEDO5011: Renewable Energy S ources
EEDO5012: Advanced Power Electronics
EEDO5013: Advanced Measurements and Instrumentation
EEDO5014: Analog and Digital Communication
Sem. VI: Department Optional Course – 2
EEDO6011: Special Electrical Machine
EEDO6012: Electric Traction
EEDO6013: High Voltage Engineering
EEDO6014: Energy Storage
Page 11
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching Scheme (Contact Hours) Credits assigned
EEC501 Electrical AC Machines -II Theory Pract./Tut. Theory Pract /Tut. Total
3 -- 3 -- 3
Course Code Course Name Examination Scheme
Theory
Term
work Pract./
Oral Total Internal Assess ment End
Sem.
Exam. Exam.
Duration
(in Hrs) Test 1 Test 2 Avg
EEC501 Electrical AC
Machines -II 20 20 20 80 03 - - 100
Course
Objectives To impart knowledge of operation and performance of synchronous machine
Cours e
Outcomes Upon successful completion of this course, the learner will be able:
1. To illustrate the working of synchronous generator
2. To determine the voltage regulation of synchronous generator by different methods
3. To analyze the parallel operation of synchr onous generators.
4. To apply Blondel’s two reaction theory and solve simple problems on sa lient pole synchronous
machines.
5. To analyze the operation of synchronous motor.
6. To derive the basic machine relations in dq0 variables for a synchronous machine without
considering damper winding.
Module Contents Hours
1 Synchronous Generator -Introduction:
Construction, Operation, E.M.F. equation, Win ding factors, Armature reaction
03
2 Analysis of Synchronous Generator:
Phasor diagrams of cylindrical rotor syn chronous generator, Voltage regulation, No load (OC)
and SC test, Voltage regulation methods: EMF, MMF, ZPF , ASA.
06
3 Performance of Synchronous Generator:
Power flow equations and maximum power conditions, Need for parallel operation and
conditions, E ffect of variation of field current and prime mover input on parallel operation,
Concept of infinite bus, Effect of variation of field current on alternator connected to infinite
bus, Numerical problems on parallel operation. 10
4 Salient pole synchronous generator:
Concept of direct and quadrature reactance, Blondel’s two reaction theory, Phasor diagram of
salient pole machine, Power angle characteristics, Synchronizing power and torque. 06
5 Synchronous Motor:
Principle of operation, Self -starting met hods, Phasor diagram, Load angle (δ), Power flow
equations and maximum power conditions, Effect of change in excitation and mechanical
power on performance of motor, V and Inverted V curves, Power factor control, Hunting,
Excitation and power circles, Meas urement of X d and X q by slip test, Starting against high
torques .
09
6 Theory of Synchronous Machines:
Ideal synchronous machine, Transformation to direct and quadrature axis variables, basic
machine relations in dq0 variables (Primitive model of synchr onous machine without
considering damper winding), steady state analysis .
05
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Text Books:
1. Bimbhra P.S., Electric Machinery , Khanna Publisher
2. Bimbhra P.S., Generalized Machine Theory , Khanna Publisher
3. V. K. Mehta, Principles of Electrical Mach ines, S Chand Publication
Reference Books:
1. M.G. Say, Performance and Design of Alternating Current M achines, CBS Pub.
2. Ashfaq Husain, Electric Machines , Dhanpat Rai and co. publications
3. A.E. Fitzgerald, Kingsly, Stephen, Electric Machinery , Tat a McGraw Hill
Web Refere nce /Video Courses
1. NPTEL Course : Electrical Machines -II By Prof. Krishna Vasudevan, Prof. G. Sridhara Rao, Prof. P. Sasidhara Rao,
IIT-Madras . Weblink - https://nptel.ac.in/courses/108/106/108106072/
2. NPTEL Course : Electrical Machine s By Prof. G. Bhuvaneshwari , Dept. of Electrical Engineering , IIT-Delhi.
Weblink :- https://nptel.ac.in/courses/108/102/108102146/
3. NPTEL Course : Electrical Machines -II By Prof. Tapas Kumar Bhattacharya, Dept. of Electrical Engg. , IIT-
Kharagpur. Weblink: - https://nptel.ac.in/courses/108/105/108105131/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course p roject.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining qu estions will be randomly selected from all the modules.
Page 13
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching Scheme (Contact Hours) Credits assigned
EEC502 Electrical Power
System II Theory Pract./Tut. Theory Pract /Tut. Total
3 -- 3 -- 3
Course Code Course Name Examination Scheme
Theory
Term
work Pract./
Oral Total Internal Assessment End
Sem.
Exam. Exam.
Duration
(in Hrs) Test 1 Test 2 Avg
EEC502 Electrical Power
System II 20 20 20 80 03 -- - 100
Course
Objectives 1. To understand different types of faults and their analysis.
2. To understand power system transients and insulation coordination.
3. To understand concept of corona.
Course
outcomes Upon successful completion of this course, the learner will be abl e to
1. Understand and analyse unsymmetrical faults on transmission line
2. Analyse symmetrical component and construct sequence network
3. Analyse symmetrical faults on transmission lines.
4. Understand power system transients
5. Understand phenomenon of lightning and insulation coordination.
6. Understand concept of corona.
Module Contents Hours
1. Symmetrical Fault Analysis:
Introduction to synchronous machine, basic construction, operation and equivalent
circuit diagram, short circuit of synchronous machine: no load and loaded machine,
transient on a transmission line, selection of Circuit breaker, short circuit MVA. Algorithm
for SC studies, Z Bus formulation, symmetrical fault analysis using Z bus.
(Numerical)
10
2. Symmetrical Components:
Introduction, Symmetrica l component transformation, phase shift in star -delta
transformers, sequence impedances and sequence network of transmission line,
synchronous machine and transformer, power invariance, construction of sequence
network of a power system . (Numerical)
08
3. Unsymmetrical Fault Analysis:
Types of unsymmetrical faults, Analysis of shunt type unsymmetrical faults: single line to
ground (SLG) fault, line to line (L -L) fault, double line to ground (LLG) fault. (Numerical)
05
4. Power System Transients:
Review of transients in simple circuits, recovery transient due to removal of short circuit,
arcing grounds, capacitance switching, current chopping phenomenon.
Travelling waves on transmission lines, wave equation, reflection and refraction of
waves, typical cases of line terminations, attenuation, Bewely lattice diagram .
(Numerical)
06
5. Lightning and Insulation Coordination:
Lightning phenomenon, mechanism of Lightning stroke, shape of Lightning voltage wave,
over voltages due to Lightning, Lightning protection problem, significance of tower
footing resistance in relation to Lightning, insulator flashover and withstand voltages,
protection against surges, surge arresters, surge capacitor, surge reactor and surge
absorber, Lightning arrestors and protective charac teristics, dynamic voltage rise and
arrester rating.
06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Insulation Coordination: - Volt time curve, basic approach to insulation co -ordination in
power system, over voltage protection, ground wires, insulation coordination based on
lightning, surge protection of rotating machines and transformers.
6. Corona:
Phenomenon of corona, Disruptive critical voltage, Visual critical voltage, corona loss,
factors affecting corona loss, Radio interference due to corona, practical considerations
of corona loss, corona in bundled conductor lines, corona ring. (Numerical)
04
Text Books: -
1. B.R. Gupta , Power System Analysis and Design , S. Chand, 4e
2. D. P. Kothari, I. J. Nagrath, “Power System Engineering‟, 3e, Mc Graw Hill
3. Wadhwa C.L. Electrical power system , New Age Inte rnational, 4e
4. Mehta V.K., Principles of Power System, S . Chand
Reference Books: -
1. Hadi Saadat, Power System Analysis, TMH publications
2. Turan Gonen, Modern power system analysis, Wiley
3. Stevenson and Grainger, Modern power system analysis, TMH publication, 1ed
Website Reference/ Video Courses :
1. NPTEL Course: Power Systems Analysis By Prof. Arindam Ghosh , Department of Electrical Engineering IIT
Kanpur : -Web link - https://nptel.ac.in/courses/108/106/108106098/
Assessment:
Internal Assessment consists of t wo tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 ma rks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 15
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course C ode Course Name Teaching scheme (Contact Hours) Credits Assigned
EEC503 Control Systems Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course C ode Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Asse ssment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEC503 Control Systems 20 20 20 80 3 - - 100
Course
Objectives 1. Modeling of electric, mechanical and electromechanical systems, using differential equations,
transfer functions, blo ck diagrams, and state variables.
2. To analyze and design system parameters to meet transient and steady state error
performance specifications.
3. To learn time response analysis and demonstrate their knowledge to frequency response
4. To learn stability analysis of system using Root locus, bode plot, polar plot, and Nyquist plot.
Course
outcomes Upon successful completion of this course, the learner will be able to :
1. Demonstrate an understanding of the fundamentals of (feedback) control systems.
2. Determine and use models of physical systems in forms suitable for use in the analysis and
design of control systems.
3. Express and solve system equations in state -variable form (state variable models).
4. Determine the time and frequency -domain responses of first and second -order systems to
step and sinusoidal (and to some extent, ramp) inputs.
5. Determine the (absolute) stability of a closed -loop control system
Module Contents Hours
1. Introduction to Control S ystem :
Elements of control systems, concept of open loop and clos ed loop systems, Examples and
application of open loop and closed loop systems. Concept of feedback and Automatic
control, Effects of feedback 03
2. Mathematical Model of Physical System
Transfer function of electrical, mechanical (translational and rotatio nal) System. Force
Voltage and Force Current analogies.
Transfer function model of AC & DC servomotor, potentiometer & tacho -generator. Block
diagram reduction technique and signal flow graph, Mason’s rule, Signal flow graph of
electrical network. Conversi on of BDR to SFG and vice versa. 08
3. Time Domain A nalysis: Time domain analysis of a standard second order closed loop system.
Concept of un -damped natural frequency, damping, overshoot, rise time and settling time.
Dependence of time domain performance p arameters on natural frequency and damping
ratio. Step and I mpulse response of first and second order systems. Effects of Pole and Zeros
on transient response. Stability by pole location. Routh‐Hurwitz criteria and applications.
Error Analysis: Steady state errors in control systems due to step, ramp and parabolic inputs.
Concepts of system types and error constants. 09
4. State Variable Analysis
Introduction to state variable, General state space representation, State space representation
of Electrical and Mechanical systems. Conversion between state space and trans fer function.
Alternative representations in state space: (Phase variable, canonical, parallel & cascade).
Similarity transformations, diagonalizing a system matrix. Laplace Transform solution of state
equation, stability in state space 07
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
5. Root locus T echniques :
Definition and properties of root locus, rules for plotting root locus, stability analysis using
root locus. 04
6. Frequency Domain Analysis :
Polar plots, Bode plot, stability in frequency domain, Nyquist plots. Nyquist stability criterion.
Gain ma rgin and phase margin via Nyquist diagram and Bode plots. 08
Text Books: -
1. Control System Engineering by Norman Nise
2. Control System Engineering by Nagrath and Gopal, 5th to latest edition , Wiley Eastern
3. Modern Control System Engineering by K. Ogata, Pren tice Hall
4. Modern Control Systems, Twelfth edition, by Richard C Dorf, Robert H Bishop, Pearson.
5. Gopal, M., Digital Control System, Wiley Eastern (1986).
Reference Books: -
1. Linear Control system Analysis and design with MATLAB, by J.J. Azzo, C. H. Houpis S. N. Sheldon, Marcel
Dekkar
2. Feedback control of Dynamic System, G.F. Franklin, Pearson higher education,
3. Control System Engineering, Shivanagraju s. Devi L., New Age International
4. Control Systems Technology, Curtis Johnson, Heidar Malki, Pearson
5. Control Sy stems Engineering, S. K. Bhattacharya, Pearson.
6. Control Systems, Theory and applications, Smarajit Ghosh, Pearson
Web Reference /Video Courses
1. NPTEL Course: Control Engineering By Prof. Ramkrishna Pasumarthy, Department of Electrical Engineering,
IIT Mad ras : -Web link - https://nptel.ac.in/courses/108/106/108106098/
2. NPTEL Course: Control Systems By Prof. C.S. Shankar Ram, Department of Design Engineering, IIT Madras : -
Web link - https://nptel.ac.in/courses/107/106/107106081/
3. NPTEL Course: Control Engineerin g By Prof. S.D. Agashe, Department of Electrical Engineering, IIT Bombay
:-Web link - https://nptel.ac.in/courses/108/101/108101037/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Mod ules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules
Page 17
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching Scheme (Contact Hours) Credits Assigned
EEC504 Electromagnetic Field
and Wave Theory Pract./Tut. Theory Pract /Tut. Total
3 -- 3 -- 3
Course Code Course Name Examination Scheme
Theory
Term
work Pract./
Oral Total Internal Assessment End
Sem.
Exam. Exam.
Duration
(in Hrs) Test
1 Test
2 Avg
EEC504 Electromagnetic Field
and Wave 20 20 20 80 03 -- - 100
Course
Objectives 1. Implement the knowledge of mathematics and physics.
2. Visualize Electric field.
3. Visualize magnetic field
4. Understand their application in electrical engineering
5. Analyse time varying electric and magnetic fields
6. Formulate electromagnetic wave equation
Course
outcomes Upon successful completion of this course, the learner will be able to :
1. Apply knowledge of mathematics and physics in electrical engineering field.
2. Analyze electrostatic fields
3. Apply and analyse magneto -static fields.
4. Analyze the effect of material medium on electric and magnetic fields.
5. Analyze and formulate time varying electric and magnetic fields.
6. Formulate wave equations for Electromagnetic wa ve propagation in different media.
Module Contents Hours
1. Vector Basics:
Introduction to Vectors Calculus, Rectangular, Cylindrical and Spherical Co -ordinate System,
Co-ordinate and vector transformation; Numericals on line , Surface and Volume Integrals . 05
2. Static Electric Fields:
Coulomb’s Law in Vector Form, Electric Field Intensity, Definition, Principle of Superposition,
Electric Field due to point charges, Electric Field due to line charge (one and two conductor
transmission lines), Electric Fiel d due to an infinite uniformly charged sheet, Definition and
physical interpretation of gradient, Electric scalar potential, Relationship between potential
and electric field and its application on Surface voltage gradient on conductor . Numericals 12
3. Static Magnetic Fields:
The Biot -Savart’s Law in vector form, Magnetic Field intensity due to a finite and infinite
wire carrying a current I, Magnetic field intensity on the axis of a circular loop carrying a
current I, Ampere’s circuital law and its applica tion on A solid cylindrical conductor and
Infinitely long coaxial transmission line, Magnetic flux density, Definition and physical
Interpretation of Curl, The Lorentz force equation for a moving charge and its applications
on Force on a wire carrying a cu rrent I placed in a magnetic field, Magnetic Vector Potential.
Numericals 08
4. Electric and Magnetic Fields in Materials:
Poisson’s and Laplace’s equation , Electric Polarization, Electric current, Current density,
Point form of ohm’s law, Continuity equa tion for current Numericals 06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
5. Time varying Electric and Magnetic Fields :
Faraday’s law, Maxwell’s Second Equation in integral form from Faraday’s Law, Equation
expressed in point form, Displacement current, Ampere’s circuital law in integral form,
Modi fied form of Ampere’s circuital law as Maxwell’s first equation in integral form,
Equation expressed in point form, Maxwell’s four equations in integral form and differential
form. Numericals 05
6. Electromagnetic Wave theory:
Derivation of Wave Equation, Uniform Plane Waves, Maxwell‟s equation in phasor form,
Wave equation in phasor form. (No numericals) 03
Self Study Topics - Potential due to electrical dipole and flux lines, Electric Flux Density, Gauss Law Definition and
physical Significance of Diverg ence, Divergence theorem. Application on Estimation and control of electric
stress, control of stress at an electrode edge .
Note : Students should be encouraged to study the self -study topics through text books, reference books , online
courses /contents etc. The students’ performance on self-study contents be verified through MCQ s and/or
presentation s or any other suitable methodology.
Text/Reference Books: -
1. W. Hayt, “Engineering electromagnetic”, McGraw Hill, 4th edition, 1987.
2. Edminister, “Schaum‟s series in electromagnetic” McGraw Hill publications, 3rd edition, 1986.
3. M.N.O.Sadiku, “Elements of Engineering Electromagnetics” Oxford University Press, 3rd Ed.
4. N. Narayan Rao, “Elements of Electromagnetic”, PHI publication, 4th edi tion, 2001.
5. David K.Cherp, “Field and Wave Electromagnetics - Second Edition -Pearson Edition
Website Reference / Video Courses :
1. NPTEL Course: Electromagnetic Fields By Prof. Harishankar Ramachandran, Department of Electrical
Engineering IIT Madras : -Web link- https://nptel.ac.in/courses/108/106/108106098/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problem s or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 19
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course C ode Course Name Teaching scheme (Contact Hours) Credits Assigned
EEDO5011 Renewable Energy
Sources Theory Pract./Tut. Theory Pract./Tut . Total
3 -- 3 3
Course C ode Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO5011 Renewable
Energy Sources 20 20 20 80 3 - - 100
Cour se
Objectives 1. To review of conventional and non -conventional energy sources.
2. To give the students basic knowledge of solar thermal energy applications
3. To give the students basic knowledge solar photovoltaic system
4. To give the students basic knowledge of w ind energy system
5. To give the students basic knowledge of fuel cell system operation
6. To give the students basic knowledge about other renewable energy sources .
Course
outcomes Upon successful completion of this course, the learner will be able to :
1. Underst and different types conventional energy sources and their reserves
2. Identify and analyse the process of power generation through solar thermal energy utilization
3. Identify and analyse the process of power generation through solar photovoltaic energy utiliza tion
4. Identify and describe the various components and types of Wind Energy system
5. Identify and describe the basic operation and types of Fuel cell system
6. Understand different types of other non -conventional energy sources
Module Contents Hours
1. Introduc tion-:
World’s and India’s production and reserves of commercial energy sources, energy
alternatives, review of conventional and non -conventional energy sources. Statistic of net
potential and current generation status of different energy alternatives.
04
2. Solar Energy (Thermal Energy applications) :
Solar thermal energy storage, Liquid flat plate collector, Solar air heater, concentrating
collectors, thermal energy storage, solar pond
04
3. Solar Energy (Direct Electricity Applications) :
Solar Photovo ltaic- solar cell: characteristics, losses, model of a solar cell, emerging solar
cell technologies; Solar PV modules, mismatch in module, hot spots, bypass diode; PV
module: I -V and power curve, effect of variation in temperature and solar radiations;
MPP T, types, different algorithms for electrical MPPT. Distributed MPPT, MPPT
converters. Types of PV systems: standalone, grid connected systems; BOS of PV system,
Battery charge controllers, Power Conditioning Unit, Solar PV Micro -inverters Solar Plant
design: mounting of PV panels supporting structures, Calculation and Design methodology
of standalone PV system and grid connected system.
12
4. Wind Energy:
Review of wind energy system and its components, types of wind turbines, characteristics;
general co ncepts of aerofoils and aerodynamics, Wind data, Energy content of the wind,
Power generation and control in wind energy systems, performance calculations of wind
energy systems. Topologies of WES, WES with rectifier / inverter system, Power
Converters for Doubly Fed Induction Generators (DFIG) in Wind Turbines.
08
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
5. Fuel Cell:
Review of fuel cells and their principle of operation, Review of types of fuel cell and their
performance comparison. Topologies of fuel cell power systems, applications.
05
6. Other Sources:
Review of other nonconventional sources, their features and applications; Biomass, Tidal,
Ocean , Thermal Electric Conversion, geothermal, Micro -hydro, Wave energy
06
Text / Reference Books:
1. Ali Keyhani, Mohammad N. Marwali, Min Dai “Integrat ion of Green and Renewable Energy in Electric
Power Systems”, Wiley
2. Green M.A “ Solar Cells” : Operating Principles, T echnology and System Applications, Prentice Hall Inc,
Englewood Cliffs N.J, U.S.A, 1982
3. James Larminie, Andrew Dicles “Fuel Cell Systems Explained,” Wiley publication
4. Chetan Singh Solanki , Solar Photo Voltaics , PHI Learning Pvt Ltd., New Delhi,2009
5. Hashem Nehrir and Caisheng Wang, Modeling and control of Fuel C ells: Distributed Generation
Applications, IEEE Press, 2009
6. J.F. Manwell an d J.G. M cGowan, Wind Energy Explained, Theory D esign and Applications, Wiley publication
7. Leo J.M.J. Blomen and Michael N. Mugerwa, “Fuel Cell System”, New York, Plenum Press, 1993.
8. D. D. Hall and R. P. Grover, Biomass Regenerable Energy, John Wiley, New York, 1987.
9. Felix A. Farret and M. Godoy Simoes, Integration of Alternative Sources of Energy, 2006, John Wiley and
Sons.
10. S. Chakraborty, M. G. Simões and W. E. Kramer, Power Electronics for Renewable and Distributed Energy
System, Springer 2013
11. N. Femi a • G. Petrone, G. Spagnuolo and M. Vitelli, Power Electronics and Control Techniques for Maximum
Energy Harvesting in Photovoltaic Systems, CRC Press, 2013.
Website Reference / Video Courses :
1. NPTEL Course: Energy Resources & Technology By Prof. S. Banerje e, IIT Kharagpur: - Web link -
https://nptel.ac.in/courses/108/105/108105058/
2. NPTEL Course: Non-Conventional Energy Systems By Prof. L. Umanand, IISC Ban galore :- Web link -
https://nptel.ac.in/courses/108/108/108108078/
Assessment:
Internal Assessment consi sts of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carryi ng 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 21
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEDO501 2 Advanced Power
Electronics Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course C ode Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO501 2 Advanced Power
Electronics 20 20 20 80 3 - - 100
Course
Objectives 1. To understand and analyse dc to dc conversion with isolation and hence to analyz e different
converter circuits for power conversion.
2. To understand the principles of design of magnetics such as high frequency transformers and
inductors.
3. To keep abreast with the latest technologies and research going on in different areas related to
pow er electronics.
4. To enhance the capability of problem solving skills.
5. To model the converter and design the controller for deeper understanding and detailed analysis .
Course
outcomes Upon successful completion of this course, the learner will be able to :
1. Analyze and select dc to dc power electronic converter topology for energy conversion
applications.
2. Apply the basic concepts of magnetics to design high frequency transformers and Inductors for
dc to dc converter topologies.
3. Analyze resonant power electroni c converter topologies for high frequency applications
4. Model and design controllers for the closed loop operation of dc to dc converters.
5. Apply the basic concepts of power electronics in the fields of AC and DC drives, power generation
and energy conversio n, industrial applications, extraction of energy from renewable sources.
Module Contents Hours
1. Switching Voltage Regulators: Comparison of Linear voltage regulators and switching voltage
regulators, Buck, Boost, Buck -Boost converters in Boundary and Di scontinuous Conduction
Mode (DCM), Isolated converters -unidirectional and bidirectional core excitation, Flybac k
converter, Forward converter, Full bridge converter (Numericals ).
11
2. Design of DC to DC converters (Boost, Buck, BDC, Flyback only): Review of magnetic concepts,
area product, design of inductor, design of high frequency transformer, numerical on design
of inductor and transformer. Selection of capacitor, switching device and diode.
07
3. Resonant converters: Drawbacks of switch -mode converte rs, basic resonant circuit
concepts, Resonant switch converters - ZVS, ZCS, comparison, Basic concept of r esonant dc
link inverter and Applications of resonant converters .
04
4. Modeling and control (Boost, Buck and Flyback only): State space model of vari ous dc to dc
converters, effect of ESR of capacitor and inductor resistance on the state space models,
state space averaging technique, small signal analysis, transfer function, feedback control,
compensator design, voltage mode c ontrol and current mode co ntrol, advantages of digital
control.
08
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
5. Multi -Level Inverter: Need for multilevel inverters, Diode clamped, flying capacitor and
cascaded MLI, Phase shifted and level shifted PWM techniques, introduction to SVM for
three level inverter .
04
6. Applicati ons of power electronic converters: Solar PV power conditioning unit , Bidirectional
converter in battery charging, Resonant converters in induction heating , converters in
residential applications, Application of Multi level inverter and three port DC to Dc
converters.
05
Self study Topics : series and parallel load resonant c onverter .
Note : Students should be encouraged to study the self -study topics through text books, reference books , online
courses /contents etc. The students’ performance on self-stud y contents be verified through MCQ s and/or
presentation s or any other suitable methodology.
Books Recommended:
Text Books:
1. N. Mohan and T. M. Undeland, “Power Electronics: Converters, Applications and Design”, John Wiley &
Sons, 2007.
2. L. Umanand, Bhatt, “ Design Of Magnetic Components for Switched Mode Power Converters”, John Wiley
& Sons.
3. Simon Ang, Alejandro Oliva, “Power -Switching Converters”, Taylor and Francis group
4. Bin Wu, “High Power Converters and AC drives”, IEEE press, John Wiley & Sons.
5. M.H. Ras hid, Hand book of Power Electronics”, Third edition Butterworth -Heinemann, 2011.
Reference Books:
1. L. Umanand, “Power Electronics: Essentials and Applications”, Wiley India, 2009.
2. R.W. Erickson and D. Maksimovic, “Fundamentals of Power Electronics”, Spring er Science & Business
Media, 2007.
3. Joseph Vithayathil, “Power Electronics”, Tata McGraw hill, 1995.
4. P. T. Krein, Elements of Power Electronics, Oxford University Press.
5. V. Ramanarayanan, “Course Material on Switched Mode Power Conversion”, 2007.
6. Simone Bu so and Paolo Mattavelli “Digital Control in Power Electronics”, Morgan & Claypool Publishers.
Website Reference / Video Courses :
1. NPTEL Course: Advance Power Electronics And Control By Prof. Avik Bhattacharya, Dept. of Electrical
Engineering, IIT Roorkee : -Web link - https://nptel.ac.in/courses/108/107/108107128/
2. NPTEL Course: Switched Mode Power Conversion By Prof. L. Umanand and Prof. V. Ramanarayanan, IISC
Bangalore : -Web link - https://nptel.ac.in/courses/108/108/108108036/
Assessment:
Internal Assessmen t consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 23
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERIN G - SEMESTER -V
Course Code Course Name Teaching Scheme (Contact Hours) Credits assigned
EEDO5013 Advanced Measurements
and Instrumentation Theory Pract./Tut. Theory Pract /Tut. Total
3 -- 3 -- 3
Course Code Course Name Examination Scheme
Theory
Term
work Pract
/
Oral Total Internal Assessment End
Sem.
Exam. Exam.
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO5013 Advanced
Measurements and
Instrumentation 20 20 20 80 03 -- - 100
Course
Objectives 1. To impart knowledge of architecture of t he analog and digital measurement system s
2. To illustrate the working principle of electrical and non -electrical parameters measurements
3. To emphasize the principles and application of MEMS
4. To acquaint with digital data acquisition and virtual instrumentation system
Course
outcomes Upon successful completion of this course, the learner will be able to :
1. Classify , select and use various types of measurement sensors/ transducers and instrumentation
system suitable for the given application
2. Classify and select pr oper measuring instrument for various electrical and non -electrical
parameters measurements
3. Illustrate the principles and application of MEMS in various fields of engineering.
4. Understand the working of digital data acquisition system
5. Understand the role o f virtual instrumentation in various application domains
Module Contents Hours
1 Measurement and Instrumentation:
Basics of measurement and instrumentation system: Measurement System Architecture:
analog and digital systems; Measuring Instruments: Class ification, Absolute and secondary
instruments, indicating instruments, constructional details, characteristics; Errors in
measurements, Sensor Dynamics, Overview of Signal Conditioning: Analog and Digital
Signal Conditioning 04
2 Sensors and Transducers:
Electrical Parameters measurement: Voltage and current, Instrument Transformers:
Potential and current transformers.
Displacement Measurement: Transducers for displacement, displacement
measurement, potentiometer, LVDT.
Strain Measurement: Theory of Strain Gauges, Bridge circuit, Strain gauge based load
cells and torque sensors,
Velocity, Spe ed, Vibration and Acceleration M easurement: Velocity and Speed :
Electromagnetic tachometer, Photoelectric tachometer, variable reluctance
tachometer, Digital Encoders.
Vibration and acceleration : Eddy current type, piezoel ectric type; Accelerometer :
Principle of working, practical accelerometers, strain gauge based and piezoelectric
accelerometers.
Pressure Measurement: Elastic pressure transducers viz. Bourdon tubes, d iaphragm,
bellows and piezoelectric pressure senso rs.
Flow Measurement: Bernoulli flowmeter, Ultrasonic f lowmeter, Magnetic flow meter,
Rotameter .
Miscellaneous Sensors: Leak detector, Flame detector, Smoke detector, pH sensors,
Conductivity sensors, Humid ity sensors, Potentiometric Biosensors and Proximity
sensors (Only basic principle of working ) 10
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
3 MEMS Technology:
Introduction Nanotechnology and MEMS, MEMS design, and fabrication technology –
Lithography, Etching, MEMS material, Bulk micromachining, Surface micromachining,
Micro -actuator, electrostatic actuation, Micro -fluidics.
MEMS types and their applications: Mechanical MEMS – Strain and pressure sensors,
Accelerometers etc., Electromagnetic MEMS – Micro -motors, Wireless and GPS MEMS,
Magnetic M EMS – all effect sensors, SQUID magnetometers, Optical MEMS – Micro -
machined fiber optic component, Optical sensors, Thermal MEMS – thermo -mechanical
and thermo -electrical actuators, Peltier heat pumps 10
4 Digital Data Acquisition System:
Interfacing tra nsducers to Electronics Control and Measuring System. Instrumentation
and Isolation Amplifier ; Review of Computer -Controlled Test Systems. IEEE -488 GPIB Bus ;
Microcontroller based data acquisition 04
5 Virtual Instrumentation:
Historical perspective, Bl ock diagram and Architecture of Virtual Instruments Data -flow
Techniques: Graphical programming in data flow, Comparison with conventional
programming. VI Programming Techniques: VIs and sub -VIs, Loops and Charts, Arrays,
Clusters and graphs, Case and sequ ence structures, Formula nodes,
Use of Analysis Tools: Advanced analysis tools such as Fourier transforms, Power
spectrum, Correlation methods, Windowing and filtering and their applications in signal
and image processing, Motion Control. 06
6 Process Control System:
Electrical, Pneumatic, Hydraulic and Thermal systems, Process Control, Selection of
Control: On -Off control, P, Pi, PID control.
Sensitivity analysis of sensor -influence of component variation, Signal conditioning:
Amplifier, Conversion, Fil tering, Impedance Buffering, Modulation / Demodulation,
Linearization, Grounding and Isolation. 05
Books Recommended:
Text Books and Reference Books :
1. Introduction To Instrumentation And Measurements by Robert B. Northro p, CRC Press, 2014
2. Instrumentation for Process Measurements and Control, by Norman Andrson, Chilton Company
3. Measurement Systems: Applications and Design, by EO Doebelin,5th Edition, McGraw Hill
4. Mechanical Engineering Measurements, A K Sawhney, Dhanpat Rai & Sons, New Delhi
5. Instrumentation & Mechanical Measurements, A K Thayal
6. Control System Engineering by Nagrath IJ and Gopal M, Wiley Eastern Ltd.
7. Control systems by Dhanesh Manik, Cengage Learning
8. Engineering Metrology and Measurements by N V Raghavendra and L Krishnamurthy, Oxford Universi ty
Press
9. Instrumentation and Control System, W. Bolton, Elsevier
10. Smart Sensors and MEMS, by Stoyan Nihtianov and Antonio Luque , Woodhead Publishing , 2018.
11. Fundamentals of Micro -fabrications and Nanotechnology - From MEMS to Bio -Mems and Bio -NEMS, by
Marc J. Madou, CRC Press, 2011
12. Handbook of Silicon Based MEMS Materials and Technologies , by Markku Tilli et al. William Andrew,
Elsevier , 2015
Website Reference / Video Courses:
1. NPTEL Course: Electrical Measurement And Electronic Instruments By Prof. Avishek Ch atterjee , Dept. of
Electrical Engineering, IIT Kharagpur: - Web link - https://nptel.ac.in/courses/108/105/108105153/
2. NPTEL Course: Industrial Instrumentation By Prof. Alok Barua , IIT K haragpur :-Web link -
https://nptel.ac.in/courses/108/105/108105064/
3. NPTEL Course: Industrial Instrumentation By Prof. Prof. S. Mukhopadhyay and Prof. S.Sen , IIT K haragpur :-
Web link - https://nptel.ac.in/courses/108/105/108105062/
Page 25
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 wi ll be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 26
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEDO5014 Analog and Digital
Communication Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course C ode Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Durat ion
(in Hrs) Test 1 Test 2 Avg
EEDO5014 Analog and Digital
Communication 20 20 20 80 3 - - 100
Course
Objectives
1. To introduce the elements of communication systems, describe the generalized block diagram
and the types of communication syste ms.
2. To make students understand analog and digital communication techniques
3. To teach data and pulse communication techniques
4. To introduce source and Error control coding
Course
Outcomes Upon successful completion of this course, the learner will be abl e to:
1. Understand theory of noise and the various methods involved in modulation techniques
2. Interpret the concepts in analog communication and differentiate various analog modulation
techniques.
3. Develop the concepts in digital communication and various digi tal modulation techniques
4. Apply and integrate various pulsed modulation in digital communication systems.
5. Conversa nt in proposing suitable error controlling and correction algorithms .
6. Understand and incorporate the basic knowledge of optical fiber communic ation and Satellite
communication.
Module Contents Hours
1. Introduction to Communication Systems :
Need and Importance of Communication, Elements of a Communication System, Types
of communication systems (block diagram approach), Electromagnetic Spec trum used
in communication, concept of bandwidth and power, Receiver characteristics, Need for
modulation ;
Noise: Source of Noise - Types of noise, External Noise - Internal Noise – Noise
Calculation, signal to noise ratio
05
2. Analog Communication :
Theo ry of Amplitude Modulation(DSBFC, DSBSC) - Evolution and Description of SSB
Techniques, Independent sideband (ISB) and Vestigial Side Band (VSB) principles and
transmitters ;
Theory of Frequency and Phase Modulation ; Comparison of various Analog
Communi cation System (AM, FM, PM)
08
3. Digital Communication :
Amplitude Shift Keying (ASK), Frequency Shift Keying (FSK), Phase Shift Keying (PSK),
BPSK,QPSK, Quadrature Amplitude Modulation (QAM); Bandwidth, Efficiency
Comparison of various Digital Communicati on System (ASK – FSK – PSK – QAM) .
07
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
4. Sampling Techniques :
Sam pling theorem, Nyquist criteria; Types of Sampling. Pulse modulation schemes –
PAM, PPM and PWM generation and detection -Pulse code modulation. Conversion of
PWM to PPM. Multiplexing Techni ques - FDM and TDM ;
Delta modulation, adaptive delta modulation, principle, generation and detection ; TDM
and FDM basic concepts and block diagram ; Applications of pulse communication
07
5. Source and Error Control Coding:
Entropy -Source encoding theor em - Shannon fano coding - Huffman coding - mutual
information – Channel capacity - Channel coding theorem ;
Error Control Coding - Linear block codes - Cyclic codes –Convolution codes - Viterbi
decoding algorithm.
08
6. Overview of other Types of Commu nication :
Optical fiber communication ; Satellite Communication; Bluetooth.
04
Text Books: -
1. G. Kennedy and B. Davis, “Electronic Communication Systems”, Tata McGraw Hill, 2011
2. Roddy and Coolen, “Electronic Communication”, 4th Edition, Pearson Education 2 008
3. Simon Haykin, “Digital Communications”, 2014, 1st edition, John Wiley, India.
4. T.L.Singal, “Analog and Digital Communication”, 2012, 1st edition, Tata McGraw Hill Education
Private Ltd, New York.
Reference Books:
1. Taub and Schilling, “Principles of Comm unication Systems”, McGraw Hill, Fourth reprint 2009.
2. Wayne Tomasi, “Electronic Communications Systems – Fundamentals Through advanced”, 5th Ed., Pearson
Education, 2009.
3. Hwei Ksu and Debjani Mitra, “Analog and Digital Communication: Schaum’s Outline Serie s”,
4. McGraw Hill Education (India) Pvt Ltd., 3rd Edition 2009.
5. John. G. Proakis, “Digital Communication”, 2014, 5th edition, Pearson Education, Noida, India.
6. Herbert Taub and Donald L Schilling,” Principles of Communication Systems”, Tata McGraw Hill, New Delhi,
2012
7. Bernard Sklar, “Digital Communications: Fundamentals and Applications”, 2016, 2nd edition,
Prentice Hall, New Jersey, US .
Website Reference / Video Courses :
1. NPTEL Course: Principles of Digital Communications By Prof. S N Merchant, Dept. of Ele ctrical Engineering,
IIT Bombay: - Web link - https://nptel.ac.in/courses/108/101/108101113/
2. NPTEL Course: Principles of Communication Systems -I By Prof. Aditya K. Jagannatham, IIT Kanpur :-Web
link- https://nptel.ac.in/courses/108/104/108104091/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
Page 28
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course Code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEL501 Electrical AC
Machines Lab -II Theory Pract./Tut. Theory Pract./Tut. Total
-- 2 1 1
Course Code Course Name Examination Scheme
Theory
Term
Work Pract
& Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEL501 Electrical AC
Machines Lab -II --- --- --- --- -- 25 25 50
Course
Objectives To impart the knowledge on the following :
1. Practical understanding of Synchronous machines and their characteristics
2. Voltage regulation and Parallel operation of Synchronous generators
Course
outcomes Upon successful completion of this cou rse, the learner will be able :
1. To analyze the opera tion of synchronous machines
2. To determine the voltage regulation of synchronous machines
3. To analyze the synchronization (or parallel operation) of synchronous machines
4. To determine the parameters of synchronous machines
Syllabus: Same as EEC501: Electri cal AC Machines -II
Suggested List of Laboratory Experiments: Minimum six experiments need to be performed.
1. Constructional details of Synchronous machine
2. Voltage regulation of Alternator by Direct loading method
3. Voltage regulation of Alternator by EMF and MMF method
4. Voltage regulation of Alternator by ZPF and ASA method
5. Synchronization / Parallel operation of Alternator
6. Starting methods of Synchronous motor
7. Load test on Synchronous motor
8. ‘V’ and ‘inverted V’ curves of Synchronous machine
9. Determination of X d and X q of Synchronous machine by Slip test
10. Use of Synchronous motor as a Synchronous condenser
11. To determine positive sequence, negative sequence and zero sequence reactance of an alternator
Any other experiment based on syllabus which will help stude nts to understand topic / concept.
Industry Visit: Students’ visit to be arranged to the nearby industry involved in design/ manufacturing/ processing in
the following electrical engineering domains: Electrical Machines / Electrical Power / Renewable ener gy / Power
Electronics / Instrumentation / Communication Systems. All students shall submit visit report in appropriate format
as a part of the submission for EEL501.
Note: Students and teachers are encouraged to use the virtual labs whose links are as gi ven below The remote -
access to Labs in various disciplines of Science and Engineering is available. Students can conduct online
experiments which would help them in learning basic and advanced concepts through remote experimentation.
Virtual Lab Website Reference
1. http://vlab.co.in/broad -area -electrical -engineering
2. http://vlab.co.in/broad -area -electronics -and-communications
Page 29
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Term work:
Term work shall consist of minimum eight experiments. The distribution of marks shall be as follows:
Experim ents Performance : 10 marks
Journal : 05 marks
Industrial Visit report : 05 marks
Attendance (Theory and Practical) : 05 marks
The final certification and acceptance of term wo rk ensures the minimum passing in the term work.
Practical and Oral Examination:
Practical and Oral examination will be based on entire syllabus of EEC501: Electrical AC Machines -II
Page 30
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course code Course Name Teachin g scheme (Contact Hours) Credits Assigned
EEL502 Simulation Lab -II Theory Pract./Tut. Theory Pract./Tut. Total
-- 2 1 1
Course
code Course Name Examination Scheme
Theory
Term
Work Oral Total Internal A ssessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEL502 Simulation Lab -II --- --- --- --- -- 25 25 50
Course
Objectives The course is aimed:
1. To understand basic block sets of different simulation platform used in electrical /electronic
circuit design.
2. To understa nd use and coding in different software tools used in electrical/ electronic circuit
design
Course
outcomes Upon successful completion of this course, the learner will be able to
1. Develop the skill to use the software packages to model and program electric al and electronics
systems
2. Model different electrical and electronic systems and analyze the results
3. Articulate importance of software packages used for simulation in laboratory
experimentation /research/industry by analyzing the simulation results.
4. Simulate circuits for performance analysis.
Suggested Software Tools to be Used for Simulation Lab -II:
Note:
1. Students should be encouraged to use open source softwares such as SCILAB, LTSPICE, Texas Instrument’s
‘Webbench’, Ngspice, Solve Elec etc. for ca rrying out the lab simulation listed below.
2. Use of Professional Licensed versions of softwares like MATLAB, Proteus, LabVIEW, NI Multisim, PSpice,
PSim, PSCAD, TINA etc. is also allowed.
3. Use of ‘Python’ platform for simulating components/ circuit behavio ur should also be emphasized
4. Many of the following suggested experimentation can be carried out on Virtual lab platform
Suggested List of Laboratory Experiment: Minimum eight experiments need to be performed from various subjects
domain. Some of the simu lation experiments can also be selected based on the department elective offered
1. Study of sampling theorem, effect of under -sampling.
2. Study of Quantization of continuous -amplitude, discrete -time analog signals.
3. Study of properties of Linear time -invariant system.
4. Simulation of Signal processing circuit (amplifier/ filter /linearizing circuits) used for sensors / transducers
5. Virtual Instrumentation based Simulations of measurement and processing of Non -electrical parameters
like temperature, pressure, force , speed etc.
6. Virtual Instrumentation based Simulation of any suitable industrial Process
7. Simulate the performance of a chemical sensor
8. Characterize the strain gauge sensor
9. Characterize the temperature sensor (Thermocouple)
10. Characterize the temperature sensor (RTD)
11. Simulate the performance of a bio -sensor
12. Measurement of level in a tank using capacitive type level probe
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Term work:
Term work shall consist of minimum eight experiments. The distribution of marks sha ll be as follows:
Experiments Performance : 10 marks
Journal : 10 marks
Attendance (Theory and Practical) : 05 marks
The final certification and acceptance of term work ensures the mi nimum passing in the term work.
Oral Examination:
Oral examination will be based on all the laboratory experiments carried out in EEL-502- Simulation Lab -II
13. Simulation of Solar PV MPPT (P&O or Incremental conductance) based characterization under different
operating conditions
14. Simulation of Solar PV and Battery hybrid energy source
15. Simulation of Fuel cell based Two stage (DC -DC converter and VSI ) power supply for AC loads
16. Simulation of Back to back converter for Wind Energy Application
17. Simulation of closed loop control of Buck/Boost/Buck -Boost DC -DC converters
18. Simulation of a Resonant converter (Series/ parallel; ZVS/ZCS)
19. Simulation of Multilevel Inverter
20. Simulation of Solar PV MPPT converter with VSI
21. Simulation of Battery based Bidirectional Converter
22. Simulation of Flyback converter based S MPS
23. Simulating a Local Area Network (Using Vlab platform: Advanced Network Technologies Virtual Lab)
24. Simulating a Wi -Fi Network (Using Vlab platform: Advanced Network Technologies Virtual Lab)
25. Simulating a Wi -Fi Network (Using Vlab platform: Advanced Ne twork Technologies Virtual Lab)
26. Setting up a Bluetooth Network (Using Vlab platform: Advanced Network Technologies Virtual Lab)
27. Setting up a ZigBee Network (Using Vlab platform: Advanced Network Technologies Virtual Lab)
28. Simulating a Wireless Sensor Netw ork (Using Vlab platform: Advanced Network Technologies Virtual Lab)
Any other simulations / algorithms based on fifth semester syllabus, which will help students to understand topic
/ concept.
Note: Students and teachers are encouraged to use the virtu al labs whose links are as given below The remote -
access to Labs in various disciplines of Science and Engineering is available. Students can conduct online
experiments which would help them in learning basic and advanced concepts through remote experiment ation.
Virtual Lab Website Reference
1. http://vlab.co.in/broad -area -electrical -engineering
2. http://vlab.co.in/broad -area -electronics -and-communications
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEL503 Control Systems
Lab Theory Pract./Tut. Theory Pract./Tut. Total
-- 2 1 1
Course code Course Name Examination Scheme
Theory
Term
Work Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEL503 Control Systems
Lab --- --- --- --- -- 25 25 50
Course
Objectives 1. To study basic concepts of control system
2. To familiarize with the modelling of dynamical systems and the characteristics of control
components like AC servo motor, DC ser vo motor, DC position control system and synchro
3. To employ time domain analysis to predict and diagnose transient performance parameters of
the system for standard input functions to ascertain the required dynamic response from the
system
Course
outco mes Upon successful completion of this course, the learner will be able to
1. Illustrate the functioning of various components of control system.
2. Analyse the response of physical system for various inputs.
3. Analyze and interpret stability of the system through Root Locus, Bode plot and Nyquist plots
4. Execute time response analysis of a second order control system using MATLAB
Syllabus: Same as EEC5 03: Control Systems
Suggested List of Laboratory Experiments: Minimum four from Group (A) and four from Group (B ), in all
minimum eight experiments need to be performed.
(A) Laboratory Experiments
1. Study of AC Servomotor
2. Study of DC Servomotor
3. Study of potentiometer as an error detector
4. Study of Synchros as an error detector
5. Study of AC position contr ol system
6. Study of DC position control system
7. Obtain time response of first order to step ramp and parabolic input
8. Obtain time response of sec ond order system to step input.
(B) Simulation Based Experiments (on Simulation Platform like MATLAB/SCI LAB or Python Programming tool )
1. a) Simulation of a typical second order system and determination of step response and evaluation of time
domain specifications
b) Evaluation of the effect of additional poles and zeroes on time response of second order system
c) Evaluation of effect of pole location on stability
d) Effect of loop gain of a negative feedback system on stability
2. Draw the Root loci for a given transfer function and verification of breakaway point and imaginary axis
crossover point.
3. Obtain the phase margin and gain margin for a given transfer function by drawing bode plots and verify the
same.
4. Draw the Nyquist plot for a given transfer function.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Term work:
Term work shall consist of minimum eight experiments. The distribution of marks shall be as follows:
Experiments Performance :10 marks
Journal :10 marks
Attendance (Theory and Practical) :05 marks
The final certification and acceptance of term work ensures the minimum passin g in the term work.
Oral Examination:
Oral examination w ill be based on entire syllabus of EEC503 : Control Systems
5. Obtain State model from Poles and zero and also from transfer function
6. Determination of step, ramp & impulse response of a state model
Any other experiment based on syllabus which will help students to understand topic / concept.
Note: Students and teachers are encouraged to use the virtual labs w hose links are as given below The remote -
access to Labs in various disciplines of Science and Engineering is available. Students can conduct online
experiments which would help them in learning basic and advanced concepts through remote
experimentation.
Virtual Lab Website Reference
1. http://vlab.co.in/broad -area -electrical -engineering
2. http://vlab.co.in/broad -area -electronics -and-communications
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course
Code Course Name Teaching scheme Credit assigned
EEL504 Professional
Communication &
Ethics-II Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 ⃰ + 2 Hours
(Batch -wise) -- -- 2 -- 02
*Theory class to be conducted for full class.
Course
Rationale This curriculum is designed to build up a professional and ethical approach, effective oral a nd
written communication with enhanced soft skills. Through practical sessions, it augments
student's interactive competence and confidence to respond appropriately and creatively to the
implied challenges of the global Industrial and Corporate requirement s. It further inculcates the
social responsibility of engineers as technical citizens.
Course
Objectives To discern and develop an effective style of writing important technical/business documents.
To investigate possible resources and plan a successfu l job campaign.
To understand the dynamics of professional communication in the form of group discussions,
meetings, etc. required for career enhancement.
To develop creative and impactful presentation skills.
To analyze personal traits, interests, values, aptitudes and skills.
To understand the importance of integrity and develop a personal code of ethics.
Course
Outcomes Upon successful completion of this course, the learner will be able to:
1. Plan and prepare effective business/ technical documen ts which will in turn provide solid
foundation for their future managerial roles.
2. Strategize their personal and professional skills to build a professional image and meet
the demands of the industry.
3. Emerge successful in gro up discussions, meetings and result -oriented agreeable solutions
in group communication situations.
4. Deliver persuasive and professional presentations.
5. Develop creative thinking and interpersonal skills required for effective professional
communicati on.
6. Apply codes of ethical conduct, personal integrity and norms of organizational behaviour.
Module Contents Hours
1 ADVANCED TECHNICAL WRITING :PROJECT/PROBLEM BASED LEARNING (PBL)
1.1 Purpose and Classification of Reports:
Classification on the bas is of:
Subject Matter (Technology, Accounting, Finance, Marketing, etc.)
Time Interval (Periodic, One -time, Special)
Function (Informational, Analytical, etc.)
Physical Factors (Memorandum, Letter, Short & Long) 06 Course
Code Course Name Examination Scheme
Theory
Term
work Pract Oral Internal
Oral Total Internal
Asses sment End
sem Duration
(hrs) Test
1 Test
2 Avg.
EEL504 Professional
Communication
& Ethics -II -- -- -- -- -- 25 -- -- 25 50
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
1.2. Parts of a Long Formal Report:
Prefato ry Parts (Front Matter)
Report Proper (Main Body)
Appended Parts (Back Matter)
1.3. Language and Style of Reports
Tense, Person & Voice of Reports
Numbering Style of Chapters, Sections, Figures, Tables and Equations
Referencing Styles in APA & MLA Format
Proofreading through Plagiarism Checkers
1.4. Definition, Purpose & Types of Proposals
Solicited (in conformance with RFP) & Unsolicited Proposals
Types (Short and Long proposals)
1.5. Parts of a Proposal
Elements
Scope and Limitations
Conclusion
1.6. Tec hnical Paper Writing
Parts of a Technical Paper (Abstract, Introduction, Research Methods, Findings
and Analysis, Discussion, Limitations, Future Scope and References)
Language and Formatting
Referencing in IEEE Format
2 EMPLOYMENT SKILLS
2.1. Cover L etter & Resume
Parts and Content of a Cover Letter
Difference between Bio -data, Resume & CV
Essential Parts of a Resume
Types of Resume (Chronological, Functional & Combination)
2.2 Statement of Purpose
Importance of SOP
Tips for Writing an Effective SOP
2.3 Verbal Aptitude Test
Modelled on CAT, GRE, GMAT exams
2.4. Group Discussions
Purpose of a GD
Parameters of Evaluating a GD
Types of GDs (Normal, Case -based & Role Plays)
GD Etiquettes
2.5. Personal Interviews
Planning and Preparation
Types of Questio ns
Types of Interviews (Structured, Stress, Behavioural, Problem Solving & Case -
based)
Modes of Interviews: Face -to-face (One -to one and Panel) Telephonic, Virtual 06
3 BUSINESS MEETINGS
3.1 Conducting Business Meetings
Types of Meetings
Roles and Resp onsibilities of Chairperson, Secretary and Members
Meeting Etiquette
3.2. Documentation
Notice
Agenda
Minutes 02
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
4 TECHNICAL/ BUSINESS PRESENTATIONS
4.1 Effective Presentation Strategies
Defining Purpose
Analyzing Audience, Location and Event
Gathering, Sel ecting &Arranging Material
Structuring a Presentation
Making Effective Slides
Types of Presentations Aids
Closing a Presentation
Platform skills
4.2 Group Presentations
Sharing Responsibility in a Team
Building the contents and visuals together
Transition Pha ses 02
5 INTERPERSONAL SKILLS
5.1 Interpersonal Skills
Emotional Intelligence
Leadership & Motivation
Conflict Management & Negotiation
Time Management
Assertiveness
Decision Making
5.2 Start -up Skills
Financial Literacy
Risk Assessment
Data Analysis (e.g . Consumer Behaviour, Market Trends, etc.) 08
6 CORPORATE ETHICS
6.1 Intellectual Property Rights
Copyrights
Trademarks
Patents
Industrial Designs
Geographical Indications
Integrated Circuits
Trade Secrets (Undisclosed Information)
6.2 Case Studies
Cases related to Business/ Corporate Ethics 02
List of assignments:
(In the form of Short Notes, Questionnaire/ MCQ Test, Role Play, Case Study, Quiz, etc.)
1. Cover Letter and Resume
2. Short Proposal
3. Meeting Documentation
4. Writing a Technical Paper/ Analyzing a P ublished Technical Paper
5. Writing a SOP
6. IPR
7. Interpersonal Skills
8. Aptitude test (Verbal Ability)
Note:
1. The Main Body of the project/book report should contain minimum 25 pages (excluding Front and Back
matter).
2. The group size for the final report presenta tion should not be less than 5 students or exceed 7 students.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
3. There will be an end –semester presentation based on the book report.
Assessment :
Term Work :
Term work shall consist of minimum 8 experiments.
The distribution of marks for term work shall b e as follows:
Assignment : 10 Marks
Attendance : 5 Marks
Presentation slides : 5 Marks
Book Report (hard copy) : 5 Marks
The final certification and acceptance of term work ensures the satisfactory performance of laboratory work
and minimum passing in the term work.
Internal oral:
Oral Examination will be based on a GD & the Project/Book Report presentation.
Group Discussion : 10 marks
Project Presentation : 10 Marks
Group Dynamics : 5 Marks
Books Recommended:
Textbooks and Reference books:
1. Arms, V. M. (2005). Humanities for the engineering curriculum: With selected chapters from Olsen/Huckin:
Technical writing and professional communication, second edition . Boston, MA: McGraw -Hill.
2. Bovée, C. L., &Thill, J. V. (2021). Business communication today . Upper Saddle River, NJ: Pearson.
3. Butterfield, J. (2017). Verbal communication: Soft skills for a digital workplace . Boston, MA: Cengage
Learning.
4. Masters, L. A., Wallace, H. R., & Harwood, L. (2011). Personal development for life and work . Mason: South -
Western Cengage Learning.
5. Robbins, S. P., Judge, T. A., & Campbell, T. T. (2017). Organizational behaviour . Harlow, England: Pearson.
6. Meenakshi Raman, Sangeeta Sharma (2004) Technical Communica tion, Principles and Practice. Oxford
University Press
7. Archana Ram (2018) Place Mentor, Tests of Aptitude For Placement Readiness. Oxford University Press
8. Sanjay Kumar &PushpLata (2018). Communication Skills a workbook, New Delhi: Oxford University Pr ess.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Course C ode Course Name Teaching scheme (Contact Hours) Credits Assigned
EEM501 Mini Project – 2A Theory Pract./Tut. Theory Pract./Tut. Total
-- 4$ -- 2 2
Course code Course Name Examination Scheme
Theory
Term
Work Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEM501 Mini Project – 2A -- -- -- -- -- 25 25 25
$ indicates work load of Learner (Not Faculty)
Course
Objectives
1. To design and dev elop a moderately complex electrical/electronic/digital circuit with practical
applications.
2. To understand basic concepts of circuit design while developing the project.
3. To enable the students to gain hands -on experience independently proposing and implem enting
the project and thus acquire the necessary confidence to deal with complex
electrical/electronic/digital systems.
Course
Outcomes Upon successful completion of this course, the learner will be able to:
1. Identify problems based on societal /rese arch needs.
2. Apply Knowledge and skill to solve societal problems in a group.
3. Develop interpersonal skills to work as member of a group or leader.
4. Draw the proper inferences from available results through theoretical/ experimental/
simulations.
5. Analyse the impact of solutions in societal and environmental context for sustainable
development.
6. Use standard norms of engineering practices
7. Excel in written and oral communication.
8. Demonstrate capabilities of self -learning in a group, which leads to life -long learning.
9. Demonstrate project management principles during project work
A. Mini Project -Topic Selection and Approval
1. The group may be of maximum FOUR (04) students.
2. Students should propose project ideas & finalize the project idea in consultation with guide/ HOD.
Students should select a problem which addresses some basic home, office or other real life applications.
The mini project must have hardware part. The software part is optional.
3. Students should identify different components/ devices, instrume nts, simulation/emulations software
tools required for the project.
4. Students should submit implementation plan in the form of Gantt/ PERT/ CPM chart, which will cover
weekly activity of project.
5. A Log Book to be prepared by each group to record the work pr ogress in terms of milestones per week by
students. Weekly comment, remarks to be put by guiding faculty.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
B. Mini Project –Execution
i. Design and Fabrication
a. Initial fabrication of the project by students can be done using standard devices/material/softwa re tools to
verify the circuit functionalities Initial project fabrication and testing is expected to be done by
soldering/assembling on general purpose PCB/ Bakelite boards or suitable platforms required for the
electrical/electronic/digital components. D iscourage the use of breadboards.
b. If essential, use of a simulation/ emulation software tools to test and verify the performance of the circuit
should be encouraged.
c. Students should prepare the proper drawings (electrical/ mechanical), schematics/ layouts of the project.
d. For final implementation of the circuit, preparation of PCB (if any required) using suitable CAD tools and
fabricating the same in the lab is expected.
ii. Devices/ Components/ Systems to be Used:
Students are encouraged to use passive comp onents like resistors, capacitors, inductors etc. If any specialize
inductor is not readily available, the fabrication of the same in the lab should be encouraged. Other
components like: Transistors, diodes, voltage regulators, logic gates, Op -amps, genera l purpose
microcontroller, DC motors/ AC motors, sensors, actuators, relays etc. (Students may add more components
as per the requirement of project).
iii. Testing and analysis of the Project
Students should test the circuit using suitable laboratory equipmen ts like power supply, multi -meter, CRO,
DSO etc. In case of any debugging requirement, students should record the problems faced during the testing
and solutions sought after for the fault in the circuit.
All the testing results must be well documented in the final project report verifying the functionalities of the
propose project.
iv. Use of Reference Material/Literature :
Students are advised to refer Application Notes, research publications & data sheets of various
electrical/electronic/digital devices fr om Texas Instruments, Microchips, International Rectifiers, ST
Microelectronics, Philips, NXP and many other manufacturers.
C. Project Report Format:
Mini Project report should include circuit diagram, operation, application, design details, testing, wave forms
(if applicable) references, simulation results and final prepared PCB image, conclusion, etc. Project report
should include report of all above steps listed in (2) and the conclusion.
Note: -
It is expected that the department should organise some o f the guidance expert lectures / video lectures/ courses/
webinars/ workshops etc. for the students at the appropriate timing during the Mini Project practical slots on
following topics:
1) Understanding passive components viz. resistors, capacitors and induc tors from practical point of view:
types/ varieties, device packages, applications and cost.
2) Understanding semiconductor components viz. diodes, BJT and JFET/MOSFETs from practical point of view:
types/ varieties, device packages, applications and cost.
3) Design principles of simple electrical / electronic circuits with some examples.
4) Selection of switches and circuit protection components.
5) Selection and sizing of wires and conductors.
6) Soldering Practice.
7) Heat -sinking and Enclosure design concepts
8) Overall w orkmanship while working on the project fabrication.
9) Use of different software tools for design and development of circuits
10) Use of standard as well as some of the advanced laboratory equipments needed for testing of such
projects
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Application Domains:
List of key application domains from where students are encouraged to derive Mini Projects topics:
1) Smart Agriculture solutions
2) Power converter applications in various Applications
3) IoT based applications in power systems
4) AI/ML applications in disaster managem ent
5) Renewable Energy
6) Energy Conservation
7) Energy Storage
8) Battery Charging and Protection
9) Fire Safety
10) Electrical System Protection
11) Lighting Control
12) Wireless Power Transfer
13) Electrical Components Testing
14) Electrical Parameters Measurement
15) Non-conventional Electricity Generation
16) Laboratory Equipments
17) E-Mobility / Electric Vehicles
18) Video Surveillance Systems
19) Robotics for Hazardous applications
20) Waste Management System
21) Smart City Solutions
22) Smart Classrooms and learning Solutions
23) Design of Electrical Equip ment
24) PLC based automation system
25) Power system Monitoring System (EMS)
It is every much expected that the complexity of the Mini Project 2A/ 2B should be increased compared to the
selection of projects during Mini Project 1A/1B. Also based on the subjects l earned in Sem . III and Sem. IV the
broader area inclusive of the concepts learned must be selected. Students can identify the mini project topics
either from above suggested domains or any other relevant electrical engineering domains. The inter -disciplina ry
nature of the project is also desirable .
Guidelines for Assessment of Mini Project:
Term Work
The review/ progress monitoring committee shall be constituted by head of departments of each institute.
The progress of mini project to be evaluated on continu ous basis, minimum two reviews in each semester.
In continuous assessment focus shall also be on each individual student, assessment based on individual’s
contribution in group activity, their understanding and response to questions.
Distribution of Term work marks for both semesters shall be as below;
o Marks awarded by guide/supervisor based on log book : 10
o Marks awarded by review committee : 10
o Quality of Project report : 05
Review/progress monitoring committee may consider following points for assessment based on either one year or
half year project as mentioned in general guidelines.
One-year Mini Project:
In first semester entire theoretical solution sh all be ready, including components/system selection and
cost analysis. Two reviews will be conducted based on presentation given by students group.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
o First shall be for finalization of problem
o Second shall be on finalization of proposed solution of problem .
In second semester expected work shall be procurement of components /systems, building of working
prototype, testing and validation of results based on work completed in an earlier semester.
o First review is based on readiness of building working protot ype to be conducted.
o Second review shall be based on poster presentation cum demonstration of working model in last
month of the said semester.
Half-year Mini Project:
In this case in one semester students’ group shall complete project in all aspects i ncluding,
o Identification of need/problem
o Proposed final solution
o Procurement of components/systems
o Building prototype and testing
Two reviews will be conducted for continuous assessment,
o First shall be for finalization of problem and proposed solutio n
o Second shall be for implementation and testing of solution.
Assessment criteria of Mini Project.
Mini Project shall be assessed based on following criteria;
1. Quality of survey/ need identification
2. Clarity of Problem definition based on need.
3. Innova tiveness in solutions
4. Feasibility of proposed problem solutions and selection of best solution
5. Cost effectiveness
6. Societal impact
7. Innovativeness
8. Cost effectiveness and Societal impact
9. Full functioning of working model as per stated requirements
10. Effective use of skill sets
11. Effective use of standard engineering norms
12. Contribution of an individual’s as member or leader
13. Clarity in written and oral communication
In one year, project, first semester evaluation may be based on first six criteria’s and remaining may be used
for second semester evaluation of performance of students in mini project.
In case of half year project all criteria’s in generic may be considered for evaluation of performance of students
in mini project.
Guidelines for Asses smen t of Mini Project Oral Examination:
Report should be prepared as per the guidelines issued by the University of Mumbai.
Mini Project shall be assessed through a presentation and demonstration of working model by the student
project group to a panel of In ternal and External Examiners preferably from industry or research
organizations having experience of more than five years approved by head of Institution.
Students shall be motivated to publish a paper based on the work i n Conferences/students competitio ns.
Oral Examination:
Mini Project shall be ass essed based on following points:
1. Quality of problem and Clarity
2. Innovativeness in solutions
3. Cost effectiveness and Societal impact
4. Full functioning of working model as per stated requirements
5. Effective use of skill sets
6. Effective use of standard engineering norms
7. Contribution of an individual’s as member or leader
8. Clarity in written and oral communication
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Reference Books:
1. P. Horowitz and W. Hill, “The Art of Electronics”, 3rd Edition, Cambridge Uni versity Press, 2015
2. R. S. Khandpur, “Printed Circuit Board”, McGraw -Hill Education; 1st edition, 2005.
3. Simon Monk, “Hacking Electronic: Learning Arduino and Raspberry Pi”, McGraw -Hill Education TAB; 2
edition (September 28, 2017).
4. Matthew Scarpino, Design ing Circuit Boards with EAGLE: Make High -Quality PCBs at Low Cost, 1st Edition
Prentice Hall.
5. P. Horowitz and W. Hill, The Art of Electronics, 3 Edition, Cambridge University Press.
6. Archambeault and D. James, PCB Design for Real -World EMI Control, Spring er Publications
7. Mitzner, Kraig, “Complete PCB design using OrCAD Capture and PCB”, Elsevier, 2009
8. Peter Dalmaris, “Kicad Like a Pro”, Tech exploration
9. Charles Platt, “Encyclopedia of Electronic Components – Vol-1: Power, electromagnetism, and discrete
semiconductors. ”, Maker Media, 2012
10. Charles Platt, “Encyclopedia of Electronic Components – Vol-2: Integrated circuits, light sources, sound
sources, heat sources, and high frequency sources. ”, Maker Media, 2015
Suggested Software tools:
1. LTspice: https://www.analog.com/en/design -center/design -tools -and-calculators/ltspice -simulator.html#
2. Eagle : https://www.autodesk.in/products/eagle/overview
3. OrCAD: https://www.orcad.com/
4. Multisim : https://www.multisim.com/
5. Webbench: http://www.ti.com/design -resources/design -tools -simulation/webench -power -designer.html
6. Tinkercad : https://www.tinkercad.com/
7. Raspbian OS: https://www.raspberrypi.org/downloads
8. Arduino IDE: https://www.arduino.cc/en/main/software
Online Repository:
1. https://www.electronicsforu.com
2. https://circuitdigest.com
3. https://www.electronicshub.org
4. Github
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code
Course Name Teaching Scheme (Contact Hours) Credits Assigned
Theory Tutorial Theory Tutorial Total
EEC601 Power System Protection
and Switchgear 3 - 3 - 3
Cour se
Code
Course Name Examination Scheme
Theory
Term
Work
Total Internal Assessment End
Sem.
Exam Exam
Duration
(Hrs.) Test 1 Test 2 Avg.
EEC601 Power System Protection
and Switchgear 20 20 20 80 03 - 100
Course
Objectives • To impart basic knowledge of power system protection, substation equipment and
protection schemes.
Course
Outcomes Upon successful completion of this course, the learner will be able to :
1. To select the appropriate switching/protecting device for substations.
2. To discriminate between the application of circuit breaker and fuses as a protective device.
3. To understand the basic concept of relay, types of relay and their applications in power system.
4. To select the specific protection required for different components of power system according
to the type of fault.
5. To apply the specific protection provided for different types of transmission lines.
Module Contents Hours
1 Substation Equipment and switching devices
Substation Equipment: Instrument Transformers: Role of instrument transformers in
measuring and protection, difference between measuring and protection CTs, selection
of technically suitable instrument transformers;
Switchgear -Definition, Types, Location of switchgear in typical power system, single lin e
diagram to show the measuring and protection scheme
Switching Devices - Isolator & Earthing switch (Requirements & definitions, types and
construction, Pantograph Isolators, Ratings), Load break switches - Ratings and
applications; Contactors - Basic workin g principle, Terms & Definitions, applications.
03
2 Circuit Breakers and Fuses:
Circuit Breaker: Arc initiation, arc quenching principles, Re -striking voltage, RRRV,
Recovery voltage, Types of Circuit Breakers: For LV application - MCB, MCCB, ELCB, ai r
circuit breakers. For HV application - SF6 circuit breakers, vacuum circuit breakers
(working principle, Construction, operating mechanisms, ratings & applications),
Mechanical life, Electrical life and testing of circuit breakers. Principle and applicat ions of
LV and HV DC circuit breakers
Fuses & their applications -Introduction, classification, working principle and applications
of re -wirable and HRC fuses, Expulsion and drop out fuses, Fusing factor, selection of fuse
link and cut off characteristics
10
3 Introduction to Protective relaying:
Shunt & Series Faults, causes and Effects of faults, Importance of protective relaying,
Protective zones, primary & Back -up protection, Different types of backup protection,
desirable qualities of protective relaying, PSM & TSM(Importance, Different types of Time -
current characteristics and application), working principle of Electromagnetic Induction
disc Relays, Thermal, bimetal relays, Frequency relays, under/over voltage relays, DC
relays,
09
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Different Princ iples of protection - Over current & earth fault (non - directional &
directional types), differential protection(current and voltage type), distance protection
(Working Principle and application of Impedance relay, Causes and remedies of Over
reach -under r each, Reactance and Mho relay, Power swing blocking relay).
4 Protection Schemes Provided for major Apparatus:
Generators - Stator side (Differential, Restricted Earth fault, protection for 100% winding,
Negative phase sequence, Reverse power, turn -turn fault), Rotor side (Field suppression,
field failure, Earth fault, turn to turn fault)
Transformers -Differential protection for star delta Transformer, Harmonic restraint relay,
REF protection, Protection provided for incipient faults (Gas actuated rel ay).
Induction motors - Protection of motor against over load, short circuit, earth fault, single
phasing, unbalance, locked rotor, phase reversal, under voltage, winding temperature,
Protection co -ordination
06
5 Protection of Transmission Lines:
Feeder protection - Time grading, current grading, combined time & current grading
protection provided for Radial, Ring Main, Parallel, T - Feeder.
Bus Zone Protection - Differential protection provided for different types of bus zones.
LV, MV, HV Transmission Lines - Protection provided by over current, earth fault,
Differential and Stepped distance protection.
EHV & UHV Transmission lines - Type and nature of faults, Need for auto -reclosure
schemes, Carrier aided distance protection (Directional comparison me thod), Power Line
Carrier Current protection (Phase comparison method). Introduction to the concept of
Islanding
06
6 Introduction to Static & Numerical Relays:
Static Relays - Introduction, Definition, Advantages and Disadvantages, Application of op -
amps, logic gates, DSP, in static/ digital Relays. Relays as comparators (Amplitude &
phase), Numerical Relays - Introduction, Block diagram of numerical relay, Signal sampling,
Anti –Aliasing Filter, Introduction to the concept of Phase Measurement Unit
05
Books Recommended:
Text Books:
1. Switchgear & Protection by Sunil.S.Rao, Khanna Publications
2. Power system Protection & Switchgear by Badriram Vishwakarma, TMH
3. Power System Protection And Switchgear by Bhuvanesh A O, Nirmal CN, Rashesh PM, Vijay HM, Mc
Graw Hill
Reference Books:
1. Fundamentals of protection by Paithanker & Bhide.S.R, P.H.I
2. Static Relays by Madhava Rao, TMH
3. A text book on Power System Engineering by Soni, Gupta, Bhatnagar & Chakraborthi, Dhanpat Rai & Co
4. Protective Relaying by Lewis Black burn, Thomas.J.Domin
5. Power System Protection by P.M. Anderson, Wiley Interscience
6. Modern Power System Protection – Divyesh Oza, TMH Publication
Website Reference / Video Courses:
1. NPTEL Course: Power System Protection By Prof. S.A. Soman, Dept. of Electric al Engineering, IIT Bombay :-
Web link - https://nptel.ac.in/courses/108/101/108101039/
2. NPTEL Course: Power System Protection and Switchgear By Prof. Bhaveshkumar Bhalja , Dept. of Electrical
Engg , IIT Roorkee :- Web link - https://nptel.ac.in/courses/108/107 /108107167/
3. NPTEL Course: Power System Protection By Prof. Ashok Kumar Pradhan , Dept. of Electrical Engineering, IIT
Kharagpur :- Web link - https://nptel.ac.in/courses/108/105/108105167/
Page 45
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining question will be randomly selected from all the modules.
Page 46
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code
Course Name Teaching Scheme (Contact Hours) Credits Assigned
Theory Tutorial Theory Tutorial Total
EEC602 Microcontroller
Applications 3 - 3 - 3
Course
Code
Course Name Examination Scheme
Theory
Term
Work
Pract/
Oral
Total Internal Assessment End
Sem.
Exam Exam
Duration
(Hrs.) Test 1 Test 2 Avg.
EEC602 Microcontroller
Applications
20
20
20
80
03
-
-
100
Course
Objectives 1. To understand the features and architecture of PIC 18 microcontroller.
2. To introduce assembly programming knowledge for PIC 18 microcontroller.
3. To impart embedded programming knowledge for PIC 18 microcontroller using C.
4. To introduce various applications using microcontroller based system
Course
Outcomes Upon successful completion of this course, the learner will be ab le to:
1. To analyse the difference between microprocessor and microcontroller based systems.
2. To write, debug and execute the software programs for internal peripheral devices of
microcontroller.
3. To write, debug and execute the software programs for external peripheral devices for
microcontroller based systems.
4. To design and implement the peripheral devices interfacing with microcontroller
Module Contents Hours
1. Introduction to Microcontroller
Block diagram of generic microcontroller, Microcontroller versu s Microprocessor, A brief
history of PIC microcontroller, Overview of PIC 18 family and features, Internal Bus
structure of PIC microcontroller, Clock frequency, machine cycle and instruction cycle.
05
2. PIC18F Programming Model and Instruction Set
PIC18 microcontroller programming model, Bus architecture, program memory and data
memory organization, Special Function Registers (SFRs), General Purpose Registers
(GPRs)
CPU registers: Working Register (Wreg), Status Register, Bank Select Register (BSR),
Instruction Decoder
Memory Pointers: Program ROM and Program Counter (PC), Data ROM and Table Pointer
(TBLPTR), File memory and File Select Register (FSR), Stack and Stack Pointer (STKPTR)
PIC 18 internal Architecture: ALU, EEPROM, RAM, IO Ports, Timer, ADC , Serial port, CCP,
Pipelining. (conceptual overview only)
Instructions and Assembly Programs: Instruction Set, Instruction formats, Addressing
modes, Assembler Directives, Assembly programs. (Assembly programs are restricted to
basic arithmetic, logical a nd data transfer operations only)
08
3. PIC 18 Support Devices
Timer Module: Basic Concept of Timers and counters, Timer Registers, Control Registers,
8 bit and 16 bit operation (only for Timer 0), CCP module (Capture, Compare and PWM),
Watch dog Tim er.
ADC module: ADC Features, Block diagram of ADC module, ADC Registers, ADCON0,
ADCON1 and ADCON2.
Interrupt Module: Basic concept of Interrupt, PIC 18 Interrupts, Interrupt versus polling,
Interrupt sources, Interrupt vector, Interrupt service routine, Interrupt process, RCON,
INTCON, IPR1 and PIE1.
06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
4. Parallel Ports and Serial Communication
IO PORT Module: Basic concept of I/O interfacing, PORT Registers, TRIS Registers, LAT
Registers, Simple input /output peripheral interfacing (switches & LEDs ).
Serial communication: Basics of serial communication, Data framing, USART module,
SPBRG, TXREG, RCREG, TXSTA, RCSTA, PIR1
06
5. PIC Programming in C
IO programming: Byte size IO, Bit addressable IO.
Timer programming: Generating delay, generating squ are wave. (for Timer0 using
Interrupt based programming only)
Serial port programming: Transmit data serially, Receive data serially. (Interrupt based
programming only)
06
6. Microcontroller Applications
Interfacing matrix keyboard and Seven segments LE D display, LCD Interfacing, ADC
Interfacing, Traffic signal controller, DC motor interfacing, Stepper motor interfacing,
PWM signal generation.
08
Text/Reference Books: -
1. Ramesh Gaonkar, “Fundamentals of Microcontrollers and Applications in Embedded Sys tems (with the PIC
18 Microcontroller Family)”, Penram International publications (Ind) Pvt. Ltd.
2. Ali Mazidi, Rolind D Mckinlay and Danny Causey , “PIC Microcontroller and Embedded Systems”, Pearson
Education ltd., 2015
3. Robert B. Reese, “Microcontroller from Assembly Language to C using PIC18FXX2”, Davinici Engineering
press.
4. Han Way Huang, “PIC Microcontroller: An Introduction to Software and Hardware Interfacing”, Cengage
Learning, 2005.
Website Reference / Video Courses:
1. NPTEL Course: Microprocessors And Microcontrollers By Prof. Santanu Chattopadhyay , Dept. of Electrical
Engineering, IIT Kharagpur :- Web link - https://nptel.ac.in/courses/108/105/108105102/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory c lass test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 wi ll be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be
asked.
4. Remaining question will be randomly selected from all the modules.
Page 48
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
code Course Name Teaching scheme
(Contact Hours ) Credits Assigned
EEC603 Control System Design Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course
Code Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEC603 Control System Design 20 20 20 80 3 - - 100
Course
Objectives
1. To establish a quantitative foundation to the design and analysis of Control systems.
2. To impart knowledge and skill on compensator design.
3. To study basics of d igital control system and design of digital compensator.
4. To understand the concept of state –space analysis, to design the compensator in time and
frequency domain, to design the PID compensator.
Course
Outcomes
Upon successful completion of this cou rse, the learner will be able to
1. Define fundamental control system design specifications and basic principles of controller design
2. Understand the basic design of various compensators.
3. Design compensators using root locus techniques.
4. Design modern controlle rs based on the state space techniques,
5. Recognize the importance of observability and controllability for system design.
Module Contents Hours
1. Introduction to the Compensator:
Basic concept of compensator design, its requirement, cascade compensator, feedback
compensator, gain compensation, lag, lead and lag -lead compensator, proportional,
derivative, integral Compensation, physical realization of compensator with passive and
active components, basic block diagrams of a compensated closed loop control system.
03
2. Design of Compensators using Root Locus Technique:
Introduction, improving steady state error by gain compensation, transient response
improvement by cascade compensation, improving steady state and transient response.
08
3. Design of Com pensators using Frequency Response Technique (Bode Plot):
Introduction, Relation between closed -loop time response parameters of peak time,
settling time, and percent overshoot with the open -loop frequency response
parameters, transient response improveme nt by gain adjustment, Lag compensation,
Lead compensation, Lag -lead compensation 08
4. Design of Compensators using State variable approach:
Introduction, pole placement topology, controller design by pole placement topology in
phase variable form, contro llability, controllability matrix, controllability by inspection,
alternative approach to controller design, controller design by transformation.
Introduction to Observer / estimator, observability, , observability matrix, observability
by inspection, obse rver design by pole placement, alternative approach to Observer
design. Steady state error design using integral control 07
5. Digital control System:
Introduction, advantage of digital control, components of digital control system,
derivation of digital/ pulse transfer function, block diagram reduction, stability of digital
system on Z -plane, bilinear transformation, steady state error and error constants 06
6. Design of Digital Compensators: 07
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Transient response on the Z -plane, gain design on Z plane for tr ansient response using
root locus, stability design by root locus, cascade compensation (design of digital lead,
lag and lag -lead compensator)of digital system using s -plane, implementing the digital
compensator.
Text Books: -
1. Control system engineerin g by Norman Nise 2nd edition
2. Digital Control Systems by Benjamin C. Kuo, Oxford series 2nd Edition
3. Contro l Engineering: An Introductory C ourse by Wilkie J., Johnson M., Katebi R., Palgrave MacMillan.
4. Industrial Control Electronics: Devices, Systems and App lications by Bartelt, Delmar Thomson Learning, 1st
edition
Reference Books: -
1. Modern control Engineering by Richard C Dorf, SH Bishop, & Wesley edition, Eighth Edition
2. Linear Control system Analysis and design with MATLAB, by J.J. Azzo, C. H. Houpis, S.N. Sheldon, Marcel
Dekkar, ISBN 0824740386
3. Control System Engineering, Shivanagraju s. Devi L., New age International latest edition
4. Control System engineering by Nagrath and Gopal, 5th to latest edition , Wiley Eastern
5. Modern control system engineering by K. Ogata, printice Hall.
6. Automatic control systems, Basic analysis and Design, William A. Wolovich, Oxford
7. Process Control principles and applications, Surekha Bharot, Oxford Higher education
Website Reference / Video Courses:
1. NPTEL Course: Advanced Linear C ontinuous Control Systems By Prof. Yogesh Hote , Dept. of Electrical
Engineering, IIT Roorkee :- Web link - https://nptel.ac.in/courses/108/107/108107115/
2. NPTEL Course: Industrial Instrumentation By Prof. Prof. S. Mukhopadhyay and Prof. S.Sen , IIT K haragpur :-
Web link - https://nptel.ac.in/courses/108/105/108105062/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules
Page 50
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code Course Name Teaching scheme ( Contact Hours) Credits Assigned
EEC604 Signals and Systems Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course
Code Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEC604 Signals and Systems 20 20 20 80 3 - - 100
Course
Objectives
1. To imp art knowledge on continuous and discrete time signals.
2. To understand the basic properties of signals & systems
3. To know the methods of characterization of LTI systems in time domain
4. To analyze discrete time signals and system in the Fourier and Z transform domain
5. Understand the design of various types of digital filters and implement them using various
implementation structures
Course
Outcomes Upon successful completion of this course, the learner will be able to
1. Discriminate continuous and discrete time s ignals and systems.
2. Understand the transformation of discrete time signal to Z domain.
3. Analyse frequency response of systems using Z domain.
4. Design, implementation, analysis and comparison of digital filters for processing of discrete
time signals
Module Contents Hours
1. Introduction - Classification of Signals and Systems:
Definitions of signal and system. Standard signals - Step, Ramp, Pulse, impulse, Real and
complex exponentials and Sinusoids , Classification of signals – Continuous time (CT) and
Discret e Time (DT) signals, Periodic & Aperiodic signals, Deterministic & Random signals,
Even and odd, Energy & Power signals , Classification of systems - Linear/ Non -Linear, Time -
Variant/Invariant , Causal /Anti causal, stable/unstable, Memory/ Memory less Syste m
(static and dynamic), Sampling Theorem (Derivation is not Required).
Basic operations on signals -Folding, Scaling and Time shifting). Convolution in DT domain
(Matr ix Method only) 07
2. Z-Transform
Z-Transform of bilateral signal, Definition of ROC, Properties of ROC, Properties of Z -
transform, Inverse Z -Transform (only partial fraction). 05
3. Frequency Response & Fourier Series
Pole -zero plot in DT domain, Minimum ph ase, Maximum phase, Mixed phase and Linear,
Phase System based on location of zeros, Low pass, high pass, Band pass and band reject
system based on pass band frequency, Formation of Difference Equation, Solution of
difference Equation (with & without initi al Conditions), Zero input, zero state and Total
Response of the system, Magnitude and phase response (only Analytical Method). ,
Introduction to Fourier Series: Representation of continuous time Periodic Signals,
convergence of the Fourier Series, Propert ies of continuous time Fourier Series, Fourier
Series representation of discrete time periodic signals, Properties of discrete time Fourier
Series 10
4. Discrete and Fast Fourier Transform
DTFT, DFT & IDFT (Only Matrix Method), Properties of DFT, DIT FFT Al gorithm (Radix -2) 06
5. Design of FIR System 06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Introduction to FIR System, Group Delay, phase Delay, Condition for Linear phase FIR
system, Window Technique (only Rectangular window function, Hamming Window
function)
6. Design of IIR System
Introduction to IIR System & Bilinear Transformation, Digital Butterworth Filter design
using Bilinear Transformation 05
Text Books: -
1. Salivahan S.,” Digital Signal Processing”, TMH Publication,2012
2. Oppenhein & Schafer,” Discrete Time Signal Processing,” PHI Publication 1989.
3. Haykin S and Van Veen B,” Signal and System”, Wiley Publication, 2nd Ed.
4. Linder D.K.,” Introduction to Signal & System,” McGraw Hill International, 1999.
Reference Books: -.
1. Proakis & Manolakis,” Digital Signal Processing”, PHI Publication, 1995.
2. Mitra S.K.,” Digital Signal Processing,” TMH Publication, 2001.
3. Digital Signal Processing: A Practitioner's Approach, Kaluri V. Rangarao, Ranjan K. Malli
November 2006, John Wiley.
4. Li Tan,”Digital Signal Processing, Fundamental & Application”, Elsevier Pub lisher, Academic Press
5. DSP – A Practical Approach – Emmanuel C. Ifeacher, Barrie. W. Jervis, 2 ed., Pearson Education
Website Reference / Video Courses:
1. NPTEL Course: Principles of Signals And Systems By Prof. Ravindra Arora , Dept. of Electrical Engineer ing, IIT
Kanpur: - Web link - https://nptel.ac.in/courses/108/104/108104100/
2. NPTEL Course: Signals And Systems By Prof. Kushal K. Shah, Dept. of Electrical Engineering, IISER Bhopal : -
Web link - https://nptel.ac.in/courses/108/106/108106163/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules
Page 52
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELEC TRICAL ENGINEERING SEM -VI
Course
code Course Name Teaching scheme
(Contact Hours) Credits Assigned
EEDO6011 Special Electrical
Machines Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course
code Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO6011 Special Electrical
Machines 20 20 20 80 3 - - 100
Course
Objectives To impart knowledge on special electrical machines and its control
Course
Outcomes
Upon successful completion of this cou rse, the learner will be able:
1. To exemplify the working of Stepper motor and its control
2. To demonstrate the functioning of SRM motor and its control
3. To illustrate the working of BLDC motor and its control
4. To illustrate the operational features of PMSM motor and its control
5. To illustrate the operational features of Synchronous reluctance motor and its control
6. To illustrate the working of Linear motors
Module Contents Hours
1 Stepper moto r and its Control :
Features, construction, application and working of Stepper motor
Characteristics – Open Loop and Closed Loop Control – Control Strategies -Power
Converter Circuit –DSP/ Microcontroller based Control 07
2 Switched reluctance Motor and i ts Control:
Features, construction, application and working of Switched Reluctance motor; Open
Loop and Closed Loop Control - Control Strategies - Power Converter Circuit –DSP/
Microcontroller based Control – Sensor less control 07
3 Brushless DC Machines and its control:
Brushless DC Machines Construction and working principle, Equivalent magnetic circuit,
Type of converter and speed control, Comparison between the axial and radial
permanent magnet motors, Applications.
Characteristics – Open Loop and Clo sed Loop Control – Control Strategies - Power
Converter Circuit –DSP/ Microcontroller based Control 07
4 Permanent Magnet Synchronous Machine and its control:
Features, construction , application and working of PMSM, Characteristics – Open Loop
and Clos ed Loop Control – Control Strategies - Power Converter Circuit –DSP/
Microcontroller based Control 07
5. Synchronous Reluctance Motor and its control
Construction, Working, Phasor Diagram, Torque Equation, Control - Direct Axis Current
Control, Fast Torqu e Response Control, Advantages 06
6. Linear Induction Machine
Construction, Types, Working, Feature, Thrust Equation, Equivalent circuit,
Characteristics, Control, Application 05
Books Recommended:
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Text Books:
1. E. G. Janardanan ― Special Electrical Mac hine PHI, publication
2. G. K. Dubey - Fundamentals of Electrical Drives, CRC press 2002 - Technology & Engineering
3. K. Venkataratnam - Special Electric Machines, Universities Press, Apr-2009 - Technology & Engineering
Reference Books :
1. D. C. Hanselman ― Brushless Permanent -Magnet Motor Design —Eman Press LLC
2. R. Krishnan, SWITCHED RELUCTANCE MOTOR DRIVES Modeling, Simulation, Analysis, Design, and
Applications, CRC Press.
3. M. Ramamoorty, O. Chandra Sekhar―Electrical Machines - PHI publicat ion
4. R Krishnan ― Permanent Magnet Synchronous and Brushless DC Motor Drives —CRC press
Website Reference / Video Courses:
1. NPTEL Course: Advanced Electric Drives By Dr. S.P. Das, Department of Electrical Engineering, IIT Kanpur :-
Web link - https://nptel.ac. in/courses/108/104/108104011/
2. NPTEL Course: Fundamentals of Electric Drives By Dr. S.P. Das, Department of Electrical Engineering, IIT
Kanpur :- Web link - https://nptel.ac.in/courses/108/104/108104140/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on l ive problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules
Page 54
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEDO6012 Electric Traction Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course
code Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO6012 Electric Traction 20 20 20 80 3 - - 100
Course
Objectives To impart knowledge of principles of electrical traction
To explore various electrical subsystems of traction
To increase the awareness of latest developments in electric traction systems
Course
Outcomes
Upon successful completion of this course, the learner will be able:
1. To illustrate the basics as well as the state of the art of electrical traction systems and
subsystems .
2. To understand traction mechanics and different factors contributing to the traction.
3. To illustrate and analyse the performance of various traction motors and drives
4. To explain the traction power Supply a rrangement and its protection aspects.
5. To understan d the design requirements of the overhead equipments
6. To demonstrate the functioning of railway signaling system
Module Contents Hours
1 Introduction to Electric Traction:
Requirements of Ideal Traction Systems, the Indian Scenario of Electric traction, Present day
State of art Electric traction as a Viable Transport Strategy, Advantages of Electric Traction
over ot her systems of traction, Ideal c hoice of traction system, Power supply systems for
Electric Traction, DC systems, Single phase ac system and three phase ac systems, Kando
systems, Latest Developments in 3phase with special reference to locomotives, EMUs and
Metro stock, Role of Battery banks in Traction, types and maintenance. 04
2. Traction Mechanics:
Types of services, Speed -Time Curve, Trap ezoidal, Quadrilateral Speed -Time Curve,
Mechanics of train movement, Different Speed - time characteristics for train movement,
Requirement of tractive effort and tractive effort produced, Train resistance, Power output
and energy output from driving axle s, Specific energy consumption & Factors affecting SEC,
Adhesion & Coefficient of adhesion, Concept of Weight Transfer and weight transfer due to
torque exerted by Traction motor, Influence of Electrical parts on Co -efficient of adhesion,
wheel slip detect ion device (Numericals) 08
3. Traction motor and Drives :
Type of traction motor best suited for traction duties, Available motor characteristics and
their suitability for traction duties, speed control methods, Braking methods, special
Emphasis and techni ques of regenerative braking, Optimization of design and construction
features for improved power to weight ratio, Power Factor and Harmonics, Tractive Effort
and Drive Ratings, Important Features of Traction Drives, conventional DC and AC Traction
drives , Semiconductor/IGBT based Converter Controlled Drives, DC Traction using Chopper
Controlled Drives, AC Traction employing Poly -phase motors, Traction control of DC
locomotives and EMU's, Traction control system of AC locomotives, Control gear, PWM
control of induction motors, Power & Auxiliary circuit equipment (Other than traction 10
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
motors), Linear Induction motors, introduction to Maglev Technology.
4. Power Supply A rrangement and Protection:
Traction substation, spacing and location of Traction subst ations, Major equipment at
traction substation, selection and sizing of major equipment like transformer and
Switchgear, Types of protection provided for Transformer and overhead lines, surge
protection, maximum demand and load sharing between substations , sectionalizing
paralleling post and feeder posts, Booster transformers, Return Conductor, 2X25KV AC
system, controlling/monitoring, Railway SCADA systems, Train lighting and Air -conditioning 07
5. Overhead Equipment and Track circuits:
Design requirem ent of catenary wire, contact wire, Dropper, Height, span length, Automatic
weight tensioning, section insulator, overlap, Different techniques of current collection
(overhead and underground systems), neutral section, overhead crossing of power lines,
Protection. 05
6. Railway Signaling:
Block Section Concept, AC/DC Track Circuits, Interlocking Principle, Train speed and
signaling, Solid state Interlocking, Automatic Warning Systems, CAB signaling, Signaling level
crossing. Permissible limit of EMI and EM C, Permissible capacitively -coupled current,
Coupling between circuits, conductive coupling, Electrostatic induction. 05
Textbook and Reference Books
1. Modern Electric traction by H.Partab :
2. Electric Traction – Motive Power and Energie Supply by Andreas St eimel, Oldenbourg Industrieverlag
GmbH, 2008
3. Electrical Railway Transportation Systems by Morris Brenna, Federica Foiadelli and Dario Zaninelli, IEEE
Press and Wiley, 2018
4. Power Electronics and Electric Drives for Traction Applications Edited by Gonzalo Ab ad, Wiley, 2017
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selecte d from all the modules.
Page 56
University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course C ode Course Name Teaching Scheme (Contact Hours) Credit Assigned
Theory Practical Theory Practical Total
EEDO6013 High Voltage
Engineering 3 - 3 3
Course C ode Course Name Examination S cheme
Total Theory Practical
Internal Assessment End
Sem.
Exam Term
work Pract. &
Oral Oral
Test 1 Test 2 Avg
EEDO6013 High Voltage
Engineering 20 20 20 80 - - - 100
Course
Objectives 1. To understand various breakdown processes in solid , liquid and gaseous insulating
materials.
2. To impart the knowledge of Generation of high voltage DC, AC and Impulse voltages and
currents.
3. To impart the knowledge of Testing and Measurement of high voltage DC, AC and
Impulse voltages and currents.
4. To un derstand the d esign and layout of H V Laboratories
Course
outcomes Upon successful completion of this cou rse, the learner will be able:
1. To know the fundamentals properties of the materials and their failure mechanisms to get
appropriate and optimal de sign.
2. To explain and calculate the generation and measurement of High DC, AC and Impulse
voltages and currents .
3. To understand testing of High voltage power apparatus.
4. To illustrate the major requirements in design of HV Laboratories.
Module Contents Hours
1 Electrostatic Fields, Their Control and Estimation:
Electric field Stress, its control and Estimation, Numerical methods – Finite difference,
Finite Element and Charge simulation method for estimation of Electric Field. Surge
voltage, their distri bution and control 04
2 Conduction and Breakdown in Air and Other Gaseous Dielectrics:
Gases as insulating media, Collision Processes, Ionization process in gas, Townsend’s
Theory, current growth equation in presence of primary and secondary ionization
processes, Townsend’s criterion for breakdown in electronegative gases, Limitation of
Townsend’s theory, Panchen’s law, Breakdown in non -uniform fields and corona
discharges.
Streamer mechanism of breakdown, Post -breakdown phenomenon and application.
Practical considerations in using gas for insulation purposes.
(Numerical on Townsend’s theory and Paschen’s law) 07
3 Breakdown in Liquid and Solid Dielectrics:
Liquid Dielectrics, Conduction and breakdown in pure liquids, Conduction and
breakdown in comme rcial liquids: Suspended Particle Theory, Cavitations and bubble
Theory.
Solid dielectrics used in practice, Intrinsic, Electro -mechanical and Thermal
breakdown, Breakdown o f solid dielectrics in practice, d ue to chemical,
electrochemical deterioration, t reeing , tracking, Internal discharges.
Breakdown of composite insulation, Application of insulating materials in electrical
power apparatus, electronic equipment’s. 06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
4 Generation & Measurement of High Voltage and Currents:
Generation of high voltage a nd currents: Generation of high DC voltages by rectifier,
Voltage doublers and multiplier circuits.
Electrostatic machines, Generation of high AC voltage – Cascading of transformers,
series and parallel Resonance transformer (system), Tesla coil.
Generati on of impulse voltages and currents -Impulse voltage definition, wave front
and wave tail time, Multistage impulse generator, Modified Marx circuit, Tripping
and control of conventional impulse generators, Introduction to Generation of high
impulse current, (Design of Marx Generators circuits - numerical can be taken).
Generation of switching surges.
(Numerical based on impulse generation, high DC voltage genera tion, optimum number
of stages) 08
5 Measurement of High Voltages and Currents:
High ohmic series resistance with micro -ammeter., HVAC and impulse voltage -
Resistance and capacitance voltage dividers, Sphere gap for measurement of High DC,
AC and impulse voltages , Capacitance Voltage Transformer
Measurement of High DC, AC and impulse currents 06
6 High Voltage Testing of Electrical Power Apparatus and H V Laboratories Layouts:
Non-destructive testing of dielectric materials, DC resistivity measurement, Dielectric
and loss factor measurement, Partial discharge measurement.
Testing of insulators and b ushing, Power capacitors and cables testing, testing of surge
diverters.
High Voltage laboratory –design, planning and layout. - Size and dimensions of the
equipment and their layout, Classification of HV laboratory, Earthing and Shielding of
H.V. laborato ries, its importance. 08
Textbooks :
1. C. L. Wadhwa, “High Voltage Engineering”, New Age International Publishers Ltd.
2. M. S. Naidu, V. Kamaraju, “High Voltage Engineering”, Tata McGraw Hill Publication Co. Ltd. New Delhi
Reference books:
1. E. Kuffel, W. S. Zaengl, J. Kuffel, “High Voltage Engineering Fundamentals”, Newnes Publication
2. Prof. D. V. Razevig Translated from Russian by Dr. M. P. Chourasia, “High Voltage Engineering”, Khanna
Publishers, New Delhi
3. Ravindra Arora, Wolf Gang Mosch, “High Voltage Insul ation Engineering”, New Age International
Publishers Ltd. Wiley Estern Ltd.
4. High Voltage Engineering Theory and Practice by M. Khalifa Marcel Dekker Inc. New York and Basel.
5. Subir Ray, “An Introduction to High Voltage Engineering” PHI Pvt. Ltd. New Delhi
Website Reference / Video Courses:
1. NPTEL Course: High Voltage Engineering By Prof. Aditya K. Jagannatham, Dept. of Electrical Engineering, IIT
Kanpur: - Web link - https://nptel.ac.in/courses/108/104/108104048/
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 m arks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code Course Name Teaching scheme
(Contact Hours) Credits Assigned
EEDO6014 Energy Storage Theory Pract./Tut. Theory Pract./Tut. Total
3 -- 3 3
Course
code Course Name Examination Scheme
Theory
Term
Work Pract/
Oral Total Internal Assess ment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEDO6014 Energy Storage 20 20 20 80 3 - - 100
Course
Objectives To explore the various energy storage technologies and their major applications
To increase awareness of ES suitabilit y and capacity calculation for any given applications
Course
Outcomes
Upon successful completion of this course, the learner will be able:
1. To illustrate the importance of energy storage systems in Power systems and other
application domains
2. To illustr ate the operational features of various energy storage technologies
3. To understand the principles and types of thermal, mechanical, electrochemical and
electrical energy storage systems.
4. To compare and contrast different types of Energy storage systems
5. To illustrate the hybridization of various ES technology to improve the performance
6. To calculate the capacity of ES system for various application requirements,
Module Contents Hours
1. Introduction to Energy Storage systems and components:
Historical Pers pective , Storage Needs, Variations in Energy Demand , Interruptions in
Energy Supply, Demand for Portable Energy, Environmental and sustainability issues ;
Necessity of energy storage, different types of energy storage, mechanical, chemical,
electrical, elec trochemical, biological, magnetic, electromagnetic, thermal, comparison
of energy storage technologies ;
07
2. Thermal Energy Storage :
Principles and applications, Latent heat, sensible heat storage. Molten salt, Solar pond,
seasonal thermal energy stora ge, Ice storage ; Energy and exergy analysis of thermal
energy storage. 05
3. Mechanical Energy Storage :
Potential Energy Storage, Energy Stora ge in Pressurized Gas, Compressed air energy
storage (CAES), Flywheel , Applications 04
4. Electrochemical Energy Sto rage :
Parameters to be considered, Cyclic behaviour, equivalent circuit of electrochemical cell,
self-discharge, Battery technologies: Flow battery, Rechargeable battery , Lead -acid,
Nickel -Metal hydride, Lithium Ion; Battery system model, parameters; emerg ing trends
in batteries.
Fuel Cell: types, comparison and applications. 07
5. Electrical Energy Storage :
Pumped hydro storage system, Energy Storage in C apacitors, Comparative Magnitudes
of Energy Storage, Transient behaviour of a Capacitor, Super -capa citor, series connection
of super capacitors, charge balancing of super capacitors ; Superconducting magnetic
energy storage (SMES) , Applications 06
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
6. Design , Sizing and Applications of Energy Storage :
Design considerations for sizing of different types of energy storage systems for various
applications, case studies;
Renewable energy storage - Battery sizing for stand -alone applications; Small scale
appli cation -Portable storage systems; (Numerical)
E-mobility storage a pplications - Electric vehicles (EVs), batteries , super -capacitors and
fuel cells, future technologies . Electric vehicle: V2X, G2V and V2G modes of operation.
Hybrid Energy storage systems: configurations and applications.
Energy Storage - Charging methodologies, SoC, SoH, SoS estimation techn iques. 10
Textbook:
1. Robert Huggins, Fundamentals, Materials and Applications Second Edition, Springer, 2016
2. Dincer I., and Rosen M. A. (2011); Thermal Energy Storage: Systems and Applications,Wiley
3. Leo J.M.J. Blomen and Michael N. Mugerwa, “Fuel Cell Sys tem”, New York, Plenum Press, 1993.
4. Ahmed Faheem Zobaa, Energy storage – Technologies and Applications, InTech Publication 2013.
5. Jiuchun Jiang and Caiping Zhang, Fundamentals and Applications of Lithium -Ion Batteries In Electric Drive
Vehicles, Wiley, 201 5
6. K.T. Chau, Energy Systems for Electric and Hybrid Vehicles, IET, UK, 2016
7. M. Broussely and G. Pistoia, Industrial Applications of Batteries From Cars to Aerospace and Energy
Storage, Elsevier, 2007.
Reference books
1. S. Kalaiselvam and R. Parameshwaran , Thermal Energy Storage Technologies for Sustainability Systems
Design, Academic Press, 2014
2. Trevor M. Letcher, Storing Energy with Special Reference to Renewable Energy Source, Elsevier, 2016.
3. Frank S. Barnes and Jonah G. Levine, Large Energy Storage Sy stems Handbook, CRC Press, 2011
4. Aiping Yu, Victor Chabot, and Jiujun Zhang, Electrochemical Super -capacitors For Energy Storage And
Delivery Fundamentals And Applications, CRC Press, 2013.
5. Younghyun Kim and Naehyuck Chang, Design and Management of Energy -Efficient Hybrid Electrical Energy
Storage Systems, Springer, 2014
Assessment:
Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02
Modules) and the other is either a class test or assignment on live problems or course project.
Theory Examination :
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining questions will be randomly selected from all the modules.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code Course Name Teaching Scheme (Contact Hours) Credit Assigned
Theory Practical Theory Practical Total
EEL601 Power System Protection
And Switchgear Lab - 2 - 1 1
Course
Code Course Name Examination Scheme
Total Theory TW/ Practical /Oral
Internal Assessment End
Sem.
Exam Term
work Pract.
& Oral Oral
Test 1 Test 2 Avg
EEL601 Power System Protection
And Switchgear Lab - - - - 25 -- 25 50
Course
Objectives To introduce the concept of different protection schemes
Course
Outcomes Upon successful completion of this course, the learner will be abl e:
1. To understand the working principle of various protective devices like Circuit breakers, fuses,
switches and contactors.
2. To understand the concept of various over current protection scheme and its applications in
power system.
3. To understand different pr otection schemes of transformer and Induction motor.
4. To understand protection schemes of transmission line.
Syllabus: Same as that of Course EEC601 -Power System Protection and Switchgear
Suggested List of Laboratory Experiments: Minimum six experiments need to be performed.
1. Demonstration of working parts of different Fuses and Contactor.
2. Demonstration of working parts of MCB, MCCB, RCCB & Circuit breakers.
3. To perform overcurrent protection using Induction Disc relay by setting different TSM and plot time vs
current characteristics.
4. To perform overvoltage protection using Induction Disc relay by setting different TSM and plot time vs
current characteristics.
5. Demonstration of different protection schemes like protection against overload, locked rotor, singl e
phasing of 3 phase Induction motor.
6. Demonstration of differential protection of 3 phase transformer.
7. Demonstration of Directional Over -current protection relay.
8. To perform simulation of Numerical Based relay.
9. To perform simulation of distance protection in transmission line.
Any other experiment based on syllabus, which will help students to understand topics/concept.
It is desirable to arrange the Visit to a substation and a report preparation.
Industry Visit: Students’ visit to be arranged to the near by industry involved in design/ manufacturing/ processing
in the following electrical engineering domains: Electrical Switchgears / Electrical Substation / Electrical Machines
/ Traction Locomotives / HV Equipments / Energy Storage . All students shall su bmit visit report in appropriate
format as a part of the submission for EEL6 01.
Note: Students and teachers are encouraged to use the virtual labs whose links are as given below The
remote -access to Labs in various disciplines of Science and Engineering i s available. Students can conduct
online experiments which would help them in learning basic and advanced concepts thro ugh remote
experimentation.
Virtual Lab Website Reference
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
1. http://vlab.co.in/broad -area -electrical -engineering
2. http://vlab.co.in/ broad -area -electronics -and-communications
Term work:
Term work shall consist of minimum six experiments. The distribution of marks shall be as follows:
Experiments Performance : 10 marks
Journal : 05 marks
Industrial Visit Report : 05 Marks
Atte ndance (Theory and Practical) : 05 marks
The final certification and acceptance of term work ensures the minimum passing in the term work.
Oral Examination:
Oral examination will be ba sed on entire syllabus of EEC601 -Power System Protection and Switchge ar
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING SEM -VI
Course
Code Course Name Teaching Scheme (Contact Hours) Credit Assigned
Theory Practical Theory Practical Total
EEL602 Microcontroller
Applications Lab - 2 - 1 1
Course
Code
Course Name Examination Scheme
Total Theory Practical
Internal Assessment End
Sem.
Exam Term
work Pract.
& Oral Oral
Test 1 Test 2 Avg
EEL602 Microcontroller
Applications Lab - - - - 25 25 - 50
Course
Objectives 1. To impart the Assembly language programming knowledge of PI C 18 microcontroller.
2. To impart the Embedded C programming knowledge of PIC 18 microcontroller
Course
Outcomes Upon successful completion of this course, the learner will be able to
1. To write, debug and execute Assembly language based programs.
2. To write, debug and execute embedded language based programs.
3. To design and implement the interfacing of internal peripheral devices.
4. To design and implement the interfacing of external peripheral devices.
Syllabus: Same as that of Course EEC602 Microcontrolle r Applications
Suggested List of Laboratory Experiments: Minimum four from Group (A) and four from Group (B) , in all
minimum eight experiments need to be performed.
(A) Assembly Language Programming:
1. To perform Addition, subtraction
2. To perform Multiplication and Division
3. To perform Logical operations (AND, OR, X -OR, NOT)
4. To sort Even and Odd numbers
5. To sort Negative and Positive numbers
6. To Find Largest Number
7. To Find Largest Number
8. To copy source array to destination array (Table related process)
9. To Toggle th e bits of Port.
(B) Embedded C Language Programming:
1. Timer programming to Generate square wave
2. Timer programming to Generate time delay
3. Timer programming to Generate the PWM pattern
4. ADC programming to perform Analog to digital conversion
5. Serial communicatio n programming for serial data transfer
6. IO port programming to interface simple switches and 7 -segment LED Display
7. IO port programming to interface Liquid Crystal Display (LCD)
8. Stepper Motor interfacing
9. DC Motor interfacing
10. Traffic Signal programming
Any o ther experiment based on syllabus, which will help students to understand topics/concept.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Note: Students and teachers are encouraged to use the virtual labs whose links are as given below The
remote -access to Labs in various disciplines of Science and E ngineering is available. Students can conduct
online experiments which would help them in learning basic and advanced concepts through remote
experimentation.
Virtual Lab Website Reference
1. http://vlab.co.in/broad -area -electrical -engineering
2. http: //vlab.co.in/broad -area -electronics -and-communications
Term work:
The term work shall consist of minimum 08 experiments based on PIC 18F microcontroller using assembly
and embedded C language and minimum 02 assignments. The distribution of marks shall be as follows:
Experiments Performance : 10 marks
Journal (Experiment and Assignments) : 10 marks
Attendance (Theory and Practical) : 05 marks
The final certification and acceptance of term work ensures the minimum passing in the term wor k.
Practical & Oral Examination:
Practical & Oral examination will be based on entire syllabus of EEC602 -Microcontroller Applications
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -VI
Course
code Course Name Teaching scheme
(Contact Hours) Credits Assigned
EEL603 Control System Design
Lab Theory Pract./Tut. Theory Pract./Tut. Total
-- 2 1 1
Subject
code Subject Name Examination Scheme
Theory
Term
Work Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEL603 Control Systems
Design Lab --- --- --- --- -- 25 - 25
Course
Objectives 1. To enable the students to strengthen their understanding of the design and analysis of control
systems through practical exercises
2. Use of modern software tools to ana lyze and simulate the performance of realistic system models
and to design control systems to satisfy various performance specifications.
Course
Outcomes Upon successful completion of this cour se, the learner will be able to
1. Implement various types of c ompensators and control algo rithms using simulation platforms
2. Apply root -locus & Bode Plot techniques to analyze and design control systems.
3. Able to design digital controllers, assess their design through the constraint specifications
Syllabus: Same as EEC603 : Control System Design
Suggested List of Laboratory Experiments: Minimum eight experiments need to be performed.
1. To draw the frequency response characteristic of a given lag - lead compensating network.
2. To study the effect of P, PI, PD and PID contr oller on step response of a feedback control system (Using
control engineering trainer/process control simulator). Verify the same by simulation.
3. Design of a Lead compensator using Root -locus method
4. Design of a lag compensator using Root -locus method
5. Design of a lead -lag compensator using Root -locus method
6. Design of a lead compensator using bode plot method
7. Design of a lag compensator using bode plot method
8. Design of a lead -lag compensator using bode plot method
9. Obtain transfer function of a given syste m from state variable model and vice versa. State variable analysis
of a physical system - obtain step response for the system by simulation
10. State variable analysis using simulation tools. To obtain step response and initial condition response for a
single input, two output system in state variable form by simulation.
11. Familiarization with digital control system toolbox
12. Determination of z -transform, inverse z -transform & pole zero map of discrete systems to study step
response of a discrete time system and e ffect of sampling time on system response
13. To explore the Properties of Digital Control Systems. Convert continuous time system to discrete system and
vice versa. Root Locus of Digital control system on z -plane
Any other experiment based on syllabus which will help students to understand topic/ concept is also suggested .
Note: Students and teachers are encouraged to use the virtual labs whose links are as given below The remote -
access to Labs in various disciplines of Science and Engineering is available. Students can conduct online
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
experiments which would help them in learning basic and advanced concepts through remote
experimentation.
Virtual Lab Website Reference
1. http://vlab.co.in/broad -area -electrical -engineering
2. http://vlab.co.in/broad -area -electronics -and-communications
Term work:
Term work shall consist of minimum eight experiments. The distribution of marks shall be as follows:
Experiments Performance : 10 marks
Journal : 10 marks
Attendance (Theory and Practical) : 05 marks
The final certification and acceptance of term work ensures the minimum passing in the term work.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEM -VI
Course
Code Course Name Teaching scheme (Contact Hours) Cred its Assigned
EEL604 SBL-III: Industrial
Automation Lab Theory Pract./Tut. Theory Pract./Tut. Total
- 4 2 2
Course
Code Course Name Examination Scheme
Theory
Term
Work Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEL604 SBL-III: Industrial
Automation Lab -- -- -- -- -- 25 25 50
Course
Objectives
1. Develop necessary acquaintance with components and subsystems used in industrial
automation
2. Develop the necessary skillset to integrate, mo nitor, maintain such systems
Course
Outcomes Upon successful completion of this cour se, the learner will be able:
1. To comprehend with various components and subsystems used in industrial automation
2. To understand the integration of components and sub -systems .
3. To interface the microcontrolle r / PLC with external devices / sensors/ actuators .
4. To interface the microcontrolle r / PLC with control circuits.
5. To design /implement / integrate such systems for any given applications
Section A:
Lab contents shall be covered through some of the following ways:
1) Class room discussions / Expert Lectures
2) Visiting various industries involving such facilities to illustrate industrial automation
3) Multiple day webinar specifically organized to cover such contents
4) In-house facility for demonstration of Industrial automation
5) Hands -on Workshop
6) Exhibitions showcasing these technologies
7) Using virtual Instrumentation platform
8) Using Virtual Lab platform (Virtual Labs (vlab.co.in)
Contents:
1) Components and subsystems used in Indu strial automation:
Controllers: Computers, Distributed Control Systems (DCS) , Programmable Logic Controllers (PLC),
Embedded Controllers.
Operator Interfaces (HMI) -Text based, Graphical, Touchscreens .
Sensors -Analog & Digital ; Encoders, Proximity sensor, U ltrasonic Sensors, Photoelectric Sensors; Limit
Switches
Actuators -Pneumatic, Hydraulic, Electric ; Motors - AC, DC, Linear, Servo and Stepper motor.
Mechanisms and Machine Elements - Cam Driven Systems, ratchets and pawl, gears; Linkages and coupling;
Convey ors- Belt, Roller, Chain, Vibrating, Pneumatic.
Motion Profile - trapezoidal velocity motion, S -curve velocity motion , Multi -axis motion
hardware and software platforms for D istributed Control System, DCS Functional Block Diagram , and
Sequential Flow Charts
Software - Design and Analysis software, PLC programming, SCADA
2) Industry 4.0:
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
Conceptual Framewor k- Main Concepts a nd Components of Industry 4.0; T echnology Roadmap for Industr y
4.0; T echnologies and Applications : Data Analytics in Manufacturing, Role o f IoT, Robotics in the era of
Industry 4.0 , Additive Manufacturing, 3D printing; Augmented Reality
3) Real life A pplications:
a) Agriculture/ farm produce -sorting and grading system
b) Automated / Robotic Assembly line
c) Temperature Control in Process Industries
d) Cyclic Operation of Traffic Lights
e) Conveyor System for an Assortment of Objects
f) Automatically filling of two tanks with liquid
g) Automated warehouse management system
h) Automated bottle filling plant
i) Automated packaging system
4) Industrial Safety Practices:
General Workplace Safety rules and procedures , recommended safety practices , Personal Protective
Equipments ( PPE), Industrial safety Acts and regulations
Section B:
Based on the insights received with the coverage of syllabus contents specified in section A, the students should
carry out detailed study of at least six different applications listed below (maximum two from any group is
desirable) . They should have hands -on experience with each of these applications. Wherever possible software
development / c oding should be done by students.
Group 1: Pneumatic and Hydraulic based Industrial Automation systems:
a) Electro -Pneumatic System for Pickup and Lay Down of Plastic Containers
b) Design and assembly of Pneumatic / Hydraulic circuit and wiring of control int erface for a particular
application
c) Application with different types of Pneumatic / Hydraulic valves and actuators
(Any other application which incorporates Pneumatic and Hydraulic components)
Group 2: Drives and Control - Industrial Automation systems
a) Linear Motion Control System
b) PLC based Motion Control System
c) VFD control of Motor
d) HMI interface based Control
e) Conveyor belt system
f) Sorting and grading System for Agriculture Applications
g) Home automation system with Web Server
h) Lift control System (Demo)
(Any other application which incorporates (Drives / Control)
Group 3: Use of IoT in following Applications
a) Smart Agriculture,
b) Smart City,
c) Smart Life —Wearable Technologies,
d) Smart Health
e) Smart Grid
(Any other application which incorporates Io T)
Group 4: Other Applications: Based on PLC/ Embedded micro -controller
a) To wire up hardware, write and implement ladder programs for the following controls.
i. Lamp control for various situations.
a. Staircase control, hospital etc.
b. Traffic light cont rol.
ii. Water level control using level sensors
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
iiii. Logic implementation for Bottle Filling Application
b) Tune PID controller for heat exchanger using DCS
(Any other suitable application)
Note: For each of the experiment carried out, stud ents should prepare a detail ed report, clearly specifying
following:
[1] Technical description and specification of the system
[2] Drawing/ schematic/ block diagram for system visualization
[3] Components used and their specs
[4] Interconnectivity between the components
[5] Working principle
[6] Software tools used
[7] Program code (if any) developed
[8] Observations
[9] Photographs of the system
Books Recommended:
1. Industrial Automation Hands -On, by Frank Lamb, McGraw -Hill, 2013
2. Industrial Motion Control - Motor Selection, Drives, Controll er Tuning, Applications, by Hakan Gürocak
Wiley, 2016
3. Industry 4.0: Managing The Digital Transformation, by Alp Ustundag and Emre Cevikcan, Springer, 2018
4. Introduction to Industrial Automation , by Stamatios Manesis and George Nikolakopoulos , CRC Press, 20 18
Term Work:
Term work shall consist of minimum requirement as given in the syllabus. The distribution of marks for term
work shall be as follows:
Laboratory Performance : 15 marks
Journal : 05 marks
Attendance : 05 marks
The final cer tification and acceptance of term work ensures the minimum passing in the term work.
Oral Examination:
Oral examination w ill be based on experiments carried out in EEL604 -SBL-III- Industrial Automation Lab
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
ELECTRICAL ENGINEERING - SEMESTER -V
Cour se
Code Course Name Teaching scheme (Contact Hours) Credits Assigned
EEM 601 Mini Project – 2B Theory Pract./Tut. Theory Pract./Tut. Total
-- 4$ -- 2 2
Course
Code Course Name Examination Scheme
Theory
Term
Work Oral Total Internal Assessment End
Sem.
Exam Exam
Duration
(in Hrs) Test 1 Test 2 Avg
EEM 601 Mini Project – 2B -- -- -- -- -- 25 25 25
$ indicates work load of Learner (Not Faculty)
Course
Objectives
1. To design and develop a moderately complex electrical/electronic/d igital circuit with practical
applications.
2. To understand basic concepts of circuit design while developing the project.
3. To enable the students to gain hands -on experience independently proposing and implementing
the project and thus acquire the necessary confidence to deal with complex
electrical/electronic/digital systems.
Course
Outcomes Upon successful completion of this course, the learner will be able to:
1. Identify problems based on societal /research needs.
2. Apply Knowledge and skill to solve s ocietal problems in a group.
3. Develop interpersonal skills to work as member of a group or leader.
4. Draw the proper inferences from available results through theoretical/ experimental/
simulations.
5. Analyse the impact of solutions in societal and environme ntal context for sustainable
development.
6. Use standard norms of engineering practices
7. Excel in written and oral communication.
8. Demonstrate capabilities of self -learning in a group, which leads to life -long learning.
9. Demonstrate project management princ iples during project work
A. Mini Project -Topic Selection and Approval
1. The group may be of maximum FOUR (04) students.
2. Students should propose project ideas & finalize the project idea in consultation with guide/ HOD. Students
should select a problem wh ich addresses some basic home, office or other real life applications. The mini
project must have hardware part. The software part is optional.
3. Students should identify different components/ devices, instruments, simulation/emulations software tools
requir ed for the project.
4. Students should submit implementation plan in the form of Gantt/ PERT/ CPM chart, which will cover weekly
activity of project.
5. A Log Book to be prepared by each group to record the work progress in terms of milestones per week by
studen ts. Weekly comment, remarks to be put by guiding faculty.
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University of Mumbai, Electrical Engineering, Rev. 2019 ‘C’ Scheme
B. Mini Project –Execution
i. Design and Fabrication
a. Initial fabrication of the project by students can be done using standard devices/material/software tools to
verify the circuit functionalities In itial project fabrication and testing is expected to be done by
soldering/assembling on general purpose PCB/ Bakelite boards or suitable platforms required for the
electrical/electronic/digital components. Discourage the use of breadboards.
b. If essential, u se of a simulation/ emulation software tools to test and verify the performance of the circuit
should be encouraged.
c. Students should prepare the proper drawings (electrical/ mechanical), schematics/ layouts of the project.
d. For final implementation of the circuit, preparation of PCB (if any required) using suitable CAD tools and
fabricating the same in the lab is expected.
ii. Devices/ Components/ Systems to be Used:
Students are encouraged to use passive components like resistors, capacitors, inductors etc. If any specialize
inductor is not readily available, the fabrication of the same in the lab should be encouraged. Other
components like: Transistors, diodes, voltage regulators, logic gates, Op -amps, general purpose
microcontroller, DC motors/ AC motors, sensors, actuators, relays etc. (Students may add more components
as per the requirement of project).
iii. Testing and analysis of the Project
Students should test the circuit using suitable laboratory equipments like power supply, multi -meter, CRO,
DSO etc. In case of any debugging requirement, students should record the problems faced during the testing
and solutions sought after for the fault in the circuit.
All the testing results must be well documented in the final project report verifying the functiona lities of the
propose project.
iv. Use of Reference Material/Literature :
Students are advised to refer Application Notes, research publications & data sheets of various
electrical/electronic/digital devices from Texas Instruments, Microchips, International R ectifiers, ST
Microelectronics, Philips, NXP and many other manufacturers.
C. Project Report Format:
Mini Project report should include circuit diagram, operation, application, design details, testing, waveforms
(if applicable) references, simulation results and final prepared PCB image, conclusion, etc. Project report
should include report of all above steps listed in (2) and the conclusion.
Note: -
It is expected that the department should organise some of the guidance expert lectures / video lectur es/ courses/
webinars/ workshops etc. for the students at the appropriate timing during the Mini Project practical slots on
following topics:
1) Understanding passive components viz. resistors, capacitors and inductors from practical point of view:
types/ var ieties, device packages, applications and cost.
2) Understanding semiconductor components viz. diodes, BJT and JFET/MOSFETs from practical point of view:
types/ varieties, device packages, applications and cost.
3) Design principles of simple electrical / elec tronic circuits with some examples.
4) Selection of switches and circuit protection components.
5) Selection and sizing of wires and conductors.
6) Soldering Practice.
7) Heat -sinking and Enclosure design concepts
8) Overall workmanship while working on the project fabri cation.
9) Use of different software tools for design and development of circuits
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11) Use of standard as well as some of the advanced laboratory equipments needed for testing of such
projects
Application Domains:
List of key application domains from where stud ents are encouraged to derive Mini Projects topics:
1) Smart Agriculture solutions
2) Power converter applications in various Applications
3) IoT based applications in power systems
4) AI/ML applications in disaster management
5) Renewable Energy
6) Energy Conservation
7) Energy Storage
8) Battery Charging and Protection
9) Fire Safety
10) Electrical System Protection
11) Lighting Control
12) Wireless Power Transfer
13) Electrical Components Testing
14) Electrical Parameters Measurement
15) Non-conventional Electricity Generation
16) Laboratory Equipments
17) E-Mobility / Electric Vehicles
18) Video Surveillance Systems
19) Robotics for Hazardous applications
20) Waste Management System
21) Smart City Solutions
22) Smart Classrooms and learning Solutions
23) Design of Electrical Equipment
24) PLC based automation system
25) Power system Monitoring System (EMS)
It is every much expected that the complexity of the Mini Project 2A/ 2B should be increased compared to the
selection of projects during Mini Project 1A/1B. Also based on the subjects learned in Sem . III and Sem. IV the
broader ar ea inclusive of the concepts learned must be selected. Students can identify the mini project topics
either from above suggested domains or any other relevant electrical engineering domains. The inter -disciplinary
nature of the project is also desirable .
Guidelines for Assessment of Mini Project:
Term Work
The review/ progress monitoring committee shall be constituted by head of departments of each institute.
The progress of mini project to be evaluated on continuous basis, minimum two reviews in ea ch semester.
In continuous assessment focus shall also be on each individual student, assessment based on individual’s
contribution in group activity, their understanding and response to questions.
Distribution of Term work marks for both semesters shall be as below;
o Marks awarded by guide/supervisor based on log book : 10
o Marks awarded by review committee : 10
o Quality of Project report : 05
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Review/progress monitorin g committee may consider following points for assessment based on either one year or
half year project as mentioned in general guidelines.
One-year Mini Project:
In first semester entire theoretical solution shall be ready, including components/system s election and
cost analysis. Two reviews will be conducted based on presentation given by students group.
o First shall be for finalization of problem
o Second shall be on finalization of proposed solution of problem.
In second semester expected work shall b e procurement of components /systems, building of working
prototype, testing and validation of results based on work completed in an earlier semester.
o First review is based on readiness of building working prototype to be conducted.
o Second review shall b e based on poster presentation cum demonstration of working model in last
month of the said semester.
Half-year Mini Project:
In this case in one semester students’ group shall complete project in all aspects including,
o Identification of need/problem
o Proposed final solution
o Procurement of components/systems
o Building prototype and testing
Two reviews will be conducted for continuous assessment,
o First shall be for finalization of problem and proposed solution
o Second shall be for implementation and t esting of solution.
Assessment criteria of Mini Project.
Mini Project shall be assessed based on following criteria;
1. Quality of survey/ need identification
2. Clarity of Problem definition based on need.
3. Innovativeness in solutions
4. Feasibility of proposed problem solutions and selection of best solution
5. Cost effectiveness
6. Societal impact
7. Innovativeness
8. Cost effectiveness and Societal impact
9. Full functioning of working model as per stated requirements
10. Effective use of skill sets
11. Effective use of standard engineering norms
12. Contribution of an individual’s as member or leader
13. Clarity in written and oral communication
In one year, project, first semester evaluation may be based on first six criteria’s and remaining may be used
for second semester evaluation of performance of students in mini project.
In case of half year project all criteria’s in generic may be considered for evaluation of performance of students
in mini project.
Guidelines for Asses sment of Mini Project Oral Examination:
Report should be prepared as per the guidelines issued by the University of Mumbai.
Mini Project shall be assessed through a presentation and demonstration of working model by the student
project group to a panel of Internal and External Exa miners preferably from industry or research
organizations having experience of more than five years approved by head of Institution.
Students shall be motivated to publish a paper based on the work i n Conferences/students competitions
Oral Examination: Mini Project shall be ass essed during oral examination based on following points:
1. Quality of problem and Clarity
2. Innovativeness in solutions
3. Cost effectiveness and Societal impact
4. Full functioning of working model as per stated requirements
5. Effective use of skill sets
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6. Effective use of standard engineering norms
7. Contribution of an individual’s as member or leader
8. Clarity in written and oral communication
Reference Books:
1. P. Horowitz and W. Hill, “The Art of Electronics”, 3rd Edition, Cambridge Uni versity Press, 2015
2. R. S. Khandpur, “Printed Circuit Board”, McGraw -Hill Education; 1st edition, 2005.
3. Simon Monk, “Hacking Electronic: Learning Arduino and Raspberry Pi”, McGraw -Hill Education TAB; 2
edition (September 28, 2017).
4. Matthew Scarpino, Design ing Circuit Boards with EAGLE: Make High -Quality PCBs at Low Cost, 1st Edition
Prentice Hall.
5. P. Horowitz and W. Hill, The Art of Electronics, 3 Edition, Cambridge University Press.
6. Archambeault and D. James, PCB Design for Real -World EMI Control, Spring er Publications
7. Mitzner, Kraig, “Complete PCB design using OrCAD Capture and PCB”, Elsevier, 2009
8. Peter Dalmaris, “Kicad Like a Pro”, Tech exploration
9. Charles Platt, “Encyclopedia of Electronic Components – Vol-1: Power, electromagnetism, and discrete
semiconductors. ”, Maker Media, 2012
10. Charles Platt, “Encyclopedia of Electronic Components – Vol-2: Integrated circuits, light sources, sound
sources, heat sources, and high frequency sources. ”, Maker Media, 2015
Suggested Software tools :
1. LTspice: https://www.analog.com/en/design -center/design -tools -and-calculators/ltspice -simulator.html#
2. Eagle : https://www.autodesk.in/products/eagle/overview
3. OrCAD: https://www.orcad.com/
4. Multisim : https://www.multisim.com/
5. Webbench: http://www.ti.com/design -resources/design -tools -simulation/webench -power -designer.html
6. Tinkercad : https://www.tinkercad.com/
7. Raspbia n OS: https://www.raspberrypi.org/downloads
8. Arduino IDE: https://www.arduino.cc/en/main/software
Online Repository:
1. https://www.electronicsforu. com
2. https://circuitdigest.com
3. https://www.electronicshub.org
4. Github