Electronics and Communications Engineering is a professional course of Bachelor of Technology or Bachelor of Engineering
which deals with the application of mathematics and science in the Electronics and Communications field. Ekeeda offers Online Electronics and Communications Engineering Courses for all the Subjects as per the Syllabus.

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slide 1:

Ekeeda – Electronics Telecommunication Engineering
AC-11.05.2017
Item No. 4.307
UNIVERSITY OF MUMBAI
Revised syllabus Rev- 2016 from Academic Year 2016 -17
Under
FACULTY OF TECHNOLOGY
Electronics and Telecommunication
Engineering
Second Year with Effect from AY 2017-18
Third Year with Effect from AY 2018-19
Final Year with Effect from AY 2019-20
As per Choice Based Credit and Grading System
with effect from the AY 2016–17

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2
Ekeeda – Electronics Telecommunication Engineering
Co-ordinator Faculty of Technology’s 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 higher
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 Technology of University of Mumbai has taken a lead in incorporating
philosophy of outcome based education in the process of curriculum development.
Faculty of Technology University of Mumbai in one of its meeting unanimously resolved that each Board of Studies
shall prepare some Program Educational Objectives PEO‟s and give freedom to affiliated Institutes to add few
PEO‟s. It is also 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. It was also resolved that maximum senior faculty from colleges and experts from
industry to be involved while revising the curriculum. I am happy to state that each Board of studies has adhered to the
resolutions passed by Faculty of Technology and developed curriculum accordingly. In addition to outcome based
education semester based credit and grading system is also introduced to ensure quality of engineering education.
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 based on the investment of time in learning and not in teaching. It also
focuses on continuous evaluation which will enhance the quality of education. University of Mumbai has taken a lead
in implementing the system through its affiliated Institutes and Faculty of Technology has devised a transparent credit
assignment policy and adopted ten points scale to grade learner‟s performance. Credit assignment for courses is based
on 15 weeks teaching learning process however content of courses is to be taught in 12-13 weeks and remaining 2-3
weeks to be utilized for revision guest lectures coverage of content beyond syllabus etc.
Choice based Credit and grading system is implementedfrom the academic year 2016-17 through optional courses at
department and institute level. This will be effective for SE TE and BE from academic year 2017-18 2018-19 and
2019-20 respectively.
Dr. S. K. Ukarande
Co-ordinator
Faculty of Technology
Member - Academic Council
University of Mumbai Mumbai

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3
Ekeeda – Electronics Telecommunication Engineering
Chairman’s Preamble:
The curriculum in higher education is a living entity. It evolves with time it reflects the ever changing needs
of the society and keeps pace with the growing talent of the students and the faculty. The engineering
education in India is expanding in manifolds and the main challenge is the quality of education. All
stakeholders are very much concerned about it. The curriculum of Electronics Telecommunication in
Mumbai University is no exception. In keeping with the demands of the changing times it contains
innovative features. The exposure to the latest technology and tools used all over the world is given by
properly selecting the subjects. It is designed in such a way to incorporate the requirements of various
industries. The major emphasis of this process is to measure the outcomes of the program. Program outcomes
are essentially a range of skills and knowledge that a student will have at the time of post-graduation. So the
curriculum must be refined and updated to ensure that the defined objectives and outcomes are achieved.
I as Chairman Ad-hoc Board of Studies in Electronics and Telecommunication Engineering University of
Mumbai happy to state here that the heads of the department and senior faculty from various institutes took
timely and valuable initiative to frame the Program Educational objectives as listed below.
Objectives:
To produce Electronics Telecommunication engineers having strong theoretical foundation
good design experience and exposure to research and development.
To produce researcher who have clear thinking articulation and interest to carry out theoretical
and/or applied research resulting in significant advancement in the field of specialization.
To develop an ability to identify formulate and solve electronics and telecommunication
engineering problems in the latest technology.
To develop the ability among students to synthesize data and technical concepts from applications
to product design.
These are the suggested and expected main objectives individual affiliated institutes may add further in the
list. I believe that the small step taken in the right direction will definitely help in providing quality education
to the stake holders.
This book of curricula is the culmination of large number of faculty members and supporting staff. It also
reflects the creative contribution of hundreds of teachers – both serving and retired. I sincerely hope that the
faculty and students of Electronics and Telecommunication in Mumbai University will take full advantage of
dynamic features of curriculum and make teaching-learning process a truly sublime experience for all.
At the end I must extend my gratitude to all experts and colleagues who contributed to make curriculum
competent at par with latest technological development in the field of Electronics Telecommunication
Engineering.
Dr. Uttam D. Kolekar
Chairman Ad-hoc Board of Studies in Electronics and Telecommunication Engineering

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4
Ekeeda – Electronics Telecommunication Engineering
Program Structure for
B.E. Electronics Telecommunication Engineering Rev. 2016
University of Mumbai
With Effect from 2017-2018
Semester III
Course
Code
Course Name
Teaching Scheme Contact
Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC301 Applied Mathematics- III 4 - 2 4 1 5
ECC302 Electronic Devices and Circuits I 4 - - 4 - 4
ECC303 Digital System Design 4 - - 4 - 4
ECC304 Circuit Theory and Networks 4 - 2 4 1 5
ECC305
Electronic Instrumentation and
Control
4 - 2 4 1 5
ECL301
Electronic Devices and Circuits I
Laboratory
- 2 - - 1 1
ECL302
Digital System Design
Laboratory
- 2 - - 1 1
ECL303 OOP using JAVA Laboratory - 2 - - 1 1
Total 20 6 6 20 6 26
2 hour to be taken as tutorial classwise
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral/
Prac
Total
Internal Assessment End Sem
Exam
Exam
Duration
Hrs Test1 Test 2 Avg
ECC301 Applied Mathematics-III 20 20 20 80 03 25 -- 125
ECC302
Electronic Devices and
Circuits I
20 20 20 80 03 -- -- 100
ECC303 Digital System Design 20 20 20 80 03 -- -- 100
ECC304
Circuit Theory and
Networks
20 20 20 80 03 25 -- 125
ECC305
Electronic Instrumentation
and Control
20 20 20 80 03 25 -- 125
ECL301
Electronic Devices and
Circuits I Laboratory
-- -- -- -- -- 25 25 50
ECL302
Digital System Design
Laboratory
-- -- -- -- -- 25 25 50
ECL303
OOP using JAVA
Laboratory
-- -- -- -- -- 25 25 50
Total 100 400 150 75 725

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5
Ekeeda – Electronics Telecommunication Engineering
Semester IV
Course
Code
Course Name
Teaching Scheme
Contact Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC401 Applied Mathematics- IV 4 - 2 4 1 5
ECC402 Electronic Devices and Circuits II 4 - - 4 - 4
ECC403 Linear Integrated Circuits 4 - - 4 - 4
ECC404 Signals Systems 4 - 2 4 1 5
ECC405
Principles of Communication
Engineering
4 - - 4 - 4
ECL401
Electronic Devices and Circuits II
Laboratory
- 2 - - 1 1
ECL402
Linear Integrated Circuits
Laboratory
- 2 - - 1 1
ECL403
Principles of Communication
Engineering Laboratory
- 2 - - 1 1
Total 20 6 4 20 5 25
2 hour to be taken as tutorial classwise
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral
Prac
Total
Internal Assessment End Sem
Exam
Exam
Duration
Hrs
Test1 Test 2 Avg
ECC401 Applied Mathematics- IV 20 20 20 80 03 25 -- 125
ECC402
Electronic Devices and Circuits
II
20 20 20 80 03 -- -- 100
ECC403 Linear Integrated Circuits 20 20 20 80 03 -- -- 100
ECC404 Signals Systems 20 20 20 80 03 25 -- 125
ECC405
Principles of Communication
Engineering
20 20 20 80 03 -- -- 100
ECL401
Electronic Devices and Circuits
II Laboratory
-- -- -- -- -- 25 25 50
ECL402
Linear Integrated Circuits
Laboratory
-- -- -- -- -- 25 25 50
ECL403
Principles of Communication
Engineering Laboratory
-- -- -- -- -- 25 25 50
Total 100 400 125 75 700

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6
Ekeeda – Electronics Telecommunication Engineering
Semester V
Course
Code
Course Name
Teaching Scheme Contact
Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC501
Microprocessor
Peripherals Interfacing
4 - - 4 - 4
ECC502 Digital Communication 4 - - 4 - 4
ECC503 Electromagnetic Engineering 4 - 1 4 1 5
ECC504
Discrete Time Signal
Processing
4 - - 4 - 4
ECCDLO
501X
Department Level Optional
Course I
4 - - 4 - 4
ECL501
Microprocessor
Peripherals Interfacing Lab
- 2 - - 1 1
ECL502 Digital Communication Lab - 2 - - 1 1
ECL503
Business Communication
Ethics Lab
- 2+2 - - 2 2
ECL504
Open Source Technology for
Communication Lab
- 2 - - 1 1
ECLDLO
501X
Department Level Optional
Lab I
- - 2 - 1 1
Total 20 10 3 20 7 27
1 hour to be taken as tutorial classwise 2 hours to be taken as either lab or tutorial based on subject requirement
2 hours to be taken as tutorial batchwise
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral/
Prac
Total
Internal Assessment End Sem
Exam
Exam
Duration
Hrs Test1 Test 2 Avg
ECC501
Microprocessor
Peripherals Interfacing
20 20 20 80 03 -- -- 100
ECC502 Digital Communication 20 20 20 80 03 -- -- 100
ECC503
Electromagnetic
Engineering
20 20 20 80 03 25 -- 125
ECC504
Discrete Time Signal
Processing
20 20 20 80 03 -- -- 100
ECCDLO
501X
Department Level Optional
Course I
20 20 20 80 03 -- -- 100
ECL501
Microprocessor
Peripherals Interfacing Lab
-- -- -- -- -- 25 25 50
ECL502 Digital Communication Lab -- -- -- -- -- 25 25 50
ECL503
Business Communication
Ethics Lab
-- -- -- -- -- 50 -- 50
ECL504
Open Source Technology
for Communication Lab
-- -- -- -- -- 25 25 50
ECLDLO
501X
Department Level Optional
Lab I
-- -- -- -- -- 25 -- 25
Total 100 400 175 75 750

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7
Ekeeda – Electronics Telecommunication Engineering
Course Code Department Level Optional Course I
ECCDLO 5011 Microelectronics
ECCDLO 5012 TV Video Engineering
ECCDLO 5013 Finite Automata Theory
ECCDLO 5014 Data Compression and Encryption

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8
Ekeeda – Electronics Telecommunication Engineering
Semester VI
Course
Code
Course Name
Teaching Scheme
Contact Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC601
Microcontrollers
Applications
4 - -- 4 -- 4
ECC602
Computer Communication
Networks
4 - - 4 - 4
ECC603
Antenna Radio Wave
Propagation
4 - - 4 - 4
ECC604
Image Processing and Machine
Vision
4 - -- 4 -- 4
ECCDLO
602X
Department Level Optional
Course II
4 - - 4 - 4
ECL601
Microcontroller
Applications Lab
- 2 - - 1 1
ECL602
Computer Communication
Network Lab
- 2 - - 1 1
ECL603
Antenna Radio Wave
Propagation Lab
- 2 - - 1 1
ECL604
Image Processing and Machine
Vision Lab
- 2 - - 1 1
ECLDLO
602X
Department Level Optional
Lab II
- 2 - - 1 1
Total 20 10 - 20 5 25
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral
Prac
Total
Internal Assessment End
Sem
Exam
Exam
Duration
Hrs
Test1
Test 2
Avg
ECC601 Microcontroller Applications 20 20 20 80 03 -- -- 100
ECC602
Computer Communication
Network
20 20 20 80 03 -- -- 100
ECC603
Antenna Radio Wave
Propagation
20 20 20 80 03 -- -- 100
ECC604
Image Processing and Machine
Vision Lab
20 20 20 80 03 -- -- 100
ECCDLO
602X
Department Level Optional
Course II
20 20 20 80 03 -- -- 100
ECL601
Microcontroller Applications
Lab
-- -- -- -- -- 25 25 50
ECL602
Computer Communication
Network Lab
-- -- -- -- -- 25 25 50
ECL603
Antenna Radio Wave
Propagation Lab
-- -- -- -- -- 25 25 50
ECL604
Image Processing and Machine
Vision Lab
-- -- -- -- -- 25 25 50

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9
Ekeeda – Electronics Telecommunication Engineering
ECLDLO
602X
Department Level Optional Lab
II
-- -- -- -- -- 25 -- 25
Total 100 400 125 100 725

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10
Ekeeda – Electronics Telecommunication Engineering
Course Code Department Level Optional Course II
ECCDLO 6021 Digital VLSI Design
ECCDLO 6022 Radar Engineering
ECCDLO 6023 Database Management System
ECCDLO 6024 Audio Processing

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11
Ekeeda – Electronics Telecommunication Engineering
Semester VII
Course
Code
Course Name
Teaching Scheme Contact
Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC701 Microwave Engineering 4 - - 4 - 4
ECC702
Mobile Communication
System
4 - - 4 - 4
ECC703 Optical Communication 4 - -- 4 - 4
ECCDLO
703X
Department Level Optional
Course III
4 - - 4 - 4
ILO701X
Institute Level Optional
Course I
3 - - 3 - 3
ECL701 Microwave Engineering Lab - 2 - - 1 1
ECL702
Mobile Communication
System Lab
- 2 - - 1 1
ECL703 Optical Communication Lab - 2 - - 1 1
ECLDLO
703X
Department Level Optional
Lab III
- 2 - - 1 1
ECL704 Project-I - 6 - - 3 3
Total 19 14 - 19 7 26
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral
Prac
Total
Internal Assessment End
Sem
Exam
Exam
Duration
Hrs
Test1
Test 2
Avg
ECC701 Microwave Engineering 20 20 20 80 03 -- -- 100
ECC702 Mobile Communication System 20 20 20 80 03 -- -- 100
ECC703 Optical Communication 20 20 20 80 03 -- -- 100
ECCDLO
703X
Department Level Optional
Course III
20 20 20 80 03 -- -- 100
ILO701X Institute Level Optional Course I 20 20 20 80 03 -- -- 100
ECL701 Microwave Engineering Lab -- -- -- -- -- 25 25 50
ECL702
Mobile Communication System
Lab
-- -- -- -- -- 25 25 50
ECL703 Optical Communication Lab -- -- -- -- -- 25 25 50
ECLDLO
703X
Department Level Optional Lab
III
-- -- -- -- -- 25 25 50
ECL704 Project-I -- -- -- -- -- 50 50 100
Total 100 400 150 150 800

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12
Ekeeda – Electronics Telecommunication Engineering
Course Code Department Level Optional Course III Course Code Institute Level Optional Course I
ECCDLO7031 Neural Networks and Fuzzy Logic ILO7011 Product Lifecycle Management
ECCDLO7032 Big Data Analytics ILO7012 Reliability Engineering
ECCDLO7033 Internet Communication Engineering ILO7013 Management Information System
ECCDLO7034 CMOS Mixed Signal VLSI ILO7014 Design of Experiments
ECCDLO7034 Embedded System ILO7015 Operation Research
ILO7016 Cyber Security and Laws
ILO7017 Disaster Management and Mitigation
Measures
ILO7018 Energy Audit and Management
ILO7019 Development Engineering
Common with all branches

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University of Mumbai B. E. Electronics Telecommunication Engineering Rev 2016 12
Ekeeda – Electronics Telecommunication Engineering
Semester VIII
Course
Code
Course Name
Teaching Scheme
Contact Hours
Credits Assigned
Theory Pracs Tut Theory TW/ Pracs Total
ECC801 RF Design 4 - -- 4 -- 4
ECC802 Wireless Networks 4 - - 4 - 4
ECCDLO
804X
Department Level Optional
Course IV
4 - - 4 - 4
ILO802X
Institute Level Optional
Course II
3 - - 3 - 3
ECL801 RF Design Lab - 2 - - 1 1
ECL802 Wireless Networks Lab - 2 - - 1 1
ECLDLO
804X
Department Level Optional
Lab IV
- 2 - - 1 1
ECL803 Project-II - 12 - - 6 6
Total 15 18 - 15 9 24
Course
Code
Course Name
Examination Scheme
Theory
TW
Oral
Prac
Total
Internal Assessment End
Sem
Exam
Exam
Duration
Hrs
Test1
Test 2
Avg
ECC801 RF Design 20 20 20 80 03 -- -- 100
ECC802 Wireless Networks 20 20 20 80 03 -- -- 100
ECCDLO
804X
Department Level Optional
Course IV
20 20 20 80 03 -- -- 100
ILO802X
Institute Level Optional Course
II
20 20 20 80 03 -- -- 100
ECL801 RF Design Lab -- -- -- -- -- 25 25 50
ECL802 Wireless Networks Lab -- -- -- -- -- 25 25 50
ECLDLO
804X
Department Level Optional Lab
IV
-- -- -- -- -- 25 25 50
ECL803 Project-II -- -- -- -- -- 100 50 150
Total 80 320 175 125 700

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University of Mumbai B. E. Electronics Telecommunication Engineering Rev 2016 13
Ekeeda – Electronics Telecommunication Engineering
Course Code Department Level Elective Course IV Course Code Institute Level Elective Course II
ECCDLO8041 Optical Networks ILO8021 Project Management
ECCDLO8042 Advanced Digital Signal Processing ILO8022 Finance Management
ECCDLO8043
Satellite Communication
ILO8023
Entrepreneurship Development and
Management
ECCDLO8044 Network management in Telecommunication ILO8024 Human Resource Management
ILO8025 Professional Ethics and CSR
ILO8026 Research Methodology
ILO8027 IPR and Patenting
ILO8028 Digital Business Management
ILO8029 Environmental Management
Common with all branches

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14
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC301
Applied
Mathematics-
III
04
--
2 04
-- 01 05
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC301 Applied
Mathematics-
III
20 20 20 80
25
--
--
125
2 hour to be taken as tutorial classwise
Course Pre-requisite:
• Applied Mathematics I
• Applied Mathematics II
Course Objectives:
1. To build the strong foundation in Mathematics of students needed for the field of electronics
and Telecommunication Engineering
2. To provide students with mathematics fundamentals necessary to formulate solve and
analyses complex engineering problems.
3. To prepare student to apply reasoning informed by the contextual knowledge to engineering
practice.
4. To prepare students to work as part of teams on multi-disciplinary projects.
Course Outcome:
After successful completion of the course student will be able to
Students will demonstrate basic knowledge of Laplace Transform. Fourier series Bessel
Functions Vector Algebra and Complex Variable.
Students will demonstrate an ability to identify and Model the problems of the field of
Electronics and Telecommunication and solve it.
Students will be able to apply the application of Mathematics in Telecommunication
Engineering

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15
Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Laplace Transform 07
1.1 Laplace Transform LT of Standard Functions: Definition of
Laplace transform Condition of Existence of Laplace
transform Laplace transform of
e
a t
S i n a t c o s a t s i nh a t c o s h a t t
n
Heaviside unit step
function Dirac-delta function Laplace transform of Periodic
function
1.2 Properties of Laplace Transform: Linearity first shifting
theorem second shifting theorem multiplication by t
n
Division by t Laplace Transform of derivatives and integrals
change of scale convolution theorem Evaluation of integrals
using Laplace transform.
2 Inverse Laplace Transform its Applications 06
2.1 Partial fraction method Method of convolution Laplace
inverse by derivative
2.2 Applications of Laplace Transform: Solution of ordinary
differential equations Solving RLC circuit differential
equation of first order and second order with boundary
condition using Laplace transform framing of differential
equation is not included
3 Fourier Series 11
3.1 Introduction: Orthogonal and orthonormal set of functions
Introduction of Dirchlet‟s conditions Euler‟s formulae.
3.2 Fourier Series of Functions: Exponential trigonometric
functions of any period 2L even and odd functions half
range sine and cosine series
3.3 Complex form of Fourier series Fourier integral
representation Fourier Transform and Inverse Fourier
transform of constant and exponential function.
4 Vector Algebra Vector Differentiation 07
4.1 Review of Scalar and Vector Product: Scalar and vector
product of three and four vectors Vector differentiation
Gradient of scalar point function Divergence and Curl of
vector point function
4.2 Properties: Solenoidal and irrotational vector fields
conservative vector field

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16
Ekeeda – Electronics Telecommunication Engineering
5 Vector Integral 06
5.1 Line integral
5.2 Green‟s theorem in a plane Gauss‟ divergence theorem a n d
Stokes‟ theorem
6 Complex Variable Bessel Functions 11
6.1 Analytic Function: Necessary and sufficient conditions No
Proof Cauchy Reiman equation Cartesian form No Proof
Cauchy Reiman Equation in polar form with Proof Milne
Thomson Method and it application Harmonic function
orthogonal trajectories
6.2 Mapping: Conformal mapping Bilinear transformations cross
ratio fixed points
6.3 Bessel Functions: Bessel‟s differential equation Properties of
Bessel function of order +1/2 and -1/2 Generating function
expression of cosxsin
sin x sin
in term of Bessel
functions
Note: Term Work should be based on Tutorials.
Textbooks :
1. H.K. Das “Advanced engineering mathematics” S . Chand 2008
2. A. Datta “Mathematical Methods in Science and Engineering” 2012
3. B.S. Grewal “Higher Engineering Mathematics” Khanna Publication
Reference Books:
1. B. V. Ramana “Higher Engineering Mathematics” Tata Mc-Graw Hill Publication
2. Wylie and Barret “Advanced Engineering Mathematics” Tata Mc-Graw Hill 6th Edition
3. Erwin Kreysizg “Advanced Engineering Mathematics” John Wiley Sons Inc
4. Murry R. Spieget “Vector Analysis” Schaum‟s outline series Mc-Graw Hill Publication

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17
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC302
Electronic
Devices
Circuits-I
04
--
-- 04
-- -- 04
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC302 Electronic
Devices
Circuits-I
20 20 20 80
--
--
--
100
Course Pre-requisite:
• Basic Electrical Engineering
• Applied Physics
Course Objectives:
1. To understand operation of semiconductor devices.
2. To understand DC analysis and AC models of semiconductor devices.
3. To apply concepts for the design of Regulators and Amplifiers
4. To verify the theoretical concepts through laboratory and simulation experiments.
5. To implement mini projects based on concept of electronics circuit concepts.
Course Outcome:
After successful completion of the course student will be able to
1. Understand the current voltage characteristics of semiconductor devices
2. Analyze dc circuits and relate ac models of semiconductor devices with their physical
Operation
3. Design and analyze of electronic circuits
4. Evaluate frequency response to understand behaviour of Electronics circuits.

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18
Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Diode and material science 06
1.1 Study of various types of resistor capacitor and inductors
1.2 Basic fabrication steps of passive elements.
1.3 PN junction Diode characteristics small signal model
2 Rectifier Filters and Regulator 08
2.1 Analysis and design of rectifier circuit with Filters L LC
CCLCCRC
2.2 Concept of load and line regulation in power supply circuits.
2.3 Analysis and design of zener voltage regulator
3 Transistor biasing and design 08
3.1 Operation of BJT FET N-CHANNEL P-CHANNEL with
characteristics and equation.
3.2 Bipolar Junction Transistor: BJT characteristics DC/AC load
line DC analysis and design of fixed bias collector to base
bias and voltage divider bias stability factor analysis
3.3 Junction Field Effect Transistor: Analysis and design of self-
bias and voltage divider bias zero temp drift biasing.
4 Transistor modeling and Small signal analysis of amplifier 12
4.1 Hybrid and
representation.
hybrid-pi model of BJT with graphical
4.2 Small signal model of FET with graphical representation.
4.3 Small signal analysis Zi Zo Av and Ai of CE CB and CC
configurations using hybrid-pi model of BJT
4.4 small signal mid-frequency analysis of CS CD and CG
amplifiers using FET
5 High frequency response of BJT and FET amplifiers 08
5.1 High frequency hybrid-pi equivalent Circuits of BJT and FET
Miller effect and Miller capacitance gain bandwidth product
5.2 Effects of capacitors on frequency response of single stage
amplifier using BJT and FET
5.3 Analysis of single stage amplifiers at HF and gain bandwidth
product.

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19
Ekeeda – Electronics Telecommunication Engineering
6 Design of small signal amplifiers 06
6.1 Design of single stage RC Coupled CE amplifier.
6.2 Design of single stage RC Coupled CS amplifier. USE of
parameters from data sheet compulsory
Textbooks :
1. D. A. Neamen “Electronic Circuit Analysis and Design” Tata McGraw Hill 2
nd
Edition.
2. A. S. Sedra K. C. Smith and A. N. Chandorkar “Microelectronic Circuits Theory and
Applications” International Version OXFORD International Students 6
th
Edition
3. R. S. Dudhe and M. Farhan “Electronic Devices and Circuits” Synergy Knowledgeware
1
st
Edition 2013.
Reference Books:
1. Boylestad and Nashelesky “Electronic Devices and Circuits Theory” Pearson Education
11
th
Edition.
2. A. K. Maini “Electronic Devices and Circuits” Wiley.
3. T. L. Floyd “Electronic Devices”Prentice Hall 9
th
Edition 2012.
4. A. Rockett “Material Science of Semiconductors” Springer 1
st
Edition 2009
5. A. Mottershead “Electronic Devices and Circuits An Introduction”

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20
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC303
Digital
System
Design
04
--
-- 04
-- -- 04
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC303 Digital
System
Design
20 20 20 80
--
--
--
100
Course Objectives:
1. To understand number representation and conversion between different representation in
digital electronic circuits.
2. To analyze logic processes and implement logical operations using combinational logic
circuits.
3. To understand characteristics of memory and their classification.
4. To understand concepts of sequential circuits and to analyze sequential systems in terms
of state machines.
5. To understand concept of Programmable Devices PLA PAL CPLD and FPGA and
implement digital system using VHDL.
6. To implement combinational and sequential circuits using VHDL.
Course Outcome:
After successful completion of the course student will be able to
1. Develop a digital logic and apply it to solve real life problems.
2. Analyze design and implement combinational logic circuits.
3. Classify different semiconductor memories.
4. Analyze design and implement sequential logic circuits.
5. Analyze digital system design using PLD.
6. Simulate and implement combinational and sequential circuits using VHDL systems.

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21
Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Number Systems and Codes 04
1.1 Review of Number System Binary Code Binary Coded
Decimal Octal Code Hexadecimal Code and their
conversions Binary Arithmetics Gray Code
2 Logic Gates and Combinational Logic Circuits 18
2.1 Analog and Digital signals and systems Logic levels TTL and
CMOS Logic families and their characteristics
2.2 Digital logic gates Realization using NAND NOR gates
Boolean Algebra De Morgan‟s Theorem SOP and POS
representation K Map up to four variables and Quine-
McClusky method
2.3 Arithmetic Circuits: Half adder Full adder Half Subtractor
Full Subtractor Serial and Parallel Addition Carry Look
ahead adder and BCD adder. Binary Multiplier Magnitude
Comparator
2.4 Multiplexer and De-multiplexer: Multiplexer operations
cascading of Multiplexer Boolean Function implementation
using multiplexer and basic gates de-multiplexer encoder and
decoder
3 Different Types of Memory 02
Classification and Characteristics of memory SRAM DRAM
ROM PROM EPROM and Flash memories
4 Sequential Logic Circuits: 12
4.1 Flip flops: RS JK Master slave flip flops T D flip flops
with various triggering methods Conversion of flip flops
Registers: SISO SIPO PISO PIPO Universal shift registers.
4.2 Counters: Asynchronous and Synchronous Up/Down MOD
N BCD
4.3 Applications of Sequential Circuits: Frequency division Ring
Counter Johnson Counter. models State transition diagram
Design of Moore and Mealy circuits-Design of Serial Adder
and vending Machine
4.4 State Reduction Techniques: Row elimination and Implication
table methods
5 Programmable Logic Devices: 09
Introduction : Programmable Logic Devices PLD

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Programmable Logic Array PLA Programmable Array
LogicPAL CPLD and FPGA Keyboard Encoder system
design using PLD
6 VHSIC Hardware Description Language VHDL 03
6.1 Data types Structural modeling using VHDL Attributes Data
Flow behavioral Implementation of Priority Encoder-
combinational circuit and Fibonacci Series Generator-
sequential circuits using VHDL
Textbooks :
1. John F. Warkerly “Digital Design Principles and Practices” Pearson Education Fourth
Edition 2008.
2. R. P. Jain “Modern Digital Electronics” Tata McGraw Hill Education Third Edition
2003.
3. J. Bhaskar “VHDL Primer” PHI Third Edition 2009.
4. Volnei A. Pedroni “Digital Electronics and Design with VHDL” Morgan Kaufmann
Publisher 2008
Reference Books:
1. Morris Mano / Michael D. Ciletti “Digital Design” Pearson Education Fourth Edition
2008.
2. Thomas L. Floyd “Digital Fundamentals” Pearson Prentice Hall Eleventh Global
Edition 2015.
3. Mandal “Digital Electronics Principles and Applications” McGraw Hill Education First
Edition 2010.
4. Stephen Brown Zvonko Vranesic “Fundamentals of Digital Logic Design with VHDL”
Second Edition TMH 2009.
5. Ronald J. Tocci Neal S. Widmer “Digital Systems Principles and Applications” Eighth
Edition PHI 2003
6. Donald P. Leach / Albert Paul Malvino/Gautam Saha “Digital Principles and
Applications” The McGraw Hill Seventh Edition 2011.

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Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC304
Circuit
Theory and
Networks
04
--
2 04
-- 1 05
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC304 Circuit
Theory and
Networks
20 20 20 80
25
--
--
125
2 hour to be taken as tutorial classwise
Course Pre-requisite:
• Basic Electrical Engineering
• Solution to Differential Educations and Laplace Transform
Course Objectives:
1. To analyze the Circuits in time and frequency domain
2. To study network Topology network Functions two port network
3. To synthesize passive network by various methods
Course Outcome:
After successful completion of the course student will be able to
1. Apply their knowledge in analysing Circuits by using network theorems.
2. Apply the time and frequency method of analysis.
3. Find the various parameters of two port network.
4. Apply network topology for analyzing the circuit
5. Synthesize the network using passive elements.

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Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Electrical circuit analysis 08
1.1 Analysis of DC AC Circuits: Analysis of Circuits with and
without controlled sources using generalized loop and node
matrix methods
Circuit Theorems: Superposition Thevenin‟s N o r t o n ‟ s maximum
power transfer and reciprocity theorems
1.2 Magnetic circuits: Concept of Self and mutual inductances
coefficient of coupling dot convention equivalent circuit
Coupled circuit- solution using mesh analysis
2 Graph Theory 08
2.1 Objectives of graph theory Linear Oriented Graphs graph
terminologies
Matrix representation of a graph: Incidence matrix Circuit
matrix Cut-set matrix reduced incident matrix tieset matrix
f-cutset matrix.
2.2 Relationship between sub matrices A B Q.
2.3 KVL KCL using matrix
3 Time and frequency domain analysis 08
3.1 Time domain analysis of R-L and R-C Circuits: Forced and
natural response initial and final values Solution using first
order differential equation for impulse step ramp exponential
sinusoidal signals
3.2 Time domain analysis of R-L-C Circuits: Forced and natural
response effect of damping factor. Solution using second
order equation for step ramp exponential sinusoidal
signals.
3.3 Frequency domain analysis: Frequency - domain
representation of R LC initial value theorem final value
theorem applications of Laplace Transform in analyzing
electrical circuits
4 Network functions 08
4.1 Network functions for the one port and two port networks
Driving point and transfer functions Poles and Zeros of
Network functions necessary condition for driving point
functions necessary condition for transfer functions
calculation of residues by analytical and graphical methods

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Time domain behavior as related to the Pole-Zero plot
Stability causality testing for Hurwitz polynomial
4.2 Analysis of ladder symmetrical lattice network
5 Two port Networks 08
5.1 Parameters: Open Circuits short Circuit Transmission and
Hybrid parameters relationship among parameters conditions
for reciprocity and symmetry
5.2 Interconnections of Two-Port networks T π representation.
5.3 Terminated two-port networks
6 Synthesis of RLC circuits 08
6.1 Positive Real Functions: Concept of positive real function
testing for necessary and sufficient conditions for Positive real
Functions
6.2 Synthesis of LC RC RL Circuits: properties of LC RC
RL driving point functions LC RC RL network Synthesis
in Cauer-I Cauer-II Foster-I Foster-II forms
Note: Term Work should be based on Tutorials.
Textbooks :
Franklin F Kuo “Network Analysis and Synthesis” Wiley Toppan 2nd.ed. 1966
M E Van Valkenburg “Network Analysis” Prentice-Hall of India Pvt Ltd New Delhi
26
th
Indian Reprint 2000
Reference Books:
1. A Chakrabarti “Circuit Theory” Dhanpat Rai Co. Delhi 6h Edition
2. A. Sudhakar Shyammohan S. Palli “circuits and Networks Tata McGraw-Hill education
3. Smarajit Ghosh Network Theory Snallysis Syntshesis PHI learning
4. K.S. Suresh Kumar Elecric circuit analysis Pearson 2013
5. D Roy Choudhury Networks and Systems New Age International 1998.
TUTORIALS: At least 10 tutorials covering various topics of the syllabus.

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Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC305
Electronic
Instrumentation
Control
04
--
2 04
-- 1 05
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC305 Electronic
Instrumentation
Control
20 20 20 80
25
--
--
125
2 hour to be taken as tutorial classwise
Course Pre-requisite:
• Basic Electrical Engineering
Course Objectives:
To provide basic knowledge about the various sensors and data acquisition systems
applied in Wireless sensor network.
To provide fundamental concepts of control system such as mathematical modeling time
response and frequency response.
To develop concepts of stability and its assessment criteria.
Course Outcome:
After successful completion of the course student will be able to
Students will be able to explain principle of operation for various sensors.
Students will be able to describe functional blocks of data acquisition system.
Students will be able to find transfer functions for given system.
Students will be able to calculate time domain and frequency domain parameter for given
system
Students will be able to predict stability of given system using appropriate criteria.

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Module
No.
Unit No. Detailed Content Hours
1 Principle of Measurement Testing and Measuring
instruments
07
1.1 Introduction to Basic instruments: Components of generalized
measurement system Concept of accuracy precision linearity
sensitivity resolution hysteresis calibration.
1.2 Measurement of Resistance: Kelvin‟s double bridge
Wheatstone bridge and Mega ohm bridge
Measurement of Inductance: Maxwell bridge and Hey bridge
Measurement of Capacitance: Schering bridge
Q-Meter: Operating principle and applications
Energy and power meters: Working of energy and power
meter
2 Sensors and Transducers 08
2.1 Basics of sensors and Transducers-Active and passive
transducers characteristics and selection criteria of
transducers working principle of Eddy-current sensors
Pizoelectric transducers photoelectric and photovoltaic
sensors capacitive sensors
2.2 Displacement and pressure- Potentiometers pressure gauges
linear Variable differential transformersLVDT for
measurement of pressure and displacement strain gauges
2.3 Temperature Transducers- Resistance temperature
detectorsRTD. Thermistors and thermocouples their ranges
and applications
3 Telemetry and Data Acquisition System 08
3.1 Introduction and characteristics Landline Telemetry Radio
Telemetry Types of Multiplexing Systems
3.2 Data Acquisition: Components of Analog and Digital Data
Acquisition System
3.3 Uses of Data Acquisition System Use of recorders in Digital
systems Modern Digital Data Acquisition System.
4 Introduction to control system Analysis 07

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4.1 Introduction: Open and closed loop systems example of
control systems
4.2 Modelling: Modelling Transfer function model of electrical
systems Block diagram reduction techniques and Signal flow
graph
4.3 Dynamic Response: Standard test signals transient and steady
state behaviour of first and second order systems steady state
errors in feedback control systems and their types
5 Stability Analysis in Time Domain 08
5.1 Concept of stability: Routh and Hurwitz stability criterion
5.2 Root locus Analysis: Root locus concept general rules for
constructing root-locus root locus analysis of control system
concept of design of lag and lead compensator
6 Stability Analysis in frequency domain 10
6.1 Introduction: Frequency domain specification Relationship
between time and frequency domain specification of
systemstability margins
6.2 Bode Plot: Magnitude and phase plot Method of plotting Bode
plotStability margins and analysis using bode plot. Frequency
response analysis of RCRLRLC circuits
6.3 Nyquist Criterion: Concept of Polar plot and Nyquist plot
Nyquist stability criterion gain and phase margin
Note: Term Work should be based on Tutorials.
Textbooks :
1. A.K. Sawhney “Electrical Electronic Measurement Instrumentation” – DRS . India
2. M.M.S. Anand “Electronic Instruments and instrumentation Technology”.
3. H.S.Kalsi “Electronic Instrumentation”-TMH 2nd Edition.
4. Nagrath M.Gopal “Control System Engineering” Tata McGraw Hill.
5. K.Ogata “Modern Control Engineering Pearson Education” IIIrd edition.
Reference Books:
1. HelfrickCopper “Modern Electronic Instrumentation Measuring Techniques” – PHI
2. W.D. Cooper “Electronic Instrumentation And Measuring Techniques” – PHI
3. Benjamin C.Kuo “Automatic Control Systems Eearson education” VIIth edition

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4. Rangan C. S. Sarma G. R. and Mani V. S. V. "Instrumentation Devices And Systems"
Tata McGraw-Hill 2nd Ed. 2004.
5. Bell David A."Electronic Instrumentation and Measurements" PHI Pearson Education
2006.
6. Madan Gopal “Control Systems Principles and Design” Tata McGraw hill 7th
edition1997.
7. Normon “Control System Engineering” John Wiley sons 3rd edition.

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Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL301
Electronic
Devices
Circuits-I
Laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of Test
1 and Test 2
ECL301
Electronic
Devices
Circuits-I
Laboratory
-- -- -- --
25
25
--
50
Laboratory plan
Maximum of 8 practicals including minimum 2 simulations should be conducted based on
following topics
Study of different measuring instruments such as CRO Function Generator Multimeter
and Power Supply. Compulsory
Filter circuits
Biasing of BJT and FET
Frequency response
Zener regulator
Single stage amplifiers
Minimum One project based on:
Design of single stage CE and CS amplifier
Design of filter and regulator circuits
Design of power supply
Any other relevant topic based on syllabus
Note : Small project should be considered as a part of term-work.
Term Work:
At least 08 Experiments including 02 simulations covering entire syllabus must be given during
the “Laboratory session batch wise”. Computation/simulation based experiments are also
encouraged. The experiments should be students centric and attempt should be made to make
experiments more meaningful interesting and innovative. Application oriented one mini-project
can be conducted for maximum batch of four students.

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Ekeeda – Electronics Telecommunication Engineering
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit and Grading System” manual and should be
added and averaged. Based on above scheme grading and term work assessment should be done.
The practical and oral examination will be based on entire syllabus.

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Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL302
Digital
System
Design
Laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of Test
1 and Test 2
ECL302
Digital
System
Design
Laboratory
-- -- -- --
25
25
--
50
Laboratory plan
Maximum of 8 practicals including minimum 2 simulations should be conducted.
Suggested list of experiments:
1. Verify different logic gates.
2. Simplification of Boolean functions.
3. Verify Universal gates NAND and NOR and design EXOR and EXNOR gates using
Universal gates.
4. Implement Half adder Full adder Half subtractor and Full subtractor circuits.
5. Implement BCD adder using four bit binary adder IC-7483.
6. Flip flops conversion JK to D JK to T and D to TFF.
7. Implement logic equations using Multiplexer.
8. Design synchronous MOD N counter using IC-7490.
9. Verify encoder and decoder operations.
10. Implement digital circuits to perform binary to gray and gray to binary operations.
11.Verify truth table of different types of flip flops.
12. Verify different counter operations.
13. Write VHDL simulation code for different logic gates.
14. Write VHDL simulation code for combinational and sequential circuits
15. Write VHDL simulation code for 4:1 Multiplexer 2 line to 4 line binary decoder

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Ekeeda – Electronics Telecommunication Engineering
Minimum One project
Suggested list of Mini Projects:
1. Design Clock pulse generator.
2. Design Clap operated remote control for Fan.
3. Design BCD counter and show operation on Seven Segment Display.
4. Design digital stop watch.
5. Write VHDL code to implement traffic light controller.
6. Design water level indicator for overhead water tank.
7. Design frequency divider circuit.
8. Design switch debounce circuit.
9. Design sequence generator circuit.
10. Design sequence detector circuit.
11. Design Even/Odd parity generator/checker circuit.
12. Design simple LED flasher circuit.
13. Design digital dice.
14. Design fastest finger first indicator.
15. Design Toggle switch using TFF.
Note : Small project should be considered as a part of term-work.
Term Work:
At least 08 Experiments including 02 simulations covering entire syllabus must be given during
the “Laboratory session batch wise”. Computation/simulation based experiments are also
encouraged. The experiments should be students centric and attempt should be made to make
experiments more meaningful interesting and innovative. Application oriented one mini-project
can be conducted for maximum batch of four students.
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit and Grading System” manual and should be
added and averaged. Based on above scheme grading and term work assessment should be done.
The practical and oral examination will be based on entire syllabus.

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Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL303 OOP using
JAVA
laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of Test
1 and Test 2
ECL303 OOP using
JAVA
laboratory
-- -- -- --
25
25
--
50
Course Pre-requisites:
• Fundamentals of C-Programming
• Control Structures
• Arrays and String
Course Objectives:
1. To understand Object Oriented Programming and its principles.
2. To describe explain keywords and Data types.
3. Able to implement Methods Constructors Arrays Multithreding and Applet
4. To help students to understand how to use a programming language to resolve
problems.
Course Outcomes:
Students will be able to code a program using JAVA constructs.
Students will be able to understand fundamental features of an object oriented
language: object classes and interfaces exceptions and libraries of object collections.
Students will be able to develop a program that efficiently implements the algorithm
for given tasks.
Students will be able to utilize the knowledge acquired in this course to develop higher
level algorithms.

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Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Fundamental Concepts of Object Oriented Programming 06
1.1 Introduction to Object-Oriented Programming
1.2 Classes Objects Creating Classes and Objects
Principles of OOP: Abstraction Encapsulation Inheritance
Polymorphism
1.3 Differences And Similarity Between C and Java
2 Fundamental Of Java Programming 08
2.1 Features of Java JDK Environment Tools Structure of
Java Program
2.2 Java Keywords Super Keyword Final Keyword Abstract
Class
2.3 Data Types Variables OperatorsExpressions
2.4 Input Output Using Scanner Class
2.5 Exception Handling Object-Oriented Containers
3 Method Constructors Destructors And Arrays 04
3.1 Passing and Returning Parameters to Methods
3.2 Constructor and Types Destructor
3.3 Arrays and Types: Create One Dimensional Arrays Two
Dimensional Array Multidimensional Array String Array
4 Inheritance Interface And Package 04
4.1 Types of Inheritance: Single Multilevel Hierarchical
4.2 Method Overloading and Method Overriding
4.3 Interface
4.4 Packages
5 Multithreading And Applet 04
5.1 Life Cycle Of Thread
5.2 Priority In Multithreading
5.3 Applet Life Cycle
5.4 Creating Applet Applet Tag

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Textbooks :
1. Herbert Schidt “The Complete Reference” Tata McGraw-Hill Publishing Company
Limited Ninth Edition
2. D.T. Editorial Services “Java 8 Programming Black Book” Dreamtech Press Edition:
2015
3. Yashwant Kanitkar”Let Us Java” BPB Publications 2nd Edition edition.
Reference Books:
1. Java: How to Program 8/e Dietal Dietal PHI
2. Grady Booch James Rumbaugh Ivar Jacobson “The Unified Modeling Languageser
Guide” Pearson Education
3. Sachin Malhotra Saurabh Chaudhary “Programming in Java” Oxford University Press
2010
Software Tools:
1. Raptor-Flowchart Simulation:http://raptor.martincarlisle.com/
2. Eclipse: https://eclipse.org/
3. Netbeans:https://netbeans.org/downloads/
4. CodeBlock:http://www.codeblocks.org/
5. J-Edit/J-Editor/Blue J
Online Repository:
1. Google Drive
2. GitHub
3. Code Guru

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Laboratory plan
Maximum of 8 practicals including minimum 2 simulations should be conducted based on
following topics
Section Experiment Name Module
1. Write a program using command line argument in java.
• Echoing Command-Line Arguments.
• Parsing Numeric Command-Line arguments.
Module 1
2. Study of simple java programs
• WAP to calculate area circumference of circle
• WAP to swap given two strings
• WAP to separate out digits of a number
• WAP to convert temperature from Fahrenheit to Celsius
• WAP to find a square squarroot and Cube of a given no.
using abstraction
Module 1
3. Study of different operators in java
• WAP to compare two numbers.
• WAP to print truth table for java logical operators
• WAP to read the number shift left right by 3 bits.
Module 1
4. Write a program for various ways of accepting data through
keyboard display its content.
• Read through DataInputstream.
• Read input through Scanner.
• Read input through BufferedReader.
Module 2
5. Study of Arrays
Write a program for addition subtraction and
multiplication of two matrices.
Module 3
6. Study of Objects and Classes
• Define a class to represent a bank account. Include the
following members:
Data:
name of the depositor
account number
Module 3

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type of account
balance amount in the account
Methods:
1.to assign initial values
2.to deposit an amount
3.to withdraw an amount after checking balance.
4.to display the name balance
• WAP using this keyword
7. Study of Strings.
Accept the two strings from user do the following operations
• convert to lowercase
• convert to uppercase
• Replace all appearance of one character by another
• Compare two strings
• Derive the substring of a string
• Derive the position of a character in a string
• Calculate the length of a string
• Derive the nth character of a string
Module 2
8. WAP to implement following constructors
• Default constructor
• Parameterized constructor
Module 3
9. Study of Interface.
Create an interface Area implement the same in different classes
Rectangle circle triangle.
Module 4
10. Study of utility package
• WAP to generate a year using random class and check
whether it is leap or not.
• Write a program to display current date. Also display Time
in hours
Module 4

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Staff
Minutes using Date class.
11. Study of Inheritance
Typist
Teacher Officer
subject
Regular
Casual
name
dailywedges
Module 4
12. Study of Exception Handling in java.
Write a program to use throw finally and try catch to handle
exception.
Module 2
Staff
code

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13. Study of Multithreading.
WAP to illustrate function yield isAlive sleep join. Create three
threads as PQR. Thread P has maximum priority thread Q has
minimum priority thread R has normal priority.
Module 5
14. Study graphics using applet.
WAP to draw all geometric shapes and fill them with different
colors.
Module 5
Minimum One project
Suggested list of mini projects
1. Inventory Control System
2. Develop Calculator
3. Develop Editor Example: Notepad
4. Devlop Multimedia App to teach primary students Sahpes Colors etc.
5. Create an audio or video applet or swing based application with play pause and stop options.
Note : Small project should be considered as a part of term-work.
Term Work:
At least 10 experiments covering entire syllabus should be set to have well predefined inference
and conclusion.
The experiments should be students centric and attempt should be made to make experiments
more meaningful interesting and innovative. Application oriented one mini-project can be
conducted for maximum batch of four students.
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit and Grading System” manual and should be
added and averaged. Based on above scheme grading and term work assessment should be done.
The practical and oral examination will be based on entire syllabus.
Students are encourages to share their experiments/mini project codes on online repository.
Practical from any 10 sections out of 14 sections is compulsory . Practical exam slip should
cover all at least 10 sections.

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Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC401
Applied
Mathematics-
IV
04
--
2 04
-- 01 05
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC401 Applied
Mathematics-
IV
20 20 20 80
25
--
--
125
2 hour to be taken as tutorial classwise
Course Pre-requisite:
• Applied Mathematics I
• Applied Mathematics II
• Applied Mathematics III
Course Objectives:
1. To build the strong foundation in Mathematics of students needed for the field of Electronics
and Telecommunication Engineering
2. To provide students with mathematics fundamentals necessary to formulate solve and
analyses complex engineering problems.
3. To prepare student to apply reasoning informed by the contextual knowledge to engineering
practice.
4. To prepare students to work as part of teams on multi-disciplinary projects
Course Outcome:
After successful completion of the course student will be able to
1. Demonstrate basic knowledge of Calculus of variation Vector Spaces Matrix Theory
Random Variables Probability Distributions Correlation and Complex Integration.
2. Demonstrate an ability to identify and Model the problems in the field of Electronics and
Telecommunication and solve it.
3. Apply the application of Mathematics in Telecommunication Engineering.

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Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Calculus of Variation: 06
1.1 Euler‟s Langrange equation solution of Euler‟s Langrange
equation only results for different cases for Function
independent of a variable independent of another variable
independent of differentiation of a variable and independent of
both variables
1.2 Isoperimetric problems several dependent variables
1.3 Functions involving higher order derivatives: Rayleigh-Ritz
method
2 Linear Algebra: Vector Spaces 06
2.1 Vectors in n-dimensional vector space: properties dot product
cross product norm and distance properties in n-dimensional
vector space.
2.2 Vector spaces over real field properties of vector spaces over
real field subspaces
2.3 The Cauchy-Schwarz inequality Orthogonal Subspaces
Gram-Schmidt process
3 Linear Algebra: Matrix Theory 10
3.1 Characteristic equation Eigen values and Eigen vectors
properties of Eigen values and Eigen vectors.
3.2 Cayley-Hamilton theorem without proof examples based on
verification of Cayley- Hamilton theorem.
3.3 Similarity of matrices Diagonalisation of matrices.
3.4 Functions of square matrix derogatory and non-derogatory
matrices.
4 Probability 10
4.1 Baye‟s Theorem without proof
4.2 Random variable: Probability distribution for discrete and
continuous random variables Density function and
distribution function expectation variance.
4.3 Moments Moment Generating Function.

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4.4 Probability distribution: Binomial distribution Poisson
normal distribution For detailed study
5 Correlation 04
5.1 Karl Pearson‟s coefficient of correlation Covariance
Spearman‟s Rank correlation
5.2 Lines of Regression.
6 Complex integration 12
6.1 Complex Integration:Line Integral Cauchy‟s Integral theorem
for simply connected regions Cauchy‟s Integral formula.
6.2 Taylor‟s and Laurent‟s Series
6.3 Zeros singularities poles of fz residues Cauchy‟s R e s i d u e
theorem.
6.4 Applications of Residue theorem to evaluate real Integrals of
different types.
Note: Term Work should be based on Tutorials.
Textbooks :
1. H.K. Das “Advanced engineering mathematics” S . Chand 2008
2. A. Datta “Mathematical Methods in Science and Engineering” 2012
3. B.S. Grewal “Higher Engineering Mathematics” Khanna Publication
4. P.N.WartilarJ.N.Wartikar “A Text Book of Applied Mathematics” Vol. I II Vidyarthi
Griha Prakashan Pune
Reference Books:
1. B. V. Ramana “Higher Engineering Mathematics” Tata Mc-Graw Hill Publication
2. Wylie and Barret “Advanced Engineering Mathematics” Tata Mc-Graw Hill 6th Edition
3. Erwin Kreysizg “Advanced Engineering Mathematics” John Wiley Sons Inc
4. Seymour Lipschutz “Beginning Linear Algebra” Schaum‟s outline series Mc-Graw Hill
Publication
5. SeymourLipschutz “Probability” Schaum‟s outline series Mc-Graw Hill Publication

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Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC402
Electronic
Devices
Circuits-II
04
--
-- 04
-- -- 04
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC402 Electronic
Devices
Circuits-II
20 20 20 80
--
--
--
100
Course Pre-requisite:
• Electronic Devices Circuits-I
Course Objectives:
To understand the operation of the various bias circuits of MOSFET and Analyze and
design MOSFET bias circuits.
To understand the operation and design of multistage amplifier for a given specification.
To understand the operation and design of transformer coupled various types of power
amplifier circuits.
To understand the effects of negative feedback on amplifier circuits.
To analyze the different RC and LC oscillator circuits to determine the frequency of
oscillation.
Course Outcome:
After successful completion of the course student will be able to
1. Design and analyse the basic operations of MOSFET.
2. Know about the multistage amplifier using BJT and FET in various configuration to
determine frequency response and concept of voltage gain.
3. Know about different power amplifier circuits their design and use in electronics and
communication circuits.
4. Know the concept of feedback amplifier and their characteristics.
5. Design the different oscillator circuits for various frequencies

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Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Introduction to MOSFET 08
1.1 MOSFET - Symbol Types of MOSFET - Depletion and
Enhancement type MOSFET N channel and P channel
1.2 Construction Operation and V-I characteristics of MOSFET
1.3 MOSFET biasing - Types of Depletion enhancement
MOSFET biasing
1.4 MOSFET as amplifier
2 Introduction of Multistage amplifiers 06
2.1 RC coupled transformer coupled direct coupled
2.2 Low and high frequency considerations of cascade amplifier
cascode amplifier CE-CB Darlington pair amplifier.
3 Design of Multistage amplifiers 10
Analysis and design considerations of multistage amplifiers
CE-CE CS-CS CS-CE effect of source and load resistance
4 Large signal amplifiers 08
4.1 Harmonic distortion and power efficiency of Class A B AB
and C amplifiers
4.2 Design of Class A Class B and Push-Pull Power amplifier
design.
4.3 Thermal considerations and design selection of heat sinks.
5 Feedback amplifiers 08
5.1 Feedback concept ideal feedback amplifier classification of
feedbacks Various topologies
5.2 Analysis and design of different types of negative feedback.
6 Oscillators 08
6.1 Principle of oscillation RC oscillator twin T oscillator
6.2 Oscillator with LC feedback. Colpitts oscillator Hartley
oscillator Crystal controlled oscillator.
6.3 Design of different oscillator circuits.

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Ekeeda – Electronics Telecommunication Engineering
Textbooks :
D. A. Neamen “Electronic Circuit Analysis and Design” Tata McGraw Hill 2
nd
Edition.
R. L. Boylestad“Electronic Devices and Circuit Theory” Pearson 11
th
Edition.
T. F. Bogart“Electronic Devices And Circuit” Merrill 6
th
Edition.
R. S. Dudhe and M. Farhan “Electronic Devices and Circuits” Synergy Knowledgeware
1
st
Edition
Reference Books:
Salivahanan N. Suresh Kumar“Electronic Devices and Circuits” Tata McGraw Hill
3
rd
Edition
J. Millman Christos CHalkias and Satyabratatajit Millman‟s“Electronic Devices and
Circuits” McGrawHill 3
rd
Edition
Muhammad H. Rashid “Microelectronics Circuits Analysis and Design” Cengage
Learning 2
nd
Edition.

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Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC403
Linear
Integrated
Circuits
04
--
-- 04
-- -- 04
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC403 Linear
Integrated
Circuits
20 20 20 80
--
--
--
100
Course Pre-requisite:
• Basic Electrical Engineering
• Electronic Devices Circuits-I
Course Objectives:
1. To understand the concepts working principles and key applications of linear integrated
circuits.
2. To perform analysis of circuits based on linear integrated circuits.
3. To design circuits and systems for particular applications using linear integrated circuits.
Course Outcome:
After successful completion of the course student will be able to
1. Understand the fundamentals and areas of applications for the integrated circuits.
2. Analyze important types of integrated circuits.
3. Demonstrate the ability to design practical circuits that perform the desired operations.
4. Understand the differences between theoretical practical simulated results in
integrated circuits.
5. Select the appropriate integrated circuit modules to build a given application.

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Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Introduction to operational amplifiers 08
1.1 Analysis of differential amplifier circuit configurations using
FETs Effect of Swamping resistor Current sources using
FETs Widlar current source Wilson current source Voltage
sources and references DC level shifters.
1.2 Ideal Practical Operational Amplifiers Operational
amplifier characteristics Operational amplifier parameters
Operational amplifier open loop and closed loop
configurations.
2 Applications of Operational Amplifier 08
2.1 Amplifiers: Inverting non-inverting buffer summing
difference amplifiers integrator differentiator ideal
practical current amplifier instrumentation amplifier log and
antilog amplifiers..
2.2 Converters: Current to voltage converters voltage to current
converters voltage to frequency converter frequency to
voltage converter.
2.3 Active Filters: Second order active low pass high pass band
pass and band reject filters Introduction to switch capacitor
filters.
2.4 Sine Wave Oscillators: RC phase shift oscillator Wien bridge
oscillator.
3 Non-Linear Applications of Operational Amplifier 08
3.1 Comparators: Inverting comparator non-inverting comparator
zero crossing detector window detector peak detector sample
hold circuits.
3.2 Schmitt Triggers: Inverting Schmitt trigger non-inverting
Schmitt trigger.
3.3 Waveform Generators: Square wave generator and triangular
wave generator.
3.4 Precision Rectifiers: Half wave and full wave precision
rectifiers.
4 Analog to Digital and Digital to Analog Convertors 08
4.1 Performance specifications of ADC single ramp ADC ADC
using DAC dual slope ADC successive approximation ADC.
4.2 Performance specifications of DAC binary weighted resistor
DAC R/2R ladder DAC inverted R/2R ladder DAC.
5 Special Purpose Integrated Circuits 08
5.1 Functional block diagram and working of IC 555 design of
astable and monostable multivibrator using IC 555 application

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Ekeeda – Electronics Telecommunication Engineering
of IC 555 as pulse position modulator pulse width modulator
and Schmitt Trigger.
5.2 Functional block diagram and working of VCO IC 566 and
application as frequency modulator Functional block diagram
and working of PLL IC 565 and application as FSK
Demodulator Functional block diagram and working of
multiplier IC 534andapplication as a phase detector
Functional block diagram and working of waveform generator
XR 2206 and application as sinusoidal FSK generator.
6
Voltage Regulators 08
6.1 Functional block diagram working and design of three
terminal fixed 78XX 79XX series and three terminal
adjustable LM 317 LM 337 voltage regulators.
6.2 Functional block diagram working and design of general
purpose 723 LVLC LVHC HVLC and HVHC with current
limit and current fold-back protection Switching regulator
topologies Functional block diagram and working of LT1070
monolithic switching regulator.
Textbooks :
Ramakant A. Gayakwad “Op-Amps and Linear Integrated Circuits” Pearson Prentice
Hall 4
th
Edition.
K. R. Botkar “Integrated Circuits” Khanna Publishers 2004
D. Roy Choudhury and S. B. Jain “Linear Integrated Circuits” New Age International
Publishers 4
th
Edition.
Reference Books:
Sergio Franco “Design with operational amplifiers and analog integrated circuits” Tata
McGraw Hill 3
rd
Edition.
David A. Bell “Operation Amplifiers and Linear Integrated Circuits” Oxford University
Press Indian Edition.
R. F. Coughlin and F. F. Driscoll “Operation Amplifiers and Linear Integrated Circuits”
Prentice Hall 6
th
Edition.
“J. Millman Christos CHalkias and Satyabratatajit Millman‟s“Electronic Devices and
Circuits” McGrawHill 3rdEdition”.

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50
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC404
Signals and
Systems
04
--
2 04
-- 01 05
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC404 Signals and
Systems
20 20 20 80
25
--
--
125
2 hour to be taken as tutorial classwise
Course Pre-requisite:
• Applied Maths-III
• Circuit Theory and Networks
Course Objectives:
1. To introduce students the concept and theory of signals and systems needed in electronics
and telecommunication engineering fields.
2. To introduce students to the basic idea of signal and system analysis and its
characterization in time and frequency domain
Course Outcome:
After successful completion of the course student will be able to
1. Understand about various types of signals and systems classify them analyze them and
perform various operations on them
2. Understand use of transforms in analysis of signals and system in continuous and discrete
time domain.
3. Observe the effect of various properties and operations of signals and systems.
4. Evaluate the time and frequency response of Continuous and Discrete time systems
which are useful to understand the behaviour of electronic circuits and communication
systems.

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51
Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Introduction to signals and systems 08
1.1 Introduction to signals: Definition sampling theorem
sampling of continuous time signals elementary signals:
exponential sine step impulse ramp rectangular triangular
signum sinc operations on signals
1.2 Classification of signals: Continuous and discrete time
deterministic and non-deterministic periodic and aperiodic
symmetric even and asymmetric odd energy and power
causal and anti-causal signal Case study of different signals
from communication and biomedical field
1.3 Introduction to systems: Definition Classification of systems:
Static and dynamic time variant and time invariant linear and
nonlinear causal and non-causal stable and unstable systems.
communication and control system as examples
2 Time domain analysis of continuous time and discrete time
systems
08
2.1 Representation of systems using differential /difference
equation Impulse step and exponential response system
stability
2.2 Use of convolution integral and convolution sum for analysis
of LTI systems properties of convolution integral/sum
impulse response of interconnected systems
2.3 Correlation and spectral Density: auto-correlation cross
correlation analogy between correlation and convolution
energy spectral density power spectral density relation of
ESDPSD with auto-correlation
3 Frequency domain analysis of continuous and discrete 10
signals:
3.1 Review of Fourier series: Trigonometric and exponential
Fourier series representation of signals Gibbs phenomenon
Discrete Time Fourier Series properties analogy between
Continuous Time Fourier Series CTFS and Discrete Time
Fourier Series DTFS.
3.2 Fourier Transform FT: Fourier Transform and Inverse
Fourier Transform on periodic and non-periodic signals
limitations of CT/DT Fourier Transform and need for
Laplace/Z Transform.
3.3 Overview of Laplace Transform: Need of Laplace
Transform review of unilateral and bilateral Laplace

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Ekeeda – Electronics Telecommunication Engineering
Transform properties inverse of Laplace Transform concept
of Region of Convergence ROCpoles and zeros relation
between continuous time Fourier Transform and Laplace
Transform.
4 Z-Transform 08
4.1 Need of Z-Transform definition of unilateral and bilateral Z-
Transform Z-Transform of finite and infinite duration
sequences properties Inverse Z-Transform relation between
discrete time Fourier Transform and Z-Transform Z-
Transform of standard signals ROC for ZT plotting poles and
zeros of transfer function.
4.2 Analysis of discrete time LTI systems using Z-Transform:
Transfer Function causality and stability of systems
frequency response impulse and step relation between
Laplace Transform and Z–Transform.
5 State Space Analysis and Realization Structures 08
5.1 State Variable Analysis: Introduction to the notion of „state‟
systematic procedure for determining state equations solution
of state equations using Laplace transform definition of
expA where A is a matrix time domain solution of state
equations.
5.2 Systems with finite duration and infinite duration impulse
response recursive and non-recursive discrete time system
realization structures: direct form–I direct form–II Transpose
cascade and parallel forms.
6 Applications of Signals and Systems 06
6.1 Signal Processing Applications: Speech and Audio
Processing Multimedia image video processing
Underwater acoustic signal processing Biological signal
analysis
6.2 Communication and Control System Application: Modulation
Analog and Digital process Feedback/Feedforward Control
system
Textbooks :
1. NagoorKani “Signals and Systems” Tata McGraw Hill Third Edition 2011.
2. B.P. Lathi “Principles of Linear Systems and Signals” Oxford Second Edition 2010.
3. S. L. Nalbalwar A. M. Kulkarni and S. P. Sheth “Signals and Systems” Synergy
Knowledgeware 2016.
4. Simon Haykin and Barry Van Veen “Signals and Sytems” John Wiley and Sons
Second Edition2004.

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Ekeeda – Electronics Telecommunication Engineering
Reference Books:
1. Hwei. P Hsu “Signals and Systems” Tata McGraw Hill Third edition 2010
2. V. Krishnaveni and A.Rajeshwari “Signals and Systems” Wiley-India First Edition
2012.
3. NarayanaIyer “Signals and Systems” Cenage Learning First Edition 2011.
4. Michael J Roberts “Fundamentals of Signals and systems” Tata McGraw Hill special
Indian Economy edition 2009.
5. Rodger E Ziemer William H. Tranter and D. Ronald Fannin “Signals and Systems”
Pearson Education Fourth Edition 2009.
6. Alan V. Oppenhiem Alan S. Willsky and S. Hamid Nawab “Signals and Systems”
Prentice-Hall of India Second Edition 2002.

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54
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory Practical Tutorial Total
ECC405
Principles of
Communication
Engineering
04
--
-- 04
-- -- 04
Subject
Code
Subject Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam
Test 1
Test2
Avg. Of Test
1 and Test 2
ECC405 Principles of
Communication
Engineering
20 20 20 80
--
--
--
100
Course Pre-requisite:
• Applied Maths III
• Electronic Devices and Circuits I
Course Objectives:
1. To introduce students to various modulation and demodulation techniques of analog
communication.
2. To analyze different parameters of analog communication techniques.
3. To study pulse modulation and demodulation.
Course Outcome:
After successful completion of the course student will be able to
1. Use different modulation and demodulation techniques used in analog communication
2. Identify and solve basic communication problems
3. Analyze transmitter and receiver circuits
4. Compare and contrast design issues advantages disadvantages and limitations of analog
communication systems

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55
Ekeeda – Electronics Telecommunication Engineering
Module
No.
Unit No. Detailed Content Hours
1 Basics of Communication System 06
1.1 Block diagram electromagnetic spectrum signal bandwidth
and power types of communication channels Introduction to
time and frequency domain.
1.2 Types of noise signal to noise ratio noise figure and noise
temperature Friss transmission formula.
2 Amplitude Modulation and Demodulation 12
2.1 Basic concepts signal representation need for modulation
2.2 Spectrum waveforms modulation index bandwidth voltage
distribution and power calculations
2.3 DSBFC: Principles modulating circuits low level and high
level transmitters DSB suppressed carrier :Multiplier
modulator nonlinear modulator and switching modulator
2.4 Amplitude demodulation: Diode detector practical diode
detector square law detector
2.5 Comparison of different AM techniques Applications of AM
and use of VSB in broadcast television
3 Angle Modulation and Demodulation 12
3.1 Frequency modulation FM: Basic concept mathematical
analysis spectrum of FM wave sensitivity phase deviation
and modulation index deviation and percent modulated
waves bandwidth requirement of angle modulated waves
deviation ratio narrowband FM and wideband FM
3.2 Varactor diode modulator FET reactance modulator
stabilized AFC Direct FM transmitter indirect FM
Transmitter noise emphasis and de-emphasis
3.3 Phase modulation PM: Principle and working of transistor
direct PM modulator and relationship and comparison between
FM and PM
3.4 FM demodulation: Balance slope detector Foster-Seely
discriminator ratio detector FM demodulator using Phase
lock loop PLL amplitude limiting and thresholding
comparison between FM demodulators comparison between
AM FM and PM
3.5 Applications of FM and PM

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4 Radio Receivers 06
4.1 TRF Super - heterodyne receiver receiver parameters and
choice of IF
4.2 AM receiver circuits and analysis simple AGC delayed AGC
forward AGC and communication receiver
4.3 FM receiver circuits comparison with AM receiver
4.4 Single and independent sideband SSB and ISB receivers
5 Analog Pulse Modulation Demodulation 08
5.1 Sampling theorem for low pass signal proof with spectrum
Nyquist criteria
5.2 Sampling techniques aliasing error and aperture effect
5.3 PAMPWM PPM generation and detection
5.4 Applications of Pulse Communication
6 Multiplexing De-multiplexing 04
6.1 Frequency Division Multiplexing transmitter receiver block
diagram
6.2 Time Division Multiplexing transmitter receiver block
diagram
6.3 Examples and applications of FDM and TDM
Textbooks :
1. Kennedy and Davis "Electronics Communication System" Tata McGraw Hill Fourth
edition.
2. B.P. Lathi Zhi Ding "Modern Digital and Analog Communication system" Oxford
University Press Fourth edition.
3. Wayne Tomasi "Electronics Communication Systems" Pearson education Fifth edition.
Reference Books:
1. Taub Schilling and Saha "Taubs Principles of Communication systems" Tata McGraw
Hill Third edition.
2. P. Sing and S.D. Sapre "Communication Systems: Analog and Digital” Tata McGraw
Hill Third edition.
3. Simon Haykin Michel Moher "Introduction to Analog and Digital Communication"
Wiley Second edition.

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Ekeeda – Electronics Telecommunication Engineering
4. Dennis Roddy and John Coolen "Electronic Communication" Prentice Hall Third
Edition.
5. Louis Frenzel “Communication Electronics” Tata McGraw Hill Third Edition.
6. Roy Blake "Electronic Communication Systems" Delmar Publication Second edition

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58
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL401
Electronic
Devices
Circuits-II
Laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of
Test 1 and
Test 2
ECL401
Electronic
Devices
Circuits-II
Laboratory
-- -- -- --
25
25
--
50
Laboratory plan
Minimum 8 practicals including minimum 2 simulations should be conducted.
Suggested list of experiments
1. Design and Analyze two stage BJT amplifier Frequency response and performance
parameters
2. Design and Analyze two stage FET amplifier Frequency response and performance
parameters
3. Design Multistage BJT amplifier and finding its parameters Verify.
4. Design and Analyze Voltage series feedback amplifier using BJT/FET and verify its
effect on frequency response. x
5. Design and Analyze Current series feedback using BJT/FET and verify its effect on
frequency response.
6. Design Multistage JFET amplifier and finding its parameters verify.
7. Design and Analyze RC Phase shift oscillator for different amplitude and frequency.
8. Design and Analyze Colpitt / Hartley oscillator for different amplitude and frequency.
9. Class C power amplifier and its efficiency
Minimum One project based on:
1. Simple Emergency light.
2. DC servo amplifier using MOSFET.
3. Audio tone control circuit.
4. Public address system.
5. Automatic Door Bell

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Ekeeda – Electronics Telecommunication Engineering
6. Clapp Switch
7. Topic related to syllabus
Note :Small project should be considered as a part of term-work.
Term Work:
At least 08 Experiments including 02 simulations covering entire syllabus must be given during
the “Laboratory session batch wise”. Computation/simulation based experiments are also
encouraged. The experiments should be students centric and attempt should be made to make
experiments more meaningful interesting and innovative. Application oriented one mini-project
can be conducted for maximum batch of four students.
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit andGrading System” manual and should be
added and averaged. Based on above scheme gradingand term work assessment should be done.
The practical and oral examination will be based on entire syllabus.

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60
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL402
Linear
Integrated
Circuits
Laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of
Test 1 and
Test 2
ECL402
Linear
Integrated
Circuits
Laboratory
-- -- -- --
25
25
--
50
Laboratory plan
Minimum 8 practicals including minimum 2 simulations should be conducted.
Suggested list of experiments
Discrete Differential Amplifier
Inverting Non inverting Buffer Summing Difference amplifiers
Differentiator Integrator
Instrumentation amplifier
I to V and V to I converters
V to F and F to V convertors
Active Filters
Wien Bridge Oscillator
RC Phase shift Oscillator
Inverting Non inverting Schmitt trigger
Square Triangular wave generator
Precision rectifiers
Peak detector Sample Hold Circuits
Analog to Digital converter

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Ekeeda – Electronics Telecommunication Engineering
Digital to Analog converter
Multivibrators using IC 555
PPM PWM and Schmitt trigger using 555
Frequency modulatorusing VCO IC 566.
FSK DemodulatorusingPLL IC 565.
Phase detectorusing multiplier IC 534.
Sinusoidal FSK generator using XR 2206
Voltage Regulators using 78XX/79XX 317/337 723
Minimum One project based on:
1. Variable Power Supply
2. Data Acquisition System
3. Function Generator
4. Topic related to syllabus
Note :Small project should be considered as a part of term-work.
Term Work:
At least 08 Experiments including 02 simulations covering entire syllabus must be given during
the “Laboratory session batch wise”. Computation/simulation based experiments are also
encouraged. The experiments should be students centric and attempt should be made to make
experiments more meaningful interesting and innovative. Application oriented one mini-project
can be conducted for maximum batch of four students.
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit andGrading System” manual and should be
added and averaged. Based on above scheme gradingand term work assessment should be done.
The practical and oral examination will be based on entire syllabus.

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62
Ekeeda – Electronics Telecommunication Engineering
Subject
Code
Subject
Name
Teaching Scheme Credits Assigned
Hrs.
Theory Practical Tutorial Theory TW/Pracs Tutorial Total
ECL403
Principles of
Communication
Engineering
Laboratory
-- 02 -- -- 1 -- 1
Subject
Code
Subject
Name
Examination Scheme
Theory Marks
Term
Work
Practical
Oral
Oral
Total
Internal assessment
End Sem.
Exam Test 1 Test2
Avg. Of
Test 1 and
Test 2
ECL403
Principles of
Communication
Engineering
Laboratory
-- -- -- --
25
25
--
50
Laboratory plan
Minimum 8 practicals including minimum 2 simulations should be conducted.
Suggested list of experiments
1. Generation and detection of AM DSB-FC DSB-SCSSB signal.
2. Generation and detection of FM signal.
3. Study of AM broadcast receiver Super heterodyne.
4. Generation of PAM signal and verify the sampling theorem.
5. Generation of PPM PWM signal.
6. Study of TDM and FDM multiplexing techniques.
Suggested list of Minimum projects
AM transmitter /receiver.
FM transmitter /receiver.
PAMPPMPWM circuits with IC 555
FM remote encoder/decoder circuits
Transistor Intercom circuit
Walkie -Talkie Circuit
Arduino based communication circuits

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Ekeeda – Electronics Telecommunication Engineering
Electronic voting machine.
Electronic Notice Board Using Android.
Home security system.
Note :Small project should be considered as a part of term-work.
Term Work:
At least 08 Experiments including 02 simulations covering entire syllabus must be given during
the “Laboratory session batch wise”. Computation/simulation based experiments are also
encouraged. The experiments should be students centric and attempt should be made to make
experiments more meaningful interesting and innovative. Application oriented one mini-project
can be conducted for maximum batch of four students.
Term work assessment must be based on the overall performance of the student with every
experiments/tutorials and mini-projects are graded from time to time. The grades will be
converted to marks as per “Choice Based Credit and Grading System” manual and should be
added and averaged. Based on above scheme grading and term work assessment should be done.
The practical and oral examination will be based on entire syllabus.

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