regarding scheme revised syllBE in Instrumentation Engg_1 Syllabus Mumbai University


regarding scheme revised syllBE in Instrumentation Engg_1 Syllabus Mumbai University by munotes

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Copy to : -
1. The Deputy Registrar, Academic Authorities Meetings and Services
(AAMS),
2. The Deputy Registrar, College Affiliations & Development
Department (CAD),
3. The Deputy Registrar, (Admissions, Enrolment, Eligibility and
Migration Department (AEM),
4. The Deputy Registrar, Research Administration & Promotion Cell
(RAPC),
5. The Deputy Registrar, Executive Authorities Section (EA),
6. The Deputy Registrar, PRO, Fort, (Publi cation Section),
7. The Deputy Registrar, (Special Cell),
8. The Deputy Registrar, Fort/ Vidyanagari Administration Department
(FAD) (VAD), Record Section,
9. The Director, Institute of Distance and Open Learni ng (IDOL Admin),
Vidyanagari,
They are requested to treat this as action taken report on the concerned
resolution adopted by the Academic Council referred to in the above circular
and that on separate Action Taken Report will be sent in this connection.

1. P.A to Hon’ble Vice -Chancellor,
2. P.A Pro -Vice-Chancellor,
3. P.A to Registrar,
4. All Deans of all Faculties,
5. P.A to Finance & Account Officers, (F.& A.O),
6. P.A to Director, Board of Examinations and Evaluation,
7. P.A to Director, Innovation, Incubation and Linkages,
8. P.A to Director, Board of Lifelong Learning and Extension (BLLE),
9. The Director, Dept. of Information and Communication Technology
(DICT) (CCF & UCC), Vidyanagari,
10. The Director of Board of Student Development,
11. The Director, Dep artment of Students Walfare (DSD),
12. All Deputy Registrar, Examination House,
13. The Deputy Registrars, Finance & Accounts Section,
14. The Assistant Registrar, Administrative sub -Campus Thane,
15. The Assistant Registrar, School of Engg. & Applied Sciences, Kalyan ,
16. The Assistant Registrar, Ratnagiri sub -centre, Ratnagiri,
17. The Assistant Registrar, Constituent Colleges Unit,
18. BUCTU,
19. The Receptionist,
20. The Telephone Operator,
21. The Secretary MUASA

for information.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 1


AC- 23/7/2020
Item No. 143


UNIVERSITY OF MUMBAI











Bachelor of Engineering
In
Instrumentation Engineering

Second Year with Effect from AY 2020 -21
Third Year with Effect from AY 2021 -22
Final Year with Effect from AY 2022 -23

(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)

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 2




















Date:
Dr. S.K.Ukarande Dr. Anuradha Majumdar
Associate Dean Dean
Faculty of Science and Technology Facult y of Science and Technology
University of Mumbai University of Mumbai
Sr.
No. Heading Particulars
1 Title of the Course S.Y of B.E in Instrumentation Engineering
2 Eligibility for
Admission
After Passing First Year Engineering as per the
Ordinance 0.6242
3 Passing Marks 40%
4 Ordinances /
Regulations ( if any) Ordinance 0.6242
5 No. of Years /
Semesters 8 semesters
6 Level P.G. / U.G. / Diploma / Certificate
(Strike out which is not applicable)
7 Pattern Yearly / Semester
(Strike out which is not applicable )
8 Status New / Revised
REV - 2019 ‘C’ Scheme
9 To be implemented
from Academic Year With effect from Academic Year: 2020 -2021 AC23/7/2020
Item No. 143
UNIVERSITY OF MUMBAI

Syllabus for Approval

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 3


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 Science and Technology (in particular Engineering)of University of
Mumbai has taken a lead in incorporating philosophy of outcome based education in the process of curriculum
development.
Faculty resolved that course objectives and course outcom es 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 muc h-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
educatio n. Credit assignment for courses is based on 15 weeks teaching learning process, however content o f
courses is 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 various 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 te chnology resolved that to minimize the burden of contact hours, total
credits of entire program will be of 170, wherein focus is not only on providing knowledge but also on building
skills, attitude and self learning. Therefore in the present curriculum sk ill based laboratories and mini projects are
made mandatory across all disciplines of engineering in second and third year of programs, which will definitely
facilitate self learning of students. The overall credits and approach of curriculum proposed in t he present revision
is in line with AICTE model curriculum.
The present curriculum will be implemented for Second Year of Engineering from the academic year 2020 -21.
Subsequently this will be carried forward for Third Year and Final Year Engineering in the academic years 2021 -
22, 2022 -23, respectively.


Dr. S. K. Uka rande Dr Anuradha Muzumdar
Associate Dean Dean
Faculty of Scien ce and Technology Faculty of Science and Technology
University of Mumbai University of Mumbai


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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 4


Incorporation and Implementation of Online Contents from
NPTEL/ Swayam Platform


The curriculum revision is mainly focused on knowledge 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 platforms such as NPTEL,
Swayam are appropriately provided. In an earlier revisi on 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 recom mendation 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 platforms such as NPTEL/ Swayam. Learners can be advised to take
up online cours es, 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






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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 5

PREAMBLE

Technical education in our country is progressing rapidly in manifolds. To maintain the quality of education
a systematic approach is necessary , which can be obtained by build ing a strong technical base with the quality.
Accreditation provide s quality assurance in higher education and recognition to the institution or program ,
meeting certain specif ied standards. The main -focus of an accreditation process is to measure the program
outcomes, essentially the range of skills and knowledge that a student will have at the tim e of graduation from
the program. Faculty of Science & Technology of the Universi ty of Mumbai has taken a lead in incorporating
a philosophy of outcome -based education in the process of curriculum development. The earlier syllabus was
more focused on providing information and knowledge across various domains, which led to loading of
students heav ily, in terms of direct contact hours.
I, as a Chairman, Board of Studies in Instrumentation Engineering of University of Mumbai, happy to state
here that, the revised curriculum focused on not only providing knowledge content but also on skill-based
activities like attitudes, self -learning, and project -based activities. More than 30 senior faculty members from
the different affiliated institutes of University of Mumbai were actively participated in this process . They are
either Heads of De partments or their senior representatives from the Department of Instrumentation
Engineering . The salient features of revised syllabus of Instrumentation Engineering, REV 2019 ‘C’ Scheme
are:
1. The overall credits and approach of the curriculum proposed in t he present revision are in line with
AICTE model curriculum.
2. Course objectives and course outcomes are framed as per NBA guidelines (Bloom’s Taxonomy) and
are clearly defined for each course.
3. Detailed guidelines are presented to un derstand the depth and t he approach to course to be taught,
which will enhance learner’s learning process.
4. The credit and grading system enables a learner -centric education since the workload estimated is
based on the investment of time in learning and not in teaching.
5. Minimizes the burden of contact hours, total credits of the entire program will be approximately 172.
Learners are now getting sufficient time for self -learning either through online courses or additional
projects for enhancing their knowledge and skillsets.
6. It als o focuses on continuous evaluation which will enhance the quality of education.
7. Credit assignment for courses is based on 15 weeks teaching -learning process, however, the content
of courses is to be taught in 12 -13 weeks and the remaining 2 -3 weeks to be utilized for revision, guest
lectures, coverage of content beyond the syllabus, etc.
8. The revised curriculum emphasizes on skill -based laboratories and project -based learning by
introducing mini projects in the second and third year of programs, which will facilitate self -learning
of students.

Dr. Alice Cheeran - Chairperson (BoS in Instrumentation Engineering )
Dr. M. D. Patil - Member
Dr. M. J. Lengare - Member
Dr. Sharad P. Jadhav - Member
Dr. Dipak Gawali – Member

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 6

Program Structure for Second Year Instrumentation Engineering
(With Effect from 2020 -2021)
Scheme for Semester - III
Course
Code Course Name Teaching Scheme
(Contact Hours)
Credits Assigned
Theory Pract. Tut. Theory Pract. Tut. Total
ISC301 Engineering Mathematics -III
3 -- 1 3 -- 1 4
ISC302 Transducers -I 4 -- 4 -- 4
ISC303 Analog Electronics 3 -- -- 3 -- -- 3
ISC304 Digital Electronics 3 -- -- 3 -- -- 3
ISC305 Electrical Networks and
Measurements 4 -- -- 4 -- -- 4
ISL301 Transducers -I - Lab -- 2 -- -- 1 -- 1
ISL302 Analog Electronics - Lab -- 2 -- -- 1 -- 1
ISL303 Digital Electronics - Lab -- 2 -- -- 1 -- 1
ISL304 Object Oriented
Program ming Lab -- 3# -- -- 1.5 -- 1.5
ISM301 Mini Project – 1 A -- 3$ -- -- 1.5 -- 1.5
Total 17 12 1 17 06 1 24
Course
Code Course Name Examination Scheme
Theory Term
Work PR &
OR Total

Internal Assessment End
Sem.
Exam Exam.
Duration
(in Hrs)
Test 1 Test2 Avg.
ISC301 Engineering Mathematics -III
20 20 20 80 3 25 -- 125
ISC302 Transducers -I 20 20 20 80 3 -- -- 100
ISC303 Analog Electronics 20 20 20 80 3 -- -- 100
ISC304 Digital Electronics 20 20 20 80 3 -- -- 100
ISC305 Electrical Networks and
Measurements 20 20 20 80 3 -- -- 100
ISL301 Transducers -I - Lab -- -- -- -- -- 25 25 50
ISL302 Analog Electronics - Lab -- -- -- -- -- 25 25 50
ISL303 Digital Electronics - Lab -- -- -- -- -- 25 25 50
ISL304 Object Oriented
Programming Lab -- -- -- -- -- 25 25 50
ISM301 Mini Project – 1 A -- -- -- -- -- 25 25 50
Total -- -- 100 400 -- 150 125 775
$ indicates work load of Learner (Not Faculty), for Mini Project
# Ou t of 3 hours, 1 hours theory shall be taught to entire class and 2 hours practical in batches

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 7

Scheme for Semester -IV
Course
Code Course Name Teaching Scheme
(Contact Hours)
Credits Assigned
Theory Pract. Tut. Theory Pract. Tut. Total
ISC401 Engineering Mathematics -IV 3 -- 1 3 -- 1 4
ISC402 Transducers -II 4 -- -- 4 -- -- 4
ISC403 Signal Conditioning and
Circuit Design 3 -- -- 3 -- -- 3
ISC404 Feedback Control System 3 -- -- 3 -- -- 3
ISC405 Control System
Components 4 -- -- 4 -- -- 4
ISL401 Process Control Components -
Lab -- 2 -- -- 1 -- 1
ISL402 Signal Conditioning and
Circuit Design - Lab -- 2 -- -- 1 -- 1
ISL403 Feedback Control System -
Lab -- 2 -- -- 1 -- 1
ISL404 Virtual Instrumentation -Lab -- 3# -- -- 1.5 -- 1.5
ISM401 Mini Project – 1 B -- 3$ -- -- 1.5 -- 1.5
Total 17 12 1 17 6 1 24
Course
Code Course Name Examination Scheme
Theory Term
Work PR &
OR Total

Internal Assessment End
Sem.
Exam. Exam.
Duration
(in Hrs)
Test 1 Test 2 Avg.
ISC401 Engineering Mathematics -IV 20 20 20 80 3 25 -- 125
ISC402 Transducers -II 20 20 20 80 3 -- -- 100
ISC403 Signal Conditioning and
Circuit Design 20 20 20 80 3 -- -- 100
ISC404 Feedback Control System 20 20 20 80 3 -- -- 100
ISC405 Control System
Components 20 20 20 80 3 -- -- 100
ISL401 Process Control Components -
Lab -- -- -- -- -- 25 25 50
ISL402 Signal Conditioning and
Circuit Design - Lab -- -- -- -- -- 25 25 50
ISL403 Feedback Control System - Lab -- -- -- -- -- 25 25 50
ISL404 Virtual Instrumentation - Lab -- -- -- -- -- 25 25 50
ISM401 Mini Project – 1 B -- -- -- -- -- 25 25 50
Total -- -- 100 400 -- 150 125 775
$ indicates work load of Learner (Not Faculty), for Mini Project
# out of 3 hours, 1 hours theory shall be taught to entire class and 2 hours practical in batches

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 8


Subject
code Subject Name Teaching scheme Credit assigned
ISC301 Engineering
Mathematics -III Theory Pract. Tut. Theory Pract. Tut. Total
3 -- 1 3 -- 1 4

Subject
code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC301 Engineering
Mathematics -III 20 20 20 80 25 - - 125

Subject Code Subject Name Credits
ISC30 1 Engineering Mathematics -III 4
Course Objectives The course is aimed
1. To familiarize with the Laplace Transform, Inverse Laplace Transform
of various functions, and its applications.
2. To acquaint with the concept of Fourier Series, its complex form and
enhance the problem solving skills
3. To familiarize the concept of complex variables, C -R equations,
harmonic functions, its conjugate and mapping in complex plane.
4. To understand the basics of Linear Algebra and its applications
5. To use concepts of vector calculus to analy ze and model engineering
problems.
Course Outcomes On successful completion of course learner/student will be able to:
1. Apply the concept of Laplace transform to solve the real integrals in
engineering problems.
2. Apply the concept of inverse Laplace transform of various functions in
engineering problems.
3. Expand the periodic function by using Fourier series for real life
problems and complex engineering problems.
4. Find orthogonal trajectories and analytic function by using basic
concepts of complex variables.
5. Illustrate the use of matrix algebra to solve the engineering problems.
6. Apply the concepts of vector calculus in real life problems.

Pre-requisite: Engineering Mathematics -I, Engineering Mathematics -II, Scalar and Vector Product: Scalar
and vector pr oduct of three and four vectors.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 9


Module Detailed Contents Hrs.
01 Module: Laplace Transform
1.1 Definition of Laplace transform, Condition of Existence of Laplace transform.
1.2 Laplace Transform (L) of Standard Functions like 𝑒𝑎𝑡, 𝑠𝑖𝑛(𝑎𝑡), 𝑐𝑜𝑠(𝑎𝑡),
𝑠𝑖𝑛ℎ(𝑎𝑡), 𝑐𝑜𝑠ℎ(𝑎𝑡) and 𝑡𝑛,𝑛≥0.
1.3 Properties of Laplace Transform: Linearity, First Shifting theorem, Second
Shifting Theorem, change of scale P roperty, multiplication by t, Division by t,
Laplace Transform of derivatives and integrals (Properties without proof).
1.4 Evaluation of integrals by using Laplace Transformation.
Self-learning Topics: Heaviside’s Unit Step function, Laplace Transform of
Periodic functions, Dirac Delta Function. CO-1

7
02 Module: Inverse Laplace Transform
2.1 Inverse Laplace Transform, Linearity proper ty, use of standard formulae to find
inverse Laplace Transform, finding I nverse Laplace transform using derivatives.
2.2 Partial fractions method to find inverse Laplace transform.
2.3 Inverse Laplace transform using Convo lution theorem (without proof).
Self-learning Topics: Applications to solve initial and boundary value problems
involving ordinary differential equatio ns. CO-2

6
03 Module: Fourier Series:
3.1 Dirichlet’s conditions, Definition of Fourier series and Parseval’s Identity
(without proof).
3.2 Fourier series of periodic function with period 2𝜋 and 2l.
3.3 Fourier series of even and odd functions.
3.4 Half range Sine and Cosine Series.
Self-learning Topics: Complex form of Fourier Series, Orthogonal and orthonormal
set of functions. Fourier Transform. CO-3

7
04 Module: Complex Variables:
4.1 Function f(z) of complex variable, limit, continuity and differentiability of f(z)
Analytic function, necessary and sufficient conditions for f(z) to be analytic (without
proof).
4.2 Cauchy -Riemann equations in cartesian coordinates (without proof).
4.3 Milne -Thomson method to determine analytic function f(z)when real part (u) or
Imaginary part (v) or its combination (u+v or u -v) is given.
4.4 Harmonic function, Harmonic conjugate and orthogonal trajec tories
Self-learning Topics: Conformal mapping, linear, bilinear m apping, cross ratio,
fixed points and standard transformations. CO-4

7

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 10

05 Module: Linear Algebra: Matrix Theory
5.1 Characteristic equation, Eigen values and Eigen vectors, Example based on
properties of Eigen values and Eigen vectors. (Without Proof).
5.2 Cayley -Hamilton theorem (Without proof), Ex amples based on verification of
Cayley - Hamilton theorem and comp ute inverse of Matrix.
5.3 Similarity of matrices, Diagonalization of matri ces. Functions of square matrix
Self-learning Topics: Application of Matrix Theory in machine learning and google
page rank algorithms, derogatory and non -derogatory
matrices . CO-5

6
06 Module: Vector Differentiation and Integra l
6.1 Vector differentiation : Basics of Gradient, Divergence and Curl (Without Proof).
6.2 Properties of vector field: Solenoidal and irrotational (conservative) vector fields.
6.3 Vector integral: Line Integral, Green’s theorem in a plane (Without Proof),
Stokes’ theorem (Without Proof) only evaluation.
Self-learning Topics: Gauss’ divergence Theorem and applications of Vector
calculus. CO-6

6

Term Work:
General Instructions:
1. Students must be encouraged to write at least 6 class tutorials on entire syllabus.
2. A group of 4 - 6 students should be assigned a self -learning topic. Students should prepare a presentation/
problem solving of 10 -15 minutes. This should be considered as mini project in Engineering mathematics.
This project should be graded for 10 marks depending on the performance of the students.

The distribution of Term Work marks will be as follows –
1. Attendance (Theory and Tutorial) 05 marks
2. Class Tutorials on entire syllabus 10 marks
3. Mini project 10 marks

Assessment :
Internal Assessment Test:
Assessment consists of two class tests of 20 marks each. The first -class test (Internal Assessment I) is to
be conducted when approx. 40% syllabus is completed and second class test (Internal Assessment II) when
additional 35% syllabus is completed. Duration of each test shall be one hour.


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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 11

End Semester Theory Examination:
1. Question paper will comprise of total 06 questions, each carrying 20 marks.
2. Total 04 questions need to be solved.
3. Question No: 01 will be compulsory and based on entire syllabus wherein 4 sub -questions of 5 marks each
will be asked.
4. Remaining questions will be randomly selected from all the modules.
5. Weightage of each module will be proport ional to number of respective lecture hours as mentioned in the
syllabus.

References: -
1. Advanced engin eering mathematics, H.K. Das, S . Chand, Publications
2. Higher Engineering Mathematics, B. V. Ramana, Tata Mc -Graw Hill Publication
3. Advanced Engineering Mathematics, R. K. Jain and S. R. K. Iyengar, Narosa publication
4. Advanced Engineering Mathematics, Wylie and Barret, Tata Mc -Graw Hill.
5. Theory and Problems of Fourier Analysis with applications to BVP, Murray Spiegel, Schaum’s Ou tline
Series
6. Vec tor Analysis Murry R. Spiegel, Schaum’s outline series, Mc -Graw Hill Publication
7. Beginning Linear Algebra, Seymour Lipschutz, Schaum’s outline series, Mc -Graw Hill Publication
8. Higher Engineering Mathematics, Dr. B. S. Grewal, Khanna Publication









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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 12


Subject
code Subject Name Teaching scheme Credit assigned
ISC302 Transducers -I Theory Pract. Tut. Theory Pract. Tut. Total
4 -- -- 4 -- -- 4

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC302 Transducers -I 20 20 20 80 - - - 100

Subject Code Subject Name Credits
ISC302 Transducers -I 4
Course Objectives The course is aimed
1. To introduce the students for the purpose of explaining the measurement
systems, errors of measurement.
2. To understand the definition and classification of sensors and transducers
based of their principle of operation and their applications in the various
industries.
3. To fam iliarize the student with the identification, classification, construction,
working principle and application of various transducers used for
displacement, level, temperature, speed and vibration measurement.
Course Outcomes On successful completion of course learner/student will be able to:
1. Explain the measurement systems, sources errors of measurement .
2. List and compare various standards used for selection of
transducers/sensors.
3. Describe the working principles of various displacement sensors and
transducers.
4. Interpret and apply different temperature transducers/sensors for industrial
applications .
5. Formulate and Design the solutions for given applications using
appropriate level sensors and transducer.
6. Apply the techniques of speed and vibration measurement in different
industries.

Prerequisite: Units and standards of measurement, concept of transducers (resistive, piezoelectric, pressure,
optical and pyro sensors, etc.), Knowledge of basic measurement.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 13

Details of Syllabus:
Module Contents Hrs. CO
Mapping
1. Instrumentation System
Units and standards of measurement , Introduction, block diagram, functional
elements of measurement system, static and dynamic characteristics of
transducer, Measurement and calibration systems - Requirement. sources of
errors and their statistical analysis, standards and calibration. 04 CO1
2. Sensor and Transducer:
Definition, working principle, classification (active, passive, primary,
secondary, mechanical, electrical, analog, digital), selection criteria,
transducer specifications, test condition and operating conditions. 04 CO2
3. Displacement transducers:
Resistive type transducers: potentiometer (linear and logarithmic), piezo -
resistive effect .
Inductive type transducers: LVDT, RVDT (transfer function, linearity,
sensitivity, source, frequency dependence, phase null, and signal
conditioning).
Capacitive type transducers: Linear and rotary (with change in distance
between plates, change in dielectric constant and change in overlapping area)
Digital transd ucer: translational and rotary encoders (absolute position and
incremental position encoders) .
Proximity sensors: inductive, capacitive, optical, ultrasonic, hall -effect and
magnetic.
Pneumatic transducer: flapper - nozzle transducer .
Comparative study for Displacement Transducers with applications, and
materials for capacitive, resistive, inductive and ultrasonic transducers . 14 CO3
4. Temperature transducers:
Modes of heat transfer, laws of conduction, convection and radiation,
Temperature scales, classification of Temperature Sensors, Overview of
mechanical temperature Sensors ( thermometer, thermostat ).
Resistance temperature detector (RTD): Principle, types, Configurations,
construction and working of RTD, Material for RTD, Signal Measurement
techniques for RTD, Comparative Response curves for RTD, 2 wire, 3wire
and 4 wire RTD Element, Lead wire Compensation in RTD, self -heating
effect, Specifications, advantages, disadvantages and applications of RTD
and sums.
Thermistor s: Principle, types (NTC and PTC), characteristics, Construction
and working of Thermistor, Materials, specifications of Thermistor,
applications and sums.
Thermocouples: Principle, thermoelectric effect, See beck effect, Peltier
effect, laws of thermocouple, types of thermocouple with Characteristic 14 CO4

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 14

curve, thermocouple table, Sensitivity, constructional Feature s of
Thermocouples., Thermo couple specifications, electrical noise and noise
reduction techniques, cold junction Compensation met hod, thermopile,
thermocouple emf measurement method, Thermo well Material of
construction and its specifications and sums.
Pyrometers: Principle, Construction and working of Radiation and optical
pyrometers and its Applications. Comparative study for Tem perature
Transducers.
5. Level Transducers: working principle, types, materials, design criterion:
float, displacers, bubbler, and DP - cell, ultrasonic, capacitive, microwave,
radar, radioactive type, laser type transducers, level gages, resistance,
thermal, TDR/ PDS type (Time domain reflectometry/ Phase difference
sensors), solid level detectors, fiber optic level detectors, Level switches.
Comparative study for Level Transducers . 08 CO5
6. Speed and Vibration Measurement: stroboscopes, toothed rotor, eddy
current, electromagnetic transducers (mo ving coil, moving magnet), AC and
DC tachometers: Hall Effect proximity pickup, photoelectric, photo -
reflective, pulse counting method. Seismic, LVDT, piezoelectric.
08 CO6

Internal Assessment:
Internal Assessment consists of two tests out of which, one should be a 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of 4 to 5 marks
will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weightage of each module will be proportional to number of respective lecture hours
as mentioned in the syllabus.
Text Books:
1. B.C Nakra, K.K. Chaudhary, Instrumentation, Measurement and Analysis, Tata McGraw -Hill
Education, 01 -Oct-2003 - Electronic instruments - 632 page.
2. Patranabis D, Sensors and Transducers, Prentice Hall India Learning Private Limited; 2 edition (2003)
- 344 pages.
3. A. K. Sawhney, Puneet Sawhney,A course in Electrical and Electronic Measurement and
Instrumentation, Dhanpat Rai and Co. Rai, 1996 -
4. Rangan, Mani, Shar ma.Instrumentation systems and Devices, 2nd Ed.,Tata McGraw Hill.
5. D.V.S. Murthi, “Instrumentation and Measurement Principles”, PHI, New Delhi, Second ed. 2003.



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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 15


Reference Books:
1. Doeblin E.D., Measurement system, Tata McGraw Hill., 4th ed, 2003.
2. Bela G. Liptak, Instrument Engineers' Handbook, Fourth Edi tion, Volume One: Process Measurement
and Analysis, June 27, 2003.
3. Neubert Hermann K. P., Instrument Transducer, 2nd ed., Oxford University Press, New Delhi, 2003.
4. Johnson Curtis D., Process Control Instrumentation Technology, 8th Ed., 2005
5. S.P. Sukhatme, Heat Transfer, 3rd edition, University Press.
6. B.E. Jones, Instrument Technology.
7. Chortle Keith R., Fundamentals of Test, Measurement Instrument Instrumentation, ISA Publication.
8. Alan S Morris, Measu rement and Instrumentation Principles; 3rd Edition

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 16

Subject
code Subject
Name Teaching scheme Credit assigned
ISC303 Analog
Electronics Theory Pract. Tut. Theory Pract. Tut. Total
3 - - 3 - - 3

Sub
Code Subject
Name Examination scheme
Theory (out of 100) Term
work Pract.
and
Oral Oral Total Internal Assessment End sem
Exam Test1 Test2 Avg.
ISC303 Analog
Electronics 20 20 20 80 - - - 100

Subject Code Subject Name Credits
ISC303 Analog Electronics 3
Course Objectives The course is aimed
1. To familiarize the student with basic electronic devices and circuits.
2. To analyze the DC biasing circuits , low and high frequency AC analysis of
various electronic devices.
3. To introduce the students with basic construction and operation of
differential and multistage amplifier.
4. To design d ifferent types voltage regulators and discuss the power
amplifiers .
5. To employ various devices for industrial and consumer electronics.
Course Outcomes On successful completion of course learner/student will be able to:
1. Demonstrate the application of diodes and formulate the DC analysis of BJT.
2. Formulate and attribute BJT biasing techniques and its frequency response.
3. Apply the basic construction and characteristics of FET to analyze the DC
and AC circuit s.
4. Utilize the basic construction and characteristics of MOSFET to formulate
the DC and AC circuits.
5. Describe the Differential and multistage amplifier and its stages in detail.
6. Discuss the power amplifiers and design power supply using different IC
volta ge regulators.
7. Pre-requisite: Introduction of PN junction

Page 20


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 17

Details of Syllabus:
Module Contents Hrs. CO
mapping
1. Bipolar Junction Transistor:
Introduction to Diodes and its applications as Clipper and Clamper, Bipolar
Junction Transistor, Device structure and physical operation, characteristics,
the BJT as an amplifier and a switch, DC Analysis of BJT Circuits, Biasing
BJT Amplifier Circuits, Stability Analysis. 08 CO1
2. BJT AC Analysis:
Amplification in AC domain, BJT transistor modelling, The re Transistor
model, Hybrid equivalent model for CE configuration, Derivation of
parameters trans -conductance, input resistances, voltage gain and current
gain. Single stage BJT amplifiers CE configuration (with and without
feedback), Small Signal equivalent circuit, frequency response of a CE
amplifier, low frequency response, high frequency response. 08 CO2
3. Field effect Transistors:
Introduction to JFET, Types, Construction, Operation, Static Characteristics,
Pinch off voltage, FET Volt -Ampere characteristics, FET Configurations
(CS/CD/CG) and their Comparison. Biasing of FET. FET as an amplifier and
its analysis (CS) and its frequency response.

06 CO3
4. MOS Field effect Transistors:
Introduction to MOSFET as basic element in VLSI, Device structure and
physical operation, current – voltage characteristics, the MOSFET as an
amplifier and a switch, DC Analysis of MOSFET Circuits, Biasing MOSFET
Amplifier Circuits, frequency response of a CS amplifier, low frequency
response. 06 CO4
5. Differential and Multistage Amplifiers:
Preview, the Differential Amplifier, Basic BJT Differential Pair (SIBO, SIUO,
DIBO, DIUO), Capacitive coupled and Direct coupled multistage amplifier.
Differential Amplifier with Active Load, Gain Stage and Simple Output Stage,
Diff-Amp Frequency Response. 04 CO5
6. Power Amplifier:
Definition and amplifier types, Series fed class A amplifier, Transformer
coupled class A amplifier, Class B amplifier operation and circuits, Amplifier
distortion, Push Pull Amplifier,
Power supply design using 78xx series, 79xx series and adjustable voltage
IC regulators like 723 and 317. Switched Mode Power Supply (SMPS) –
Block diagram with advantages and disadvantages over conventional power
supply. 07 CO6

Page 21


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 18


Internal 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire sy llabus wherein sub questions of 4 to 5
marks will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weightage of each module will be proportional to number of respective Lecture
hours as mentioned in the syllabus.
Text Books:
1. Robert L. Boylestad, Louis Nashelsky, “Electronic Devices and Circuit Theory”, PHI publishers,
2004
2. Thomas L. Floyd,” Electronic Devices”, Pearson 2015.
3. Adel S. Sedra, Kenneth C. Smith & Arun N. Chandorkar , “ Microelectronic Circuits,: Theory and
Applications” , OUP, 2013
4. D. A. Neamen, “Micro Electronic Circuit Analysis and Design ”, McGraw -Hill, New Delhi, 201 0.
Reference Books:
1. J. Millman and C. C. Halkias , “Integrated Electronics: Analog and Digital Circuits and Systems”,
Tata McGraw -Hill Publishing Company, 1988.
2. D. A. Bell, “ Electronic Devices and Circuits ”, OUP, India, 2010.
3. T. F. Boghart, J. S. Beasle y and G. Rico, “ Electronic Devices and Circuits ”, Pearson Education,
2004.








Page 22


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 19

Subject
code Subject
Name Teaching scheme Credit assigned
ISC304 Digital
Electronics Theory Pract. Tut. Theory Pract. Tut. Total
3 - - 3 - - 3

Sub
Code Subject
Name Examination scheme
Theory (out of 100) Term
work Pract.
and
Oral Oral Total Internal Assessment End sem
Exam Test1 Test2 Avg.
ISC304 Digital
Electronics 20 20 20 80 - - - 100

Subject Code Subject Name Credits
ISC304 Digital Electronics 3
Course Objectives The course is aimed
1. To provide an understanding of the principles of digital electronics and use
of number systems.
2. To give knowledge about combinational circuits .
3. To describe working and design methods of sequential circuits.
4. To familiarize with the basics of asynchronous sequential circuits and design
techniques.
5. To provide understanding of memory devices and state machines.
6. To make the students understand basic logic families and their applications.
Course Outcomes On successful completion of course learner/student will be able to:
1. Represent numerical values in various number systems and perform number
conversions between different number systems.
2. Analyze and design, digital combinational circuits using logic gates with
IEEE/ANSI standard symbols .
3. Formulate and design sequential logic circuits.
4. Formulate and design asynchronous sequential logic circuits.
5. Explain nomenclature and technology in memory devices.
6. Apply the concept of logic families and their application t o design the digital
system.

Pre-requisite: Knowledge of number systems and Boolean logic.

Page 23


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 20

Details of Syllabus:
Module Contents Hrs. CO
mapping
1. Binary number system:
Binary Arithmetic, Binary codes: Weighted, BCD, 8421, Gray code, Excess
3 code, ASCII, Error detecting code.
Reduction methods: Boolean laws, De -Morgan‘s Theorem, Minimization
of Boolean expressions, Sum of Products (SOP), Product of Sums (POS),
Karnaugh map Minimization, Don‘t care conditions. 06 CO1
2. Design of combinational logic circuits:
Adders, Subtractors, Code conversion, Parity checker , Magnitude
compa rators, BCD adder, Multiplexer, Demultiplexer, Encoder and
Decoder. Implementation of combinational logic circuits using Multiplexer
and Demultiplexer. Hazards in logic circuits and its elimination. 10 CO2
3. Sequential logic circuits :
Flip flops - SR, D and Master slave JK, T, Realization of one flip flop using
other flip flops, Asynchronous & Synchronous counters, Mo dulo n counter,
shift registers . 06 CO3
4. Asynchronous sequential circuits:
Circuit Design – primitive state / flow table, Minimization of primitive state
table, state assignment, Excitation table, Excitation map, cycles. 05 CO4
5. Logic families:
Basics of digital integrated circuits, basic operational characteristics and
parameters. TTL, Schottky clamped TTL, tri -state gate ECL, IIL, MOS
devices CMOS comparison of logic families. PMOS, NMOS and E2 CMOS,
BiCMOS . 06 CO5
6. Memory and programmable logic devices:
PROM / EPROM / EEPROM / EAPROM Programmable Logic Devices –
Programmable Logic Array (PLA), Programmable Array Logic (PAL),
Introduction to Complex Programmable Logic Device (CPLD), Field
Programmable Gate Arrays (FPGA). 06 CO6







Page 24


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 21



Internal 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of
4 to 5 marks will be asked.
4. Remaining questions w ill be mixed in nature.
5. In question paper weightage of each module will be proportional to number of respective
lecture hours as mentioned in the syllabus.

Text Books

1. M. Morris Mano, “Digital Design”, Prentice Hall of India, 2003.
2. John .M Yarbrough, “Digital Logic Applications and Design”, Thomson -Vikas publishing house,
2002.
3. Barry B. Brey, “The Intel Microprocessors ”, Pearson/Prentice Hall, 2006.
4. B. Ram, “Fundamentals of Microprocessors and Microcontrollers”, Dhanpat Rai Publications,
2004.

References Books:

1. Charles H. Roth., “Fundamentals of Logic Design”, Thomson Publication Company, 2003.
2. Donald P. Leach and Albert Paul Malvino , “Digital Principles and Applications”, Tata McGraw
Hill Publishing Company Limited, 2003.
3. R. P. Jain, “Modern Digital Electronics”, Tata McGraw –Hill publishing company limited, 2003.
4. Thomas L. Floyd, “Digital Fundamentals”, Pearson Education, 2003.







Page 25


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 22

Subject
code Subject Name Teaching scheme Credit assigned
ISC305 Electrical
Networks and
Measurements Theory Pract. Tut. Theory Pract. Tut. Total
4 - - 4 - - 4

Sub
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC305 Electrical
Networks and
Measurements 20 20 20 80 - - - 100

Subject Code Subject Name Credits
ISC305 Electrical Networks and Measurements 4
Course Objectives The course is aimed
1. To introduce the concept of circuit elements lumped circuits, circuit laws and
reduction.
2. To introduce the concept of circuit elements and analyze DC and AC circuits
using various theorems.
3. To analyze the transient response of series and parallel A.C. circuits.
4. To analyze two port model of circuit and evaluate its parameters.
5. To synthesize the circuits using different techniques.
6. To demonstrate basic analog and digital Instruments.
7. To identify the various techniques for measurement of R -L-C.

Course Outcomes On successful completion of course learner/student will be able to:
1. Analyze AC and DC circuits using different theorems.
2. Evaluate transient and steady -state the param eters of passive electrica l
networks.
3. Analyze network using poles and zeros and determine their parameters like
Z, Y, and ABCD.
4. Synthesize the networks using canonical forms.
5. Demonstrate construction and working principle and applications of analog
and digital instruments.
6. Formulate electrical bridges and evaluate electrical parameter like R, L, C.

Prerequisite: Analysis of DC networks for independent sources, mesh, node analysis, network theorems,
and fundamentals of RLC networks.

Page 26


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 23

Detailed Syllabus
Module Contents Hrs. CO
mapping
1. Network Theorems
Analysis of networks with dependent sources: mesh analysis, nodal
analysis, super mesh and super node concept, source transformation
technique, superposition theorem, Thevenin’s theorem, Norton‘s
theorem, Maximum power transfer theorem.
Solution of network s with AC sources, Analysis of coupled circuits
(self-inductance, mutual inductance, and dot convention) . 12 CO1
2. Transient Analysis
Initial Conditions in Elements, Solution of a First order and Second
order differential equations, Transients in R -L, R-C and RLC Circuits.
08 CO2
3. Network Functions and Two -Port parameters
Network functions for one port and two port networks, driving point and
transfer functions, ladder network, poles and zeros of network functions,
time domain behaviour from pole-zero plot.
Two-Port parameters, Open circuit, Short circuit, transmission and
hybrid parameters, relationship between parameter sets, reciprocity and
symmetry conditions, parallel connection of two port networks.
08 CO3
4. Fundamentals of Network Synthesis.
Causality and stability, Hurwitz polynomials, positive real functions,
synthesis of one port networks with two kinds of elements. Properties
and synthesis of L -C, R -C, R -L driving point impedances, synthesis of
R-L-C function .
10 CO4
5. Analog & Digital Meters
D‘Arsonaval galvanometers, PMMC and PMMI instruments. Shunts
and multipliers, Construction and working principle of: ammeters,
voltmeters, ohmmeters, power factor meter, energy meter, Q meters,
Analog multimeters. Electronic Voltmeters, D igital Voltmeter and
digital multimeter. CRO, Measurement of phase and frequency.
07 CO5
6. Measurement of R, L, C
Measurement of medium, low and high resistance, Megger AC bridges,
measurement of self and mutual inductances (Maxwell and Hay
Bridges). Measurement of capacitance (Schering Bridge). Derivations
and numerical related to all bridges. 07 CO6


Page 27


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 24


Internal Assessment Test:
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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire s yllabus wherein sub questions of 4 to 5 marks
will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weightage of each module will be prop ortional to number of respective lecture hours
as mentioned in the sylla bus.

Text Books:
1. Kuo Franklin F., “Network analysis and synthesis”, Wiley International, 1962.
2. Van Valkenburg M.E., “Network analysis”, Eastern Economy Edition, 1983.
3. A. K. Sawhney, Puneet Sawhney, “A course in Electrical and Electronic Measurement and
Instrumentation”, Dhanpat Rai and Co. Rai, 1996.

Reference Books:
1. Hayt William, Kemmerly Jr.Jack E ., “Engineering circuit Analysis”, Tata McGraw Hill, 2002.
2. Edminister Joseph A., Nahvi Mohmood, “Electric Circuits”, Tata McGraw Hill, 1999.
3. Shyammohan Sudhakar, “Circuits and Networks Analysis and Synthesis”, Tata McGraw Hill, 2000.
4. Ravish Singh, “ Electrical Networks Analysis and Synthesis”, Mc -Graw Hill








Page 28


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 25

Subject
code Subject Name Teaching scheme Credit assigned
ISL301 Transducers -I -
Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 -- -- 1 -- 1

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISL301 Transducers -I -
Lab -- -- -- -- 25 25 - 50

Subject Code Subject Name Credits
ISL301 Transducers -I –Lab 1
Course Objectives The course is aimed
1. To make students understand the Identification, construction, working
principle of various transducers used for Displacement measurement,
Temperature measurement, Level measurement and miscellaneous
measurement .
2. To experimentally verify the principle and characteristics of various
transducers .
Course O utcomes On successful completion of course learner/student will be able to:
1. Demonstrate various measurement techniques and measuring
instruments.
2. Demonstrate Flapper Nozzle system .
3. Plot and validate the performance characteristics of displacement
transducers
4. Validate the characteristics of various temperature transducers.
5. Describe the construction and operation of various level transducers .
6. Demonstrate the performance characteristics of miscellaneous
transducers. Syllabus : Same as that of Subject ISC302 Transducers -I
List of Experiments:
Sr. No Contents CO
Mapping
1. Demonstrate the basic measurements techniques and Measuring Instruments. CO1
2. Plot response curve for Flapper Nozzle system and validate the results with
stand values. CO2
3. Plot and validate the LVDT characteristics. CO3

Page 29


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 26

4. Test and evaluate distance using ultrasound transducer. CO3
5. Measure and verify the given displacement using Potentiometer . CO3
6. Plot and validate the characteristics of RTD CO4
7. Draw and validate the characteristics of various Thermocouples. CO4
8. Draw and validate the characteristics of Thermistors. CO4
9. Test and compare temperature measurement with and without Thermo -well. CO4
10. Perform and validate Liquid Level Measurement using DP Cell CO5
11. Plot and validate performance characteristics of capacitive level sensor. CO5
12. Perform and distinguish Liquid Level Measurement using Tubular Level
Gauge and ultra -sonic sensor. CO5
13. Plot the static characteristics of different proximity sensors. CO6
14. Demonstrate the Humidity measurement . CO6

Any other experiments based on syllabus which will help students to understand topic/concept.
Practical/Oral Examination :

Practical Examination will be based on performing one Experiment in the Laboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on ISC 302 Transducer -I
Term Work:
1) Minimum of Ten experiments covering all cos can be conducted during the semester for term work
and practical examination.
2) Assignments bas ed on syllabus which will help students to understand the Topic can be given during
the semester as a support to Evaluate Term work.
The distribution of marks for term work shall be as follows:

Laboratory work (Experiments/assignments) : 10 Marks
Labora tory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of Laboratory work
and minimum passing in the term work.

Page 30


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 27

Subject
code Subject Name Teaching scheme Credit assigned
ISL302 Analog Electronics -
Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 -- -- 1 -- 1

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total
Internal Assessment End
sem
Exam
Test1 Test2 Avg.
ISL302 Analog
Electronics - Lab -- -- -- -- 25 25 -- 50

Subject Code Subject Name Credits
ISL302 Analog Electronics -Lab 1
Course Objectives
The course is aimed
1. To familiarize the student with basic electronic devices and circuits.
2. To modal and analyze applications of diodes, bipolar and MOSFET, DC
biasing circuits, AC analysis and low and high Frequency response,
3. To experiment with differential and multistage amplifier.
4. To design d iffere nt types of power supply .
Course Outcomes On successful completion of course learner/student will be able to:
1. DC analysis of BJT.
2. Analyze BJT biasing techniques and frequency response.
3. Plot and evaluate parameters using FET characteristics .
4. Draw and evaluate parameters of MOSFET characteristics .
5. Implement and simulate Differential amplifier configuration
6. Design of power supply.

Syllabus: Same as that of Subject ISC30 3 Analog Electronics.

Page 31


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 28

List of Experiments:
Sr.
No Contents CO
mapping
1. Design the Diode circuit as Clipper and Clamper. CO1
2. Verify the input -output characteristics of BJT in CE configuration. CO1
3. Implement ation of a biasing circuit for BJT and estimate the parameters. CO1
4. Plot and validate the frequency response of BJT amplifier. CO2
5. Analyse the JFET circuit and validate its transfer characteristics. CO3
6. Plot and validate the frequency response of FET amplifier. CO3
7. Analyse the MOSFET circuit and validate its transfer characteristics. CO4
8. Plot the frequency response of MOSFET amplifier CO4
9. Simulate the multistage amplifier and analyse its frequency response with the
help of simulation software. CO5
10. Simulate the differential amplifier and analyse its frequency response with the
help of simulation software. CO5
11. Simulate the class A power amplifier and analyse with the help of simulation
software. CO6
12. Design of fixed voltage regulator using adjustable regulator IC. CO6

Any other experiment based on syllabus which will help students to understand topic/concept.

Practical/Oral Examination :
Practical Examination will be based on performing one Experiment in the Laboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on ISC30 3 Analog Electronics ..

Term Work:

Term work shall consist of minimum 08 Ex periments covering all C Os and any 02 practical should be verified
with simulation software .

The distribution of marks for term work shall be as follows:
Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of
Laboratory work and m inimum passing in the term work

Page 32


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 29

Subject
code Subject Name Teaching scheme Credit assigned
ISL303 Digital Electronics -
Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 -- -- 1 -- 1

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total
Internal Assessment End
sem
Exam
Test1 Test2 Avg.
ISL303 Digital Electronics -
Lab -- -- -- -- 25 25 -- 50

Subject Code Subject Name Credits
ISL303 Digital Electronics - Lab 1
Course Objectives
The course is aimed
1. To provide an understanding of the principles of digital electronics and use
of number systems.
2. To give knowledge about combinational circuits,
3. To describe working and design methods of sequential circuits.
4. To familiarize with the basics of asynchronous sequential circuits and design
techniques.
5. To provide under standing of memory devices and state machines.
6. To make the students understand basic logic families and their applications.
Course Outcomes On successful completion of course learner/student will be able to:
1. Demonstrate numerical values in various number systems and perform
number conversions between different number systems.
2. Exemplify operation of logic gates using IEEE/ANSI standard symbols.
Analyze and design, digital combinational circuits.
3. Design and validate sequential logic circuits.
4. Design and veri fy asynchronous sequential logic circuits.
5. Demonstrate nomenclature and technology in memory devices.
6. Analyze logic families and their application to design the digital system.
Syllabus: Same as that of Subject ISC304 Digital Electronics.

Page 33


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 30

List of Experiments:
Sr. No Detailed Contents CO
Mapping
1 Implement conversion of Gray/Binary code. CO1
2 Truth table verification and implementation of all gates using Universal gates. CO2
3 Implementation of half/ full adder/ Subtractor. CO2
4 Implementation of magnitude comparator. CO3
5 Realise full adder using 2:1 Multiplexer. CO3
6 Realise full Subtractor using 2:1 Multiplexer. CO3
7 Implementation of various flip -flops. CO4
8 Design and implement RS flip flop into other flip flops. CO4
9 Design and implement JK flip flop into other flip flops. CO4
10 Design and implement modulo -n counter. CO5
11 Design and implement ring counter. CO5
12 Design and implement universal shift register. CO5
13 Implement BCD to seven segments display. CO6
14 Design finite state machine for a digital lock CO6
Any other experiment based on syllabus which will help students to understand topic/concept.

Practical/Oral Examination :
Practical Examination will be based on performing one Experim ent in the Laboratory from the l ist of
Experiments given in the syllabus & the Oral Examination will be based on ISC30 4 Digital Electronics ..

Term Work:

Term work shall consist of minimum 08 Experiments covering all C Os and any 02 practical should be verified
with simulation software .

The distribution of marks for term work shall be as follows:
Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of
Laboratory work and m inimum passing in the term work

Page 34


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 31


Subject
Code Subject Name Teaching Scheme Credits Assigned

ISL304 Object Oriented
Programmin g - Lab Theory Pract. Tut. Theory Pract. Tut. Total
- 3# - - 1.5 - 1.5

Subject
Code Subject Name Examination scheme
Internal Assessment End
Sem
Exam Term
work Pract.
and
Oral Oral Total
ISL304 Object Oriented
Programming - Lab - - - - 25 25 - 50

# out of 3 hours, 1 hours theory shall be taught to entire class and 2 hours practical in batches.

Subject Code Subject Name Credits
ISL304 Object Oriented Programming - Lab 1.5
Course Objectives
The course is aimed
1. To learn the object -oriented programming concepts
2. To study various java programming constructs like multithreading,
exception handling, packages etc.
3. To explain components of GUI based programming
Course Outcomes On successful completion of course learner/student will be able to:
1. Apply fundamental programming constructs.
2. Illustrate the concept of packages, classes and objects.
3. Elaborate the concept of strings arrays and vectors.
4. Implement the concept of inheritance and interfaces.
5. Implement the notion of exception handling and multithreading.
6. Develo p GUI based application


Prerequisite: Structured Programming Approach




Page 35


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 32


Details of Syllabus:
Module Contents Hrs. CO
Mapping
1 Introduction to Object Oriented Programming
OO Concepts: Object, Class, Encapsulation, Abstraction, Inheritance,
Polymorphism.
Features of Java, JVM
Basic Constructs/Notions: Constants, variables and data types,
Operators and Expressions, Revision of Branching and looping 02 CO1
2 Classes, Object and Packages
Class, Object, Method.
Constructor, Static members and methods
Passing and returning Objects
Method Overloading, Packages in Java, creating user defined packages,
access specifiers. 03 CO2
3 Array, String and Vector
Arrays, Strings, String Buffer, Wrapper classes, Vector 02 CO3
4 Inheritance and Interface
Types of Inheritance, super keyword, Method Overriding, abstract class
and abstract method, final keyword,
Implementing interfaces, extending interfaces 02 CO4
5 Exception Handling and Multithreading
Error vs Exception, try, catch, finally, throw, throws, creating own
exception, Thread lifecycle, Thread class methods, creating threads,
Synchronization 02 CO5
6 GUI programming in JAVA
Event Handling: Event classes and event listener
Introduction to AWT: Working with windows, Using AWT controls -
push Buttons, Label, Text Fields, Text Area, Checkbox and Radio
Buttons. 02 CO6


Text books:
1. Herbert Schildt, ‘JAVA: The Complete Reference’, Ninth Edition, Oracle Press.
2. Sachin Malhotra and Saurabh Chaudhary, “Programming in Java”, Oxford University Press, 2010

Reference Books:
1. Ivor Horton, ‘Beginning JAVA’, Wiley India.
2. Dietal and Dietal, ‘Java: How to Program’, 8/e, PHI
3. ‘JAVA Programming’, Black Book, Dreamtech Press.



Page 36


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 33

List of Experiments/ Assignments:
Sr.
No. Detailed Contents CO
mapping
1. Program on various ways to accept data through keyboard and unsigned right shift
operator. CO1
2. Program on branching, looping, labelled break and labelled continue. CO1
3. Program to create class with members and methods, accept and display details for
single object. CO2
4. Program on constructor and constructor overloading CO2
5. Program on method overloading CO2
6. Program on passing object as argument and returning object CO2
7. Program on creating user defined package CO2
8. Program on 1D array CO3
9. Program on 2D array CO3
10. Program on String CO3
11. Program on String Buffer CO3
12. Program on Vector CO3
13. Program on single and multilevel inheritance (Use super keyword) CO4
14. Program on abstract class CO4
15. Program on interface demonstrating concept of multiple inheritance CO4
16. Program on dynamic method dispatch using base class and interface reference. CO4
17. Program to demonstrate try, catch, throw, throws and finally. CO5
18. Program to demonstrate user defined exception CO5
19. Program on multithreading CO5
20. Program on concept of synchronization CO5
21. Program to create GUI application without event handling using AWT controls CO6
22. Program to create GUI application without event handling using AWT controls CO6
23. Program to create GUI application without event handling using AWT controls CO6
24. Program to create GUI application with event handling using AWT controls CO6
25. Mini Project based on content of the syllabus. (Group of 2-3 students) CO1 -CO6

Page 37


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 34



Any other experiment based on syllabus which will help students to understand concept.

Practical and Oral Examination:
Practical and Oral examination will be based on entire syllabus.

Term Work:
Term work shall consist of minimum 20 programs from the list of suggested programs, two assignments
covering whole syllabus and one Mini -project of your choice.
The distribution of marks for term work shall be as follows:
Laboratory work (Performing Exper iments): 10 Marks
Laboratory work (programs/ journal) : 05 Marks
Mini Project : 05 Marks
Marks Attendance : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of laboratory work
and minimum passing in the term work.

Page 38


University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 35


Subject
code Subject Name Teaching scheme Credit assigned
ISM301 Mini Project – 1 A Theory Pract. Tut. Theory Pract. Tut. Total
-- 3$ -- -- 1.5 -- 1.5

Sub
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISM301 Mini Project – 1 A -- -- -- -- 25 -- 25 50


Subject Code Subject Name Credits
ISM301 Mini Project – 1 A 1.5
Course Objectives
The course is aimed
1. To acquaint with the process of identifying the needs and converting it into
the problem.
2. To familiarize the process of solving the problem in a group.
3. To acquaint with the process of applying basic engineering fundamentals to
attempt solutions to the problems.
4. To inculcate the process of self -learning and research.

Course Outcomes On successful completion of course learner/student will be able to:
1. Identify problems based on societal /research 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.



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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 36

Guidelines for Mini Project

 Students shall form a group of 3 to 4 students, while forming a group shall not be allowed less than
three or more than four students, as it is a group activity. 
 Students should do survey and identify needs, which shall be converted into problem statement for
mini project in consultation with faculty supervisor/head of department/internal committee of
faculties.
 Students hall submit implementation plan in the form of Gantt/PERT/CPM chart, which will cover
weekly activity of mini project. 
 A log book to be prepared by each group, wherein group can record weekly work progress,
guide/supervisor can verify and record notes/comments. 
 Faculty supervisor may give inputs to students during mini project activity;however, focus shall be
on self -learning.
 Students in a group shall understand problem effectively, propose multiple solution and select best
possible solution in consultation with guide/ supervisor. 

 Students shall convert the best solution into working model using various components of their
domain areas and demonstrate. 
 The solution to be validated with proper justification and report to be compiled in standard format of
University of Mumbai. 
 With the focus on the self -learning, innovation, addressing societal problems and entrepreneurship
quality development within the students through the Mini Projects, it is preferable that a single project
of appropriate le vel and quality to be carried out in two semesters by all the groups of the students. i.e.
Mini Project 1 in semester III and IV. Similarly, Mini Project 2 in semesters V and VI. 
 However, based on the individual students or group capability, with the ment or’s recommendations, if
the proposed Mini Project adhering to the qualitative aspects mentioned above gets completed in odd
semester, then that group can be allowed to work on the extension of the Mini Project with suitable
improvements/modifications or a completely new project idea in even semester. This policy can be
adopted on case by case basis. 

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 each semester. 

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 37

 In continuous assessment focus shall also be on each individual student, assessment based on
individual’s contribution in group activity, their unders tanding 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 project:

 In first semester entire theoretical solution shall be ready, including components/system selection
and cost analysis. Two reviews will be conducted based on presentation given by students group. 
 First shall be for finalisation of problem
 Second shall be on finalisation of proposed solution of problem.
 In second semester expected work shall be procurement of component’s/systems, building of
working prototype, testing and validation of results based on work completed in an earlier
semester. 
 First review is based on readiness of building working prototype to be conducted.
 Second review shall be based on poster presentation cum demonstration of working
model in last month of the said semester.

Half -year project:

In this case in one semester students’ group shall complete project in all aspects including, 
 Identification of need/problem 
 Proposed final solution 
 Procurement of components/systems 
 Building prototype and testing 

Two reviews will be conducted for continuous assessment, 
 First shall be for finalisation of problem and proposed solution
 Second shall be for implementation and testing of solution.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 38


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 Assessment of Mini Project Practical/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 Examiners preferably from industry or
research organisations having experience of more than five years approved by head of Institution. 
 Students shall be motivated to publish a paper based on the work in Conferences/students
competitions. 

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 39

Mini Project shall be assessed 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 writt en and oral communication
****************

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 40

SEM IV

Subject
code Subject Name Teaching scheme Credit assigned
ISC401 Engineering
Mathematics -IV Theory Pract. Tut. Theory Pract. Tut. Total
3 -- 1 3 -- 1 4

Sub
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC401 Engineering
Mathematics -IV 20 20 20 80 25 -- -- 125

Subject Code Subject Name Credits
ISC401 Applied Mathematics -IV 4
Course Objectives
The course is aimed
1. To study the line and c ontour integrals and expansion of complex valued
function in a power series .
2. To understand the basic techniques of statistics for data analysis,
Machine learning and AI.
3. To study the probability distributions and expectations.
4. To acquaint with the concepts of vector spaces used in the field of
machine learning and engineering problems.
5. To familiarize with the concepts of Quadratic forms and Singular value
decomposition .
6. To learn the concepts of Calculus of Variations.

Course Outcomes On successful completion of course learner/student will be able to :
1. Use the concepts of Complex Integration for evaluating integrals,
computing residues & evaluate various contour integrals.
2. Demonstrate the use of Correlation and Regression to the engineering
problems in data science, machine learning and AI.
3. Illustrate understanding of the concepts of probability and expectation
for getting the spread of the data and distribution of probabilities.
4. Apply the concept of vector spaces and orthogonalization process in
Engineering Problems.
5. Use the concept of Qua dratic forms and Singular value decomposition in
various Engineering applications.
6. Find the extremals of the functional using the concept of Calculus of
variation.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 41


Pre-requisite: Engineering Mathematics -I, Engineering Mathematics -II, Engineering Mathe matics -III,
Binomial Distribution.

Module Detailed Contents Hrs.
01 Module: Complex Integration
1.1 Line Integral, Cauchy’s Integral theorem for simple connected and multiply
connected regions (without proof), Cauchy’s Integral formula (without proof).
1.2 Taylor’s and Laurent’s series (without proof).
1.3 Definition of Singularity, Zeroes, poles of f(z), Residues, Cauchy’s Residue
Theorem (without proof).
Self-learning Topics: Application o f Residue Theorem to evaluate real integrations ,
Z- Transfor m. CO-1

7
02 Module: Statistical Techniques
2.1 Karl Pearson’s Coefficient of correlation (r) .
2.2 Spearman’s Rank correlation coefficient (R) (repeated and non -repeated ranks)
2.3 Lines of regression.
2.4 Fitting of first and second degree curves.
Self-learning Topics: Covariance, fitting of exponential curve. CO-2

6
03 Module: Probability Distributions
2.1 Baye’s Theorem, Random variable: Probabilit y distribution for discrete and
continuous random variables, Density function and distribution function.
3.2 Expectation, mean and variance.
3.3 Probability distribution: Poisson & normal distribution.
Self-learning Topics: Moments, Moment Generating Function, Applications of
Probability Distributions in Engineering. CO-3

7
04 Module: Linear Algebra: Vector Spaces: -
4.1 Vectors in n -dimensional vector space, norm, dot product, The Cauchy
Schwarz inequality (with proof), Unit vector.
4.2 Orthogonal projection, Orthonormal basis, Gram -Schmidt process for vectors.
4.3 Vector spaces over real f ield, subspaces.
Self-Learning Topics :- Linear combinations, linear Dependence and
Independence, QR decomposition .

CO-4
6

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 42

05 Module: Linear Algebra: Quadratic Forms
5.1 Quadratic forms over real field, Linear Transformation of Quadratic form,
Reduction of Quadratic form to diagonal form using congruent transformation.
5.2 Rank, Index and Signature of quadratic form, Syl vester’s law of inertia,
Value -class of a quadratic form -Definite, Semidefinite and Indefinite.
5.3 Reduction of Quadratic form t o a canonical form using congruent
transformations.
5.4 Singular Value Decomposition.
Self-learning Topics: Orthogonal Transformations , Applications of Quadratic
forms and SVD in Engineering. CO-5

7
06 Module: Calculus of Variations:
6.1 Euler - Lagrange equation (Without Proof), When F does not contain y, When F
does not contain x, When F contains x, y, y’.
6.2 Isoperimetric problems - Lagrange Method.
6.3 Functions involving higher order derivatives: Rayleigh -Ritz Method.
Self-Learning Topics: - Brachistochrone Problem, Variational Problem, Hamilton
Princ iple, Principle of Least action , Several dependent variables. CO-6

6
Term Work:
General Instructions:
1. Students must be encouraged to write at least 6 class tutorials on entire syllabus.
2. A group of 4 -6 students should be assigned a self -learning topic. Students should prepare a
presentation/problem solving of 10 -15 minutes. This should be considered as mini project in Engineering
mathematics. This project shou ld be graded for 10 marks depending on the performance of the students.
The distribution of Term Work marks will be as follows –
1. Attendance (Theory and Tutorial) 05 marks
2. Class Tutorials on entire syllabus 10 marks
3. Mini project 10 marks

Assessment :
Internal Assessment Test:

Assessment consists of two class tests of 20 marks each. The first -class test (Internal Assessment I) is to
be conducted when approx. 40% syllabus is completed and second class test (Internal Assessment II) when
addit ional 35% syllabus is completed. Duration of each test shall be one hour.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 43


End Semester Theory Examination:

1. Question paper will comprise of total 06 questions, each carrying 20 marks.
2. Total 04 questions need to be solved.
3. Question No: 01 will be compulsory and based on entire syllabus wherein 4 sub -questions of 5
marks each will be asked.
4. Remaining questions will be randomly selected from all the modules.
5. Weightage of each module will be proportional to number of respective lecture hours as mentio ned
in the syllabus.

References:
1. Complex Variables and Applications, Brown and Churchill, McGraw -Hill education.
2. Probability, Statistics and Random Processes, T. Veerarajan, McGraw -Hill education.
3. Advanced engineering mathematics H.K. Das, S . Chand, Publications.
4. Higher Enginee ring Mathematics B. V. Ramana, Tata Mc -Graw Hill Publication
5 Advanced Engineering Mathematics, R. K. Jain and S. R. K. Iyengar, Narosa publication
6. Advanced Engineering Mathematics Wylie and Barret, Tata Mc -Graw Hill.
7. Beginning Linear Algebra Seymour Lipschutz Schaum’s outline series, Mc -Graw Hill Publication
8..Higher Engineering Mathematics, Dr. B. S. Grewal, Khanna Publication

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 44

Subject
code Subject Name Teaching scheme Credit assigned
ISC402 Transducers -II Theory Pract. Tut. Theory Pract. Tut. Total
4 -- -- 4 -- -- 4

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC402 Transducers -II 20 20 20 80 -- -- -- 100

Subject Code Subject Name Credits
ISC4 02 Transducers -II 4
Course Objectives
The course is aimed
1. To make students understand the construction, working principle and
application of various transducers used for flow measurement, strain
measurement, pressure and vacuum measurement, force, torque and power
measurement
2. To study electro -chemical sensors and transducers used for density and
viscosity measurement

Course Outcomes On successful completion of course learner/student will be able to:
1. Explain working principle of strain gauges.
2. Demonstrate working principle of pressure transducers
3. Illustrate b asic fundamentals of flow transducers.
4. List and identify flow transducers for flow measurement.
5. Describe the terminologies of electrochemical sensors and their applications
in industry.
6. Select sensors for force measurement, density, humidity, pH measurement.

Prerequisite: Units and standards of measurement, concept of transducers (resistive, piezoelectric, pressure,
etc.), Knowledge of basic measurement.



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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 45

Details of Syllabus:
Module Contents Hrs. CO
mapping
1. Strain Measurement
Introduction, types of strain gauge, gauge factor calculation, materials for
strain gauge, resistance strain gauge bridges, temperature compensation and
applications of strain gauges and its sums . 04 CO1
2. Pressure Measurement
Pressure scales, units and relations, classification
Primary pressure sensors - elastic elements like bourdon tube, diaphragm,
bellows, properties and selection of elastic materials, Calibration using dead
weight tester.
Electrical/Secondary Pressure Transducers : Capacitive, piezo -electric
and its material, variable reluctance, LVDT, strain gauge.
High Pressure Measurement : Bulk modulus cell, Bridgeman type.
Differential pressure measurement : Materials, construction and working
of DP Cell.
Pressure measurement using manometer : U-tube types, well type,
inclined type, micro manometer and its sums.
Vacuum Measurement
Units and relations, McLeod gauge, Pirani gauge, thermocouple gauge 14 CO2
3. Fundamentals of flow measurement
Properties of fluid, types of fluid, dimensionless numbers, types of fluid
flow, continuity equation, Bernoulli’s equation, hydrostatic law, Pascal’s
law, flow through pipes – major and minor losses, flow measurement through
open channel -weirs and notches. Materials used for flow sensors,
performance of materials, corrosion resistors, erosion, effect of vapour
pressure 08 CO3
4. Flow Measurement
Head Type : Orifice, Venturi, Nozzle, Pitot tube, Annubar , characteristics of
head type flow meters and its sums.
Variable Area Type : Rotameter
Velocity and Inertia based flowmeters : Turbine, Electromagnetic,
Ultrasonic, Positive displacement, Anemometers,
Mass flow measurement : Coriolis and Vortex flow meter
Solid flow measurements. 14 CO4
5. Electro -chemical Sensors :
Terminology, equations, units. pH measurement -electrodes, measuring
circuits, maintenance, temperature compensation, calibration. Conductivity
measurement -probes and measuring circuits 06 CO5
6. Force Measurement:
Strain gauge, LVDT, piezoelectric.
Torque: Torsion bar, strain gauge.
Density Measurement – Displacement and float type densitometers
Hydrometers, Radiation and Ultrasonic densitometers
Viscosity Measurement – Capillary tube viscometer, Efflux type viscometer,
Variable area viscometer 06 CO6

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 46


Internal 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of 4 to 5 marks
will be asked.
4. Remaining questions will be mix ed in nature.
5. In question paper weightage of each module will be proportional to number of respective lecture hours
as mentioned in the syllabus.
6. The weightage for numerical should be of maximum 25%.

Text Books :
1. Nakra B.C., Chaudhary K.K., Instrumentation Measurement and Analysis, Tata Mc Graw Hill.
2. Patranabis D , Sensors and Transducers, Prentice H all India Learning Private Limited; 2nd edition
(2003) - 344 pages.
3. Sawhney A.K., Electrical and Electronic Measurement and Instrumentation, Dhanpatrai And Co.
4. Rangan, Mani, Sarma, “Instrumentation Systems and Devices”, 2nd ed., Tata Mc Graw Hill.
Referen ce Books :
1. Doeblin E.D., “Measurement system”, Tata Mc Graw Hill., 4th ed, 2003
2. Liptak B.G., “Instrument engineer’s handbook – Process measurement and analysis”.
3. Douglas M. Considine, “Process Instruments and controls”, Handbook, Mc Graw Hill.
4. Curtis John son, “Process Control Instrumentation Technology”, 8th ed, 2005
5. Andrew Williams, “Applied Instrumentation in process industry”, Vol -I, Gulf publishing company.
6. Bansal R.K., “Fluid Mechanics and Hydraulic Machines”, Laxmi publications.
7. David W. Spitzer, “ Industrial Flow Measurement”, ISA Publication.
8. Sawhney A.K., “Mechanical Measurement”, Dhanpatrai And Co.





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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 47


Subject
code Subject Name Teaching scheme Credit assigned
ISC403 Signal
Conditioning
Circuit Design Theory Pract. Tut. Theory Pract. Tut. Total
3 -- -- 3 -- -- 3

Sub
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC403 Signal
Conditioning
Circuit Design 20 20 20 80 -- -- -- 100

Subject Code Subject Name Credits
ISC403 Signal Conditioning Circuit Design 3
Course Objectives
The course is aimed
1. To introduce the students the basic properties of OpAmp, analysis and design
of electronic circuits using OpAmp.
2. To give the knowledge about the various components analog signal
conditioning.
3. To impart knowledge of design considerations of analog signal conditioning
of components.
4. To give the students knowledge about various components digital signal
conditioning.
5. To make the students capable to apply knowledge to design various
transducer signal conditioning circuits.

Course Outcomes On successful completion of course learner/student will be able to:
1. Describe op-amp parameters and types and derivation of operational
amplifiers.
2. Design the various operation amplifier circuits for linear .
3. Formulate and design non -linear applications of op -amp.
4. Design of analog signal conditioning circuits.
5. Design of Digital signal conditioning circuits.
6. Apply signal conditio ning concepts to design various transducers signal
conditioning circuits .

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 48


Prerequisite: Knowledge of various sensors and basic electronics.

Details of Syllabus:
Module Contents Hrs. CO
mapping
1. Fundamentals of Operational Amplifier
Block diagram of Operational amplifier, Ideal Op Amp, characteristics of
op-amp, op -amp parameters, Operational amplifier open loop and closed
loop configurations, Inverting and non -inverting amplifier. 04 CO1
2. Linear Applications of Operational Amplifier
Amplifiers: Adder, subtractor, difference amplifier, Integrator, and
practical integrator, , Differentiator and practical differentiator, Current to
Voltage converter, voltage to current converter (grounded and floating
load), Instrumentation amplifier wit h three Op -amps, and application of
Op-Amp in Transducer Measurement System. 08 CO2
3. Nonlinear Applications of Operational Amplifier
Comparator and its characteristics, Zero Crossing Detector (ZCD), Schmitt
trigger, window detector, Sample and Hold Circuit, Peak to Peak Detector,
Precision half wave and full wave rectifiers, Sine wave oscillators using op -
amp.: Barkhausen criteria, Wei n bridge oscillator, RC phase shift oscillator.
Waveform Generators: Square wave generator and triangular wave
generator, Design and applications of Multivibrators: Astable, Monostable
using IC 555, PLL. 08 CO3
4. Analog Signal Conditioning
Standard analog signals, Signal Level and bias changes, Linearization,
conversion, filtering and impedance matching, concept of loading. Voltage
divider, Wheatstone bridge circuits, Active filter.
Guidelines for analog signal conditioning design and design based
problems. 04 CO4
5. Digital Signal Conditioning
Converters – ADCs and their different types, DACs and their different
types, V to F and F to V converters. Characteristics of digital data –
digitized value, sampled data system and linearization. 07
CO5
6. Transducer Signal Conditioning
Signal Conditioning of Temperature, Pressure, optical, strain gauges,
Displacement and piezoelectric transducers signal conditioning.
Data logger circuit, Data acquisition system (Block Diagram Level) 08 CO6

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 49



Internal 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of
4 to 5 marks will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weightage of each module will be proportional to number of respective
lecture hours as mentioned in the syllabus.

Text Books:

1. Ramakant Gaikwad, “Op-amp & Linear ICs”, PHI Pearson Education, 2003.
2. C. D. Johnson, “Process Control Instrumentation Technology” , 2016.
3. D. E. Pippenger and E. J. Tobanen, “Linear and Interface Circuits Applications”, McGraw Hill,
1988.
4. William D. Stanley, “Operational Amplifiers with Linear Integrated Circuits”, Pearson.
Reference Book s:
1. Roy Choudhary, “Linear Integrated Circuits”, Wiley Eastern, 1991.
2. Coughlin & Driscoll, “Op-amp and Linear ICs” 6th Edition, PHI 2002.
3. Sergio Franco, “Design with op -amp analog ICs” McGraw Hill, 1988.
4. Robert G. Seippel, “Transducer Interfacing – Signal Conditioning for Process Control”,
Prentice Hill, 2000.






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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 50

Subject
code Subject
Name Teaching scheme Credit assigned
ISC404 Feedback
Control
System Theory Pract. Tut. Theory Pract. Tut. Total
3 -- -- 3 -- -- 3

Sub
Code Subject
Name Examination scheme
Theory (out of 100) Term
work Pract.
and
Oral Oral Total Internal Assessment End sem
Exam Test1 Test2 Avg.
ISC404 Feedback
Control
System 20 20 20 80 -- -- -- 100

Subject Code Subject Name Credits
ISC404 Feedback Control System 3
Course Objectives
The course is aimed
1. The students should be able to learn the type of System, dynamics of
physical systems, classification of control system, analysis and design
objective.
2. The students should learn how to represent system by transfer function
and block diagram reduction method and Mason’s gain formula.
3. The students should able to learn time response analysis and demonstrate
their knowledge to frequency response.
4. Students can be able to learn stability analysis of sys tem using Root locus,
bode plot, polar plot, and Nyquist plot.
Course Outcomes On successful completion of course learner/student will be able to:
1. Identify open -loop and closed -loop control systems
2. Formulate mathematical model for the physical systems
3. Simplify representation of complex systems using reduction techniques.
4. Identify performance characteristics of first and second -order systems.
5. Apply root -locus technique for stability analysis.
6. Analyze performance characteristics of systems using frequency response
methods.


Prerequisite: Knowledge of mathematics and network theory.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 51


Details of Syllabus:
Module Contents Hrs. CO
mapping

1 Introduction
Definition of control system and related terms, open loop and closed loop
system, examples. Development of automatic control systems,
classifi cation of control system, examples 04 CO1
2 Mathematical Models of Physical
Systems
Definition of physical systems, principle of superposit ion and
homo geneity, linear/non -linear, time variant /time invariant systems .
Types of dynamic model, linear elements of electrical and mechanical
systems. 06 CO2
3 Transfer Function a nd Feedback
Chara cteristics
Definition of transfer function, sinusoid al transfer function, tr ansfer
functions of physical systems , block dia gram algebra, reduction rul es,
signal flow graphs-definition, constru ction, properties, and Mason's gain
formula, effect of feedback, effect of disturbances signals. 09 CO3
4 Time Response Ana lysis
Standard test signals, pulse and impulse function, step function,
ramp fun ction, parabolic function , sinusoidal fun ction, dynamic
response, time response of first order system, time response of second
order system, sp ecifications, steady - state error, system types and error
constants, design specifications of second order system - desired close lo op
pole lo cation and the dominant condit ion.
08 CO4
5 Stabil ity Analysis a nd Root Locus
Concept of stabil ity, definitions, bound ed inpu t-bound ed output stabili ty,
relative stability, necessary and sufficient conditions for stabili ty, Routh
stabil ity criterion, relative stabil ity analysis, root locus technique,
applications, concept, constru ction of root loci, root loci of dif ferent
systems, electrical RLC circuits, etc.
06 CO5
6 Frequency R esponse and Stabil ity
Analysis
Correlation between time and frequency respon se, polar plots, Bode plots,
Nyquist stability criterion , frequency response specifications , stabil ity
analysis using-bode, polar, definitions and significance of gain margin and
phase ma rgin. 06 CO6

Internal 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.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 52

Theory Examination:
1. Question paper will comprise of 6 questions, each carrying 20 Marks.
2. Total 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of
4 to 5 marks will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weightage of each module will be proportional to number of respective lecture
hours as mentioned in the syllabus.

Textbooks
1. Nagrath I. G., Gopal M., Control System Engineering , New Age Inte rnational (P) Ltd. Publishers 2000
2. Kuo Benjamin C., “Automatic Control System s”, 6th ed., Prentice Hall of India, New Delhi, 1993.


Reference Books

1. Gopal M., “Control Systems Principles and Design”, Tata McGraw Hill Publishing Co. Ltd. New
Delhi, 1998.
2. Nise Norman S., “Contr ol Systems En gineering”, 3rd ed., John Wiley and Sons, Inc.-2000.
3. Lewis Paul H., Ch ang Yang, “Basic Cont rol Systems Engineering”, Prentice Hall International,
Inc. 1997.
4. Raymond T. Stefani, Bahram Shahian, Clement J. Savant and Gene H. Host etter, “Design of
Feedback Control Systems”, 4th ed., O xford Universi ty Press, New Delhi, 2001.
5. Dhanesh N. M anik, “Control System”, Cengage Lerning India, 1st edition, 2012









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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 53


Subject
code Subject Name Teaching scheme Credit assigned
ISC405 Control System
Components Theory Pract. Tut. Theory Pract. Tut. Total
4 -- -- 4 -- -- 4

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISC405 Control System
Components 20 20 20 80 -- -- -- 100

Subject Code Subject Name credits
ISC405 Control System Components 4
Course objective
The course is aimed
1. To impart knowledge of different control system components like
Hydraulic, Pneumatic, Electrical & Electronics and their comparison.
2. To make the students to learn different types of Transmitters.
3. To make the students to understand concept of control valve, different
types, their working & selection crit eria.
4. To make the students to learn various Auxiliary process control
components and its applications.
5. To give the students an overview of Industrial Control components &
their Need in Instrumentation.
Course Outcome
On successful completion of course learner/student will be able to:
1. Explain and s elect various pneumatic system components and circuits.
2. Select and compare various control systems like Hydraulic, pneumatic
and electric.
3. Apply knowledge to classify, select and use various transmitters.
4. Classify and select various control valves and their accessories.
5. Describe and select industrial components and study their usage .
6. Demonstrate auxiliary process components .


Prerequisite: Knowledge of sensors, Measurement system, basic control system and Electrical Engineering.

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Details of Syllabus:
Module Contents Hrs. CO
mapping
1 Pneumatic system components
Pneumatic System Components: ISA symbols, Instrument Air and Plant
Air. Air compressor system and its accessories. Directional control valves
and special types of pneumatic valve such as Pilot -operated valves, Non -
return valves, Flow control valves, Sequen ce valves, and Time delay valve,
Linear actuators - Single -acting, Double -acting, and special type of double -
acting cylinder, Rotary actuators - Air motors.
Process Control Pneumatics: Volume boosters, Air relays, Pneumatic logic
gates, Pneumatic Circuits -Standard Symbols used for developing
pneumatic circuits, Sequence diagram. 10 CO1
2 Hydraulic System Components:
Hydraulic pumps(centrifugal, gear , lobe), Pressure regulation method,
Loading valves, Hydraulic valves, Electro Hydraulic actuators, speed
control circuits for Hydraulic actuators, Selection and comparison of
pneumatic, hydraulic and electric systems. 04 CO2
3 Transmitters
Need, specifications and classification of transmitters, Need for
Standardization of signals, concept of live zero and dead zero, 2 -wire; 3 -
wire and 4 -wire transmitters and its calibration, Electronic versus
pneumatic transmitters, Electronic type transmitters - temperature;
Pressure (gauge); differential pressure; level(capacitive type); flow
transmitter (magnetic); SMAR T /Intelligent transmitter; Block schematic
and Comparison with conventional transmitter; applications of transmitters,
Multivariable transmitter. 12 CO3
4 Process Control Valves & converters
Need and specifications of Control Valve; Control valve terminology;
Control valve constructional details; Air to Open(AO), Air to Close (AC);
MOC (Material of construction); classification of control valve;
applications, advantages, disadvantage of - Globe, Ball, Needle, Butterfly,
Diaphragm, Pinch, Gate, Sole noid; Flow characteristics (Inherent and
Installed); Valve positioners: necessity, types -motion balance and force -
balance, Effect on Performance of control valve; Control Valve Actuators -
Electrical, Pneumatic, Hydraulic, Electro -mechanical, and piston act uators;
selection guidelines for control valve .
Converters: Need for Converters and types, working of Pneumatic to
Electrical and Electrical to Pneumatic converters.
Feeders and dampers.
Working of safety valve, relief valve and their application. 14 CO4

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 55

5 Industrial Control Components
Panel Switches : Construction, symbolic representation, working,
application of Toggle switches, Push buttons, Selector switches, DIP
switches, Rotary switches, Thumbwheel switches, Drum switch, Limit
switches, emergency push button, Tactile switch, Switch specifications.
CAM SWITCHES MAGNETIC contactors, PILOT Light.
Industrial switches: Temperature, Flow, Level and, Pressure Switch,
Vibration switch.
Control Relays: Construction, working, specifications, and applicatio ns of
Electro -mechanical relay, Solid state relays. Interposing relays and
Overload relays.
Contactors/starters: Construction, working, specifications and
applications of starters and contactors. Comparison between relays and
starters /contactors. 08 CO5
6 Auxiliary Process Control Components
Alarm annunciators and its sequences; Temperature regulator, Flow
regulator, stepper motor (working principle) 04 CO6

Internal 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 4 questions need to be solved.
3. Question No. 1 will be compulsory and based on entire syllabus wherein sub questions of
4 to 5 marks will be asked.
4. Remaining questions will be mixed in nature.
5. In question paper weight age of each module will be proportional to numbe r of respective
Lecture hours as mentioned in the syllabus.

Text Books Recommended:
1. Andrew Parr, Hydraulic &pneumatics; A Technicians & Engineers Guide, Second Edition
2. Control Valve Handbook – Forth Edition, Fisher.
3. Pneumatics workbook Basic Level - FESTO
4. C.L.Albert and D.A. Coggan, “Fundamentals of Industrial Control”, ISA, 1992.
5. Bela G. Liptak, “Instrument Engineer’s Hand Book – Process Control”, Chilton Company, 3rd
Edition, 1995.
6. Andrew Williams, “Applied instrumentation in the process industries”, 2nd Edition, Vol. 1 & 3, Gulf
publishing company.
7. Guy Borden, Paul G Friedman , style Editor Control Valves - ISA
8. Process Instruments & Control Handbook, Douglas. M.Considine, McGraw -Hill

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 56


Course Objectives
The course is aimed
1. To make students understand the construction, working principle and
application of various transducers used for flow measurement, strain
measurement, pressure and vacuum measurement, force, torque and
power measurement
2. To study electro -chemical sensors and transducers used for density
and viscosity measurement
3. To impart knowledge of different control system compon ents like
Hydraulic, Pneumatic and Electrical and their comparison.
4. To make the students to learn different process components and
auxiliary process control components.
Course Outcomes On successful completion of course learner/student will be able to:
1. Explain working principle of strain gauges, pressure transducers
2. Learn Basic fundamentals of flow transducers identify types of flow
and use different transducers for flow measurement.
3. Explain the terminologies of electrochemical, density, humidity, pH
measurement sensors , and their applications in industry.
4. Study, select and implement various pneumatic, hydraulic and
electro -pneumatic system components and circuits.
5. Apply knowledge to classify, select and use various Transmitters,
control valves and their accessories
6. Describe the Need of Auxiliary process control components and
study their industrial usage.
Syllabus: Same as that of Subject ISC402 Transducers -II and ISC40 5 Control System Components .
List of the Experiments: Subject
code Subject Name Teaching scheme Credit assigned
ISL401 Process Control
Components – Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 -- -- 1 -- 1
Subject
Code Subject Name Examination scheme
Theory (out of 100) Term
work Pract
. and
Oral Oral Total
Internal Assessment End sem
Exam
Test1 Test2 Avg.
ISL401 Process Control
Components –
Lab -- -- -- -- 25 25 50

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 57

Sr.
No. Detailed Contents CO
mapping
1. Strain gauge characteristics and weight measurement CO1
2. Study use of semiconductor strain gauges for pressure measurement CO1
3. Study measurement of pressure using bellows, diaphragm, bourdon tube,
manometer. CO1
4. Test and calibration of pressure gauges using dead weight tester. CO1
5. Measurement of flow using orifice/venturi tube/nozzle/pitot tube. CO2
6. Meas urement of flow using rotameter/ electromagnetic flow meter. CO2
7. Study and characterization of pH meter / conductivity meter. CO3
8. Measurement of Density/Viscosity CO3
9. Study of various pneumatic / hydraulic control system components. CO4
10. Study of various electro -pneumatic control system components. CO4
11. Study operation and calibration of flow/ level/ temperature transmitter CO5
12 Study of different types of control valve actuator. CO5
13 Calibration of I to P and / P to I converter. CO5
14. Study characteristics of control valve CO5
15. Study different types and operation of control valve and valve positioner. CO6
16. Study of pressure/temperature/level/flow switches and control relays . CO6

Note:
1. Minimum of Ten experiments can be conducted during the semester for term work and practical
examination.
3) Factory visit is advised to understand the working of the control system components.
4) Assignments based on syllabus which will help students to understand the Topic can be given
during the semester as a support to Evaluate Term work.

Practical/Oral Examination :

Practical Examination will be based on performing one Experiment in the Laboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on Entire subject.

Term Work:
Term work shall consist of minimum Ten Experiments covering all COs.

The distribution of marks for term work shall be as follows:
Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of Laboratory work
and m inimum passing in the term work

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 58

Subject
code Subject Name Teaching scheme Credit assigned
ISL402 Signal
Conditioning
Circuit Design -
Lab Theory Pract. Tut. Theory Pract . Tut. Total
-- 2 -- -- 1 -- 1

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total
Internal Assessment End
sem
Exam
Test1 Test2 Avg.
ISL402 Signal
Conditioning
Circuit Design -
Lab -- -- -- -- 25 25 50

Subject Code Subject Name Credits
ISL402 Signal Conditioning Circuit Design - Lab 1
Course Objectives
The course is aimed
1. To introduce the students the basic properties of OpAmp, analysis and design
of electronic circuits using OpAmp.
2. To give the knowledge about the various components analog signal
conditioning.
3. To impart knowledge of design considerations of analog signal conditioning
of components.
4. To give the students knowledge about various components digital signal
condition ing.
5. To make the students capable to apply knowledge to design various
transducer signal conditioning circuits.
Course Outcomes On successful completion of course learner/student will be able to:
1. Evaluate op-amp parameters and design of basic op -amp amplifier circuits .
2. Design and Implement various linear applications using op -amp.
3. Design and Implement various non-linear applications using op -amp.
4. Apply principles of analog signal conditioning for op -amp based circuit
design.
5. Apply concepts of digital signal conditioning for op -amp based circuit
design.
6. Design and develop signal conditioning circuits for different transducers.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 59

Syllabus: Same as that of Subject ISC403 Sign al Conditioning Circuit Design.
List of Experiments:

Sr.
No Detailed Contents CO
Mapping
1. Demonstrate use of Op -Amp as inverting and non -inverting amplifier CO1
2. Determination of opamp parameters - CMRR, Slew Rate, Offset Voltages & currents CO1
3. Adder and Subtractor using Op -amp CO2
4. Design Instrumentation Amplifier using 3 Op-amps. CO2
5. Design and demonstrate I to V and V to I converter circuit CO2
6. Design and implement Astable and Monostable Multivibrator using IC 555 CO2
7. Implementation of Precision rectifiers using Op -amp. CO3
8. Design and d emonstrate integrator and differentiator using Op -amp. CO3
9. Design of Wein bridge oscillator using Op -amp CO3
10. Design of RC phase shift oscillator using Op -amp CO3
11. Design and demonstrate second order LPF and HP F. CO4
12. Design and demonstrate general signal conditioning circuit to convert sensor output to
0-5 V CO4
13. Design and demonstrate general signal conditioning circuit to convert sensor output to
4-20 mA CO4
14. Design and demonstrate Analog to Digital converter circuit or Digital to Analog
converter circuit CO5
15. Design and demonstrate signal conditioning circuit for weight measuring system using
strain gauge CO6
16. Study and Simulation of Data Acquisition System CO6
17. Design signal conditioning circuit for RTD CO6

Practical/Oral Examination :

Practical Examination will be based on performing one Experiment in the Laboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on subject ISC403 Signal
Conditioning Circuit Design .




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Term Work:

Term work shall consist of minimum 08 experiments ( any 5 Experiments from 1 to 10 plus any 3 experiments
from remaining list of experiments ) covering all CO s and out of that 02 experiment should be simulation
software.




The distribution of marks for term work shall be as follows:
Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of Laboratory work
and minimum passing in the term work.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 61

Subject
code Subject Name Teaching scheme Credit assigned
ISL403 Feedback Control
System - Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 2 -- -- 1 -- 1

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total
Internal Assessment End
sem
Exam
Test1 Test2 Avg.
ISL403 Feedback Control
System -Lab -- -- -- -- 25 25 -- 50

Subject Code Subject Name Credits
ISL403 Feedback Control System - Lab 1
Course Objectives
The course is aimed
1. The students should be able to examine steady -state and frequency response of
the Type 0, 1, and 2 systems.
2. The students should be able to examine steady -state and frequency response of
first and second order electrical systems.
3. The students should able to examine time response analysis of first and second
order systems.
4. Students can be able to inspect stabilit y analysis of system using Root locus,
Bode plot, polar plot.
Course Outcomes On successful completion of course learner/student will be able to:
1. Plot frequency response of first -order electrical system.
2. Plot time response of second -order electrical system and calculate the steady -
state error.
3. Demonstrate the way to obtain the transfer function and validate transient and
steady -state response using test signals such as step, ramp, and parabolic.
4. Validate the effect of damping factor on response of sec ond order system.
5. Inspect the time response specifications of systems by using root -locus.
6. Inspect the frequency response specifications of systems by using bode -plot,
Polar plot, Nyquist -plot techniques, and comment on the stability of system

Syllabus: Same as that of Subject ISC404 Feedback Control System.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 62

List of the Laboratory Experiments:
Module Contents CO
mapping
1. To plot the effect of time constant on first – order systems response. CO1
2. To plot the frequency response of first -order system CO1
3. To plot the time response of second – order systems CO2
4. To examine steady state errors for Type 0, 1, 2 systems CO3
5. To study the block diagram reduction technique by using simulation software CO3
6. To interpret the effect of damping factor on the performance of second order
system. CO4
7. To inspect the relative stability of systems by Root -Locus using Simulation
Software CO5
8. To inspect the stability of systems by Bode plot using Simulation Software CO6
9. To determine the frequency response specifications from Polar plot of system CO6
10. To inspect the stability of systems by Nyquist plot using Simulation Software CO6

Any other experiment based on syllabus which will help students to understand topic/concept.

Note: Sr. 1 to 4 experiments should be performed using practical kit /breadboard and Sr. 5 to 10 by using
simulation software like MATH CAD/MATLAB/SCILAB/OCTAVE or equivalent.

Practical and Oral Examination:

Practical Examination will be based on pe rforming one Experiment in the l aboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on subject ISC404 - Feedback Control
System.

Term Work:

Term work shall consist of minimum Eight experiments to cover all COs of thi s Lab Practice Course.

The distribution of marks for term work shall be as follows:

Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of laboratory work
and minimum passing in the term work.



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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 63

Subject
code Subject Name Teaching scheme Credit assigned
ISL404 Virtual
Instrumentation -
Lab Theory Pract. Tut. Theory Pract. Tut. Total
-- 3# -- -- 1.5 -- 1.5

Subject
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISL404 Virtual
Instrumentation -
Lab -- -- -- -- 25 25 -- 50

Subject Code Subject Name Credits
ISL404 Virtual Instrumentation Lab 1.5
Course Objectives
The course is aimed
To study graphical programming language for creating simulation and custom
applications that interact with real-world data or signals in fields of science and
engineering.
Course Outcomes On successful completion of course learner/student will be able to:
1. Design logical operations, using Graphical programming language
2. Develop customized virtual instruments and represent them in required
format with user friendly graphical programming software for LOOPS like
FOR LOOP, WHILE LOOP etc.
3. Plot the generated data and also able to export the data outside the
programming environment
4. Select the data acquisition card or simulated software module and make
user interface in the field of engineering.
5. Describe the concepts of different analysis tool.
6. Design and develop real world applications using graphical programming
software.

# out of 3 hours, 1 hours theory shall be taught to entire class and 2 hours practical in batches.

Prerequisite: Knowledge of Mathematics and conversion, LOOPs, switch CASE of any other software like
C program, simple concept of proportional process control action.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 64

Details of Syllabus:

Module Contents Hrs. CO
mapping
1 INTRODUCTION
Virtual Instrumentation: Historical perspective, block diagram and
Architecture of a virtual instrument, Conventional Instruments versus
Virtual Instruments, data -flow techniques, graphical programming in data
flow. 2 CO1
2 VI PROGRAMMING TECHNIQUES
Data types, VIs and sub -VIs, Structures (For, While etc.) arrays, clusters,
shift registers, case and sequence structures, formula nodes. Debugging
techniques 2 CO2
3 PLOTING AND EXPORT DATA
Strings, File I/O, Plotting data: graphs and charts, report generation. 2 CO3
4 DATA ACQUISITION
Introduction to data acquisition on PC, Digital I/O, counters and timers,
Software and Hardware installation, Calibration, Resolution, Data
acquisition interface requirements, VISA programming. 3 CO4
5 MEASUREMENT ANALYSIS TOOLS
Use of analysis tools for measurement of max, min, peak to peak voltage.
Time period of signal, correlation methods. Design of oscilloscope, digital
multimeter. 2 CO5
6 APPLICATIONS
System development for a process. Development of Graphical User
Interface (GUI). Implementation of various controllers (ON / OFF control,
PID control) for a process. Simulation of a simple second order system. 2 CO6


List of Experiments:
Module Contents CO
mapping
1. To develop a VI to calculate speed, convert degree Celsius to Fahrenheit CO1
2. To develop a Sub VI to implement Half adder and Full ADDER CO2
3. To develop VI using FOR and WHILE loop to add 10 numbers, calculate Factorial
of a given number CO2
4. To create VI to find roots of quadratic equation, user defined unit conversions etc
using case structure. CO2
5. To create VI student database using String control and Array and cluster functions. CO2
6. Applications of Graphical Programming Software in digital electronics —binary to
decimal conversion etc. CO1,
CO2
7. To develop a VI for storing all the points of simulated signal using File I/Os CO3
8. Build a VI to plot circle in XY graph, generate and plot random numbers on chart,
different colors in an intensity graph etc with graph, chart properties and options. CO3

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 65

9. Measurement of AC/ DC voltage and current using DAQ cards. CO4
10. Develop the VI, to On/Off the LED’s using DAQ devices (Arduino, Raspberry Pi
etc.) CO4
11. Applications of Graphical Programming Software in process tank level /
temperature control, alarm annunciator, batch process control etc. CO5
12. To create VI to simulate bottle filling plant using Sequence structure. CO5
13. Applications of Graphical Programming Software in control —simulate first and
second order system response, effect of damping factor etc. CO6
14. To create VI to simulate traffic light control, stirred tank heater etc. using
Sequence structure CO6


Practical/Oral Examination :

Practical Examination will be based on performing one Experiment in the laboratory from the List of
Experiments given in the syllabus & the Oral Examination will be based on subject ISL404 Virtual
Instrumentation Lab .

Note:
1. Any other experiments based on syllabus which will help students to understand topic/concept can
also be included.
2. For this course use Graphical Programming Software like LabVIEW or Open Source Software

Term Work:

Term work shall consist of minimum 10 programs from the list of suggested programs.

The distribution of marks for term work shall be as follows:

Laboratory work (Experiments/assignments) : 10 Marks
Laboratory work (journal) : 10 Marks
Attendance (class Room plus Lab Practice) : 05 Marks

The final certification and acceptance of term work ensures the satisfactory performance of laboratory work
and minimum passing in the term work.

Reference Books:
1. Jovitha Jerome, “Virtual Instrumentat ion”, PHI, 2018.
2. Robert Bishop, “Learning with LabVIEW TM 7 express”, Pearson Education, 2005.
3. Gupta S, “Virtual Instrumentation Using LabVIEW”, Tata McGraw Hill Publishing Company
Limited.
4. Labview for everyone, - Lisa K. Wells & Jettrey Travis Prentice Ha ll, New Jersey, 1997.
5. LabVIEW users manual.

Website : www.ni.com


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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 66

Subject
code Subject Name Teaching scheme Credit assigned
ISM 401 Mini Project – 1 B Theory Pract. Tut. Theory Pract. Tut. Total
-- 3$ -- -- 1.5 -- 1.5

Sub
Code Subject Name Examination scheme
Theory (out of 100)
Term
work Pract.
and
Oral Oral Total Internal Assessment End
sem
Exam Test1 Test2 Avg.
ISM 401 Mini Project – 1 B -- -- -- -- 25 25 -- 50

Subject Code Subject Name Credits
ISM401 Mini Project – 1 B 1.5
Course Objectives
The course is aimed
1. To acquaint with the process of identifying the needs and converting it into
the problem.
2. To familiarize the process of solving the problem in a group.
3. To acquaint with the process of applying basic engineering fundamentalsto
attempt solutions to the problems.
4. To inculcate the process of self -learning and research.
Course Outcomes On successful completion of course learner/student will be able to:
1. Identify problems based on societal /research 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.


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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 67

Guidelines for Mini Project

 Students shall form a group of 3 to 4 students, while forming a group shall not be allowed less than
three or more than four students, as it is a group activity. 

 Students should do survey and identify needs, which shall be converted into problem statement for
mini project in consultation with faculty supervisor/head of department/internal committee of
faculties.

 Students hall submit implementation plan in the form of Gantt/PERT/CPM chart, which will cover
weekly activity of mini project. 

 A log book to be prepared by each group, wherein group can record weekly work progress,
guide/supervisor can verify and record notes/comments. 

 Faculty supervisor may give inputs to students during mini project activity;however, focus shall be
on self -learning.

 Students in a group shall understand problem effectively, propose multiple solution and select best
possible solution in consultation with guide/ supervisor. 

 Students shall convert the best solution into working model using various components of their
domain areas and demonstrate. 

 The solution to be validated with proper justification and report to be compiled in standard format of
University of Mumbai. 

 With the focus on the self -learning, innovation, addressing societal problems and entrepreneurship
quality development within the students through the Mini Projects, it is preferable that a single project
of appropriate level and quality to be carried out in two semesters by all the groups of the students. i.e.
Mini Project 1 in semester III and IV. Similarly, Mini Project 2 in semesters V and VI. 

 However, based on the individual students or group capability, with the mentor’s recommendations, if
the propo sed Mini Project adhering to the qualitative aspects mentioned above gets completed in odd
semester, then that group can be allowed to work on the extension of the Mini Project with suitable
improvements/modifications or a completely new project idea in ev en semester. This policy can be
adopted on case by case basis. 

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 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 . 

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 68

 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 project:

 In first semester entire theoretical solution shall be ready, including components/system selection
and cost analysis. Two reviews will be conducted based on presentation given by students group. 
 First shall be for finalisation of problem

 Second shall be on finalisation of proposed solution of problem .
 In second semester expected work shall be procurement of component’s/systems, building of
working prototype, testing and validation of results based on work completed in an earlier
semester. 
 First review is based on readiness of building working prototype to be conducted.
 Second review shall be based on poster presentation cum demonstration of working
model in last month of the said semester.

Half -year project:

 In this case in one semester students’ group shall complete project in all aspects
including, o Identification of need/problem  
o Proposed final solut ion
o Procurement of components/systems 
o Building prototype and testing
 Two reviews will be conducted for continuous assessment, 
 First shall be for finalisation of problem and proposed solution
 Second shall be for implementation and testing of solution.

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 69


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 engi neering 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 Assessment of Mini Project Practical/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 Examiners preferably fro m industry or
research organisations having experience of more than five years approved by head of Institution. 
 Students shall be motivated to publish a paper based on the work in Conferences/students
competitions. 

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University of Mumbai, Instrumentation Engineering, REV 2019 ‘C’ Scheme 70



Mini Project shall be assessed based on following points;
1. Quality of problem and Clarity
2. Innovativeness in solutions
3. Cost e ffectiveness 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