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Third Year Syllabus

University of Mumbai, Instrumentation Engineering, Rev 2012-13 1

UNIVERSITY OF MUMBAI

Bachelor of Engineering

Instrumentation Engineering (Third Year Sem. V & VI), Revised course

(REV- 2012) from Academic Year 2014 -15, Under

FACULTY OF TECHNOLOGY

(As per Semester Based Credit and Grading System)

University of Mumbai, Instrumentation Engineering, Rev 2012-13 4

Semester V

Subject Code Subject Name

Teaching Scheme Credits Assigned

Theory Pract./ Tut. Theory Pract./

Tut. Total

ISC501 Signals and Systems 4 2 4 1 5 ISC502 Applications of

Microcontroller -I 4 2 4 1 5

ISC503 Control System Design 4 2 4 1 5 ISC504 Signal Conditioning

Circuit Design 4 2 4 1 5

ISC505 Control system components 4 2 4 1 5

ISC506 Business Communication and Ethics

- 2*+2 - 2 2

20 14 20 7 27

Subject Code Subject Name

Examination scheme Theory Marks Ter

m wor

k

Pract./

Oral Total

Internal Assessment End Sem

exam

Exam Duration (in Hrs) Test 1

Test 2 Avg.

ISC501 Signals and Systems 20 20 20 80 03 25 - 125

ISC502 Applications of Microcontroller -I 20 20 20 80 03 25 25 150

ISC503 Control System Design 20 20 20 80 03 25 - 125 ISC504 Signal Conditioning

Circuit Design 20 20 20 80 03 25 50+ 175

ISC505 Control system components 20 20 20 80

03 25 25+ 150

ISC506 Business Communication and Ethics

- - - - - 50 - 50

Total 100 400 -- 175 100 775 + Includes both Practical and Oral examination, * Theory for entire class to be conducted

University of Mumbai, Instrumentation Engineering, Rev 2012-13 6

Subject Code

Subject Name

Teaching Scheme (Hrs.)

Credits Assigned

Theory Practical Tutorial Theory Practical Tutorial Total ISC501 Signals

and Systems

4 2 -- 4 1 -- 5

Subject Code

Subject Name

Examination Scheme Theory Marks Term

Work Practical & Oral

Oral Total Internal assessment End

Sem. Exam

Test 1 Test 2 Avg

ISC501 Signals and Systems

20 20 20 80 25 -- -- 125

Subject Code

Subject Name Credits

ISC501 Signals and System 5 Course Objectives

To introduce students to the idea of signal and system analysis and characterization in time and frequency domain.

To provide foundation of signal and system concepts to areas like communication, control and comprehend applications of signal processing in communication systems.

Course Outcomes

Students will be able to understand significance of signals and systems in the time and frequency domains.

Students will be able to interpret and analyze signal and report results. Students will be able to evaluate the time and frequency response of

continuous and discrete time, system which is useful in understanding behavior of communication and control systems.

Module Topics

Hours 1

Introduction: Definition of signal, Singular Functions, Basic Operations on signal such as: Addition, Multiplication, Time Scaling, Time Shifting, Folding, and Amplitude Scaling.

Classification: C.T. D.T, Periodic, aperiodic, / non-periodic, Even/Odd, Energy/ Power, causal and anticausal signals.

Classification of System: Static and dynamic, time invariant and time variant, Linear and Non linear, Causal and Non causal stable and unstable invertible and non invertible.

10

2

Linear Time Invariant System: Linear differential equations, Impulse response Representation of signals by a continuum of impulses.

07

University of Mumbai, Instrumentation Engineering, Rev 2012-13 7

Convolution for continues time and discrete time (Linear and Circular) Properties of LTI System.

3

Fourier Series Orthogonal functions, definitions, Approximation, Co-efficient calculation on the basis of min. Mean square error. Representation of Fourier series in terms of trigonometric, exponential, complex. Gibbs phenomenon.

04

4

Fourier Transform Continuous and Discrete time Fourier transform Properties. Linearity, time shifting, time reversal, frequency shifting, Scaling, Convolution in time domain, diff. in time domain. Differentiation in freq. domain parsevals relation. Relationship between Z, Laplace and Fourier transform.

06

5

Laplace Transform: Definition ROC concept, Properties, Inverse LT Transient and steady state response of LTI system. Stability & Causality of system.

07

6

Z-Transform: Definition, Convergence, properties and inversion (PFE long division Residue method) of Z-Transform. Concept of single and double sided Z- Transform. Analysis of discrete time system using Z-Transform. Stability and Causality.

14

List of Tutorials / Experiments: 1. Difference between continuous time and discrete time signals, classification,

problems on Signal classification. 2. Difference between continuous time and discrete time signals, classification,

problems on Systems classification. 3. Problems on Basic Operations on signals. 4. Singular functions, Impulse function and its approximation, I/O systems.

Difference equation formulation. 5. Problems on convolution Integral, convolution sum and correlation. 6. Problems on Laplace and its properties. 7. Concept of Z-Transform (Single and Double Sided), analysis, relation between

Laplace Transform and Z-Transform. 8. Fourier series representation, properties, problems on Fourier series and

Fourier Transform. 9. Fourier Transform, properties, problems on Fourier Transform. 10. Relation between Fourier and Laplace, Solutions to differential equations

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.

University of Mumbai, Instrumentation Engineering, Rev 2012-13 8

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.

Practical & Oral Examination:

Practical examination will be based on one experiment performed from the list of experiments given in the syllabus and the oral will be based on entire subject.

Term work: Term work consists of minimum eight tutorials. The distribution of the term work shall be as follows,

Laboratory work (Experiments / Assignments) :10 marks Laboratory work (Programs / Journal) :10 marks Attendance (Practical and Theory) :05 marks

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

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. End Semester Examination: Some guidelines for setting the question papers are as, six questions to be set each of 20 marks, out of these any four questions to be attempted by students. Minimum 80% syllabus should be covered in question papers of end semester examination.

Text Books: 1. Oppenhelm, Wilsky and Nawab, Signals and Systems, PHI / Pearson

Education, 2nd edition, 2002. 2. S. P. Xavier, Signals and Systems, 2nd Edition, S. Chand and Co., 1998. 3. J.B. Gurung, Signals and Systems, 1st Edition, PHI, 2009.

Reference Books: 1. Reddy and Prasad, Signals Processing, TMH, Vol. II, 1994. 2. Taylor, Principles of Signals and Systems, McGraw Hill, 1994. 3. Haykin, Simon S., Signals and Systems, John Wiley, New York, 1978. 4. Lathi B. P., Signals Processing and Linear Systems, Oxford University

Press,2003. 5. I. J. Nagrath, Signals and Systems, 1st Edition, TMH, 2000. 6. Douglas K. Lindner, Introduction to Signals and Systems, TMH, 1999. 7. Rodger E. Ziemer, William H. Tranter, Signals & Systems Continuous and

Discrete, Pearson Education, 4th Edition, 2002.

University of Mumbai, Instrumentation Engineering, Rev 2012-13 9

Sub code Subject Name Teaching Scheme (Hrs) Credits Assigned Theory Pract. Tut. Theory Pract. Tut. Total

ISC502 Applications of Microcontroller - I

4 2 - 4 1 - 5

Sub code Subject Name

Examination Scheme Theory(out of 100)

Term Work

Pract and oral

Oral Total Internal Assessment (out of 20) End sem

Exam Test 1 Test 2 Avg

ISC502 Applications of Microcontroller - I

20 20 20 80 25 25 -- 150

Subject Code

Subject Name Credits

ISC502 Applications of Microcontroller - I 5 Course Objectives

To make the students understand the fundamentals of 8051 Microcontroller. Students should understand the working of these systems and should be able to determine hardware and software interfacing with real time systems. They should further understand how to design any application based on these systems.

Course Outcomes

The students will be able to

Define Microprocessor and Microcontroller family with comparison. Understand working of 8051/8052and MCS251 Microcontrolle

Architecture and Programming model. Understand the concept of Timer, Interrupt, I/O Port interfacing with 8051

Microcontroller. Understand the concept of Interfacing with Real time System.

Module Topics

Hrs.

1 Introduction Micropr