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k) Students will demonstrate skills to use modern engineering tools, software and .... Chilton Book Company. 2. Process Control ..... A. K. Sawhney, A course in.
Department of Applied Electronics & Instrumentation

DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

RSET VISION

To evolve into a premier technological and research institution, moulding eminent professionals with creative minds, innovative ideas and sound practical skill, and to shape a future where technology works for the enrichment of mankind.

RSET MISSION

To impart state-of-the-art knowledge to individuals in various technological disciplines and to inculcate in them a high degree of social consciousness and human values, thereby enabling them to face the challenges of life with courage and conviction.

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

DEPARTMENT VISION

To evolve into a centre of academic excellence, developing professionals in the field of electronics and instrumentation to excel in academia and industry.

DEPARTMENT MISSION

Facilitate comprehensive knowledge transfer with latest theoretical and practical concepts, developing good relationship with industrial, academic and research institutions thereby moulding competent professionals with social commitment.

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

PROGRAMME EDUCATIONAL OBJECTIVES PEOI: Graduates will have the fundamental and advanced knowledge in mathematics, science, electronics, instrumentation and allied engineering. PEOII: Graduates shall pursue higher studies, or take up engineering profession in design and development or take up engineering research assignments. PEOIII: Graduates will be conscious of the need for environment friendly engineering solutions and will be equipped with positive attitude, to help them to acquire leadership qualities as well as team spirit and get adapted to the current industrial scenario.

PROGRAMME OUTCOMES a) Students will be capable of applying the knowledge of mathematics, science and engineering in the field of electronics and instrumentation engineering. b) Students will have the ability to design and conduct experiments, analyze and interpret data in electronics and instrumentation engineering. c) Students will have the ability to design electronics and instrumentation system components or processes to meet desired needs within realistic constraints such as health and safety, economic, environmental and societal considerations. d) Students will be able to work individually as well as in multidisciplinary teams, as a member or as a leader, to accomplish the common goal. e)

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

e) Students will be able to identify, analyze, formulate and solve engineering problems. f) Students will be capable of applying the knowledge of mathematics, science and engineering in the field of electronics and instrumentation engineering. g) Students will have the ability to design and conduct experiments, analyze and interpret data in electronics and instrumentation engineering. h) Students will have the ability to design electronics and instrumentation system components or processes to meet desired needs within realistic constraints such as health and safety, economic, environmental and societal considerations. i) Students will be able to work individually as well as in multidisciplinary teams, as a member or as a leader, to accomplish the common goal. j) Students will be aware of the contemporary issues, which help them to integrate advanced and sustainable solutions into the user environment. k) Students will demonstrate skills to use modern engineering tools, software and equipment to analyze and model complex engineering solutions. l) Students will demonstrate knowledge and understanding of the management principles to estimate the requirements and to manage projects in multidisciplinary environments. m) Students will excel in competitive examinations like GATE, GRE and Engineering Services Examination.

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

INDEX 1. 2. 3. 4.

5.

6.

7.

8.

9.

10.

11.

SEMESTER PLAN ASSIGNMENT SCHEDULE SCHEME AI010 601: PROCESS CONTROL INSTRUMENTATION 4.1. COURSE INFORMATION SHEET 4.2. COURSE PLAN AI010 602: DIGITAL SIGNAL PROCESSING 5.1. COURSE INFORMATION SHEET 5.2. COURSE PLAN AI010 603: INDUSTRIAL INSTRUMENTATION I 6.1. COURSE INFORMATION SHEET 6.2. COURSE PLAN AI010 604: MICROCONTROLLER BASED SYSTEM DESIGN 7.1. COURSE INFORMATION SHEET 7.2. COURSE PLAN AI010 605: CONTROL ENGINEERING II 8.1. COURSE INFORMATION SHEET 8.2. COURSE PLAN AI010 606 L01: MECHATRONICS 9.1. COURSE INFORMATION SHEET 9.2. COURSE PLAN AI010 607: MICROPROCESSOR & MICROCONTROLLER LAB 10.1. COURSE INFORMATION SHEET 10.2. COURSE PLAN AI010 608: MINI PROJECT 10.1. COURSE INFORMATION SHEET 10.2. COURSE PLAN

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

SEMESTER PLAN

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

ASSIGNMENT SCHEDULE Week 5 Week 5 Week 6 Week 6 Week 7 Week 7 Week 10 Week 10 Week 11 Week 11 Week 12 Week 12

AI010 601: PROCESS CONTROL INSTRUMENTATION AI010 602: DIGITAL SIGNAL PROCESSING AI010 603: INDUSTRIAL INSTRUMENTATION I AI010 604: MICROCONTROLLER BASED SYSTEM DESIGN AI010 605: CONTROL ENGINEERING II AI010 606 L01: MECHATRONICS AI010 601: PROCESS CONTROL INSTRUMENTATION AI010 602: DIGITAL SIGNAL PROCESSING AI010 603: INDUSTRIAL INSTRUMENTATION I AI010 604: MICROCONTROLLER BASED SYSTEM DESIGN AI010 605: CONTROL ENGINEERING II AI010 606 L01: MECHATRONICS

COURSE HANDOUT: S6

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DEPARTMENT OF APPLIED ELECTRONICS & INSTRUMENTATION

SCHEME

COURSE HANDOUT: S6

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AI010 601

PROCESS CONTROL INSTRUMENTATION

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: PROCESS CONTROL INSTRUMENTATION COURSE CODE: AI 010 601 REGULATION: 2012 COURSE AREA/DOMAIN: INSTRUMENTATION CORRESPONDING LAB COURSE CODE (IF ANY): NA SYLLABUS: UNIT I

II

DEGREE: BTECH SEMESTER: 6

CREDITS: 4

COURSE TYPE: CORE CONTACT HOURS: 3+1 (Tutorial) Hours/Week. LAB COURSE NAME: NA

DETAILS HOURS Process Control System: Need for process control, classification of 12 process variables, Process characteristics: Process equation, degrees of freedom, modeling of simple systems – thermal, gas, liquid systems. Process lag, load disturbance and their effect on processes. Selfregulating processes, interacting and non interacting processes, Regulator and servo control. Piping and Instrumentation diagraminstrument terms and symbols. 12 Controller modes: Basic control action, two position (ON-OFF), multiposition, floating control modes. Continuous controller modes: Proportional, Integral, Derivative. Composite controller modes: P-I, P-D, P-I-D. response of controllers for different types of test inputs, electronic controllers to realize various control actions, selection of control mode for different processes, Integral wind-up and prevention. Auto/Manual transfer, Bumpless transfer.

III

IV

V

Optimum Controller Settings: Controller tuning Methods- Process reaction curve method, Ziegler Nichols method, damped oscillation method, ¼ decay ratio. Evaluation criteria - IAE, ISE, ITAE. Response of controllers for different test inputs. Selection of control modes for processes like level, pressure, temperature and flow. Final control elements: I/P and P/I converter, Pneumatic and Electric actuators. Pneumatic control valves, classification, construction details (Globe, butterfly and ball valve types), various plug characteristics. Valve sizing, inherent and installed valve characteristics. Cavitation and flashing in control valves. Valve actuators and positioners. Selection of control valves. Advanced control schemes: Cascade control, ratio control, feed forward control, Adaptive and Inferential control, split range and averaging control. Multivariable process control, interaction of control loops. Case Studies: Steam boiler – control of heat exchangers, drum level control and combustion. Distillation column – Control of top and bottom product

COURSE HANDOUT: S6

12

12

12

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PROCESS CONTROL INSTRUMENTATION

S6AEI

compositions – Reflux ratio, control schemes in distillation column. TOTAL HOURS TEXT/REFERENCE BOOKS:

60

T/R BOOK TITLE/AUTHORS/PUBLICATION T1 George Stephenopoulos: Chemical Process Control T2 Donald P. Eckman, Automatic Process Control T3 Peter Harriot : Process Control,TMH,1985. T4 D. R. Coughanowr: Process Systems Analysis and Control, McGraw Hill. R1 Patranabis D: Principles of Process Control, TMH, 1981. R2 Bela G. Liptak, Process Control, Instrument Engineers' Handbook, Third Edition. COURSE PRE-REQUISITES: C.CODE COURSE NAME AI 010 Control Engineering 1 505 COURSE OBJECTIVES: 1

DESCRIPTION Basics of Control system, Introduction to controller design

SEM S5

To study the basics of Process Control.

2 3

To study about the various controller modes and methods of tuning of controllers. To give an idea about the construction, characteristics and applications of control valves. 4 To have a case study of distillation column control. COURSE OUTCOMES: SNO

DESCRIPTION

1

PO MAPPING a, b, c, e, i, k, m a, b, c, e, m

Graduates will be able to understand the elements of a Process control system like Process variables, P& ID diagrams etc. 2 Graduates will be able to understand the various continuous and discontinuous controller modes and its working principles. 3 Graduates will be able to study the various controller tuning methods a, b, e, k, m and the evaluation criteria for selection of a controller. 4 Graduates will be able to understand the working of various control a, b, c, j, l, valves, its characteristics and valve sizing methods. m 5 Graduates will be able to examine the various control schemes, case a, b, c, k, m studies of a Distillation column and a steam boiler. GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO 1

DESCRIPTION Introduction to basics of various chemical processes

PROPOSED ACTIONS Assignments

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

COURSE HANDOUT: S6

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PROCESS CONTROL INSTRUMENTATION

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TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Practical sessions on working of various control valves. 2 Videos on working of control valves 3 Visit to Process control lab in the college WEB SOURCE REFERENCES: 1 http://nptel.iitm.ac.in/courses/103103037/ 2 http://www.itl.nist.gov/div898/handbook/pmc/section1/pmc13.htm 3 http://nptel.iitm.ac.in/courses/103105064/ DELIVERY/INSTRUCTIONAL METHODOLOGIES: CHALK & TALK 

STUD. ASSIGNMENT 

WEB RESOURCES

LCD/SMART BOARDS 

STUD. SEMINARS  ADD-ON COURSES ASSESSMENT METHODOLOGIES-DIRECT ASSIGNMENTS 

STUD. SEMINARS

STUD. LAB STUD. VIVA PRACTICES ADD-ON COURSES OTHERS ASSESSMENT METHODOLOGIES-INDIRECT ASSESSMENT OF COURSE OUTCOMES (BY FEEDBACK, ONCE) ASSESSMENT OF MINI/MAJOR PROJECTS BY EXT. EXPERTS

TESTS/MODEL EXAMS  MINI/MAJOR PROJECTS 

UNIV. EXAMINATION  CERTIFICATIONS

STUDENT FEEDBACK ON FACULTY (TWICE)  OTHERS

Prepared by

Approved by

Mr. Pravin P. S.

Ms. Liza Annie Joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

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COURSE PLAN Module 1 Sl. No.

Topic

No. of lecture hours

1

Introduction to process control Process Control System: Need for process control Classification of process variables, Process characteristics: Process equation Degrees of freedom, modelling of simple systems – thermal, gas, liquid systems Process lag, load disturbance and their effect on processes Self-regulating processes, interacting and non interacting processes

1

7

Regulator and servo control

1

8

Piping and Instrumentation diagraminstrument terms and symbols

1

2 3

4 5 6

Reference Books

1 2

2 2 2

1. George Stephenopoulos, Chemical Process Control. 2. D R Coughanowr, Process Systems Analysis and Control, McGraw Hill. 3. B.G Liptak, Process Control, Chilton Book Company.

Total hours : 12 Module 2 Sl. No. 1 2 3 4 5 6 7 8

Topic Controller modes: Basic control action, two position (ON-OFF) Multi-position, floating control modes. Continuous controller modes: Proportional, Integral, Derivative Composite controller modes: P-I, P-D, P-I-D Response of controllers for different types of test inputs Electronic controllers to realize various control actions Selection of control mode for different processes Integral wind-up and prevention COURSE HANDOUT: S6

No. of lecture hours

Reference Books

1 1 1 2 2 1

1. George Stephenopoulos, Chemical Process Control. 2. D R Coughanowr, Process Systems Analysis and Control, McGraw Hill. 3. B.G Liptak, Process Control, Chilton Book Company.

1 1 Page 13

AI010 601

9 10

PROCESS CONTROL INSTRUMENTATION

Auto/Manual transfer Bumpless transfer Total hours : 12

S6AEI

1 1

Module 3 Sl. No.

1 2 3 4 5 6 7 8 9

Topic

No. of lecture hours

Optimum Controller Settings: Controller tuning Methods- Process reaction curve Ziegler Nichols method Damped oscillation method ¼ decay ratio ,Evaluation criteria - IAE, ISE, ITAE Response of controllers for different test inputs Selection of control modes for processes like level Selection of control modes for processes like presure Selection of control modes for processes like temperature Selection of control modes for processes like flow Total hours : 12

Reference Books

2 1 1 2 2 1 1

1. George Stephenopoulos, Chemical Process Control. 2. D R Coughanowr, Process Systems Analysis and Control, McGraw Hill. 3. B.G Liptak, Process Control, Chilton Book Company.

1 1

Module 4 Sl. No.

Topic

No. of lecture hours

1

Final control elements: I/P and P/I converter

2

2

Pneumatic and Electric actuators

1

3

Pneumatic control valves, classification, construction details (Globe, butterfly and ball valve types)

2

4

Various plug characteristics

1

COURSE HANDOUT: S6

Reference Books

1. George Stephenopoulos, Chemical Process Control. 2. D R Coughanowr, Process Systems Analysis and Control, McGraw Hill. 3. B.G Liptak, Process Control, Chilton Book Company.

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PROCESS CONTROL INSTRUMENTATION

5

Valve sizing, inherent and installed valve characteristics

2

6

Cavitation and flashing in control valves

2

7

Valve actuators and positioners

1

8

Selection of control valves

1

S6AEI

Total hours : 12

Module 5 Sl. No.

Topic

No. of lecture hours

1

Advanced control schemes: Cascade control, ratio control

2

2

Feed forward control, Adaptive and Inferential control

2

3

Split range and averaging control

2

4

Multivariable process control, interaction of control loops

2

5

Case Studies: Steam boiler – control of heat exchangers, drum level control and combustion

2

6

Distillation column – Control of top and bottom product compositions

1

7

Reflux ratio, control schemes in distillation column

1

Reference Books

1. George Stephenopoulos, Chemical Process Control. 2. D R Coughanowr, Process Systems Analysis and Control, McGraw Hill. 3. B.G Liptak, Process Control, Chilton Book Company.

Total hours : 12

COURSE HANDOUT: S6

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AI010 602

DIGITAL SIGNAL PROCESSING

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: DIGITAL SIGNAL PROCESSING COURSE CODE: AI 010 602 REGULATION: 2010 COURSE AREA/DOMAIN: ELECTRONICS CORRESPONDING LAB COURSE CODE (IF ANY): DSP LAB SYLLABUS: UNIT I

II

DEGREE: BTECH SEMESTER: 6 CREDITS: 4 COURSE TYPE: CORE CONTACT HOURS: 2+2 (Tutorial) Hours/Week. LAB COURSE NAME: AI 010 708

DETAILS HOURS Advantages of DSP – Review of discrete time signals and systems – 12 Discrete time LTI systems – Review of DTFT – Existence – Symmetry properties – DTFT theorems – Frequency response - Review of Z transform – Region of Convergence – Properties Sampling of Continuous time signals – Frequency domain representation of sampling – Aliasing - Reconstruction of the analog signal from its samples – Discrete time processing of continuous time signals – Impulse invariance – Changing the sampling rate using discrete time processing – Sampling rate reduction by an integer factor – Compressor – Time and frequency domain relations – Sampling rate increase by an integer factor – Expander – Time and frequency domain relations – Changing the sampling rate by a rational factor. 12 Transform analysis of LTI systems – Phase and group delay – Frequency response for rational system functions – Frequency response of a single zero and pole – Multiple poles and zeros - Relationship between magnitude and phase – All pass systems – Minimum phase systems – Linear phase systems – Generalised linear phase – 4 types – Location of zeros.

III

Structures for discrete time systems – IIR and FIR systems – Block diagram and SFG representation of difference equations – Basic structures for IIR systems – Direct form - Cascade form - Parallel form Transposed forms – Structures for FIR systems – Direct and Cascade forms - Structures for Linear phase systems – Overview of finite precision numerical effects in implementing systems Analog filter design: Filter specification – Butterworth approximation – Pole locations – Design of analog low pass Butterworth filters – Chebyshev Type 1 approximation – pole locations – Analog to analog transformations for designing high pass, band pass and band stop filters.

COURSE HANDOUT: S6

12

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S6AEI

IV

Digital filter design: Filter specification – Low pass IIR filter design – Impulse invariant and Bilinear transformation methods – Butterworth and Chebyshev – Design of high pass, band pass and band stop IIR digital filters – Design of FIR filters by windowing – Properties of commonly used windows – Rectangular, Bartlett, Hanning, Hamming and Kaiser.

12

V

The Discrete Fourier Transform - Relation with DTFT – Properties of DFT – Linearity – Circular shift – Duality – Symmetry properties – Circular convolution – Linear convolution using the DFT – Linear convolution of two finite length sequences – Linear convolution of a finite length sequence with an infinite length sequence – Overlap add and overlap save – Computation of the DFT – Decimation in time and decimation in frequency FFT – Fourier analysis of signals using the DFT – Effect of windowing – Resolution and leakage – Effect of spectral sampling.

12

TOTAL HOURS

60

TEXT/REFERENCE BOOKS: T/R BOOK TITLE/AUTHORS/PUBLICATION R1 A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd Edition Pearson Education. R2

S. K. Mitra, Digital Signal Processing: A Computer Based Approach ,TMH

R3

J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

R4

L. C. Ludeman, Fundamentals of Digital Signal Processing, Wiley

R5

J. R. Johnson, Introduction to Digital Signal Processing, PHI

COURSE PRE-REQUISITES: C.CODE COURSE NAME EN 010 ENGINEERING MATHEMATICS I 101 EN 010 ENGINEERING MATHEMATICS II 301 EN 010 SIGNALS & SYSTEMS 403 COURSE OBJECTIVES: 1 2 3

DESCRIPTION SEM To develop basic idea about calculus S1S2 and differential equations. To know the fundamentals of z- S3 transform. To understand the basics of discrete S4 signals and systems.

To study the methods of analysis of Linear Time Invariant Systems To study the methods of design and analysis of filters To study the methods to apply Fourier transform in signal processing

COURSE HANDOUT: S6

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S6AEI

COURSE OUTCOMES: SNO

DESCRIPTION

1

PO MAPPING a, i, m

Graduates will be able to identify the basic difference between compressor and expander. 2 Graduates will be able to describe sampling and reconstruction of a, e, i, m signals from samples. 3 Graduates will be able to explain the significance of Transform a, b, e, i, m analysis of LTI systems 4 Graduates will be able to apply the basics of filtering in real time a, i, m applications 5 Graduates will be able to draw basic structures for discrete time a, e, i, m systems 6 Graduates will be able to design suitable Butterworth and Chebyshev a, b, i, m digital IIR filters and FIR filters required for signal processing applications. 7 Graduates will develop skills to solve problems based on DFT and to a, e, i, m compare the computational complexity of DFT and FFT . GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO 1 2

DESCRIPTION FIR filter design using frequency sampling method MATLAB Exercises

PROPOSED ACTIONS NPTEL Lab in S7

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Architecture and features of TMS & ADSP signal processing chips. 2 Applications of Multirate signal processing 3 Adaptive Filters 4 Speech Processing WEB SOURCE REFERENCES: 1 2 3 4 5 6

http://nptel.iitm.ac.in/video.php?subjectId=117102060 http://nptel.iitm.ac.in/courses/Webcourse-contents/IIT-KANPUR/Digi_Sign_Pro/ ui/ Course_home1_1.htm http://www.dspdimension.com/tutorials/ http://www.analog.com/en/processors-dsp/blackfin/products/manuals/ resources/index.html http://www.tapr.org/dsp_info http://dsp.rice.edu/cs

COURSE HANDOUT: S6

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7 http://www.dspguide.com/pdfbook.htm 8 http://pdf1.alldatasheet.com/datasheet-pdf/view/29031/TI/TMS320.html 9 http://nptel.iitm.ac.in/video.php?subjectId=117105075 10 http://www.youtube.com/watch?v=8JAPMsjPixY DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK  ☐ STUD. SEMINARS

☐ STUD. ASSIGNMENT 

☐ WEB RESOURCES ☐ LCD/SMART BOARDS

☐ ADD-ON COURSES

ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS  ☐ STUD. LAB

☐ STUD. SEMINARS

☐ TESTS/MODEL

☐ UNIV.

☐ STUD. VIVA

EXAMS  ☐ MINI/MAJOR

EXAMINATION  ☐ CERTIFICATIONS

PRACTICES 

PROJECTS

☐ ADD-ON ☐ OTHERS COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY

☐ STUDENT FEEDBACK ON FACULTY

FEEDBACK, ONCE)  ☐ ASSESSMENT OF MINI/MAJOR PROJECTS

(TWICE)  ☐ OTHERS

BY EXT. EXPERTS

Prepared by

Approved by

Mr. Arun A. Balakrishnan

Ms. Liza Annie Joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

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DIGITAL SIGNAL PROCESSING

S6AEI

COURSE PLAN Module 1

Sl. No.

Topic

No. of lecture hours

1

Introduction to DSP, Advantages of DSP Review of discrete time signals and systems, Discrete time LTI systems Review of DTFT Existence ,Symmetry properties, DTFT theorems – Frequency response Review of Z transform – ROC – Properties Sampling of Continuous time signals – Frequency domain representation of sampling – Aliasing - Reconstruction of the analog signal from its samples Discrete time processing of continuous time signals – Impulse invariance – Changing the sampling rate using discrete time processing, Sampling rate reduction by an integer factor – Compressor – Time and frequency domain relations Sampling rate increase by an integer factor – Expander – Time and frequency domain relations Changing the sample rate by a rational factor

1

Problems

1

2 3 4

5

6

7

8 9 10

Reference Books

1 1 1

1

1

2

2

1. A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd Edition, Pearson Education. 2. S. K. Mitra, Digital Signal Processing: A Computer Based Approach ,TMH 3. J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

1

Total hours : 12

Module 2

Sl. No.

Topic

No. of lecture hours

1

Transform analysis of LTI systems, Phase and group delay Frequency response for rational system functions

1

2

COURSE HANDOUT: S6

1

Reference Books 1. A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd

Page 20

AI010 602

3 4 5 6

DIGITAL SIGNAL PROCESSING

Frequency response of a single zero and pole

1 1

Multiple poles and zeros Relationship between magnitude and phase

1 1

All pass systems

7

Minimum phase systems

1

8

Linear phase systems –

1

9

Generalised linear phase – 4 types, Location of zeros

2

10

Problems

2

S6AEI

Edition, Pearson Education. 2. S. K. Mitra, Digital Signal Processing: A Computer Based Approach ,TMH 3. J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

Total hours : 12

Module 3

Sl. No.

Topic

No. of lecture hours

1

Structures for discrete time systems – IIR and FIR systems

1

Block diagram and SFG representation of difference equations – Basic structures for IIR systems

1

Direct form - Cascade form

1

Parallel form - Transposed forms

1

5

Structures for FIR systems – Direct and Cascade forms

1

6

Structures for Linear phase systems

1

7

Overview of finite precision numerical effects in implementing systems

1

8

Analog filter design: Filter specification

1

9

Butterworth approximation – Pole locations

1

2

3 4

COURSE HANDOUT: S6

Reference Books

1. A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd Edition, Pearson Education. 2. S. K. Mitra, Digital Signal Processing: A Computer Based Approach ,TMH 3. J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

Page 21

AI010 602

10

11

DIGITAL SIGNAL PROCESSING

Design of analog low pass Butterworth filters – Chebyshev Type 1 approximation

2

Pole locations – Analog to analog transformations for designing high pass, band pass and band stop filters

1

S6AEI

Total Hours:12

Module 4

Sl. No.

Topic

No. of lecture hours

1

Digital filter design: Filter specification

1

2

Low pass IIR filter design – Impulse invariant and Bilinear transformation methods

2

3

Butterworth and Chebyshev - Design of high pass, band pass and band stop IIR digital filters

4

4

Design of FIR filters by windowing

3

5

Properties of commonly used windows – Rectangular, Bartlett, Hanning, Hamming and Kaiser

2

Reference Books

1. A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd Edition, Pearson Education. 2. S. K. Mitra, Digital Signal Processing: A Computer Based Approach ,TMH 3. J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

Total Hours: 12 Module 5

Sl. No.

Topic

No. of lecture hours

Reference Books

1

The Discrete Fourier Transform Relation with DTFT

1

2

Properties of DFT – Linearity – Circular shift

1

3

Duality – Symmetry properties

1

1. A. V. Oppenheim, R. W. Schaffer, Discrete Time Signal Processing , 2nd Edition, Pearson Education. 2. S. K. Mitra, Digital Signal

COURSE HANDOUT: S6

Page 22

AI010 602

DIGITAL SIGNAL PROCESSING

4

Circular convolution – Linear convolution using the DFT

1

5

Linear convolution of two finite length sequences

1

6

Linear convolution of a finite length sequence with an infinite length sequence - Overlap add and overlap save – Computation of the DFT

2

7

Decimation in time and decimation in frequency FFT

4

8

Fourier analysis of signals using the DFT – Effect of windowing – Resolution and leakage – Effect of spectral sampling

1

S6AEI

Processing: A Computer Based Approach ,TMH 3. J. G. Proakis, D. G. Manolakis, Digital Signal Processing: Principles, Algorithms and Applications, PHI.

Total Hours: 12

COURSE HANDOUT: S6

Page 23

AI010 603

INDUSTRIAL INSTRUMENTATION I

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: INDUSTRIAL INSTRUMENTATION I COURSE CODE: AI010 504 REGULATION: 2010 COURSE AREA/DOMAIN: INSTRUMENTATION CORRESPONDING LAB COURSE CODE (IF ANY): AI 010 707 SYLLABUS: UNIT I

II

III

DEGREE: BTECH SEMESTER: 6

CREDITS: 4

COURSE TYPE: CORE CONTACT HOURS: 4 + 1 (Tutorial) hours/week. LAB COURSE NAME: INDUSTRIAL INSTRUMENTATION LAB

DETAILS HOURS Measurement of Force, Torque, Velocity :10 Basic methods of measurement of force (weight) :scales and balancesmechanical balances- electromagnetic balance – Different types of load cells : hydraulic load cells - pneumatic loadcell - magneto elastic (pressductor)- strain gauge loadcell - proving ring. Different methods of torque measurement: Strain gauge, Relative regular twist-measurement of torque with spur gears – and proximity sensors. Speed and velocity measurement: Revolution counter- Capacitive tachometer -Drag cup type tacho meter- D.C and A.C tacho generators – Stroboscope- translational velocity transducers. Velocity measurement using variable reluctance proximity pickup. Calibration methods. Measurement of acceleration, vibration and density :12 Accelerometers – potentiometric type – LVDT- Piezo-electric, capacitive Strain gauge and variable reluctance type accelerometers. Mechanical type vibration instruments – Seismic instrument as an accelerometer and vibrometer – measurement of relative motion Calibration of vibration pick ups Units of density, specific gravity and viscosity used in industries – Baume scale API scale – hydro meter- density measurement using LVDTdifferential pressure method- pressure head type densitometer – float type densitometer – Ultrasonic densitometer – Bridge type gas densitometer-coriolis densitometer. Pressure measurement : - Units of pressure – different types of pressure10 Manometers – Different types –errors in manometers- Elastic type pressure gauges – Bourden tube - Bellows – Diaphragms – Electrical methods – Elastic elements with LVDT and strain gauges – potentiometric pressure transducers- Capacitive type pressure gauge –Piezo electric pressure sensor –Resonator pressure sensor – optical pressure transducers- pressure switches- Measurement of vacuum – McLeod gauge –Thermal vacuum gauges – Ionization gauge -Testing and calibration of pressure gauges – Dead weight tester- Bulk gauge(high pressure measurement).

COURSE HANDOUT: S6

Page 24

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INDUSTRIAL INSTRUMENTATION I

S6AEI

IV

Temperature measurement :- Definitions and standards – Primary and secondary fixed points – Calibration of thermometers - Different types of filled in system thermometer – Sources of errors in filled in systems and their compensation – Bimetallic thermometers – Electrical methods of temperature measurement – resistance thermometers-3 lead and 4 lead RTDs - Thermistors –Linearization techniques. V Thermocouples –thermocouple junctions- Law of thermocouple – Fabrication of industrial thermocouples– Signal conditioning of thermocouple output –– Commercial circuits for cold junction compensation –– Special techniques for measuring high temperature using thermocouples – Radiation methods of temperature measurement – Radiation fundamentals – Total radiation pyrometers – Optical pyrometer – infra red pyrometers- Two colour radiation pyrometer.- IC temperature sensors- fiber optic temperature measurement- calibration of temperature transducers. TOTAL HOURS TEXT/REFERENCE BOOKS/JOURNALS:

7

11

50

T/R R1

AUTHOR/ TITLE/PUBLISHER D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999.

R2

Doeblin, Measurement Systems

R3

T. R. Padmanabhan, Industrial Instrumentation

R4

A. K. Sawhney, A course in mechanical measurements and Instrumentation– Dhanpat Ra and Sons, New Delhi, 1999.

R5

James W. Dally, et al, Instrumentation for Engineering Measurements

R6

Alan S. Morris, Measurement and Instrumentation Principles

R7

Ferdinand P. Beer, E. Russell Johnson Jr., Vector Mechanics for Engineers.

COURSE PRE-REQUISITES: 1 Knowledge of basics of electrical parameters like charge, current and voltage. 2 Knowledge of SI units. 3 Familiarity with T&E equipment like power supply, signal generator and CRO. 4 Awareness of need for measurements in industry. 5 Basics of analogue electronics. COURSE OBJECTIVES: 1 2 3 4 5

Provide the students with a basic understanding of the topics covered in the syllabus. Enable the students to appear for the university exam with confidence. Make the students aware of practical approach to industrial instrumentation. Making the students understand the significance and meaning of specifying error band/accuracy/etc. Helping the students gain confidence to take up higher studies on the subject as well

COURSE HANDOUT: S6

Page 25

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INDUSTRIAL INSTRUMENTATION I

S6AEI

as to take up industrial jobs related to instrumentation. COURSE OUTCOMES: SNO

DESCRIPTION

1

Upon completion of the subject, students will be able to answer questions on the fundamentals of industrial instrumentation with confidence.

2

Upon completion of the subject, students will be able to learn instrumentation topics more seriously Majority of students will pass university exam. A few students will take up higher studies.

3 4

PO MAPPING a, b, e, g

a, b, e

d, g a, b, e, g, m 5 A few students will take up jobs in core industries. a, b, d, e, g, m GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO

DESCRIPTION

PROPOSED ACTIONS The syllabus is sufficient enough to help the students learn and do well in any industry, and that is what is needed. So, no gap. PROPOSED ACTIONS: NA TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 2 3 4 5

Introduction to instrumentation, with examples and explanation General instrumentation scheme, explanation with block diagram Major functions of instrumentation, with detailed explanation Design of unequal arm balance to get different ranges Fundamentals of magnetic induction, and permeability, dimensional formula for permeability, units of permeability 6 Scheme to achieve temp compensation in strain gauge circuit. 7 Disadvantage of deriving velocity from displacement 8 Mounted resonance and frequency response of accelerometers 9 Why PE accelerometers cannot be used for lateral velocity measurement; use of microdot cables and connectors. 10 Self heating in RTD, how to take care 11 Thermocouple signal conditioning scheme used in industries DELIVERY/INSTRUCTIONAL METHODS: 1 2 3

Black board. Write all necessary key words. Develop schematics, drawing required blocks one by one explaining one by one. Develop any topic from basics.

COURSE HANDOUT: S6

Page 26

AI010 603

4 5

INDUSTRIAL INSTRUMENTATION I

S6AEI

Post purposeful breaks almost every 15 minutes, using 2/3 minutes for interaction with students. Wherever a topic is a continuation of the topic discussed in previous class, summarise/revise the previous class at start of the period.

ASSESSMENT METHODS – DIRECT 1 Asking questions in class. 2 Through home work. 3 Through assignments. 4 Through test paper. ASSESSMENT METHODS - INDIRECT 1 2

Through interaction with students. Through feedback from HoD, which she gives based on class committee meeting.

Prepared by

Approved by

Mr. P. R. Madhava Panicker

Ms. Liza Annie Joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

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COURSE PLAN Module 1

Sl. No. 1

2 3 4 5 6 7 8

9

Topic

No. of lecture hours

Basic methods of measurement of force (weight) :scales and balancesmechanical balances- electromagnetic balance Different types of load cells : hydraulic load cells - pneumatic loadcell magneto elastic (pressductor)- strain gauge loadcell - proving ring. Different methods of torque measurement: Strain gauge Relative regular twist measurement of torque with spur gears and proximity sensors. Speed and velocity measurement: Revolution counter. Capacitive tachometer -Drag cup type tachometer D.C and A.C tacho generators – Stroboscope, translational velocity transducers Velocity measurement using variable reluctance proximity pickup. Calibration methods. Total hours : 12

Reference Books

1

2

1. A. K. Sawhney, A course in mechanical measurements and Instrumentation – Dhanpat Ra and Sons, New Delhi, 1999. 2. R. K. Jain, Mechanical & Industrial measurements 3. D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999. 4. B. C. Nakra & K. K. Chaudary, Instrumentation Measurement & Analysis. 5. S. K. Singh, Industrial Instrumentation and Control

Reference Books

1 1 1 1 1 1 2

Module 2

Sl. No.

Topic

No. of lecture hours

1

Accelerometers – potentiometric type – LVDT- Piezo-electric Capacitive - Strain gauge and variable reluctance type accelerometers. Mechanical type vibration instruments – Seismic instrument as an accelerometer vibrometer – measurement of relative motion, Calibration of vibration pick

2

2 3 4

COURSE HANDOUT: S6

2 2 1

1. A. K. Sawhney, A course in mechanical measurements and Instrumentation – Dhanpat Ra and Sons, New Delhi, 1999. 2. R. K. Jain, Mechanical & Industrial measurements Page 28

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1

3. D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999. 4. B. C. Nakra & K. K. Chaudary, Instrumentation Measurement & Analysis. 5. S. K. Singh, Industrial Instrumentation and Control

Topic

No. of lecture hours

Reference Books

Pressure measurement : - Units of pressure – different types of pressureManometers-Different types

1

2

errors in manometers- Elastic type pressure gauges – Bourden tube

1

3

Bellows – Diaphragms – Electrical methods

1

4

Elastic elements with LVDT and strain gauges

1

5

Potentiometric pressure transducers, Capacitive type pressure gauge

1

6

Piezoelectric pressure sensor – Resonator pressure sensor

1

7

optical pressure transducers- pressure switches

1

8

Measurement of vacuum – McLeod gauge

1

Thermal vacuum gauges – Ionization gauge -Testing and calibration of

1

5 6 7 8 9

ups Units of density, specific gravity and viscosity used in industries, Baume scale API scale hydro meter- density measurement using LVDT differential pressure methodpressure head type densitometer float type densitometer – Ultrasonic densitometer Bridge type gas densitometer-coriolis densitometer. Total hours : 12

1 1 1 1

Module 3

Sl. No.

1

9

COURSE HANDOUT: S6

1. A. K. Sawhney, A course in mechanical measurements and Instrumentation – Dhanpat Ra and Sons, New Delhi, 1999. 2. R. K. Jain, Mechanical & Industrial measurements 3. D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999. 4. B. C. Nakra & K. K. Chaudary, Instrumentation Measurement & Analysis. 5. S. K. Singh, Industrial Instrumentation and Control

Page 29

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INDUSTRIAL INSTRUMENTATION I

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pressure gauges 10

Dead weight tester- Bulk gauge(high pressure measurement)

1

Total Hours:12

Module 4

Sl. No.

Topic

No. of lecture hours

Reference Books

1

Temperature measurement :Definitions and standards – Primary and secondary fixed points

1

2

Calibration of thermometers Different types of filled in system thermometer

1

3

Sources of errors in filled in systems and their compensation – Bimetallic thermometers

2

4

Electrical methods of temperature measurement – resistance thermometers

1

5

3 lead and 4 lead RTDs - Thermistors – Linearization techniques.

2

1. A. K. Sawhney, A course in mechanical measurements and Instrumentation – Dhanpat Ra and Sons, New Delhi, 1999. 2. R. K. Jain, Mechanical & Industrial measurements 3. D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999. 4. B. C. Nakra & K. K. Chaudary, Instrumentation Measurement & Analysis. 5. S. K. Singh, Industrial Instrumentation and Control

Total Hours: 7

Module 5

Sl. No.

Topic

1

Thermocouples –thermocouple junctions- Law of thermocouple – Fabrication of industrial thermocouples

COURSE HANDOUT: S6

No. of lecture hours

2

Reference Books 1. A. K. Sawhney, A course in mechanical measurements and Instrumentation – Dhanpat Ra and Sons, New

Page 30

AI010 603

INDUSTRIAL INSTRUMENTATION I

2

Signal conditioning of thermocouple output –– Commercial circuits for cold junction compensation

3

Special techniques for measuring high temperature using thermocouples

1

4

Radiation methods of temperature measurement –Radiation fundamentals

1

5

Total radiation pyrometers – Optical pyrometer

2

6

infra red pyrometers- Two colour radiation pyrometer

2

7

IC temperature sensors- fiber optic temperature measurementcalibration of temperature transducers.

1

2

S6AEI

2. 3.

4.

5.

Delhi, 1999. R. K. Jain, Mechanical & Industrial measurements D. Patranabis, Principles of Industrial Instrumentation, Tata McGraw Hill Publishing Ltd., 1999. B. C. Nakra & K. K. Chaudary, Instrumentation Measurement & Analysis. S. K. Singh, Industrial Instrumentation and Control

Total Hours: 12

COURSE HANDOUT: S6

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AI010 604

MICROCONTROLLER BASED SYSTEM DESIGN

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: MICROCONTROLLER BASED SYSTEM DESIGN COURSE CODE: AI 010 604 REGULATION: 2010 COURSE AREA/DOMAIN: SYSTEM DESIGN CORRESPONDING LAB COURSE CODE (IF ANY): AI 010 607 SYLLABUS: UNIT I

II

III

IV

V

DEGREE: BTECH SEMESTER: S6

CREDITS: 4

COURSE TYPE: CORE CONTACT HOURS: 3+1 (Tutorial) hours/Week. LAB COURSE NAME: MICROPROCESSOR & MICROCONTROLLER LAB

DETAILS HOURS Various logic families – features – comparison – PLA – PAL- GAL 12 comparison – combinational PAL – PAL with flip-flops – study of 16L8, 22V10 GAL – dual port RAM – FIFO – FPGA – gate arrays. Embedded C compiler – advantages – memory models – interrupt 12 functions – code optimization – 89C2051 micro-controller- architecturecomparison with 89C51- design of a simple trainer circuit using 89C51/89C2051 µC. Introduction to latest micro controllers (ARM Processor/ PIC microcontrollers) - introduction, architecture (block diagram explanation only), Memory organization etc Analog to digital converters- single slope, dual slope, successive 12 approximation, sigma delta, flash – comparison – typical ICs – A/D interface – digital to analog converters – different types – D/A interface – optically isolated TRIAC interface- design of a temperature control system- sensors - opto isolator -interfacing programs using C and assembly language Serial Communication :Serial bus standards – I2C bus, SPI bus – 12 operation – timing diagrams – 2 wire serial EEPROM – 24C04 – 3wire serial EEPROM – 93C46 – interfacing – serial communication standards – RS232, RS422, RS485 – comparison – MAX232 line driver/ receiver – interfacing –– universal serial bus – PCI bus - interfacing programs using C and assembly language – low voltage differential signaling – PC printer port – registers – interfacing. Real World Interfacing: Matrix key board interface – AT keyboard – 12 commands – keyboard response codes – watch dog timers – DS1232 watch dog timer – real time clocks – DS1302 RTC – interfacing – measurement of frequency – phase angle – power factor – stepper motor interface – dc motor speed control – L293 motor driver – design of a position control system –– interfacing of DIP switch, LED, 7 segment display, alphanumeric LCD – relay interface – design of a traffic light control system – interfacing programs using C and assembly language. TOTAL HOURS 60

COURSE HANDOUT: S6

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AI010 604

MICROCONTROLLER BASED SYSTEM DESIGN

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TEXT/REFERENCE BOOKS: T/R BOOK TITLE/AUTHORS/PUBLICATION R1 The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education. R2 The 8051 Microcontroller: Kenneth J Ayala, Penram International. R3 Digital fundamentals: Floyd, Pearson Education. R4 Programming and customizing the 8051 µC: Myke Predko, TMH R5 Programming with ANSI C and turbo C: Kamthane, Pearson Education. R6 Microcomputers and Microprocessors: John Uffenbeck, PHI. COURSE PRE-REQUISITES: C.CODE COURSE NAME AI 010 Digital Electronics 404 AI 010 Microprocessor and 606 Microcontroller COURSE OBJECTIVES:

DESCRIPTION Knowledge of basic digital electronics and logic families Familiarity with microcontroller programming

SEM S4 S5

1

To study the programming of microcontrollers in assembly and Embedded C and its interfacing techniques 2 To study the methods of signal transmission and reception in embedded devices 3 To get an exposure to latest microcontrollers used COURSE OUTCOMES: SNO

DESCRIPTION

1

Graduates will be able to understand the different logic families and programmable logic devices

PO MAPPING a, m

2

Graduates will learn the basics of 89C2051, ARM and PIC microc controller 3 Graduates will study about different ADC and DACs and will be able to a, b, c interface them with micro-controller 4 Graduates will be able to understand the different serial bus standards, c, m compare and program micro-controller for serial data transfer 5 Graduates will learn the interfacing and programming of different c, e modules with micro-controller for real time applications GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO 1

DESCRIPTION ARM Processors

PROPOSED ACTIONS Reading Assignments

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

COURSE HANDOUT: S6

Page 33

AI010 604

MICROCONTROLLER BASED SYSTEM DESIGN

S6AEI

TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Basics of PIC programming and its applications 2 Currently available processors and microcontrollers WEB SOURCE REFERENCES: 1

http://nptel.iitm.ac.in/courses/Webcourse-contents/IIT-KANPUR/ microcontrollers/micro/ui/TOC.htm 2 www.atmel.com DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK 

☐ STUD. ASSIGNMENT 

☐ LCD/SMART ☐ STUD. SEMINARS  BOARDS  ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS  ☐ STUD. LAB PRACTICES  ☐ ADD-ON

☐ STUD. SEMINARS  ☐ STUD. VIVA 

☐ WEB RESOURCES  ☐ ADD-ON COURSES

☐ TESTS/MODEL EXAMS  ☐ MINI/MAJOR

☐ UNIV. EXAMINATION  ☐ CERTIFICATIONS

PROJECTS ☐ OTHERS

COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY

☐ STUDENT FEEDBACK ON FACULTY

FEEDBACK, ONCE)  ☐ ASSESSMENT OF MINI/MAJOR PROJECTS BY EXT. EXPERTS

(TWICE)  ☐ OTHERS

Prepared by

Approved by

Ms. Aparna George

Ms. Liza Annie joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

Page 34

AI010 604

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COURSE PLAN Module 1 Sl. No.

Topic

No. of lecture hours

1

Introduction

1

2

Various logic families – features – comparison

2

3

PLA & PAL

2

GAL 4

1 PLA – PAL- GAL - comparison

5

Combinational PAL – PAL with flipflops

1

6

Study of 16L8, 22V10 GAL

2

7

FPGA

1

8

Dual port RAM – FIFO - gate arrays.

2

Reference Books

1. Digital fundamentals: Floyd, Pearson Education. 2. Fundamemtals of Digital Electronics, M. Anand Kumar

Total hours : 12

Module 2 Sl. No.

Topic

No. of lecture hours

1

Embedded C compiler – advantages

1

2

Memory models – interrupt functions – code optimization

2

1. Web site of Atmel semiconductors – www.atmel.com

3

89C2051 micro-controllerarchitecture-comparison with 89C51

2

2. PIC16F87X Data Sheet

Design of a simple trainer circuit using 89C51/89C2051 µC

1

4

COURSE HANDOUT: S6

Reference Books

3. infocenter.arm.com

Page 35

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MICROCONTROLLER BASED SYSTEM DESIGN

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Introduction to latest micro

5

controllers (ARM Processor/ PIC microcontrollers) - introduction, architecture (block diagram explanation only), Memory organization etc.

4

Total hours : 12

Module 3

Sl. No.

Topic

No. of lecture hours

1

Analog to digital converters- single slope dual slope,

2

2

Successive approximation, sigma

Reference Books

3

delta, flash 3

Comparison of analog to digital converters

1

4

Typical ICs – A/D interface – programming using C and assembly

2

5

Digital to analog converters – different types – D/A interface – programming using C and assembly

2

6

Design of a temperature control system- sensors - optoisolator

2

1. The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education . 2. Linear Integrated circuits, Roy Choudhry

Total hours : 12

Module 4

Sl. No.

Topic

No. of lecture hours

1

Serial Communication :Serial bus standards – I2C bus, SPI bus – operation – timing diagrams

3

COURSE HANDOUT: S6

Reference Books 1. The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education

Page 36

AI010 604

MICROCONTROLLER BASED SYSTEM DESIGN

2

2 wire serial EEPROM – 24C04 – 3wire serial EEPROM – 93C46 – interfacing

3

3

Serial communication standards – RS232, RS422, RS485 – comparison

2

4

MAX232 line driver/ receiver – interfacing –– universal serial bus – PCI bus

2

5

Low voltage differential signalling – PC printer port – registers – interfacing.

2

S6AEI

2. Programming with ANSI C and turbo C: Kamthane, Pearson Education.

Total hours : 12

Module 5

Sl. No.

Topic

No. of lecture hours

1

Real World Interfacing: Matrix key board interface – AT keyboard – commands –keyboard response codes

2

2

Watch dog timers – DS1232 watch dog timer – real time clocks – DS1302 RTC – interfacing

2

3

Measurement of frequency – phase angle – power factor

2

4

Stepper motor interface– dc motor speed control – L293 motor driver – design of a position control system

2

5

Interfacing of DIP switch, LED, 7 segment display using assembly and C

2

6

Interfacing of alphanumeric LCD – relay interface using assembly and C

3

7

Design of a traffic light control system using assembly and C

1

Reference Books

1. The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education 2. Programming with ANSI C and turbo C: Kamthane, Pearson Education.

Total hours : 12

COURSE HANDOUT: S6

Page 37

AI010 605

CONTROL ENGINEERING II

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: CONTROL ENGINEERING II COURSE CODE: AI 010 605 REGULATION: 2010 COURSE AREA/DOMAIN: SYSTEM THEORY CORRESPONDING LAB COURSE CODE (IF ANY): NIL SYLLABUS: UNIT I

II

III

IV

V

DEGREE: BTECH SEMESTER: S6 CREDITS: 4 COURSE TYPE: CORE CONTACT HOURS: 2+1 (Tutorial) hours/Week. LAB COURSE NAME: NA

DETAILS HOURS System modeling using state variable approach -Limitation of 12 Conventional Control Theory. Concepts of state variables and state model - State model for linear time invariant systems.-State space representation of dynamic systems – Nonuniqueness of state modelBlock diagram representations- State diagrams- Lagrange’s equations . Transformation of state variables- State space representations of transfer 12 functions- Solution of differential equations in state space formInterpretation and properties of the state transition matrix - Solution by the Laplace transform - The resolvent - Transfer function from state model. State variable analysis - controllability and observability. Gilber test and 12 Kalman’s tests. Design of regulators for single input single output systems, Bass- gura pole placement formula. Linear observers: Need of observers, Structure and properties of observers, Pole placement for single output systems. Discrete time systems- Introduction to digital control system –Review of 12 Z-transform and properties.- inverse z transform- z transform method for solving difference equations- Impulse sampling and data hold circuits Zero order and First order hold – signal reconstruction –Practical aspects of the choice of sampling rate-Pulse transfer function - The Z and S domain relationships -Stability analysis - Jury's test-Bilinear transformation . Nonlinear systems- Behaviour of nonlinear systems-Common physical 12 nonlinearities-The phase plane method- basic concepts- Singular pointsDescribing function method – Basic concepts-- Describing functions of saturation and dead zone nonlinearities. – Stability of nonlinear systemslimit cycles.(Detailed analysis not required). TOTAL HOURS 60

COURSE HANDOUT: S6

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CONTROL ENGINEERING II

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TEXT/REFERENCE BOOKS: T/R T1 T2 T3 T4 T5 T6

BOOK TITLE/AUTHORS/PUBLICATION K. Ogata , Modern Control Engineering , Prentice Hall of India K. Ogata , Discrete Time Control Systems ,Prentice Hall Of India M. Gopal , Digital Controls and State Variable Methods ,TMH Pub. B. C. Kuo , Automatic Control Systems, Prentice Hall of India. J. Nagrath & M. Gopal ,Control System Engineering , New Age Int. (P) Ltd B.Friedland, Control System Design- An Introduction to state space methods- Mc Graw Hill, Inc. N Y. COURSE PRE-REQUISITES: C.CODE COURSE NAME AI 010 Control Engineering I 505 COURSE OBJECTIVES:

DESCRIPTION Basic control engineering, system modelling

SEM S5

1 To study the modeling of the systems using state space methods 2 To learn State variable analysis and design of continuous time systems 3 To get an exposure to digital control systems. 4 To understand the basic concepts of nonlinear systems COURSE OUTCOMES: SNO

DESCRIPTION

PO MAPPING 1 Graduates will be able to understand the basic of states space a, b, c, d, techniques e, m 2 Graduates will be able to apply the concept of state space techniques for a, b, c, d, liner time invariant systems e, m 3 Graduates will be able to analyse the systems using state space a, b, c, d, techniques for stability analysis e, m 4 Graduates will be able to get design a simple control system for the a, b, c, d, desired poles e, m 5 Graduates will be able to understand the concept of digital control and a, b, c, d, non linear control theory e, m GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO 1

DESCRIPTION Introduction to linear algebra

PROPOSED ACTIONS Taken the basics of LA

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

COURSE HANDOUT: S6

Page 39

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CONTROL ENGINEERING II

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TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Inverted pendulum Design 2 Matlab tool box WEB SOURCE REFERENCES: 1 www.nptel.iitm.ac.in 2 www.ocw.mit.edu DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK 

☐ STUD. ASSIGNMENT 

☐ WEB RESOURCES 

☐ LCD/SMART

☐ STUD. SEMINARS 

☐ ADD-ON COURSES

BOARDS ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS 

☐ STUD.

☐ TESTS/MODEL

☐ UNIV.

☐ STUD. LAB

SEMINARS ☐ STUD. VIVA

EXAMS  ☐ MINI/MAJOR

EXAMINATION  ☐ CERTIFICATIONS

PRACTICES PROJECTS ☐ ADD-ON ☐ OTHERS COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY

☐ STUDENT FEEDBACK ON FACULTY

FEEDBACK, ONCE)  ☐ ASSESSMENT OF MINI/MAJOR PROJECTS

(TWICE)  ☐ OTHERS

BY EXT. EXPERTS

Prepared by

Approved by

Mr. Anish T.

Ms. Liza Annie joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

Page 40

AI010 605

CONTROL ENGINEERING II

S6AEI

COURSE PLAN Module 1

Sl. No. 1 2 3 4 5 6 7 8

Topic System modelling using state variable approach Concepts of state variables and state model Small signal diode model for low and high frequencies State model for linear time invariant systems State space representation of dynamic systems Nonuniqueness of state model Block diagram representations- State diagrams

No. of lecture hours

Lagrange’s equations

2

1 1 2 1 1 2 2

Reference Books 1. K. Ogata, Modern Control Engineering, Prentice Hall of India 2. M. Gopal, Digital Controls and State Variable Methods ,TMH Pub. Com. 3. B. C. Kuo, Automatic Control Systems, Prentice Hall of India. 4. B. Friedland, Control System Design- An Introduction to state space methods- McGraw Hill, Inc. N

Total hours : 12 Module 2 Sl. No.

Topic

No. of lecture hours

1

Transformation of state variables

2

2

State space representations of transfer functions

2

3

Solution of differential equations in state space form

2

4

Interpretation and properties of the state transition matrix

2

5

Solution by the Laplace transform

2

6

The resolvent - Transfer function from state model.

2

Reference Books

1. K. Ogata, Modern Control Engineering, Prentice Hall of India 2. M. Gopal, Digital Controls and State Variable Methods ,TMH Pub. Com. 3. B. C. Kuo, Automatic Control Systems, Prentice Hall of India. 4. B. Friedland, Control System DesignAn Introduction to state space methods- McGraw Hill, Inc. N

Total hours : 12

COURSE HANDOUT: S6

Page 41

AI010 605

CONTROL ENGINEERING II

S6AEI

Module 3 Sl. No.

Topic

No. of lecture hours

1

State variable analysis - controllability and observability

3

Gilber test and Kalman’s tests

2

Design of regulators for single input single output systems

2

Biasing of MOSFETs amplifiers

2

5

Bass- gura pole placement formula

1

6

Linear observers: Need of observers, Structure and properties of observers

2

2 3 4

Total Hours:12

Reference Books 1. K. Ogata, Modern Control Engineering, Prentice Hall of India 2. M. Gopal, Digital Controls and State Variable Methods ,TMH Pub. Com. 3. B. C. Kuo, Automatic Control Systems, Prentice Hall of India. 4. B. Friedland, Control System DesignAn Introduction to state space methods- McGraw Hill, Inc. N

Module 4 Sl. No. 1 2 3 4 5 6 7 8 9

Topic Introduction to digital control system Review of Z-transform and properties inverse z transform z transform method for solving difference equations Impulse sampling and data hold, Zero order and First order hold signal reconstruction Practical aspects of the choice of sampling rate-Pulse transfer The Z and S domain relationships Stability analysis - Jury's test-Bilinear transformation Total Hours:12

COURSE HANDOUT: S6

No. of lecture hours 1 2 1 2 1

1.

2.

3.

1 1 2 2

4.

Reference Books K. Ogata, Modern Control Engineering, Prentice Hall of India M. Gopal, Digital Controls and State Variable Methods ,TMH Pub. Com. B. C. Kuo, Automatic Control Systems, Prentice Hall of India. B. Friedland, Control System DesignAn Introduction to state space methods- McGraw Hill, Inc. N

Page 42

AI010 605

CONTROL ENGINEERING II

S6AEI

Module 5

Sl. No. 1 2 3 4 5 6

Topic Nonlinear systems- Behaviour of nonlinear systems The phase plane method- basic concepts- Singular points Analysis and design of discrete circuits in various feedback topology Describing function method Basic concepts-- Describing functions of saturation and dead zone nonlinearities Stability of nonlinear systems- limit cycles Total Hours:12

COURSE HANDOUT: S6

No. of lecture hours

Reference Books

1 1 2 3

1. M. Gopal , Digital Controls and State Variable Methods ,TMH Pub. Com.

2 3

Page 43

AI010 606 L01

MECHATRONICS

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: MECHATRONICS COURSE CODE: AI 010 606 L01 REGULATION: 2010 COURSE AREA/DOMAIN: ELECTROMECHANICAL SYSTEMS, MEMS CORRESPONDING LAB COURSE CODE (IF ANY): NIL SYLLABUS:

DEGREE: BTECH SEMESTER: S6 CREDITS: 4 COURSE TYPE: ELECTIVE CONTACT HOURS: 3+1 (Tutorial) hours/Week. LAB COURSE NAME: NA

UNIT I

DETAILS HOURS Introduction to mechatronics: What is mechatronics – advantage of 12 integrating electronics to mechanical devices; Introduction to basic elements of mechatronics: mechanical systems, control systems, electronics systems and computer systems; generalised block schematic of mechatronics. II Signal conditioning: requirements – basic approach – filters – 8 multiplexing – data acquisition – role of micro processors and micro controllers III Actuation systems: pneumatic and hydraulic systems - directional control 10 valves - pressure control valves - process control valves - rotary actuators - electro-mechanical actuators - electrical switches mechanical Switches - solid-state switches - dc motors - stepper motors piezoelectric actuators. IV Introduction to MEMS: what are MEMS – microsystems and nano 7 technology; Typical MEMS applications: pressure sensors – accelerometers - micro pumps - ink jet printers. V Modeling Electromechanical Systems- Mathematical models of 8 mechanical system building blocks, Electrical system building blocks, Thermal system building blocks, Fluid Power systems. TOTAL HOURS 45 TEXT/REFERENCE BOOKS: T/R BOOK TITLE/AUTHORS/PUBLICATION T1 Mechatronics - Electronic Control systems in Mechanical and Electrical Engineerng, -W. Bolton, 2 Ed. Addison Wesley Longman, Pub, 1999 (Delhi) T2 “Introduction to Mechatronics and Measurement systems”,David G. Alciatore and Michael B.Histand, 2nd edition Tata McGraw-Hill, 2003. T3 Mechatronics: Integrated Mechanical Electronic Systems With Cd by K.P. Ramachandran, G.K. Vijayaraghavan, M.S.Balasundaram : ISBN 9788126518371 R1 Mechatronics - Dan S. Necsulescu, Prentice Hall, 2002, (311 p.). ISBN: 0-201-444917 R2 Mechatronics: Electronics in Products and Processes, Dawson, D et.al, Nelson COURSE HANDOUT: S6

Page 44

AI010 606 L01

MECHATRONICS

S6AEI

Thornes, ISBN: 0-7487-5742-2 R3 Mechatronics , Shanmugam, Anuradha Agencies, 2001, ISBN 81-87721-21-9 R4 Analytical Robotics and Mechatronics - Wolfram Stadler, McGraw-Hill ISBN 0-07-060608-0 COURSE PRE-REQUISITES: C.CODE COURSE NAME AI 010 Control Engineering I 505 AI 010 Data Acquisition System 504 COURSE OBJECTIVES:

DESCRIPTION Basic control engineering, System modelling Signal conditioning and data acquisition

SEM S5 S5

1

To introduce the concept of integration of mechanical, electronic and computer system to achieve high precision and quality. 2 To help the students develop knowledge and skills that allow them to adopt interdisciplinary and integrated approach to engineering design. 3 To help the students understand modern integrated approach to development of precision mechanisms and machineries. COURSE OUTCOMES: SNO

DESCRIPTION

1

PO MAPPING c, e, h, i, j

Graduates will be able to understand basics of mechatronics approach to system design. 2 Graduates will be able to describe various key elements in a c, e, h, j mechatronics system and how they work in combination 3 Graduates will be able to model any electrical, mechanical, fluid or a, e, m thermal system. 4 Graduates will be able to get a general idea about MEMS and will c, h, i, j, understand how MEMS system are working in our day-to-day life 5 Graduates will be able to design multidisciplinary instrumentation b, e systems GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO 1

DESCRIPTION Commonly used sensors in mechatronics system, their selection and working.

PROPOSED ACTIONS Web reference [3]

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

COURSE HANDOUT: S6

Page 45

AI010 606 L01

MECHATRONICS

S6AEI

TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Web examples of different valves and actuators 2 Online lectures covering sensors WEB SOURCE REFERENCES: 1

https://docs.google.com/presentation/d/15m3WFVymrwllVbBFFaT21no1WJuWO8 uh0kRe4qrlQvY/edit 2 http://www.youtube.com/user/JUMechatronics?feature=watch 3 http://mechatronics.poly.edu/smart/html/resources/lectures.html DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK 

☐ STUD. ASSIGNMENT 

☐ LCD/SMART ☐ STUD. SEMINARS  BOARDS ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS  ☐ STUD. LAB PRACTICES ☐ ADD-ON

☐ WEB RESOURCES  ☐ ADD-ON COURSES

☐ STUD.

☐ TESTS/MODEL

☐ UNIV.

SEMINARS ☐ STUD. VIVA

EXAMS  ☐ MINI/MAJOR PROJECTS

EXAMINATION  ☐ CERTIFICATIONS

☐ OTHERS

COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY

☐ STUDENT FEEDBACK ON FACULTY

FEEDBACK, ONCE)  ☐ ASSESSMENT OF MINI/MAJOR PROJECTS

(TWICE)  ☐ OTHERS

BY EXT. EXPERTS

Prepared by

Approved by

Mr. Balu Raveendran

Ms. Liza Annie joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

Page 46

AI010 606 L01

MECHATRONICS

S6AEI

COURSE PLAN Module 1

Sl. No. 1 2 3 4 5 6 7

Topic

No. of lecture hours

What is Mechatronics, advantages of integrating electronics to mechanical devices

Reference Books

2

Basic Elements of Mechatronics

1

Mechanical system

2 2

Control System

2

Electronics System Computer System

1

Generalised block schematic of Mechatronics

2

1. Introduction to Mechatronics and Measurement systems, David G. Alciatore and Michael B. Histand, Tata McGraw-Hill

Total hours : 12

Module 2

Sl. No.

Topic

No. of lecture hours

1

Signal conditioning – Basic approach, filters, multiplexers

4

2 3

2

Data Acquisition Role of Microprocessors and Microcontrollers Total hours : 8

2

Reference Books

1. Mechatronics - Electronic Control systems in Mechanical and Electrical Engineering, -W. Bolton

Module 3

Sl. No.

Topic

No. of lecture hours

Reference Books

1

Directional control valves, pressure control valves, process control valves rotary actuators, electro-mechanical actuators

4

1. Mechatronics - Electronic Control systems in Mechanical and Electrical

COURSE HANDOUT: S6

Page 47

AI010 606 L01

2 3

MECHATRONICS

Electrical switches, mechanical switches, solid-state switches DC motors, stepper motors, piezoelectric actuators

S6AEI

3

Engineering, -W. Bolton

3

Total Hours: 10

Module 4

Sl. No.

Topic

No. of lecture hours

1

MEMS, microsystems and nanotechnology Typical MEMS applications: pressure sensors

2

2 3 4

2 1

Accelerometers

2

Micro pumps, Ink jet printers

Reference Books

1. Introduction to

Mechatronics and Measurement systems, David G. Alciatore and Michael B.Histand, Tata McGraw-Hill

Total Hours: 7

Module 5

Sl. No.

Topic

No. of lecture hours

1

2

2

Mathematical models of mechanical system building blocks Electrical system building blocks

3

Integrated coprocessor

1

4

Thermal system building blocks

2

5

Fluid Power systems

1

Reference Books

2 1. Mechatronics - Electronic

Control systems in Mechanical and Electrical Engineering, -W. Bolton

Total Hours: 12

COURSE HANDOUT: S6

Page 48

AI010 607

MICROPROCESSOR & MICROCONTROLLER LAB

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: MICROPROCESSOR & MICROCONTROLLER LAB COURSE CODE: AI 010 607 (P) REGULATION: 2010 COURSE AREA/DOMAIN: ELECTRONICS CORRESPONDING THEORY COURSE CODE (IF ANY): AI 010 506

DEGREE: BTECH SEMESTER: 6

CREDITS: 2

COURSE TYPE: CORE CONTACT HOURS: 3 Practical Hours/Week. THEORY COURSE NAME: MICROPROCESSORS & MICROCONTROLLERS

SYLLABUS: UNIT I

DETAILS Programming experiments using 8086 (MASM) 1. Sum of N Numbers. 2. Display message on screen using code and data segment. 3. Sorting, factorial of a number 4. Addition /Subtraction of 32 bit numbers. 5. Concatenation of two strings. 6. Square, Square root, & Fibonacci series. II Programming experiments using 8051 simulator (KEIL). 1. Addition and subtraction. 2. Multiplication and division. 3. Sorting, Factorial of a number. 4. Multiplication by shift and add method. 5. Matrix addition. 6. Square, Square root, & Fibonacci series. III Interface experiments - Direct down loading the programs from Personal computer. 1. Stepper motor interface. 2. Display (LED, Seven segments, LCD) interface. 3. Frequency measurement. 4. Wave form generation. 5. Relay interface. TOTAL HOURS TEXT/REFERENCE BOOKS: T/R R1 R2 R3 R4 R5 R6

HOURS 3X3=9

3X3=9

4X3=12

30

BOOK TITLE/AUTHORS/PUBLICATION The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education. The 8051 Microcontroller: Kenneth J Ayala, Penram International Microprocessors and Architecture: Ramesh S Goankar Microcomputers and Microprocessors: John Uffenbeck, PHI The Microprocessors 6th Edition Barry B. Brey Pearson Edu. Microprocessor and Interfacing 2nd Edition Douglous V. Hall TMH

COURSE HANDOUT: S6

Page 49

AI010 607

MICROPROCESSOR & MICROCONTROLLER LAB

S6AEI

R7 The 80x 86 families John Uffenbeck R8 Advanced Microprocessors and Pheripherals - A. K. Ray COURSE PRE-REQUISITES: C.CODE AI010 506

COURSE NAME Microprocessors and Microcontrollers

DESCRIPTION Familiarization of the basic concepts of microprocessor and microcontroller. Programming concepts were introduced

SEM S5

COURSE OBJECTIVES: 1

To develop an extensive knowledge in programming the 8086 processor and 8051 microcontroller. 2 The students will write and debug assembly language programs using the Microsoft Macro Assembler (MASM) and 8051 IDE – Integrated Development area. 3 To familiarize with interfacing of microcontroller. COURSE OUTCOMES: SNO

DESCRIPTION

1

Students must be able to program a 8086 microprocessor using a development environment that includes debuggers, editing tools, and compilers.

2

Students must be able to program a 8051 microcontroller using a development environment that includes debuggers, editing tools, and compilers.

PO MAPPING b, c, d, k, m

b, c, d, k, m

3

By acquiring the knowledge of programming they get basic idea to b, c, j, k program advanced controllers. 4 The students will be equipped with the basic knowledge of b, c, d, k, m Microcontroller interfacing. 5 They know about the interfacing applications which can be used for b, c, d, k, j their projects. GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO

DESCRIPTION

1

Embedded C and other user friendly languages

2

Interfacing various practical devices

PROPOSED ACTIONS Free tutorials. Extra lab experiments.

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

COURSE HANDOUT: S6

Page 50

AI010 607

MICROPROCESSOR & MICROCONTROLLER LAB

S6AEI

TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 2

Detailed study about advanced microcontrollers. Familiarization of various development boards and Integrated development area. (IDE) WEB SOURCE REFERENCES: 1 Web site of Atmel - www.atmel.com 2 Microchip semiconductor web site – www.microchip.com 3 www.embeddedcraft.org 4 www.mikroe.com 5 www.technologystudent.com DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK 

☐ STUD. ASSIGNMENT 

☐ STUD. SEMINARS

☐ ADD-ON COURSES

☐ WEB RESOURCES ☐ LCD/SMART BOARDS

ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS 

☐ STUD.

☐ TESTS/MODEL

☐ UNIV.

☐ STUD. LAB

SEMINARS  ☐ STUD. VIVA 

EXAMS  ☐ MINI/MAJOR

EXAMINATION  ☐ CERTIFICATIONS

PRACTICES  ☐ ADD-ON

PROJECTS ☐ OTHERS

COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY FEEDBACK, ONCE)  ☐ ASSESSMENT OF MINI/MAJOR PROJECTS

☐ STUDENT FEEDBACK ON FACULTY (TWICE)  ☐ OTHERS

BY EXT. EXPERTS

Prepared by

Approved by

Ms. M. Shanmuga Priya

Ms. Liza Annie Joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

Page 51

AI010 607

MICROPROCESSOR & MICROCONTROLLER LAB

S6AEI

COURSE PLAN Sl. No. 1

EXPERIMENTS Batch 1: Addition of two 8 bit numbers, Simple Calculator, Multiplication of two 16 bit numbers

2

BATCH 2: Addition of two 8 bit numbers, Simple Calculator, Multiplication of two 16 bit numbers

3

BATCH 1: Arranging an array in ascending order, Counting number of one's in a given data

4

BATCH 2: Arranging an array in ascending order, Counting number of one's in a given data

5

BATCH 1: Factorial of a number, Square root

6

BATCH 2: Factorial of a number, Square root

7

BATCH 1: Fibonacci series, Square of a number

8

BATCH 2: Fibonacci series, Square of a number

9

BATCH 1: Matrix addition, Multiplication by shift and add method

10

BATCH 2: Matrix addition, Multiplication by shift and add method

11

BATCH 1: Wave generation

12

BATCH 2: Wave generation

13

BATCH 1: LED, seven segment display

14

BATCH 2: LED, seven segment display

15

BATCH 1: stepper motor, LCD display

16

BATCH 2: stepper motor, LCD display

17

BATCH 1: Traffic light control - 2way and 4 way

18

BATCH 2: Traffic light control - 2way and 4 way

19

BATCH 1: 8086 programming sum of n numbers, display a message, factorial

20

BATCH 2: 8086 programming sum of n numbers, display a message, factorial

23

BATCH 1: 8086 programming concatenation, square root

24

BATCH 2: 8086 programming concatenation, square root

25

BATCH 1: Model Exam

26

BATCH 2: Model Exam

COURSE HANDOUT: S6

Page 52

AI010 608

MINI PROJECT

S6AEI

COURSE INFORMATION SHEET PROGRAMME: APPLIED ELECTRONICS & INSTRUMENTATION COURSE: MINI PROJECT COURSE CODE: AI 010 608 (P) REGULATION: 2010 COURSE AREA/DOMAIN: INSTRUMENTATION, ELECTRONICS, MICROPROCESSOR, CONTROL CORRESPONDING THEORY COURSE CODE (IF ANY): NIL SYLLABUS:

DEGREE: BTECH SEMESTER: 6 CREDITS: 2 COURSE TYPE: CORE CONTACT HOURS: 3 Practical Hours/Week.

THEORY COURSE NAME: NA

UNIT I II III IV V VI VII VIII IX

DETAILS Literature survey, Initial design, and work dairy meeting with guides First presentation in front of panel Interim presentation in front of panel Final presentation in front of panel Demo in front the panel PCB fabrication and lab works 1 PCB fabrication and lab works 2 PCB fabrication and lab works 3 Design, assembly and testing in any one the department /interdepartmental labs TOTAL HOURS TEXT/REFERENCE BOOKS:

HOURS 3 3 3 3 3 3 3 3 6 30

T/R BOOK TITLE/AUTHORS/PUBLICATION R1 Instrument handbook by E. B. Jones R2 Electronics design handbooks by Milman R3 The 8051 Microcontroller: Muhammad Ali Mazidi, Pearson Education. COURSE PRE-REQUISITES: C.CODE COURSE NAME AI 010 Microprocessor and 506 Microcontroller AI 010 Digital Electronics 404 COURSE OBJECTIVES: 1 2

DESCRIPTION Gives idea about applications of microprocessors Gives idea about digital systems

SEM S5 S4

To familiarize with project managements To familiarize with product development cycles

COURSE HANDOUT: S6

Page 53

AI010 608

MINI PROJECT

S6AEI

3 Gives exposure in terms of application engineering ,design etc COURSE OUTCOMES: SNO

DESCRIPTION

PO MAPPING a, c, e

1

Graduates will be able to understand basic of product development life cycle 2 Graduates will be able to understand project management and team d working 3 Graduates will be able to understand the application of the acquired a, e, k knowledge 4 Graduates will be able make work dairies and maintain it f, g 5 Graduates will be able make specification list, Bill of material ,and f, g, h Documentation , Product spec sheets etc GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS: SNO

DESCRIPTION

1

PCB Fabrication

2

OrCAD

PROPOSED ACTIONS Extra classes given Short Term Course

PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC

TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: 1 Introduction to PLC and instrumentation systems 2 Introduction to ORCAD, Project management etc 3 Introductory courses on robotics, PSPICE, Matlab, Labview etc WEB SOURCE REFERENCES: 1 www.howstuffworks.com 2 www.engineering toolbox.com 3 www.ni.com 4 www.edn.com 5 www.microcontrollers.com 6 www.orcad.com DELIVERY/INSTRUCTIONAL METHODOLOGIES: ☐ CHALK & TALK 

☐ STUD. ASSIGNMENT 

☐ STUD.

☐ ADD-ON COURSES

☐ WEB RESOURCES 

☐ LCD/SMART BOARDS 

SEMINARS 

COURSE HANDOUT: S6

Page 54

AI010 608

MINI PROJECT

S6AEI

ASSESSMENT METHODOLOGIES-DIRECT ☐ ASSIGNMENTS  ☐ STUD. LAB

☐ STUD. SEMINARS  ☐ STUD. VIVA 

☐ TESTS/MODEL EXAMS  ☐ MINI/MAJOR

☐ UNIV. EXAMINATION  ☐ CERTIFICATIONS

PRACTICES  PROJECTS  ☐ ADD-ON ☐ OTHERS COURSES ASSESSMENT METHODOLOGIES-INDIRECT ☐ ASSESSMENT OF COURSE OUTCOMES (BY

☐ STUDENT FEEDBACK ON FACULTY

FEEDBACK, ONCE) 

(TWICE) 

☐ ASSESSMENT OF MINI/MAJOR PROJECTS BY EXT. EXPERTS

☐ OTHERS

Prepared by

Approved by

Mr. Krishna Kumar K. P.

Ms. Liza Annie Joseph

(Faculty)

(HOD)

COURSE HANDOUT: S6

Page 55

AI010 608

MINI PROJECT

S6AEI

COURSE PLAN Sl. No. 1

EXPERIMENTS BATCH 1: Literature survey, Initial design, and work dairy meeting with guides

2

BATCH 2: Literature survey, Initial design, and work dairy meeting with guides

3

BATCH 1: First presentation in front of panel

4

BATCH 2: First presentation in front of panel

5

BATCH 1: Interim presentation in front of panel

6

BATCH 2: Interim presentation in front of panel

7

BATCH 1: Final presentation in front of panel

8

BATCH 2: Final presentation in front of panel

9

BATCH 1: Demo in front the panel

10

BATCH 2: Demo in front the panel

11

BATCH 1: PCB fabrication and lab works 1

12

BATCH 2: PCB fabrication and lab works 1

13

BATCH 1: PCB fabrication and lab works 2

14

BATCH 2: PCB fabrication and lab works 2

15

BATCH 1: PCB fabrication and lab works 3

16

BATCH 2: PCB fabrication and lab works 3

17

BATCH 1: Design, assembly and testing

18

BATCH 2: Design, assembly and testing

COURSE HANDOUT: S6

Page 56