DEPARTMENT OF INSTRUMENTATION ENGINEERING

JORHAT ENGINEERING COLLEGE

JORHAT-785007 (ASSAM)

GOVT INSTITUTE

AFFILIATED

TO

DIBRUGARH UNIVERITY,

NH-37, RAJAPETA, DIBRUGARH, ASSAM -786004

PROGRAMME

BACHELOR OF ENGINEERING

IN

INSTRUMENTATION ENGINEERING

SYLLABUS

III to VIII SEMESTERS

(OLD CURRICULUM)

2015-16 Batch

VISION OF THE INSTITUTION

Development of quality human resources for sustainable industrial and societal growth

through excellence in technical education and research.

MISSION OF THE INSTITUTION

1. To impart quality technical education at UG, PG and PhD levels through good academic

support facilities.

2. To develop a system for effective interactions among industries, academia, alumni and

other stake holders.

3. To provide an environment conducive to innovation and creativity, group work and

entrepreneurial leadership.

4. To provide a platform for need based research with special focus on regional development.

VISION OF THE DEPARTMENT

To be a pre-eminent Department of studies in Instrumentation Engineering by imparting

quality education to meet the needs of industry and society.

MISSION OF THE DEPARTMENT

1. To produce instrumentation engineers having strong theoretical foundation.

2. To keep abreast with latest developments in the domain and continuously upgrade the

skills of students for better employability.

3. To inspire students for higher education and research.

4. To provide state of the art facilities so as to make the students adaptable to frontier areas

of Instrumentation Engineering for the benefit of society and the region.

PROGRAM EDUCATIONAL OBJECTIVES (PEOS)

The students are expected to

PEO1: Apply new and emerging technologies to analyse, design, implement and provide

solutions to problems appropriate to the discipline.

PEO2: Be industry ready with adequate hands on experience on instrumentation techniques.

PEO 3: Possess keenness to proceed for higher education in interrelated areas of

Instrumentation.

PEO 4: Be proficient in computational systems and softwares related to domain needs.

PROGRAMME SPECIFIC OUTCOMES (PSOS):

PSO1: Acquire knowledge of sensor technology for applications in wide area of

instrumentation.

PSO2: Practise principles of automation in industries.

PROGRAM OUTCOMES (POs):

Engineering Graduates will be able to:

1. Engineering knowledge: Apply the knowledge of mathematics, science, engineering

fundamentals, and an engineering specialization to the solution of complex

engineering problems.

2. Problem analysis: Identify, formulate, review research literature and analyze

complex engineering problems reaching substantiated conclusions using first

principles of mathematics, natural sciences, and engineering sciences.

3. Design/development of solutions: Design solutions for complex engineering

problems and design system components or processes that meet the specified needs

with appropriate consideration for the public health and safety, and the cultural,

societal, and environmental considerations.

4. Conduct investigations of complex problems: Use research-based knowledge and

research methods including design of experiments, analysis and interpretation of data,

and synthesis of the information to provide valid conclusions.

5. Modern tool usage: Create, select, and apply appropriate techniques, resources and

modern engineering and IT tools including prediction and modeling to complex

engineering activities with an understanding of the limitations.

6. The engineer and society: Apply reasoning informed by the contextual knowledge to

assess societal, health, safety, legal and cultural issues and the consequent

responsibilities relevant to the professional engineering practice.

7. Environment and sustainability: Understand the impact of the professional

engineering solutions in societal and environmental contexts, and demonstrate the

knowledge of and need for sustainable development.

8. Ethics: Apply ethical principles and commit to professional ethics and responsibilities

and norms of the engineering practice.

9. Individual and team work: Function effectively as an individual and as a member or

leader in diverse teams, and in multidisciplinary settings.

10. Communication: Communicate effectively on complex engineering activities with

the engineering community and with society at large, such as, being able to

comprehend and write effective reports and design documentation, make effective

presentations, and give and receive clear instructions.

11. Project management and finance: Demonstrate knowledge and understanding of

the engineering and management principles and apply these to one’s own work, as a

member and leader in a team, to manage projects and in multidisciplinary

environments.

12. Life-long learning: Recognize the need for, and have the preparation and ability to

engage in independent and life-long learning in the broadest context of technological

change.

SYLLABUS FOR

III to VIII SEMESTERS

BE IN INSTRUMENTATION ENGINEERING

Semester-III

Sl.

No

Course

Code

Course Title Theory Sessional Practical

1 MA-31` Mathematics-III 100 50 -

2 IN-31 Transducers 100 - 50

3 IN-31L Transducers Lab - - -

4 CS -31 Fundamental of Computing 100 50 -

5 EE-31 Basic Electronics 100 50 50

6 EE-31L Basics Electronics laboratory - - 50

7 ME-31 Theory of Machines 100 - 50

Semester-IV

Sl.

No

Course

Code

Course Title Theory Sessional Practical

1 MA-41` Mathematics-IV 100 50 -

2 IN-41 Instrumentation System Components 100 - 50

3 IN-42 Mechanical and Industrial Instruments 100 50 -

4 EE-41 Digital Systems and Logic Design 100 50 -

5 EE-42 Digital Systems and Logic Design Lab - - 50

6 EE-43 Electrical Measurement-I 100 100 -

7 CE-41 Fluid Mechanics 100 - 50

Semester-V

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Practical

1 C301 MA-51 Mathematics-V 100 50 -

2 C302 CS-51 Object Oriented Programming 100 50 -

3 C303 EE-51 Advanced Electronics 100 50

4 C304 EE-52 Electrical Measurement-II 100 50 -

5 C305 PH-51 Electrical Engineering Materials 100 50 25

6 C306 IN-51 Introduction to Chemical

Processes

100 50 -

7 C307 EE-51L Advanced Electronics Lab - - 50

Semester-VI

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Practical

1 C308 HS-61 Principles of Economics &

Accountancy

100 50 -

2 C309 EE-61 Communication Engineering 100 50 -

3 C310 EE-62 Microprocessors-I 100 50 -

4 C311 EE-63 Electrical Machines &

Applications

100 50 -

5 C312 IN-61 Analytical Instruments 100 50 -

6 C313 IN-62 Drawing & Design of

Instrumentation System

Components

- 100 -

7 C314 EE-62L Microprocessors-I Lab - - 50

8 C315 EE-63L Electrical Machines &

Applications Lab

- - 50

Semester-VII

Sl.

No

SAR

Code

Course

Code

Course Title Theor

y

Sessional Viva

1 C401 HS-71 Industrial Organisation and

Management

100 50 -

2 C402 EE-71 Microprocessors-II 100 50 -

3 C403 EE-72 Power Electronics 100 50 -

4 C404 IN-71 Optoelectronics 100 50 -

5 C405 IN-72 Elective-I 100 50 -

6 C406 IN-73 Project-I - 100 50

Elective-I

1. Biomedical Instrumentation (IN-72)

2. Advanced Communication (EE-735)

3. Artificial Intelligence (CS-723)

4. Digital Image Processing (CS-726)

5. Electronic Instrumentation (IN-74)

6. Interactive Computer Graphics (CS-729)

Semester-VIII

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Viva

1 C407 EE-81 Automatic Control Systems 100 50 -

2 C408 IN-81 Process Modelling andControl 100 50 -

3 C409 IN-82 Digital Signal Processing 100 50 -

4 C410 IN-83 Elective-II 100 50 -

5 C411 IN-84 Project-II - 150 50

6 C412 IN-85 General Viva-Voce - - 100

Elective-II:

1. Data Communication & Networks (EE-84)

2. Robotics and Applications (ME-89)

3. Environmental Monitoring & Control (IN-83)

4. Computer Control Systems (EE-86)

5. Non-destructive Testing (IN-85)

SYLLABUS

FOR

SEMESTER-III

Sl.

No

Course

Code

Course Title Theory Sessional Practical

1 MA-31` Mathematics-III 100 50 -

2 IN-31 Transducers 100 - 50

3 IN-31L Transducers Lab - - -

4 CS -31 Fundamental of Computing 100 50 -

5 EE-31 Basic Electronics 100 50 50

6 EE-31L Basics Electronics laboratory - - 50

7 ME-31 Theory of Machines 100 - 50

3rd SEMESTER B.E ( Instrumentation)

SYLLABUS FOR

Sub: MATHEMATICS-III (MA31)

Theory:100 Sessional :50

Course objective:

To expose the students to knowledge of series solution, Fourier series, partial

differential equation and Laplace transform.

Course outcome:

At the end of the course students, the student will be able to

CO1: Apply different methods for solving linear differential equation with variable

coefficient in series, Solve Bessel’s and Legendre’s equations and explain Bessel and

Legendre function.

CO2: Find Fourier series of periodic function in any interval and sine - cosine series, half

range series and harmonic analysis.

CO3 Define various terms related to P.D.E and explain the method of forming P.D.E , Apply

different methods to solve P.D.E and some engineering and physical problems.

C04: Find Laplace and Inverse Laplace transforms of functions and list theorems on them,

Apply Laplace transforms to solve differential equation with boundary values and

engineering problems arising in electrical and mechanical engineering.

Relation of CO-PO

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PS

O1

PS

O2

CO

1 2

CO

2 2

CO

3 1 2

CO

4 3

Av

g 2 2

3rd SEMESTER B.E ( Instrumentation)

SYLLABUS FOR

TRANSDUCERS(IN31)

Theory:100 Sessional :50 Practical : 50

L-3 T-1 P-3

Course Outcomes: On Completion of this course the students should be able to

COs

CO1 Analyze static and dynamic characteristics of a measurement

system.

CO2 Explain the working principles of resistive, inductive, capacitive

and piezoelectric transducers.

CO3 Explain the working principles of transducers used for

temperature measurement.

CO4 Select/choose special transducers for measurement of various

physical parameters.

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 1 1

3 CO

2 3 2 2

CO

3 3 1 1 1

CO

4 3 1 1

Av

g 3 2

1.2

5 1 1 3

1. Classification of Transducers; Their characteristics – static and dynamic; Errors and Uncertainity.

2. Statistical analysis of errors: Probability distribution function; Gaussian

distribution; Chi-square test; Regression analysis; Best fit curve; Pultering;

Averaging and Correlation techniques; Application to improve signal-to-noise

ratio.

3. Resistance transducers: Principle of potentiometers; RTD and Thermistors; Strain Gauge – application in measurement of pressure, force, torque and vibration.

4. Capacitive transducers: Air gap and dielectric types and their applications.

5. Piezoelectric transducers: Piezoelectric crystal and its properties; Sensitive coefficients; Materials, Application.

6. Optical Transducers: LDR, LED, Photo detector, Radiation pyrometer.

7. Thermo couple: Characteristics, Installation and compensation, IC temperature sensors.

8. Combination of Elastic and Electrical transducers: Hall effect transducers; Magnetostrictive transducers; Feed back transducers.

Text books:

1. Instrument transducers – An introduction to their performance and design – Neubert MKP, Clarendon Press.

2. Measurement Systems: Application and Design – Doeblin E.O., McGraw Hill.

3. Transducers and Instrumentation – Murthy D.V.S., P.M.I. New Delhi.

4. Sensors and Transducers – Patranabis D., Wheeler.

5. Instrumentation, Measurement and Feed Back – Jones B.E., T.M.H. New Delhi.

6. Instrumentation Devices and Systems – Ranga, Sarma, Mani; T.M.H.

Course Title: Transducers Laboratory

Course Code: IN31L Semester : 3rd

COURSE OUTCOMES:

CO1: Analyze different types of transducers/sensors data.

CO2: Apply their knowledge in conducting experiments.

CO3: Interact Effectively on a social & interpersonal level with fellow students to receive

clear procedural instructions.

CO4: Share task responsibilities to complete assignments and ethically Develop professional

and technically sound reports.

CO-PO MAPPING:

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3

1 1

CO

2 3 1

CO

3 1 3 3 2

CO

4 3 3 3 2

Av

g 3 1 1 3 3 3 2 1 1

Experiment

No

Title of the

Experiments

Objective of the experiments

1 LVDT 1. To draw the characteristics Of a LVDT 2. To determine the sensitivity of the system

2 Torque Transducer 1. Study of the torque transducer.

2. To use torque transducer having strain gauges

as sensors & to determine its I/O

characteristics.

3 Load Cell 1. T study the Colum type Load Cell 2. To calculate the sensitivity of load cell

4 Orifice 1. To study the flow of air through an orifice and

hence determine the flow rate with the help of

U-Tube manometer.

2. To plot the flow versus pressure difference

characteristics for different flow rates.

5 Rotational Potentiometer 1. To study the input output characteristics of

rotational

Potentiometer

6 Thermocouple 1. To determine the sensitivity and time constant

of a thermocouple [iron constantan or copper

constantan] for step input .

2. To compare its response with that for ramp

input.

7 I/P-P/I Converter To determine-

A. Linearity of I/P converter

B. Hysteresis of I/P converter

C. Accuracy of I/P converter

D. Linearity of P/I converter

E. Hysteresis of P/I converter

F. Accuracy of p/i converter.

8 PV cell 1 To draw the characteristic curve of a PV cell

9 LDR Study of light dependent register

10 optical Weight sensor To Obtain the voltage VS weight graph

Text books:

1. Principle of indrustrial Instrumentatoon; D Patranabis

2. Introduction to instrumentation engineering ; AK Sahwany

Course Title: Fundamentals of Computing

Course Code: CS31 Semester : 3rd

CO1: To explain the components of Computing System (L2: understanding)

CO2: To make use of algorithms for mathematical and scientific problems (L3: applying)

CO3: To apply conditional branching, iteration and data types for problem solving (L3:

applying)

CO4: To develop modular programs using functions and recursion (L3: applying)

CO5: To use arrays, pointers, structures and file handling to formulate algorithms and

programs (L3: applying)

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 1

CO2 3 2 2

CO3 3 2 1

CO4 3 2

1

CO5 3 2 1

Avg 2.6 2 2 1

SYLLABUS

Components of a digital computer, block diagram, software, hardware, I/O devices,

languages-machine, assembly, high level, compiler, interpreter, problem solving – algorithms

, pseudo code, flowchart , Learning the form of a C program, Declaring variables, designing

program flow and control, defining and using functions, using standard terminal I/O

functions.

Character types, Integer, short, long, unsigned, single and double-precision floating point,

storage classes - automatic, register, static and external , Using numeric and relational

operators, mixed operands and type conversion, Logical operators, Bit operations, Operator

precedence and associativity.

Applying if and switch statements, nesting if and else, restrictions on switch values, use of

break and default with switch. Uses of while, do and for loops, multiple loop variables,

assignment operators, using break and continue.

Passing arguments by value, scope rules and global variables, separate compilation, and

linkage, building your own modules.

Array notation and representation, manipulating array elements, using multidimensional

arrays, arrays of unknown or varying size, Purpose and usage of structures, declaring

structures, assigning of structures, Components in overlapping memory, declaring and using

unions .h vs. private .c files, Hiding private variables and functions.

Pointer and address arithmetic, pointer operations and declarations, using pointers as

function arguments, Dynamic memory allocation, manipulation of linked linear list, pointer

to structure, arrays and pointers, array of pointers, function pointers

Bit access and masking, pointing to hardware structures. Reading command line arguments,

creating and accessing files, file opening modes, formatted disk I/O.

Preprocessor directives, Defining and calling macros, utilizing conditional compilation,

passing values to the compiler, Input / Output : fopen , fread, etc, string handling functions,

Math functions : log, sin, alike Other Standard C functions.

Books and references:

1. Herbert Schield, Complete reference in C, TMH

2. Yashwant Kanetkar, Let US C, BPB

3. Balaguruswamy, Programming in ANSI C, TMH

4. Yashwant Kanetkar Pointers in C

5. Kernighan and Ritchie, The C programming language

Course Title: Basic Electronics

Course Code: EE31 Semester of Study: 3rd

COURSE OUTCOMES:

BE1: Analyze operational characteristics of diodes, BJT and FET.

BE2: Design simple analog circuits using BJT and FET.

BE3: Analyze BJT, FET amplifiers(small and large signal), oscillators circuits.

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2

3 CO2 2 3 2 2

CO3 1 3 2 2

Avg 2 3 2 2 3

1. Bond model of Silicon crystal: Intrinsic carrier concentration, Effect of

doping on carrier concentration, Holes and electrons, Majority and minority

carriers, Mobility and diffusion constants, Passage of current through

semiconductor materials, Drift and diffusion processes, Recombination and carrier life-time, Effect of temperature.

2. The p-n junction: Basic construction, Abrupt junction and graded junctions,

Symmetrically and asymmetrically doped devices, Built-in field and depletion region approximation, Analysis of the capacitance associated with a diode

devices, Effect of temperature on the current flow.

3. Circuit models of a diode: Piece-wise linear static model and dynamic

incremental model; Practical circuits employing diode; Voltage multiplier, Clipper and clamper; Power rectifying circuits; Power filters; Special purpose

diodes – LED, Photodiode, Schottky diode.

4. Bipolar junction transistor (BJT): Basic construction and the physical

behaviour of the device; Low level injection condition; Forward active region

(FAR) and the study of the flow of carriers through the BJT; Control valve

action; Volt-amp curves; Base width modulation and early effect; Static circuit

models; Ebers – Moll equations for the current of BJT forward bias

conditions; A simple amplifier circuit; Bias stability, compensation and

biasing methods; The common base (CB), common emitter (CE) and common

collector (CC) configurations.

5. Small signal operation of the BJT amplifier: Incremental models for the

BJT; Hybrid- model; Analysis of amplifiers with the help of incremental

models; Simplified low frequency operation; Gains, input and output

impedances of the amplifiers; Some ideas about high frequency analysis such

as Miller effect and Dominant pole approximation; Determination of the

Hybrid- parameters; Details about Two port - and h-parameter analysis.

6. Multiple stage BJT amplifiers: PNP and NPN combinations; Voltage and

current biasing methods; Gains; Frequency response of the amplifiers; High

power circuits (Class A, B & B-Push-Pull, AB and C operations) and their

efficiencies; Distortion; Introduction to negative feedback amplifier.

7. Field effect transistor (FET): Construction and characteristics of Junction

FET (JFET); Principle of operation; Characteristic parameters of JFET; Effect

of temperature on JFET parameters; Biasing of JFETs; Common drain (CD),

Common source (CS) and Common gate (CG) configurations; Frequency

response of JFET amplifiers; Metal oxide semiconductor FET (MOSFET);

Enhancement MOSFET (EMOSFET) and Depletion MOSFET (DMOSFET); Differences between JFETs and MOSFETs; Biasing of EMOSFET and DMOSFET; Applications of MOSFETs; Complementary MOSFET (CMOS).

Text Books:

1. Electronic Principles Physics Models and Circuits – Paul S. Gray and Campbell J Scarls, Wiley Eastern Ltd

2. Electronics Devices and Circuits – Allen Mottershed, PHI

3. Electronic Principles – Alvert Paul Malvino, TMH

4. Integrated Electronics – Millman & Halkias, TMH

5. Electronic Devices and Circuits – Boylested & Nashlsky

Course Title: Basic Electronics Laboratory

Course Code: EE31L Semester of Study: 3rd

L-0 T-0 P-2 C-1

COURSE OUTCOMES:

CO1: Analyze the diode and transistor characteristics.

CO2: Analyze rectifier, filter, clipper, clamper circuit, biasing circuits, R-C couple amplifier

circuit.

CO3: Interact Effectively on a social & interpersonal level with fellow students to receive

clear procedural instructions.

CO4: Share task responsibilities to complete assignments and ethically Develop professional

and technically sound reports.

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2 2 1

1 CO2 3 2 3 1

CO3 1 3 3 2

CO4 3 3 3 2

Avg 3 2 2.5 1 3 3 3 1.5 1

SYLLABUS:

1 Study of Electronic Components

2 Study of Instruments and Equipment (DMM, CRO, FG and Power Supply etc.)

3 Find the step response of RC and RL circuits and RLC series circuit resonance

4 Characteristic of a PN diode

5 Voltage regulation of Half wave and Full wave rectifier at No-load and Full-load

6

7

Design and analysis of clipper circuits.

Design and analysis of clamper circuits.

8 Transistor Characteristic in CB configuration.

9 Transistor Characteristic in CE configuration

10 Current, Voltage and Power Amplifications of an CE NPN/PNP Transistor

Amplifier

11 Study of FET characteristics (n-channel JFET)

12 Study the switching characteristic of a switching transistor.

Course Title: Theory of Machines

Course Code: ME31 Semester Of Study: 3rd

CO1: Explain the basics of kinematics and concepts of links and mechanisms.

CO2: Illustrate the functions and applications of gear trains, governors and flywheels

CO3: Utilize concepts of cam and gyroscopic couple for mechanical system development and

analysis

CO PO mapping :

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 1

CO2 3 1

CO3 3 2 2 1

Avg 3 2 2 1

SYLLABUS

FOR

SEMESTER-IV

Sl.

No

Course

Code

Course Title Theory Sessional Practical

1 MA-41` Mathematics-IV 100 50 -

2 IN-41 Instrumentation System Components 100 - 50

3 IN-42 Mechanical and Industrial Instruments 100 50 -

4 EE-41 Digital Systems and Logic Design 100 50 -

5 EE-42 Digital Systems and Logic Design Lab - - 50

6 EE-43 Electrical Measurement-I 100 100 -

7 CE-41 Fluid Mechanics 100 - 50

MATHEMATICS-IV

Course Code: MA41 Semester Of Study: 4th

Course objective :

To expose the students to knowledge of vector calculus ,Tensor analysis ,infinite series and

multiple integrals.

Course outcome:

At the end of the course student will be able to

CO1:Define Vector functions ,differentiation and integration of vectors ,gradient ,divergence

,curl by using Vector differential operator∆, List the properties of gradient ,divergence ,curl

and their physical meaning, Understand line ,surface and volume integrals ;apply Green’s,

Gauss, Stokes theorem to evaluate line ,surface and volume integrals.

CO2:Explain the transformation of co-ordinates ,different types of tensors, algebra of tensors,

Christoffel symbols.

CO3: Classify infinite series as convergent or divergent and make use of comparison and

special tests for convergence of infinite series.

CO4:Apply concepts of line and double integrals in and line ,surface and volume integrals

in to evaluate length ,area and volume; explain improper integrals ,Beta ,Gamma function

and differentiation under integral sign.

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 1 2 3

CO2 2 2

CO3 2

CO4 2 2 3

Avg 1.67 2 3

SUB. CODE – IN-41

4th Semester B.E (Instrumentation))

Syllabus For

INSTRUMENTATION SYSTEM COMPONENTS

Theory: 100

Sessional: 50

On Completion of this course the students should be able to

COs Course Outcomes

CO1 Explain the operation of different types of inductive transducers.

CO2 Demonstrate the knowledge of different control system

components like stepper motors, servomotors, Tachogenerators

flapper nozzle and jet valves etc.

CO3 Develop their transfer functions of P-D, P-I & P-I-D controllers.

Course

Outcome

Programme Outcome PS01 PS02

1 2 3 4 5 6 7 8 9 10 11 12

CO1 2 1 2

CO2 2

CO3 2 1

1. Inductive Transducers: Types and their principles of measurements; LVDT and its phase

sensitive detector; Synchro- principle, constructions and applications.

2.Stepper Motors: Construction; Method of operation; Torque equation; Driver circuits;

Logic translator; applications.

3.D.C. & A.C (2-phase) Servo Motors: Construction; working principle; Torque equation;

Transfer functions; Effect of load variation.

4.Ultrasonic Devices: Principle and applications.

5.Special Transducers: D.C & A.C Techogenerators; Digital transducers; Pneumatic and

Hydraulic components – Flapper Nozzle, Jet valves and their applications.

6.P-D, P-I & P-I-D Controllers: Principle, Transfer functions, Physical realization and

applications.

Reference Books:

1. Neubert H.K.P – Instrument Transducers: An Introduction to their Performance &

Design (Clarendon Press)

2. Murthy D.V.S – Transducers & Instrumentation ( PHI)

3. Liptak V.G – Instrument Engineer’s Hand Book (Vol-I & II )

4. Doebelin E.O- Measurement Systems : Applications & Design (McGrow Hill)

5. Armensky E.V & Falk G.B – Fractional H.P Electrical Machines (Mir Publishers)

6. Gibson J.E &Tuteur F.B- control System components (Mc Grow Hill)

MECHANICAL AND INDUSTRIAL INSTRUMENTS(IN42)

L-3 T-1 P-0

Theory : 100

Sessional : 50

Course Objective:

To provide sound knowledge about various techniques used for the measurement of industrial

parameters.

Course Outcomes: On Completion of this course the students should be able to

COs Course Outcomes Level

CO1 Select a suitable vacuum and medium pressure measurement sensors. L3

CO2 Choose a proper flow and level sensors for industrial measurements. L3

CO3 Identify the relevant force, torque, velocity and acceleration sensors for

industrial applications.

L3

CO4 List different pneumatic instruments commonly used in industry. L2

Mapping of Course outcome and Programme outcome and Programme Specific Outcome:

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PS

O1

PS

O2

CO

1 3 2

2 1

CO

2 3 2

CO

3 3 2

CO

4 3 2

Av

g 3 2 2 1

1. Introduction to Metrology

2. Measurement of thickness, angle, slope, diameter, taper, screw parameters, Gauge etc.

3. Pressure Measurement - Manometers ; Bellows ; Bourdon tubes – design

features, calibration and dynamic measurement ; Vacuum measurement –

Mcleod gauge, Pirani gauge , Knudsen gauge , Ionization gauge etc.

4. Flow Measurement - Head type, Area type , Mass flow meter, Electrical type –

Electromagnetic, Ultrasonic, Hotwire, Anemometers and Digital type- operating principle & design features; Flowmeters for solid materials.

5. Level, Humidity, Viscosity and Density Measurement - Basic principles

6. Measurement of Force, Velocity, Displacement, Acceleration, Torque,

Vibration, Revolution counters, Seismic accelerometers and Vibrometers.

7. Pneumatic Instrumentation - Introduction, Power supply, Air filter, Pressure

regulator, Servo valve, Relay, Amplifier, Controller & Recorders, Introduction to Fluidic devices.

Reference Books :

1. Doebelin E.O – Measurement Systems : Applications and Design (McGrow Hill)

2. Patranibis D – Principles of Industrial Instrumentation

3. Jones B.E – Instrument Technology ( Vol-I & II )

4. Backwith T. G , Buch N. L and Marangoni R.D – Mechanical Measurements

5. K.Krishnaswamy- Industrial Instrumentation (New Age)

6. Eckman D.P – Industrial Instrumentation (WE)

Course Title: Digital Systems & Logic Design

Course Code: EE41 Semester of Study:4th

COURSE OUTCOMES:

DSLDL1:Illustrate the circuits and characteristics of logic gates.

DSLDL2:Solve problems related to number systems and Boolean algebra.

DSLDL3: Design combinational and sequential logic circuits.

DSLDL4: Explain the functioning of memory devices.

CO-PO MAPPING:

COs PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO1 3 2 - - - - - - - - - - 3 2

CO2 3 2 - - - - - - - - - 1 - -

CO3 - 3 3 - 2 - - - - - - 1 - -

CO4 3 - - - 2 - - - - - - 1 - -

1. Introduction : Switching circuits & devices ; Characteristics of ICs and logical level; Positive & negative logic levels.

2. Realization of Logic Gates : Elementary idea of TTL & MOS technology for logic gates ; Important Characteristics of logic gate families.

3. Representation of Informations : General number Systems – decimal, binary

, octal & hexadecimal numbers ; Conversion from one system to another ; Codes & code conversion ; BCD, Gray, Natural BCD & Extended code ;

Negative, positive

& floating point numbers ; Sign magnitude ; 1’s compliment and 2’s compliment representation ; Arithmetic operations ; Representation of textual

informations in ASCII & EBCDIC codes.

4. Boolean Algebra & Logic Functions : Concept of Boolean algebra ; Theorems

& laws ; Boolean expressions ; Canonical & standard forms of logic functions & their properties ; Truth table representation ; Minimization of

logic functions – Karnaugh map and Quine Mclusky method of minimization.

5. Combinational Logic Circuits : AND, OR, NOT, NAND, NOR, XOR &

XNOR gates and their truth tables ; Implementation of Boolean functions

using logic gates ; Multiplexer ; Decoder ; Encoder ; Code converters ; Half and full adder ; Parity generator & parity checker.

6. Sequantial Logic Circuits : Concept of sequential circuits ; Flip-flop

and its different types – clocked R-S , J-K, D, T & master slave ;

Registers – buffers, serial and parallel ; Hazards of sequential circuits ; Sequence generator ;State diagram ; Design of Counters – Synchronous

& Asynchronous , Up & down ; Presettable counters.

Reference Books :

1) Digital Principles and Applications – Malvino & Leach

2) Logic Design and Switching Circuits – Doglas Lewin

3) Digital Circuits and Logic Design – Samual & Lee

Course Title: Digital Systems & Logic Design LAB

Course Code: EE42 Semester of Study:4th

COURSE OUTCOMES:

CO1:.Design, simulate and implement basic combinational and sequential logic circuits.

CO2:Become proficient with computer skills for analyzing circuits using Logisim.

CO3: Design synchronous and asynchronous circuits.

CO4: Interact Effectively on a social & interpersonal level with fellow students to

receive clear procedural instructions.

CO 5: Share task responsibilities to complete assignments and ethically Develop

professional and technically sound reports.

CO-PO MAPPING:

CO P

O1

P

O2

P

O3

P

O4

P

O5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

CO1 3 3 1

CO2 3 3

CO3 3 3

C04 1 3 3 2

CO5 3 3 3 2

Experi

ment

No.

Title of the Experiment Objective of the Experiment

1 To study and verify the

truth table of logic gates

Identify various ICs and their specification

OR gate

AND gate

NAND gate

NOR gate

2 Realization of a

Boolean function

To simplify the given expression and to realize it

using Basic gates and Universal gate

3 Design and

implementation using

NAND gate

To realize why NAND gate is known as the

universal gate by implementation of :

NOT using NAND

AND using NAND

OR using NAND

XOR using NAND

4 Adders and Subtractors To realize

Half Adder and Full Adder

Half Subtractor and Full Subtractor by using

Basic gates and NAND gates

5 Binary to grey generator To learn the importance of weighted and non

weighted code To learn to generate gray code

.

6 Multiplexer and

Demultiplexer

To design and set up a 4:1 Multiplexer (MUX)

using only NAND gates.

To design and set up a 1:4 Demultiplexer(DE-

MUX) using only NAND gates.

7 Realization of a

Boolean function using

Logisim

To learn the use of Logisim software to design

digital electronics circuits.

8 FlipFlop a. Truth Table verification of

RS Flip Flop

T type Flip Flop.

D type Flip Flop.

JK Flip Flop.

b. Conversion of one type of Flip flop to

another

Text book:

Modern Digital Electronics - R P Jain

Digital Electronics: An Introduction To Theory And Practice by William Gothmann

H

Digital Electronics by John Morris

Fundamentals of Digital Circuits by Anand Kumar

ELECTRICAL MEASUREMENT – I(EE43)

Theory : 100

Sessional : 100

1. Ammeter, Voltmeter & Ohmometers :

a) Review of PMMC & MI type instruments ; Construction and working principle of Magger.

b) Construction , operating principle & torque equation for Electrodynamic, Electrostatic & Induction type instruments.

c) Relative comparison among PMMC, MI, Electrodynamic, Electrostatic & Induction type instruments.

2. Wattmeter & Energymeters : Principle of measuring power by using

Dynamometer and Induction type wattmeters ; Errors and compensation ; low power factor polyphase wattmeters ; Energymeter – difference between

wattmeter

& energymeter ; Principle of construction of Induction type energymeter ; Error compensation and adjustments in energymeter.

3. Special Type Meters : Construction and working principle of Frequency meter, Synchroscope, Power factor meter, Flux meter, Maximum demand meter.

4. Instrument Transformers : Uses of instrument transformers ; Theory of CT & PT ; Ratio & phase angle errors ; Errors compensations ; Testing of CT & PT.

5. Oscilloscope : Block diagram representation ; Cathode ray tube ; Vertical and

Horizontal deflection systems ; Delay line ; Multiple trace ; CRO probe &

transducers ; Measurement of voltage, current, phase & frequency by CRO ;

Storage Oscilloscope.

6. Electronic Instruments : (a) Electronic Voltmeters : Advantage &

disadvantages of using electronic voltmeters ; Different stages in AC & DC

electronic voltmeters ; Balanced bridge voltmeter ; Principle and circuit

diagrams for average responding ; peak responding & RMS responding

voltmeters.(b) Digital voltmeters : Classification of digital voltmeters ;

Principle, block diagram and signal wave form of ramp type, stair case ramp

type and integrating type digital voltmeters. (c) Electronic Multimeters & Q-

meters.

7. Recorders : Different types of recorders ; Construction, working principle and

circuit diagrams of Strip- chart & X-Y recorders.

Reference Books :

1) E.W. Golding & F.C Widdis – Electrical Measurement and Measuring Instruments.

2) William D. Cooper -Electronic Instrumentation & Measurement Techniques.

3) A.K. Sawhney – A Course in Electrical Measurement and Measuring Instruments.

FLUID MECHANICS(CE41)

Theory : 100

Sessional : 100

CO-1 Illustrate different properties and kinematics of fluid. L-2

CO-2 Apply knowledge of hydrostatic principle on submerged or floating

bodies.

L-3

CO-3 Apply equation of motion, dimensional and model analysis to establish

different relationship for different flow conditions.

L-3

CO-4 Interpret the concept of compressible flow and its characteristics. L-3

CO-5 Demonstrate the basic of turbine and centrifugal pump. L-2

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1

3 1

CO

2

1 2

CO

3

1 2

CO

4

3

CO

5

1 1

SYLLABUS

FOR

SEMESTER-V

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Practical

1 C301 MA-51 Mathematics-V 100 50 -

2 C302 CS-51 Object Oriented Programming 100 50 -

3 C303 EE-51 Advanced Electronics 100 50

4 C304 EE-52 Electrical Measurement-II 100 50 -

5 C305 PH-51 Electrical Engineering Materials 100 50 25

6 C306 IN-51 Introduction to Chemical

Processes

100 50 -

7 C307 EE-51L Advanced Electronics Lab - - 50

Course Outcomes: Upon completion of the course, students shall be able to

CO1 Apply the knowledge of interpolation technique and root finding technique in

different fields of engineering.

CO2 Solve problems on numerical differentiation and integration, simultaneous equations

and differential equations numerically.

CO3 Solve engineering problems on analytic functions, harmonic functions and complex

integrations using calculus of complex variable.

CO4 Explain Conformal Transformations and the concept of contour integration for

evaluating real definite integrals.

MA: 51

C301 Mathematics V SemesteR - V

Theory

100 marks

Sessional

50 Marks

Mapping of COs with POs

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PS

O1

PS

O2

CO

1 2 2 1 1 2

CO

2 2 2 1 1

CO

3 2 2 1 1

CO

4 2 2 1 1

Av

g 2 2 1 1 2

MA51: Numerical Analysis and Complex Variables

Module 1: Numerical Analysis (2 credits) [25 lectures]

Interpolation, Finite differences, Newton-Gregory forward and backward interpolation,

Newton’s and Lagrange’s formulae for unequal intervals, Sterling’s and Bessel’s

interpolation formulas.

Numerical differentiation, Numerical Integration: Trapezoidal and Simpson’s 1/3rd and 3/8th

rules for numerical integration. Solution of Transcendental and polynomial equations,

Bisection,Regula-Falsi and Newton-Raphson method. Solution of simultaneous linear

equations:Gauss elimination and Gauss-seidel iterative method. Solution of ordinary

differential equation:Taylor’s series, Runge-Kutta (4th order) and Milne’s predictor-corrector

methods.

Module 2: Complex Variables: (2 credits)[25 lectures]

Functions of complex variables, Elementary functions, Analytic functions,Cauchy-Riemann

equations, Harmonic functions and their application to two-dimensional problems.

Conformal transformation.

Complex line integral, Cauchy’s integral theorem Cauchy-Goursat theorem(without proof),

Cauchy’s integral formula, Liouville’s theorem, Morera’s theorem. Taylor’s theorem ,

Laurent’s theorem (without proof). Singularities, Residue theorem and its applications.

TextBooks/References

1. Finite Differences and Numerical Analysis By H.C. Saxena,S.Chand and Company.

2. Numerical Analysis By Gupta and Malik

3. Complex Variables By J.N. Sharma

4. Complex Variables and applications By R.V.Churchill and J.W. Brown

COURSE TITLE: Object Oriented Programming

COURSE CODE: CS-51

Theory: 100 Sessional: 50

COURSE OUTCOMES:

OOP1: To explain representation and operations on linear data structures

OOP2: To explain representation and operations on non-linear data structures

OOP3: To list the underlying concepts of object oriented programming.

OOP4: To demonstrate C++ language features like classes, inheritance, access

control, abstract class, operator overloading, virtual function, friend function, streams

and pointers by writing example programs.

OOP5: To build C++ programs for implementation of data structures.

CO-PO MAPPING:

CO

s

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 2 1 2 3

CO

2 2 1 2 3

CO

3 2 3

CO

4 2 2 1 3

CO

5 3 3 3

avg 2.2 1

2.2

5 1 3

SYLLABUS:

Fundamental Notating: Primitive and composite data types, Dependence of algorithms on

data structure.

Data structures: Linear lists, stakes, queues, arrays, link-lists, spose matrices (transpose and

multiplication algorithms), trees and graphs (binary tree traversing, dfs and bfs algorithm,

connected components algorithms, spanning tree algorithm) --- their representation in

sequential storage and link lists and algorithms for manipulation operation.

Concept of object-oriented programming: Object-oriented language features- object,

classes, instances, inheritance, class library, abstraction, polymorphism, encapsulation,

dynamic binding, operator overloading.

Study of following features of C++ : Review of C language, class, objects, operator

overloading, inheritance, containership, arrays and strings; virtual, friend and static functions,

abstract classes, pointer in C++, files and streams, features of graphic functions in C++.

TEXTBOOKS:

1. Data structures in Pascal – Horowits and Sahni.

2. Object- oriented programming with C++ -- E. Balaguruswami.(TMH)

3. Programming with C++ - John R. Hubbard, Ph.D ( Schum’s Series) McGraw Hill

International Editions

COURSE TITLE: Advanced Electronics

Semester: 5th sem.

COURSE CODE: EE-51

Theory: 100 Sessional: 50

Practical: 50

COURSE OUTCOMES:

AE1: Explain the various fabrication techniques of monolithic ICs.

AE2: Analyze power amplifiers e.g. Class A, B, AB, C, D, E and various transistor

oscillators.

AE3: Design differential amplifier and Operational amplifier circuits.

AE4: Analyze linear and nonlinear applications of opamp.

AE5: Develop first and second order passive or active filters.

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 2 1 2

3

CO2 2 2 1 2

CO3 2 3 2

CO4 3 2 2

CO5 3 2 2

SYLLABUS:

1. Transistor High Input Impedance and Power Amplifier: Need for High input

impedance amplifier, Emitter follower; Darlington amplifier; Tuned amplifier; Class-A,

Class-B, Class-AB and Class-C amplifiers; Distortions in power amplifiers.

2. Transistor Oscillators: Positive feedback and Barkhausen criterion for sustained

oscillations; Classification of oscillators, Tuned collector oscillator; Hartley oscillator;

Colpitt’s oscillator, RC oscillators, Crystal oscillator.

3. Linear Integrated Circuits: Classification and fabrication of ICs, Integrated difference

amplifiers; Biasing techniques; Operational amplifier; Characteristics and specification of

OPAMPs; OFFSET compensation; FET OPAMPs.

4. Linear Applications of OPAMPs: Open loop operation of OPAMPs; Voltage-series and

current-series feedback; Non-inverting and inverting configurations of OPAMP circuits;

Instrumentation amplifiers; V to I and I to V converters; Summing scaling and averaging

amplifiers; Log and antilog amplifiers; Integrators and differentiators; Electronic analog and

computation.

5. Non Linear Applications of OPAMPs: Comparators; Schimitt trigger; Voltage limiter; F

to V and V to F converters; OPAMP oscillators; OPAMP multivibrators; Triangular and

sawtooth wave generator; Clipper, clamper, peak detector; Sample and hold circuit.

6. Active Filters: Classification of filters; Butterworth RC filters of various types and orders

using OPAMP; High Q band pass and band stop filter; All pass filters; Universal active filter;

Switched capacitor filter.

7. Specialized IC Applications: The 555 timer IC; PLL, voltage regulator ICs; DAC, ADC

ICs.

TEXTBOOKS:

1. Integrated Circuit Electronics - Millman and Halkins

2. Microelectronics- Millman

3. OPAMP and Linear IC Applications - Ramakant and Gayakwad

4. Linear Integrated Circuit--Roy Chowdhury and Jain

COURSE TITLE: Electrical Measurement-II (EE52)

COURSE CODE: EE-52

Theory:100 Sessional:50

COURSE OUTCOMES:

EM-II1: Apply AC and DC bridges to measure electrical parameters (R/L/C) of various

ranges.

EM-II2: Explain magnetic measurement and characteristics.

EM-II3: Identify measuring methods and testing methods for High Voltage equipments,

cables

and circuits.

EM-II4: Explain measurement of various non electrical parameters.

CO-PO MAPPING:

CO

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 2 2 1

CO

2 2

CO

3 1 1

CO

4 2 1

2.3 2 1.5 1 2 1

SYLLABUS:

(1) Introduction: D.C Potentiometer, Basic D.C Potentiometer Circuit, Cromtonn’s Potentiometer, Multirange

Potentiometer, Standard Cell Dial, Volt-Ratio Box, Application For The Measurement Of

Voltage,Resistance And Power, Calibration Of Voltmeter, Ammeter And Wattmeter. Self

Balancing Potentiometer, A.C Potentiometer—Principle and Classification, Gall-Tinslay A.C

Potentiometer, (Co-Ordinate Type), Drystal Polar Potentiometer, Standardization, Errors And

Applications.

(2) Measurement Of Resistance:

Idea Of Low, Medium& High Resistance, Measurement Of Medium Resistance By

Ammeter-Voltmeter Method, Substitution Method, Wheatstone Bridge Method,

Measurement Of Low Resistance By Kelvin Double Bridge Method, Difficulties Of

Measurement High Resistances, Use Of Guard Circuit, Loss Of Charge Method,

Measurement Of Insulation Resistance With Power On, Factors Effecting Earth Resistance,

Methods Of Measuring Earth Resistance.

(3) A.C Bridges:

General Form Of A.C Bridge, Maxwell’s Inductance Bridge, Maxwell’s

Inductance/Capacitance Bridge, Hay’s Bridge, Anderson’s Bridge, Owen’s Bridge, High

Voltage Schering Bridge, Heaviside Mutual Inductance Bridge, Campbell’s Modification Of

Heaviside Bridge, Heaviside –Campbell Equal Ratio Bridge, Cary-Foster Bridge, Wien’s

Bridge, Sources Of Errors In Bridge Circuits, Shielding Of Bridge Elements, Wager Earthing

Device.

(4) Magnetic Measurement:

Different Magnetic Measuring Quantities, Flux Measurement By Fluxmeter, Principle Of

Magnetic Potentiometer, Ewing Double Bar & Illiovici Permeameter, Determination Of B-H

Curve And The B-H Loop By The Method Of Reversal And Step By Step Method,

Hysteresis Loss Measurement By Wattmeter Method, Bridge Method And Potentiometer

Method.

(5) Transducers: Classification And Selection Of Transducers, Construction Principle And Applications Of

Diaphragms, Bellows, Bouden Tubes, Springs, Capacitive Pizeoelectric And Photoelectric

Transducers.

(6) High Voltage Measurements And Testing:

Types Of Tests, High Voltage Transformers, Voltage Control By Variation Of Alternator

Field Current, Tapped Transformers, Induction Regulators, Control Gear And Protective

Devices, Equipment For Voltage Measurement, Measurement Of R.M.S, Peak, Instantaneous

Values Of Voltages, Low Frequency High Voltage Tests, High Voltage D.C Testing, High

Voltage D.C Testing Of Cables, Localization Of Faults In H.V Cables, High Frequency H.V

Testing, Surge Testing, Basic Impulse Generator, Testing Of Insulating Material, Impulse

Testing Of Transformer, H.V Testing Of Cables, Testing Of Strength Of Insulating Oils, H.V

Testing Of Porcelain Insulators.

TEXTBOOKS:

1) Elect. Measurement & Measuring Instruments – Golding E.W & Wides F.C

2) A Course in Elect. & Electronics Measurement & Instrumentation- Shawney A.K

3) Elect. Measurement & Measuring Instruments—Suryanarayan.

COURSE TITLE: Electrical Engineering Materials Semester: 5th sem.

COURSE CODE: PH-51

Theory: 100 Sessional: 50

COURSE OUTCOMES:

EEM1: Interpret solids based on knowledge of crystal structure.

EEM2: Relate the working of devices with the Physics of conducting, magnetic, dielectric,

semiconducting & superconducting materials.

EEM3: Outline the applications of the different classes of materials.

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 2 1 2

2 CO2 3 2 2

CO3 2 2 2

2.33 1.667 2 2

SYLLABUS:

1. Crystal Structure: Unit cell and Bravais lattice; Bravais lattice in tow-dimensional and

three-dimensional crystal structures; Direction and planes in a crystal lattice: Miller indices;

Crystal structures of solids-LCC, FCC, BCC, simple cubic and diamond structures; X-ray

diffraction and Bragg’s law.

2. Conductor Materials: Free electron theory of metals-conductivity, drift velocity,

relaxation time, collision time and mean free path; Fermi-Direc distribution; Temperature and

impurity effect; Frequency effect; Effect of magnetic fields-Hall effect and

megnetoresistance; Heat developed in current carrying conductors; Thermal conductivity;

Conductor materials-choice of conductor materials, high conductive materials, materials of

high resistivity, materials for fuse and soldiers, materials for lamp filaments, thermoionic

materials; Superconductivity-basic theory and application.

3. Semiconductor Materials: Intrinsic semiconductors- chemical bond in ST and Ge,

Energy band in semiconductors, Density of charge carriers, Conductivity of intrinsic

semiconductors; Extrinsic semiconductors; Doping in semiconductors, Effect of doping in

electrical conductivity, p-type semiconductors, density and mobility of charge carriers; Hall

effect; Drift current and defusion currents; Einstein relation; Fabrication of PN junction, PNP

junctions and integrated circuits; Social applications of semiconductors-nonlinear

resistors(Varistors), themistors, alloy semiconductors- like Ga-As, Ga-I-As, Ga-I-Al , etc.

used in optoelectronic devices.

4. Magnetic Materials: Magnetic parameters-permeability and magnetic susceptibility;

Magnetic dipole moment and angular momentum; Classification of magnetic materials;

Diamagnetism; Paramagnetism; Ferromagnetism and Curie-Wiess law; Ferrimagnetism;

Magnetic domain; Magnetic anisotrophy and magnetostriction; Ferrimagnetic materials.

5. Dielectric Materials: Dielectric parameters-Dielectric constant, dipole moment,

polarization and polarizability, Clausius-Mosotti equation; Mechanism of polarization-

electronic polarization, ionicpolarization and dipolar polarization; Frequency dependence of

polarizability; Dielectric losses; Ferroelectric materials their properties and classification;

Piezoelectricity; Mechanism of dielectric breakdown of gases; Liquids and solids; Factors

influencing dielectric strength; Insulating materials; Properties of common insulating

materials used in electrical apparatus like mica, asbestos, glass, bakelite, porcelain, rubber,

paper, cotton, silkfiber, wood, plastics, PVC resins, varnishes, insulating oil and liquids,

gaseous insulator etc.

TEXTBOOKS:

1. Electrical Engineering Materials----A. J. Dekker (Prentice Hall, India)

2. Science of Engineering Materials---C. M. Srivastava and C. Srinivasan (WE)

3. An Introduction to Engineering Materials---C. Indulkar (S. Chand & Company)

4. Electrical Engineering Materials---G. P. Chalotra & B. K. Bhatt.

COURSE TITLE: Introduction to Chemical Process

Semester: 5th sem.

COURSE CODE: IN-51

Theory: 100 Sessional: 50

COURSE OUTCOMES:

ICP1: Explain the concept of Chemical Process. Also explain the material balance and

energy balance for analysis of unit processes and unit operations.

ICP2: Illustrate the concept of Fluid Mechanics

ICP3: Illustrate the concept of different mode of heat transfer; Explain different heat transfer

equipment

ICP4: Explain the concept of mass transfer. Also summarize batch reactors and continuous

flow reactors.

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2 1

CO2 3 2

CO3 3 2

CO4 2

2.75 2 1

SYLLABUS:

1) CHEMICAL AND PHYSICALES PRINCIPLES: - Chemical formulas, chemical

equations, Temperature, pressure and Gas laws.

2) UNIT OPERATION:-- The scientific foundation of unit operation, basic laws, material

and energy balance. Dimensional and dimensionless equation, dimensional analysis.

Classification of units operation e.g. fluid flow, heat transmission, blending operation,

separation process, solid handling etc. Classification of chemical process e.g. combustion,

oxidation, halogenation, hydrogenation, fermentation etc.

3) FLUID MECHANICS: Energy and momentum relationships, nature and type of fluid,

ideal and non-ideal gas. Compressible and incompressible fluid, basic equation of fluid flow,

flow through pipe, fittings and valves, pumps, compressors and blowers, calculation of power

and size of agitated vessel.

4) HEAT TRANSFER: -- Mode of heat transfer, steady and unsteady conduction-Fourier’s

law, introduction to convection, individual and overall heat transfer co-efficient, nature and

force convection with and without phase change, viscous, transition and turbulent region.

Design of heat transfer equipment e.g. heat exchanger, condenser, furnace and evaporators.

Radiant heat transmission, energy emitted by black body, laws of black body radiation.

5) MASS TRANSFER:-- Fundamental, theory of diffusion, comparison of diffusion and

heat transfer, fick’s law, equimolal diffusion, diffusivity of gases and liquid, turbulent

diffusion, mass transfer co-efficient and film theory, penetration theory. Experimental

measurement of mass transfer and design of mass transfer equipment e.g. absorbers, plate and

packed column. Separation process by membrane. Flash distillation of binary mixture,

continuous distillation with reflux.Equilibrium stage calculation, no of ideal plate, McCabe-

Thiele method.

Definition of rate reaction, the general balance equation, batch reactors continuous flow

reactors both isothermal and non-isothermal operations, Industrial reactors, Stoichimetric

relationship and reactor T

TEXTBOOKS:

(1). McCabe W L, Smith J.C.; Peter harriott. H- Unit Operation of chemical Engg McGraw

Hill

(2) Levenspiel O ―Chemical Reaction Engg‖ Wiley Eastern Pvt Ltd. New Delhi.

(3) Himmelban D.H: ―Basic Principles and Calculation in Chemical Engg.‖ Prentice Hall of

India

Reference Books

1. Coulson, J. M; Rechardson J. F; ―Chemical Engineering ― Pergamon International

Library.

2. Williams T Edwin ; Jonson Curtis R; ―Stoichiometry for Chemical Engineers‖ McGraw

Hill Book Co.

3. Haugen , O. A; Watson K. M; Ragatz R. A. ―Chemical Process Principle‖ Asia Publishing

House.

4. Fogler H C; ―The Elements of Chemical Kinetics and Reactor Calculation‖ Prentice Hall

International Series in Physical and Chemical Engineering Sc.

5. Denbigh K. G; Turner J. C. R; ―Chemical Reactor Theory‖ The English Language Book

Society and Chembridge University Press.

6. Noble F. D. and Stern A. A. ―Membrane Separation Technology Principles and

Application‖ Elsivier.

COURSE TITLE: Advanced Electronics Lab

Semester: 5th sem.

COURSE CODE: EE-51L

COURSE OUTCOMES:

CO1: Implement different circuits using Op Amp for various applications.

CO2: Interact Effectively on a social & interpersonal level with fellow students

CO3: Share task responsibilities to complete assignments and ethically develop professional

and technically sound reports

CO-PO MAPPING:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 2 2 1

CO2 1 1 1 3 2

CO3 3 3 2 2

2 2 1 2 2 2.5 1.6667

SIX SEMESTER

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Practical

1 C308 HS-61 Principles of Economics &

Accountancy

100 50 -

2 C309 EE-61 Communication Engineering 100 50 -

3 C310 EE-62 Microprocessors-I 100 50 -

4 C311 EE-63 Electrical Machines &

Applications

100 50 -

5 C312 IN-61 Analytical Instruments 100 50 -

6 C313 IN-62 Drawing & Design of

Instrumentation System

Components

- 100 -

7 C314 EE-62L Microprocessors-I Lab - - 50

8 C315 EE-63L Electrical Machines &

Applications Lab

- - 50

Course Outcomes: Upon completion of the course, students shall be able to

CO1 Explain the fundamental concepts of economics.

CO2 Apply the basic concepts of managerial economics.

CO3 Explain banking, nature and different sources of public revenue and five years

HS-61

C309

PRINCIPLES OF

ECONOMICS AND

ACCOUNTANCY

SEMESTER -

VI

Theory

100 marks

Sessional

50 Marks

plan.

CO4 Explain the basic accounting terms, procedure of recording transactions, the

preparation of bank reconciliation statement and cash book.

CO5 Outline the procedure of preparation of trial balance, trading account, profit &

loss account and balance sheet.

Explain cost estimation procedure by preparing cost statement.

Mapping of COs with POs

COs PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO309.1 1 - - - - - - - - - 2 1

CO309.2 1 - - - - - - - - - 2 1

CO309.3 1 - - - - - - - - - 2 1

CO309.4 2 - - - - - - - - - 2 1

CO309.5 2 1 - - - - - - - - 2 1

CO309.6 2 1 - - - - - - - - 2 1

C309 1.5 1 2 1

COMMUNICATION ENGINEERING(EE61)

Theory:100 Sessional:50

Course Outcomes :

At the end of the course, student will be able

CO1: Explain various types of signals, Fourier series & transform, energy & power spectral

density of signal, ideal filters like LPF, BPF and communication channels.

CO2: Illustrate different distributions and noise.

CO3: Analyze concepts of analog modulation in both time and frequency domains.

CO4: Explain pulse modulation systems, Digital modulation and Information theory.

CO5: Explain propagation modes of various waves and basic antenna structures.

Mapping of COs with POs

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2 1

1

CO2 3 2 1 1

CO3 3 1 1

CO4 3 1 1

CO5 2 1 1

2.8 2 1 1 1

Introduction: An over view of communication process-electronic communication.

(1) Signals and spectra:Classification of signals,spectrum of signal,Fourier series and Fourier transform,Convolution,singularity function,Fourier transform of periodic

signals,Hilbert transform,normalised power,Parseval’s theorem,Raligh’s

theorm,spectral density,correlation between wave forms-cross correlation and

auto-correlation,signal transmission through a linear time invarient

system,transfer function,impulse response,ideal filter-

LPF&BPF,causality,practical filters,typical communication channels,distortion

less transmission,signal transmission through BPF-pre envelope and complex

envelope.

(2) Random signals and noise:Review of probability theory,random variables,probability distribution functions&probability density function,joint

probablity,Gaussian distribution,Raleigh’s distribution and exponential

distribution,error function,random processes,average and variance of random

processes,source of noise,noise as a random process,white noise,noise

transmission through LTI system,SNR,noise temperature,available power of a

noise source,calculation of rms noise voltage,noise equivalent resistance of an

amplifier,noise figure.

(3) C.W modulation and detection:Need for modulation,amplitude modulation,AM

modulators-low level and high level modulation techniques,AM detectors,superheterodyne reciever princples,ICIC reciver for AM,frequency

modulation-NBFM&WBFM,FMmodulators,FMdetectors,noiseinFM

systems,phase modulation,supressed carrier modulation-DSB-SC&SSB-

SC,generation and detection of SC modulation system,phase and frequency error in SC modulation system,FDM.

(4) Pulse modulation:Nyquist sampling theorem,pulse modulation system-

PAM,PWM,PPM,aliasing,naturalsamplingandflattop

sampling,quantization,quantization error,PCM,companding,TDM,cross top,differential PCM,delta modulation,adaptive DM.

(5) Electromagnetic wave propagation:Electromagnetic radiation,propagation

modes of EM waves-ground wave,sky wave,space wave,tropospheric scatter,extra

terrestrial communication,dipole antenna,resonant antenna ,non resonant

antenna,Marconi and Hartz antenna, antenna coupling at medium frequencies,directional high frequency antenna,microwave antenna,wide band antenna.

Ref. Books:

(1) Principles Of Communication Systems-Taub & Schilling.

(2) Communication Principles-Simon Haykin.

(3) Analog And Digital Communication Systems-Martin Roden.

(4) Electronic Communication Systems-George Kennedy.

MICROPROCESSORS –I(EE62)

Theory:100

Sessional:50

Practical:50

CO1: Illustrate the architecture of microprocessor along with its peripherals.

CO2: Apply different 8085 instructions.

CO3: Construct assembly language program for microprocessor applications.

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 1 2 1 3

CO

2 3 2 1 2 1

CO

3 3 2 1 2 1

3 2 1 2 1 3

1. Introduction to Microprocessors and Microcomputers : Evolution of

Microprocessors & Digital Computers ; Single chip Microprocessors ;

Microprocessor applications ; Microcomputer programming languages ; Large

& small computers ; Supercomputers ; Main frame (Large) computers, Minicomputers and Microcomputers.

2. Microcomputer System Peripherals : Microcomputer displays ; Raster

scan CRT graphics display ; CRT terminals ; Raster scan colour graphics ; Vector scan CRT display ; Alphanumeric / Graphics LCD display ; Keyboard ,

Mouse and other input devices ; Computer vision ; Mass data storage systems-

floppy disc, hard disc, optical disc : Printer mechanisms ; Speech synthesis and recognition by computer.

3. Microcomputer Architecture : Basic blocks of microcomputer ; Typical microcomputer architecture ; Microcomputer bus ; Clock signal ; Single chip Microprocessor ; Register sections ; Control unit ; ALU ; Functional representation of simple and typical Microprocessors ; Processor memory – primary, secondary and cache memory ; Memory array design and interfacing ; Input/ Output – programmed I/O , Interrupt I/O , Handshaking signals , Standard I/O versus Memory mapped I/O ; Main characteristics of interrupt I/O ; Interrupt types ; Interrupt address vector; Interrupt priorities ; Polled

interrupt ; Daisy chain interrupt ; DMA and different types ; Coprocessors.

4. Microcomputer Software Concept : Instruction format ; Addressing modes ; Instruction types ; Instructions for Assembly Language Programming.

5. INTEL 8085 Microprocessor : Introduction ; Register structure ; Memory addressing ; Addressing modes ; Instruction sets ; Timing methods ; CPU pins and associated signals ; Instruction timing and execution ; T-state and Machine cycle ; Timing diagrams ; Programmed I/O ; Interrupt systems ; DMA operations ; SID & SOD lines ; 8085 based system design.

6. INTEL 8085 Programming : Writing ALP ; Debugging of Program ; Programming techniques – looping , counting and indexing , counters and time delays , stack and subroutines ; Code conversion – BCD arithmetic and 16-bit data operations.

7. MDS and Other Development Aids : Introduction to MDS ; Hardware &

software support to MDS ; PROM programmer ; EPROM eraser ; Simulators

and Emulators ; Monitor : Operating systems ; File manager ; Linker ; Loader

; Locator; Debugger ; Assembler ; Text editor ; Compiler ; System software ; Application software ; Utility program ; BIOS.

Reference Books :

1. Microprocessor theory and Applications - M. Raffiqzzaman ( Mc Graw Hill Ltd)

2. Microprocessor Architecture , Programming & Applications – R.S. Goankar

Electrical Machines and Application(EE63)

Theory:100 Sessional :50 Practical:50

COs Statement

EMA1 Explain constructional details and principle of operation of AC machines, DC machines

and transformers.

EMA2 Choose suitable method of speed control of DC motor and 3-phase induction motor for

various societal and industrial applications.

EMA3 Analyze performance of Transformers and 3 phase Induction motor using phasor

diagram and equivalent circuits.

EMA4 Explain the characteristics and applications of dc machines, 3 phase induction motor and

Alternator.

EMA5 Analyze performance of DC machines and synchronous machines.

EMA6 Identify suitable electrical machines for different applications.

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2

CO2 3 2

CO3 2 3 1

CO4 3 1

CO5 2 3

CO6 3 3

1. D.C generator: Construction and principle of operation; Armature windings- Lap

and Wave windings, Equaliser rings, dummy coils; E.M.F equations, Types of d.c. generators, Armature reaction; Compensation windings, Commutations and

methods of improving commutation; Characteristic of separately excited self

excited generators; Applications of d.c. generators; Losses and efficiency.

2. D.C Motor: Construction and principle of operation; Back e.m.f; Torque

equation; Condition for maximum torque; Losses and efficiency; Type of d.c. motor; Speed regulation; characteristic of shunt, Series and compound motors;

Application of d.c. motors; Starting of d.c. motors; Speed control of d.c. motors.

3. Transformer: Working principle; Construction of core type and shell type

transformer; e.m.f equation; Transformation ratio; Resistance and magnetic lekage

reactance; No-load and on-load phasor diagrams; Equivalent circuits; Losses and

efficiency; Open circuit and S.C testes; Voltage regulation; Condition for

maximum efficiency; All-day efficiency; Autotransformer.

4. Three-phase induction motor: Classification of a.c. motors; General principle;

Construction and classification; Theory of operation, slip and frequency of rotor current; Torque and torque-slip characteristic; Starting torque; Condition for

maximum torque; Losses and efficiency; Starting of induction motor.

5. Single phase motor: Type of single phase motors- Single phase induction motor-

double revolving field theory; Torque-speed characteristics; Split phase motors-

resistance start; Capacitor start, permanent capacitor and capacitor start-capacitor

run motors; Shaded pole motors; Single phase commutator motors-repulsion

motor, repulsion start induction motor; repulsion induction motor; A.C. series

motor-universal motor; Reluctance motor and hysteresis motor.

6. Alternator: Classification; Construction of cylindrical and salient pole alternator;

Armature winding and winding factors; e.m.f equation; Armature reaction, armature reaction and impedance; Phasor diagram; Voltage regulation; O.C and

S.C tests; Determination of voltage regulation by synchronous impedance method

and AT method.

Ref. Books:

7) Theory of A.C Machinery- A.S Langsdrof (TMH)

8) Elect. Machines-Nagrath & Kothari (TMH)

9) Performance & Design of A.C Machines- M. G Say

10) Advanced Elect. Technology- H. Cotton

11) Fundamentals Of Elect. Machines – B.R Gupta & V. Singhal (New Age)

12) Prblems in Elect. Engg.- N.N Parker Smith)

6 TH SEMESTER

B.E (INSTRUMENTATION ENGINEERING)

ANALYTICAL INSTRUMENTS(IN61)

Theory:100 Sessional :50

On Completion of this course the students should be able to

C312.1 Compare various analytical instruments with other instruments.

C312.2 Apply an analytical instrument in measuring relevant chemical

parameters.

C312.3 Analyze various analytical instrumentation techniques.

C312.4 Explain the functioning of gas analysis instruments.

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 2

3 1

CO2 2 2

CO3 1 3 1

CO4 3

1. Introduction: Difference between analytical and other instruments , on line

instrumentation and laboratory techniques for liquid and gases for analysis purpose.

2. Gas analysis: Gas chromatography, thermal conductivity method, heat of reaction

method, estimation of oxygen, hydrogen methane, carbondioxide, carbon monoxide

etc. in binary and complex gas mixtures.

3. Humidity and moisture measurement techniques.

4. Chemical composition analysis, measurement of viscosity, consistency, PH, electrical

conductivity.

5. Techniques of density measurement: solid, liquid and gases.

6. Spectro chemical analysis: MSS, emission and absorption spectrometry, dispersive

and non dispersive techniques.

Ref. Books:

1. Patranabis.D.- Principles Of Industrial Instrumentaton.

2. Jones.E.B. - Instrument Technology, Vol II Analysis Instruments Butter-Worths Scientific

Publication, London.

3. O higgins P S - Basic Instrumentation In Industrial Measurement-Mc- Graw Hill Book Co.

4. Hand Books Of Analytical Instrumentation

SUB.CODE-IN-62

6TH SEMESTER B.E.(INST. ENGG.)

DRAWING AND DESIGN OF INSTRUMENTATION SYSTEM COMPONENTS

Sessional :100

Course Objective:

To provide basic concepts of Design and Drawing of Instrumentation system

Course Outcomes: On Completion of this course the students should be able to

COs Course Outcomes

CO1 Develop Drawing for Instrumentation System Components.

CO2 Analyse various instrumentation system Components using modern LabVIEW and

multisim

CO3 Adopt professional ethics and responsibilities.

CO4 Communicate instruction delivery for working and making drawings.

Cos

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 2 2 2 2

CO

2 3 2 3

CO

3 3

C0

4 3 3

1. Design and drawing of mechanical components- linkages, gears, pivots, bearings, springs dampers etc.

2. Design of electrical components-permanent magnets, electromagnets, small transformers, relays, LVDT, variable capacitance transducers, variable resistance

transducers, strain gauges, display and recording devices.

3. Instrumentation amplifiers.

4. Design of transducers with associated circuitry, interface of primary elements with end devices, design of bridge circuits for thermocouples and thermistors.

5. Design of pneumatic and electronic controllers.

Ref.Books:

1. Neubert H K P- Instrument Transducers- An Introduction to Their Performance And

Design-Claredon Press, Oxford.

2. Trylinsky W -Fine Mechanism And Precision Instruments: Principles Ofdesign,

Pergaman Press, Oxford

Course Title: Microprocessor_I Laboratory

Course Code: EE62L Semester of Study: 6th

CO1: Demonstrate the results of different arithmetic operations like addition ,

subtraction,multiplication,and division with 8085.

CO2: Find the results of different 8085 instructions.

CO3: Apply different arithmetic,logical,data transfer and implicit instructions of 8085

for various microprocessor applications.

Interface different peripheral devices with 8085.

CO4: Interact Effectively on a social & interpersonal level with fellow students to

receive clear procedural instructions.

CO5: Share task responsibilities to complete assignments and ethically Develop

professional and technically sound reports.

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3 2 1 2 1

1 2

CO2 3 2 1 2 1

CO3 3 2 1 2 1

CO4 1 3 3 2

CO5 3 3 3 2

Experi

ment

No.

Title of the Experiment Objective of the Experiment

1 Addition of two 8-bit

numbers

To write a assembly language program for adding 2 bit (8)

numbers by using-8085 micro-processor kit.

2 Subtraction of two 8 bit

numbers.

To write a assembly language program for subtracting 2 bit (8) numbers by using-8085 micro-processor kit.

3 Addition of two 8 bit

decimal numbers.

To write a assembly language program to add two 8 bit

decimal numbersby using-8085 micro-processor kit.

4 To find the 2’s complement

of an 8-bit number.

To write a assembly language program to find the 2’s

compliment of an 8 bit decimal numbers by using-8085

micro-processor kit.

5 To find the larger of the two

numbers. To write a assembly language program to find the larger of

the two numbers (04H and 08H) by using-8085 micro-

processor kit.

6 To arrange three numbers in

descending order.

To write a assembly language program to arrange 3

numbers in descending order by using-8085 micro-

processor kit.

7 To find the summation of

series of four 8-bit numbers.

To write a assembly language program tofind the

summation of series of four 8-bit numbers by using-8085

micro-processor kit.

8 To multiply two 8-bit

numbers.

To write a assembly language program tomultiply two8-bit

numbers by using-8085 micro-processor kit.

9

To divide 16 bit number by

8 bit number.

To write a assembly language program to divide 16 bit

number by8-bit numbers by using-8085 micro-processor

kit.

Text book:

“Microprocessor Architecture, Programming and Applications

with 8085” by R S Gaonkar,

“Fundamentals of Microprocessors and Microcontrollers” by B Ram

Course Title: Electrical Machines and Application Laboratory

Course Code: EE63L Semester of Study: 6th

COs Statement

EMA1 Interpret the constructional details of the DC machines, Transformers and

alternators

EMA2 Work in a team sharing individual responsibilities to conduct Experiment with DC

generators (Shunt and series), Transformers and alternators to model different

performance characteristics (such as internal, external and OCC)

EMA3 Analyse the various speed control techniques for DC shunt motor sharing

individual responsibilities in a group.

EMA4 Interact Effectively on a social & interpersonal level with fellow students to

receive clear procedural instructions.

EMA5 Share task responsibilities to complete assignments and ethically Develop

professional and technically sound reports.

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 3

2

CO2 2 2 3 2

CO3 2 1 3 2

CO4 1 3 3 2

CO5 3 3 3 2

Experi

ment

No.

Title of the Experiment Objective of the Experiment

1 Open circuit characteristics

of a DC generator To draw the open CIRCUIT CHARACTRISTICS (OCC) or

magnetization characteristic and to determine the critical

field resistance and the critical speed of a DC shunt

generator.

2 Load test on a shunt

generator

To determine the external and internal characteristic of a

DC shunt generator.

3 Characteristic of a dc shunt

generator

To determine the external and internal characteristic of a

DC series generator.

4 Speed control of a dc shunt

motor

I.

To control the speed of a DC shunt motor by the method of

a. Armature control and

b. Flux control or field control

c.

5 Open circuit test and short

circuir test on a single phase

transformer

To perform open circuit test and short circuit test on a

single phase transformer and to calculate the parameters of

the equivalent circuit. Also to estimate the efficiency and

regulation of the transformer for the full range of loading.

6 Polarity test and load test on a

single phase transformer

To perform polarity test on a single phase transformer also

to estimate the efficiency and regulation of the transformer

for the full range of loading.

7 Regulation of an alternator To perform the open-circuit and short-circuit tests on a three

phase alternator and to determine the regulation by

synchronous impedance method

8 Measurement of power in

three phase circuit by two

wattmeter method

To measure the power and power factor in a three phase

balanced circuit by two wattmeter.

Text book

Electrical Machines, D P Kothari and R J Nagrath

Semester-VII

Sl.

No

SAR

Code

Course

Code

Course Title Theor

y

Sessional Viva

1 C401 HS-71 Industrial Organisation and

Management

100 50 -

2 C402 EE-71 Microprocessors-II 100 50 -

3 C403 EE-72 Power Electronics 100 50 -

4 C404 IN-71 Optoelectronics 100 50 -

5 C405 IN-72 Elective-I 100 50 -

6 C406 IN-73 Project-I - 100 50

Elective-I

1. Biomedical Instrumentation (IN-72)

2. Advanced Communication (EE-735)

3. Artificial Intelligence (CS-723)

4. Digital Image Processing (CS-726)

5. Electronic Instrumentation (IN-74)

6. Interactive Computer Graphics (CS-729)

Course Outcomes (COs): Upon completion of the course, students shall be able to

CO1 Demonstrate the concept of group dynamics, industrial psychology, organization,

types of organization, and functions of management.

CO2 Explain plant layout and location, locational economics and scheduling, routing

& dispatching in production planning.

CO3 Make use of decision and productivity improvement tools in SME- enterprises

and entrepreneurial ventures.

CO4 Explain quality management, maintenance management, project management,

inventory management and the safety norms to be adopted in workplace.

CO5 Explain the meaning and importance of management, functions and principle of

management, material management.

Illustrate the meaning and importance of financial planning, concept of capital,

HS: 71

C401

Industrial Organization And

Management Semester - Vii Theory

100 marks

Sessional

50 Marks

sources of finance, budget and budgetary control system.

Apply the meaning and concept of cost relevance to management decisions and

control, breakeven point, break even analysis.

Mapping of COs with POs:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12 PSO1 PSO2

CO1 2 1 1

CO2 2 1 1

CO3 2 1 1 1 1 1

CO4 2 1 1 1 1 1

CO5 2 1 1 1

CO6 2 1 1 1

CO7 2 1 1 1

Avg 2 1 1 1 1 1 1 1 1

Detailed Syllabus

Unit Course No. of

Lectures Marks

I

Concept of Group Dynamics, Industrial Psychology,

Organization, Types of Organization, Functions of

Management 5 5

II

Plant Location and Locational Economics, Methods of

Locational Analysis, Plant Layout- Types, Scheduling,

Routing and Dispatching

15 10

III

Decision Tools, Decision Tree, Productivity: Definition,

Factor Productivity, Productivity Improvement Tools, SME-

Entrepreneurship, Government Initiatives for Development of

SMEs

5 5

IV

Quality Management: Concept of Quality, Control Charts,

Latest Trend in Quality Management, TQM, ISO 9000 Series

Maintenance Management: Different types, Latest Trend in

Maintenance Management, TPM

Project Management: Definition of Project, Network Analysis,

PERT and CPM Inventory Management: Concept, EOQ

Model

Safety in Workplace, Fire and Safety

15 30

TEXT BOOKS:

1. Work Study by R.C. Patel

2. Plant Layout and Design by J. M. Moore Inventory Control by Starr and Miller

3. Mass Production by M.L. Riggs

4. Hand Book of Industrial Engineering by L. Grant Industrial Engineering

Detailed Syllabus

Unit Course No. of

Lectures Marks

I

Management: Concept, importance, principle, function of

Management in brief.

Industrial Finance : Importance and characteristic of a sound

financial plan, methods and principles of determining the

requirements, concept of capital, fixed and working capital,

meaning of capitalization, over capitalization and under

capitalization, sources of finance.

Budgeting: Business Budgeting, definition and importance,

Master Budget and its components, fixed and flexible budget,

benefits of budgetary control system.

Material Management: Meaning, objectives, aspects and benefits

of scientific management of materials.

Managerial Economics : Concept of costs, relevance to

managerial decisions and control, standard cost and standard

costing, opportunity cost, fixed and variable cost, marginal cost

and marginal costing, break event analysis, problem of break event

analysis.

25 50

Text books

1. Business Administration and Management by S.C. Saxena

2. Management Accounting by R.K. Sharma and S.K. Gupta

3. Cost Accounting Principle and Practice by S.P. Jain and K.L. Narang

4. Business organization and management by S.S. Sarkar, R.K. Sarma, S.K. Gupta

Course Title: MICROPROCESSOR-II

Course Code: EE71 Semester of Study: 7th

CO1: Illustrate the architecture of microprocessor along with the different peripherals.

CO2: Identify the different 8085/8086 instructions.

CO3: Apply assembly language instructions for interfacing input output devices with 8085

through general purpose programmable peripheral devices.

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 2 2

3 CO

2 3 2 2 2

CO

3 3 2 2 2

1) Peripheral Interfacing: Parallel versus serial transmission; Synchronous and Asynchronous serial data transmission; Universal Synchronous / Asynchronous

Receivers / Transmitters (USART) & Universal Asynchronous Receivers /

Transmitters (UART) ; 8251 Programmable communication interface.

General purpose programmable peripheral devices; 8155 & 8255 programmable

peripheral interfaces; 8253 programmable interval timer; 8259 programmable

interrupt controller; 8257 DMA controller; 8279 programmable key-board/

display

controller; Key debounce; 8-bit input/out-put port 8212; ADC & DAC interfacing;

Interfacing standard; IEEE 488 parallel interface bus; RS 232C serial interface.

2) Advanced Microprocessor & Microcontrollers: Intel 8086

microprocessor; Architecture of 8086 ; 8086 addressing mode; 8086 instruction

sets; Brief discussion & comparison of INTEL 8088 , 80186, 80188, 80286,

80386, 80486 & Pentium processors; Other 8-bit microprocessors- Z –80 &

Motorola 6800 ; 8-bit microcontroller; Architecture and programming of 8031/8051.

3) Microprocessor Based Applications: Digital clock, Traffic light controller, Hex key-board interface, Seven segment display interface, Stepper motor control, Washing machine controller, Microprocessor based protective relays, Measurement of electrical quantities, Measurement & control of non-electrical quantities.

Ref. Books:

1) Microprocessors & Interfacing- Douglas V Hall.

1) Microprocessors (Theory & Applications) : - M. Rafiqzzaman

2) Microprocessor Architecture Programming & Applications- Goankor

3) Fundamentals of Microprocessor & Microcomputers – B. Ram.

Course Title: POWER ELECTRONICS

Course Code: EE72 Semester of Study: 7th

CO1: Explain different types of Semiconductor power devices.

CO2: Solve problems related to rectifiers,inverters and DC to DC converters.

CO3: Illustrate construction of different types of cycloconverters.

CO4: Explain different types of AC voltage controllers and regulated power supplies.

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 1

3

CO

2 3 2 1

CO

3 3 2 1

CO

4 3 2 1

1) Semiconductor Power Devices : Characteristics of power devices – diode, power transistor, thyristor and triac; Firing circuits for thyristor & triac; Rating , cooling & mounting of thyristor; Series & parallel connection of thyristor ; Protection of Thyristor; Gate trigger & commutation circuits; Gate turn-off thyristor (GTO) ; Power MOSFET; UJT ; Diac & IGBT.

2) Rectfying Circuits: Circuit nomenclature, commutating diode, Single-phase

half wave; bi-phase half wave; single phase bridge uncontrolled, fully control &

half controlled rectifiers; 3-ph half wave, 6-ph half wave 3-ph bridge & 12-ph circuits; Transformer rating; Rectified with R-L & R-C loads; power factor

improvement; Excitation angle control; Symmetrical angle control; PWM & sinusoidal PWM.

3) Inverter: Principle of operation of inverter; voltage driven inverter; current driven inverter; Forced-commutated inverter; Classification of circuits for forced commutation; parallel inverter; poly-phase inverter; self commutated inverter; Bridge inverter; Mc Murray –Bedford commutation; Bridge circuit using Mc Murray –Bedford commutation ; 3-ph bridge inverter; current source inverter; PWM inverter; voltage control of 3-ph inverter; Harmonics reduction; inverter applications.

4) Chopper: Principle of operation of chopper; constant frequency operation; variable frequency operation; Classification- class A, class B, class C , class D & class E operation; Series turn-off chopper; Parallel capacitor turn-off chopper; Morgan chopper; Jones chopper.

5) Cycloconverters: Mathematical analysis; Bridge configuration; control circuits; improved cycloconverter circuits; Harmonic analysis; input characteristics ; circulating current mode; control; Envelope cycloconverter.

6) A.C Voltage Controllers: Introduction ; ON-OFF control ; phase angle control;

Single phase bi-directional controller with resistive load.

7) Power Supplies: D.C power supply; SMPS d.c power supply; Resonant d.c power supply; Bi-directional power supplies; A.C power supplies; UPS configuration; SMPS a..c power supplies; Power factor conditioning.

Course Title: Opto Electronics

Course Code: IN71 Semester of Study: 7th

Course Objective:

The objective of this course is to give the students the idea about different optoelectronics

devices and their applications.

Course Outcomes: On Completion of this course the students should be able to

COs Course Outcomes Level

CO1 Analyze different types of LED and Laser sources. L2

CO2 Select different photo detectors in analog and digital circuits. L1

CO3 Apply optical fibre to measure various physical parameters. L3

CO4 Compare Holographic data storage with other memories. L2

Mapping of Course outcome and Programme outcome and Programme Specific Outcome:

Course

Outcome

Programme Outcome PS01 PS02

1 2 3 4 5 6 7 8 9 10 11 12

CO1 2 2 1 1 2

CO2 2 2 1 1

CO3 2 2 1 1

CO4 2 2 1 1

Characteristics of optical radiation, Electro luminescence, Heterojunction LED,

Characteristics of Laser Radiation, Structure of gas and solid state laser, Pulse mode laser,

Semiconductor laser.

Internal and External Photo effects, Photo diodes, PIN diode, Shottky barrier diode,

Heterojunction diode, Barrier APD, Phototransistor, CCD, Optocouplers and their

applications in the analog and digital devices.

Optical fiber fundamentals, Modes in optical fiber, Step index and graded index fibers, Fiber

coupling, OTDR, Fiber optic sensor for industrial applications, Displacement, Pressure,

Acceleration, Force, Velocity and Flow sensor, Fiber optic voltage and current sensor.

Holographic data systems, Memories and read out optical data processing fundamentals.

Reference books:

1. Optoelectronics and Introduction- Wilson and Hawkas, PHI.

2. Optical fibre communication- Senior, PHI.

3. Optical fibre sensors- Culshame and Dakim.

4. Semiconductor Optoelectronics- P. Bhattacherjee, PHI.

5. Optoelectronics and Fibre optic communication- Sarkar&Sarkar

PROJECT-I (IN73)

sessional :100 Viva:50

Course Outcomes: Upon successful completion of the course, students should be able to:

CO1 Survey research literature of relevant fields of engineering.

CO2 Design solutions for selected project problem.

CO3 Show leadership quality during the execution of the project.

CO4 Develop communication skills and team work.

CO5 Apply engineering knowledge for sustainable development of the society.

CO-PO MAPPING:

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 2 3

CO

2 3 3 3 3 3

CO

3 3 2 2

CO

4 3

CO

5 3 3

7th SEMESTER B.E (ELECT. & INST.)

THEORY: 100

SESSIONAL:50

SYLLABUS FOR (ELECTIVE-I)

BIOMEDICAL INSTRUMENTATION(IN72)

L-3 T-1 P-0

Course Objective:

To provide basic concepts of biomedical instrumentation.

Course Outcomes: On Completion of this course the students should be able to

Os Course Outcomes Level

CO1 Explain the role of biopotential electrodes. L2

CO2 Outline different Cardiovascular measurement techniques. L2

CO3 Outline different electroencephalography and Electromyography

instrumentation.

L2

CO4 Illustrate different respiratory system measurement. L2

CO5 Analyse different clinical instruments. L2

CO6 Explain different medical imaging and diagnosis techniques. L2

Mapping of Course outcome and Programme outcome and Programme Specific Outcome:

1. INTRODUCTION : Introduction to the physiology of cardiac, nervous , mascular &

respiratory systems.

2. TRANSDUCERS & ELECTRODES : Different types of transducers and their

selections for biomedical applications ; Electrode theory ; Different types of

electrodes – Hydrogen , Colomel, Ag-Agcl , pH , PO2 , PCO2 electrodes ; Selection of

electrodes.

3. CARDIOVASCULAR MEASUREMENT : The heart and other cardiovascular

systems ; Measurement of blood pressure ; Blood flow cardiac output and cardiac rate

Course

Outcome

Programme Outcome PS01 PS02

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1 3 - 1 - - 2 - 2 - - - 1

1

CO2 3 - 1 - - 2 - 2 - - - 1

CO3 3 - 1 - - 2 - 2 - - - 1

CO4 3 - 1 - - 2 - 2 - - - 1

CO5 3 - 1 - - 2 - 2 - - - 1

CO6 3 - 1 - - 2 - 2 - - - 1

; Electrocardiography ; Phonocardiography ; Ballistocardiography ; Plethysmography

; Magneto-cardiography ; Cardiac pacemaker ; Computer applications.

4. MEASUREMENT OF ELECTRICAL ACTIVITIES IN MUSCLES & BRAIN:

Electromyography ; Electroencephalograph & their interpretation ; Respiratory system

measurement ; Respiratory mechanism ; Measurement of gas volume & Flow rate ;

Carbon dioxide & Oxygen concentration in inhaled air ; Respiratory controller.

5. INSTRUMENTATION FOR CLINICAL LABORATORY : Measurement of pH

values of blood ; ESR measurement ; Haemoglobin measurement ; Measurement of

oxygen & carbon dioxide concentration in blood ; GSR measurement ; Polarographic

measurements ; Computer applications.

6. MEDICAL IMAGING : Ultra sound imaging ; Radiography & applications .

7. BIOTELEMETRY : Transmission & reception aspects of biological signals via long

distance ; Aspect of patient care monitoring.

Reference Books :

1. Webster JS – Medical Instrumentation Applications & Design

2. Cromwell L – Biomedical Instrumentation (PHI)

3. Khandpur RS – Hand Book of Biomedical Instrumentation (TMH)

4. Astor BR – Introduction to Biomedical Instrumentation & Measurement (Mc Millan )

SYLLABUS FOR (ELECTIVE-I)

THEORY:100

SESSIONAL:50

DIGITAL IMAGE PROCESSING(CS726)

1) Introduction: Digital image representation, fundamental steps in image processing,

elements of image processing systems, geometry of image formation, image acqusition, color image sensing, stereo imaging, range sensing, tesselation,

sampling and

quantization.

2) Image tranforms: Fourier, Walsh, Hadamard, Discrete Cosine, Hotelling, Discrete Wavelet Transforms and their properties.

3) Image enhancement and restoration: Spatial and frequency domain enhancement

Techniques (Histogram based techniques, smoothing, filtering, sharpening, Homomorphic filtering), Unconstrained and Constrained Restoration, Inverse

filtering, Wiener filter.

4) Image compression: Coding, Interpixel and Psychovisual Redundancy; Image

compression models; Error free compression – Huffman, Arithmetic and LZW,

Bit-Plane coding ( Constant Area coding, 1-D & 2-D Run length coding ),

Lossless predictive coding; Lossy compression – Lossy predictive coding ( Delta

modulation, Optimal predictors – Differential Pulse Code Modulation), Transform

coding – ( Discrete Fourier Transform, Walsh-Hadamard Transform, Discrete

Cosine Transform, and Discrete Wavelet Transform methods ), Sub-image size

selection, Bit Allocation, Zonal & Threshold coding, Image compression

standards – CCITT Group 3 & 4 Binary Image 1-D & 2-D Compression

standards, JPEG using DCT & DWT Continuous Tone Still Image Compression

standard, Basics of MPEG Video Compression standard.

5) Digital geometry and its application in image processing:

Neighbourhood, connectedness, path, holes and surroundness, Borders,

distances, Medial axis transformation, shrinking and expanding, thinning,

Morphological operations- Erosion, Dilation, Opening, Closing, Parallel

implementation, Smoothing, Component labelling, Thinning.

Image segmentation: Edge detection – Roberts, Prewitt, Sobel & Laplacian

Operators, Edge linking and Boundary Detection – Local Processing, Global

Processing via the Hough Transform to detect straight lines and parameterised

curves, Global Processing via Graph-Theoretic Techniques; Pixel Classification

via Grey Level Thresholding – Optimal Global and Adaptive Thresholding,

Multispectral Thresholding; Region based segmentation- Region growing, Region

splitting & merging; Segmentation by Morphological Watersheds; Use of motion

in segmentation; Frequency domain techniques.

6) Representation and Description: Representation – Chain codes, Polygonal

Approximations, Signatures, Boundary Segments, Skeletons; Boundary

Descriptors – length, diameter, major axis, minor axis, basic rectangle,

eccentricity, curvature, shape numbers; Fourier Descriptors; Statistical Moments;

Regional Descriptors – area, perimeter, compactness, etc.; Topological

Descriptors- number of holes, connected component, Euler number, Euler

formula; Texture – statistical, structural and spectral description; Moments of Two

dimensional functions; Use of Principal Components for Description; Relational

Descriptors.

Reference Books:

1) Digital Image Processing- R C Gonzales and R E Woods.

2) Fundamental Of Digital Image Procassing- Anil K Jain,PHI.

3) Computer Vision- D H Ballard and C M Brown.PHI.

SYLLABUS FOR (ELECTIVE-I)

ELECTRONIC INSTRUMENTATION(IN74)

THEORY: 100

SESSIONAL:50

Instrumentation amplifiers and their applications; Active filter & their

design consideration ; Transducer oscillators; Function generators; Regulated

power supply; DAC & ADC – different types ,quantization error, resolution &

accuracy of DAC & ADC ; DAC & ADC chips; Multiplexing & demultiplexing;

PLL & V-F converters; Lock-in amplifier & its applications; Automated

voltmeter; Digital frequency meter; R.M.S detector, Digital multimeter; Wave &

spectrum analyser; Harmonic distortion analyser; Hetrodyne frequency meter;

Recorders of different types.

Ref. Books:

1) Modern Electronic Instrumentation & Measurement Techniques-Helfric

A D & Cooper W.D (PHI)

2) Digital Measurement Techniques –Rathore T. S (Narosa)

3) Microelectronics: Digital & Analog Circuit & Systems –Millman (Mc

Grow Hill)

SYLLABUS FOR

(ELECTIVE-1)

ADVANCED COMMUNICATION(EE735)

Theory :100 Sessional :50

1) DIGITAL DATA TRANSMISSION:

Review of sampling & quantization, Timing & synchronization ,.Base band data

transmission & reception, Binary matched filter ,

ASK,FSK,PSK,QASK,QPSK,MSK. Error probability . Digital system design

consideration .

2) INFORMATION THEORY:-

Information content of a signal, Information rate, Shannon’s Capacity theorem,

Channel capacity, Shannon Limit , Coding , Entropy coding , Error detection &

correction coding, Parity check coding , Block code , Algebraic codes,

convolutional codes, ARQ, Optimum modulation system.

3) TELEPHONE SYSTEM:-

Telephone exchange , automatic strowger dialing , Hierarchy of switching offices

, Cross bar switch , switching matrices, Multiple Stage switching , TDM in

telephone, time slot interchanging , Space array for digital signals, combined

space & time switching , mobile phone, cellular phone , pager , global positioning

satellites, fax, videotext.

4) COMPUTER COMMUNICATION SYSTEMS:-

Design features of computer communication networks , LAN , packet radio &

satellite , TDMA, FDMA , ALOHA , CSMA, computer communication protocols,

the various layers.

5) Microwave SYSTEMS:

Rectangular and circular wave guide, wave guide coupling, Cavity resonators,

Directional couplers, Isolators, Circulators, Mixers, Detectors switches,

Microwave tubes- microwave triodes, Klystron, Magnetron, Travelling wave

tube, Cross field amplifier, Backward wave oscillators; Semiconductor

microwave devices- Passive microwave components, microwave transistors,

microwave IC’s, varactor diodes, step recovery diodes, Parametric amplifier,

Tunnel diode, Gunn effect diode, TRAPATT diodes, PIN diodes, Shottkey

barrier diode, Backward diode, MASERS & LASERS , Introduction to optical

communication.

5) RADAR SYSTEMS :

Introduction , Pulsed RADAR, MTI, RADAR beacons, CW doppler

RADAR, FM RADAR, Phased array RADAR, Planar array RADAR.

6) TELEVISION FUNDAMENTALS:

TV systems and standards , B/W TV transmission and reception, Colour TV.

Ref. Books:

1) Principles of Communication Systems- Taub & Schilling

2) Analog and Digital Communication Systems – Martin S Roden

3) Electronic Communication Systems- George Kennedy

4) Principle of RADAR – Meril Skolnik.

Semester-VIII

Sl.

No

SAR

Code

Course

Code

Course Title Theory Sessional Viva

1 C407 EE-81 Automatic Control Systems 100 50 -

2 C408 IN-81 Process Modelling andControl 100 50 -

3 C409 IN-82 Digital Signal Processing 100 50 -

4 C410 IN-83 Elective-II 100 50 -

5 C411 IN-84 Project-II - 150 50

6 C412 IN-85 General Viva-Voce - - 100

Elective-II:

6. Data Communication & Networks (EE-84)

7. Robotics and Applications (ME-89)

8. Environmental Monitoring & Control (IN-83)

9. Computer Control Systems (EE-86)

10. Non-destructive Testing (IN-85)

AUTOMATIC CONTROL SYSTEMS(EE81)

Theory:100 Sessional : 50

L-3 T-3 P-3

CO1: Analyze characteristics of physical systems with mathematical model.

CO2: Analyze different systems using time and frequency domain techniques.

CO3:Illustrate the design of control system using both time and frequency domain

techniques.

CO4: Show the state space modelling of different systems.

CO P

O1

P

O2

P

O3

P

O4

P

O5

P

O6

P

O7

P

O8

P

O9

PO

10

PO

11

PO

12

PS

O1

PS

O2

CO1 3 3 3 3

CO2 3 3 2 3

CO3 3 2 2 2 3

CO4 3 2 2 3

AVERA

GE 3 2.5 2 2 3 3

1) Introduction : Concept of automatic control systems; classifications- open loop

and closed loop systems, linear and non linear systems, continuous and discrete

time systems, SISO and MIMO systems, time-invariant and time varying

systems, servo systems and automatic regulating systems, adaptive control

systems.

2) Block diagram and signal flow graphs: Block diagram representation of physicalsystems,BDreductiontechniques;signalflowgraph(SFG):defination,terminoloy

,SFG representation of physical systems, Mason’s Gain formula, BD reduction using

SFG techniques.

3) Mathematical modelling of physical systems: Differential equations and

transfer function form of model, mathematical model of electrical, mechanical and electro mechanical systems, analogous systems,

4) Transient response analysis: Type and order of systems, standard test signal, steady state error and error constants, generalized error series, sensitivity, characteristic equation, transient response of 1st,2nd and higher order systems, transient response specifications, definition of absolute and relative stability, Routh-Hurwitz stability criterion.

5) Root locus method: Introduction, angle and magnitude conditions, construction of complete root locus, stability analysis, effect of addition of poles and zeroes.

6) Frequency response analysis: Frequency response of systems, frequency domain specifications, correlation between time domain and frequency domain specification, Polar plot, Nyquist plot and Nyquist stability criterion, construction of Bode plot, Gain margin &Phase margin, minimum and non minimum phase transfer function, determination of transfer function from Bode plot, magnitude vs phase angle plot, constant-M& constant-N circles, Nichol’s chart.

7) Designandcompensationtechniques:Preliminarydesignconsiderations,lead,lag,& lag-lead compensation techniques based on Root locus and Bode plot method.

8) State space method of system analysis: Concept of state and state variables, state model, state-space representation of physical systems, BD representation, state transition matrix and its properties, relation between state equation and transfer function, solution of state equation, characteristic equation, eigen values & eigen vectors, concept of controllability and observability of linear systems, Liapunov stability analysis of time invariant systems.

9) Control system components: Potentiometer, Synchros, DC and AC servomotors, rotating amplifier, stepper motor, tachogenerators.

Ref.Books:

1) Ogata K-Modern Control Engg(PHI).

2) Nagrath I J&Gopal M-Control System Engg.

3) Kuo B C-Automatic Control Systems(PHI).

4) Distefano-Feedback and Control Systems(Schaum Series).

5) Sukla R C –Control Systems(Dhanpat Rai&Sons).

6) M.Gopal – Control Systems –Principles & Design (TMH)

8th SEMESTER B.E (INSTRUMENTATION)

PROCESS MODELLING AND CONTROL(IN81)

Theory: 100 Sessional:50

L-3 T-3 P-3

Course Objective:

To provide basic concepts of process control used in industries.

Course Outcomes: On Completion of this course the students should be able to

COs Course Outcomes Level

CO1 Develop Mathematical modelling of various physical systems. L3

CO2 Apply control actions e.g. P, PI, PD and PID in process control. L3

CO3 Illustrate different controller tuning methods. L2

CO4 Apply multi loop control systems , PLC and DCS in process automation L3

CO5 Explain different types of control valves for various industrial applications. L2

Mapping of Course outcome and Programme outcome and Programme Specific Outcome:

1) Introduction : Definition of process & process control systems; Objectives & requirements;

Classification & selection of process variables; Sources &nature of disturbances; hardware

elements of process control systems.

2) Modelling of physical systems: Mathematical model of physical systems-liquid level

system, thermal system, mixing process, CSTR, pressure system, flow system etc; interacting

and non interacting systems, RLC elements in process, linerization of non linear systems.

3) Transient response analysis: Response of first and second systems due to load change at

arbitrary points with P,I,P-I and P-I-D controllers; transient response specifications, effect of

time delay and measurement lag on system response.

4) Controllability and stability: Concept of controllability, DRF &SR, stability analysis using

Routh’s criteria, Root locus, Bode plot, GM &PM, system controllability using Bode plot.

5) Control action and controllers: On-Off,P,I,D,PI,PD and PID control actions; pneumatic,

hydraulic and electronic controllers; programmable controller.

6) Design of feed back controllers: Selection criterion for type of controllers, controller

tuning-process reaction curve, Zeigler-Nichol’s method, Cohen and Coon method and

frequency domain method.

Course

Outcome

Programme Outcome PS01 PS02

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10 PO11 PO12

CO1 3 2 - - - - - - - - - - 3 3

CO2 3 - 2 - - - - - - - - 3 - -

CO3 3 - - - - - - - - - - 3 - -

CO4 - 2 3 - - - - - - - - 3 - -

CO5 2 - - - - - - - - - - - - -

7) Multi loop control systems: Cascade control, override control, split-range control, feed-

forward control and ratio control systems.

8) Control valve: Construction and working principle, valve sizing, valve plug, valve

characteristics, selection of control valve, valve positioners.

9) Computer control of processes: Control computer-Basic functions and specifications,

hardware elements, data acquisition and control, direct digital control, supervisory control,

distributed control systems.

Ref. Books:

1) Stephinopoulos G- Chemical process control (PHI).

2) Pollard A –Process control.

3) Coughanowr – Process System Analysis and Control (MH).

4) Hariot P-Process Control (TMH).

5) Johnson-Process Control Instrumentation Technology (JW).

8th SEMESTER B.E ( INST. )

THEORY: 100 SESSIONAL:50

SYLLABUS FOR

DIGITAL SIGNAL PROCESSING(IN82)

L-3 T-1 P-0

CO P

O1

P

O2

P

O3

P

O4

P

O5

P

O6

P

O7

P

O8

P

O9

PO

10

PO

11

PO

12

PS

O1

PS

O2

CO1 3 2 1 1 1 2 2

CO2 3 2 1 1 1

CO3 3 2 1 1 1

CO4 3 2 1 1 1

AVERA

GE 3 2 1 1 1 2 2

8. Introduction : Introduction to signals, systems & signal processing ; Classification of signals ; Concept of frequency in continuous-time and

discrete-time signals ; Analog to digital and digital to analog converters from

signal processing view point ; Linear time-invariant systems.

9. Z-Transforms : Definitions & properties ; Inverse Z-transforms ; Transfer

functions ; Unit sample response ; Difference equations ; Basic network structure for IIR & FIR systems.

10. Discrete Fourier Transform (DFT) : Fourier transform of discrete-time

signals ; Fourier series representation of discrete-time signal ; Sampling theorem ; Discrete Fourier transform and its properties ; Filtering of long data

sequences.

11. Coputational Methods of DFT : Fast Fourier Transform (FFT) ; Decimation

in time and decimation in frequency radix-2 FFT algorithms ; In-place computations and bit-reversing rules ; Parallel & pipeline processing of FFT

radix-2 algorithms ; Efficient computation of the DFT of two real sequences ;

Efficient computation of DFT of the DFT of a 2N-point real sequence.

12. FIR Digital Filters : Properties , window, frequency sampling and computer aided design of filter design.

13. IIR Digital Filters : Properties, impulse invariance and bilinear and matched Z-transform methods og filter design.

14. Linear Prediction and Optimum Linear Filters : Representation of

stationary random process ; Relation power spectra ; Relationship between the

filter parameters and the Auto correlation sequence ; Forward and backward

linear prediction ; Solution of normal equations by Levinson Durbin algorithm

; Properties of Linear prediction – error filter ; AR lattice & ARMA lattice-

ladder filters ; FIR & IIR Wiener filters ; Orthogonality principle in linear

mean-square estimation ; Non-casual Wiener filter.

REFERENCES :

4. Digital Signal Processing-Principles, Algorithms & Applications

– John G. Manolakis ( PHI )

5. Digital Signal Processing – Alan V. Oppenheim & Ronald W. Schafer (PHI)

6. Theory and Applications of Digital Signal Processing

– Lawrence R. Rabiner & Bernard Gold ( PHI )

PROJECT-II (IN84)

sessional :150 Viva:50

Course Outcomes: Upon successful completion of the course, students should be able to:

CO1 Survey research literature of relevant fields of engineering.

CO2 Design solutions for selected project problem.

CO3 Show leadership quality during the execution of the project.

CO4 Develop communication skills and team work.

CO5 Apply engineering knowledge for sustainable development of the society.

CO-PO MAPPING:

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2 2 3

CO

2 3 3 3 3 3

CO

3 3 2 2

CO

4 3

CO

5 3 3

General Viva Voce (IN85)

Viva:100

Course Outcomes: Upon successful completion of the course, students should be able to:

CO1 Explain the basic concepts of topics studied in Instrumentation

Engineering Programme.

CO2 Show overall technical knowledge and industry readiness.

CO3 Develop interpersonal skills and presentation skills.

CO4 Demonstrate professional ethics.

CO PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO1

0

PO1

1

PO1

2

PSO

1

PSO

2

CO

1 3 2

1 2 3

CO

2 3 2 2 1

CO

3 3 2

CO

4 3 2

SYLLABUS FOR (ELECTIVE-II)

ENVIRONMENTAL MONITORING AND CONTROL(IN83)

THEORY: 100

SESSIONAL: 50

Course Objective:

To provide sound knowledge about various causes and monitoring methods of air and water

pollution.

Course Outcomes: On Completion of this course the students should be able to

COs Course Outcomes Level

CO1 Explain the working principles of different environmental

pollution detecting and monitoring methods.

1

CO2 Compare different water pollution monitoring instruments. 1

CO3 Summarize the sources of noise and its effect on human being. 2

CO4 Explainthe sources, types and monitoring methods of industrial

pollution.

2

Mapping of Course outcome and Programme outcome and Programme Specific Outcome:

Course

Outcome

Programme Outcome PS01 PS02

1 2 3 4 5 6 7 8 9 10 11 12

CO1 2 2 1 3 1

CO2 2 1 1 3

CO3 2 1 1 3

CO4 2 1 1 3

1. Air Pollution Monitor: Environment pollution monitoring classification- Air pollution &

their effect on human beings and environment- methods of detecting & monitoring using

conductometry, coulometry, electrochemical cell method; piezo electric oscillation

method; paper tape method; optical laser method; Air pollution monitoring instruments;

Laser instruments for monitoring environment.

2. Water Pollution Monitoring: Water pollution & their effect on environment-Health

hazards; Basic technique of detection, monitoring ;spectrometric method –Emission

spectrography, atomic absorption spectrophotometry, absorption photometry; marine

pollution monitoring; polarography; chromatographic method; Water pollution

monitoring instruments.

3. Noise Pollution & Measurement: The effect of noise on human beings and environment;

various sources of noise; Methods to reduce the noise; Method of measurement.

4. Solid Pollution & Measurement: Industrial solid pollution pesticides- their effect on

agricultural product; methods for reduction ; methods of measurement; Industrial

pollution & their monitoring; Industrial pollutant; Industrial wastes; Health hazards; -

monitoring, incineration ,ecological balance; Pollution abatement in core sector

industries.

Ref.Books:

1. Air Pollution (Vol-3) –Arthur C Stern (Ed), Academic Press.

2. Pollution Control in Process Industries – Mahajan S P (TMH)

3. Environmental Engg. Handbook (Vol-1,2 &3) , Chilton– Liptak B G (Ed)

8TH SEMESTER B.E (ELECT. & INST.)

THEORY: 100

SESSIONAL:50

SYLLABUS FOR (ELECTIVE –II)

COMPUTER CONTROL SYSTEMS(EE86)

L-3 T-1 P-0

Introduction to Computer Control Theory; Sampling of continuous time

signals; Sampling mechanism and Sampling theorems; Reconstruction of sampling

waves; Choice of sampling period; Computer oriented mathematical models-

Difference Equations,Z-transform, Pulse transfer function, inverse Z-transform,

Sampling of Continuous time state-space model; Response of linear discrete time

systems; Analysis of simple feed back systems; Stability analysis; Design and

compensation Techniques of discrete time systems.

Ref. Books:

1) Digital Control Engineering- Modon Gopal.(WI)

2) Digital Control System – B.C Kuo.

3) Computer Control Systems- K.J Astrom & B. Wittenmark (PHI)

4) Digital and Sampled Data Control Systems – J.T Tou.

8TH SEMESTER B.E ( INST.)

THEORY: 100 SESSIONAL:50

SYLLABUS FOR (ELECTIVE –II)

NON-DESTRUCTIVE TESTING(IN85)

L-3 T-1 P-0

Introduction and importance of NDT; General principle and basic elements of NDT; Liquid penitrant method ;Optical method (Laser Holography) ; Thermography ; Ultrasonic testing method ; Radiological methods- X-ray, Gamma ray , Tomography.

Ref. Books:

1) Non-destructive Testing Handbook – American Society for NDT, 1989.

2) Non-Destructive Testing – Hull .B & John . V (ELBS / Mc-Millan)