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CURRICULA AND SYLLABI FOR EACH OF THE
PROGRAMMES AS APPROVED BY THE UNIVERSITY.
B.E. Semester-I
HUM-101-E ESSENTIALS OF COMMUNICATION
(COMMON FOR ALL BRANCHES)
L T P Class Work :
50 Marks
3 1 - Exam. :
100 Marks
Total :
150 Marks
Duration of Exam:
3 Hrs
The course aims at inculcating a minimum level of language proficiency
among students of Engineering and Technology. The purpose is to
sensitise them to the nuances of English and its applications for
various communication needs.
COURSE CONTENT:
Unit-I
Semantics: Synonyms, Antonyms, Homophones, Homonyms, Form and function
of words
Unit-II
Syntax: Sentence structures, Verb patterns and their usage
Unit-III
Phonetics: Basic Concepts – Vowels, Consonants, Phonemes, Syllables;
Articulation of Speech Sounds – Place and Manner of Articulation;
Transcription of words and simple sentences, using International
Phonetic Alphabet.
Unit-IV
Comprehension: Listening and Reading comprehension – Note taking,
Reviewing, Summarising, Interpreting, Paraphrasing and Précis Writing.
Unit-V
Composition: Descriptive, Explanatory, Analytical and Argumentative
Writing - description of simple objects like instruments, appliances,
places, persons, principles; description and explanation of processes
and operations; analysis and arguments in the form of debate and group
discussion
Unit-VI
Text: English for Students of Science by A.Roy and P.L. Sharma (Orient
Longman)
Chapters for Study:
i) "The year 2050" by Theodore J. Gordon.
ii) "The Mushroom of Death" by A. Bandhopadhyay.
iii) "The Discovery" by Herman Ould.
The prescribed text will be used as a case study for various components
of the syllabus.
Unit-VII (For Internal Evaluation Only):
Book Review – Herein the students will be required to read and submit a
review of a book (Literary or non-literary) of their own choice. This
will be followed by a presentation of the same in the class.
MATH-101-E MATHEMATICS-I
---------- -------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 50
Marks
3 2 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hours
Part-A
Infinite series : Convergence and divergence,
Comparison, D' Alembert's ratio, Integral, Raobes,
Logrithmic and Cauchy root tests, Alternating series,
Absolute and conditional convergence.
Applications of Differentiation : Taylor's and
Maclaurin's series, Asymptotes, Curvature Asymptotes.
Partial Differentiation & its Applications :
Functions of two or more variables; partial
derivatives, Total differential and differentiability,
Derivatives of composite and implicit functions,
Jacobians, Higher order partial derivatives.
Homogeneous functions, Euler's theorem, Taylor's
series for functions of two variables (without proof),
maxima-minima of function of two variables, Lagrange's
method of undetermined multipliers, Differentiation
under integral sign.
Part-B
Applications of Single & Multiple Integration :
Applications of single integration to find volume of
solids and surface area of solids of revolution.
Double integral, change of order of integration,
Double integral in polar coordinates, Applications
of double integral to find area
enclosed by plane curves and volume of solids of
revolution.
Triple integral, volume of solids, change of
variables, Beta
and gamma functions and relationship between them.
Vector Calculus : Differentiation of vectors,
scalar and vector point functions Gradient of a
scalar field and directional derivative, divergence and
curl of a vector field and their physical
interpretations.
Integration of vectors, line integral, surface
integral,
volume integral, Green, Stoke's and Gauss theorems
(without
proof) and their simple applications.
PHY-101-E : PHYSICS-I (COMMON FOR ALL
BRANCHES)
--------- --------------------------------
---
L T P Sessional : 50
Marks
3 1 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hrs.
PART-A
PHYSICAL OPTICS
Interference : Division of wave front-Fresnel's
biprism,
Division of amplitude – Newton's rings, Michelson
interferometer, applications.
Diffraction : Difference between Fraunhofer and
Fresnel
diffraction. Fraunhofer diffraction through a slit.
Plane
transmission diffraction grating, its dispersive and
resolving
powers.
Polarization : Polarised and unpolarized light,
double
refraction; Nicol prism, quarter and half wave
plates,
Polarimetry; Biquartz and Laurent's half-shade
polarimeters,
Simple concepts of photoelasticity.
LASER
Spontaneous and stimulated emissions, Laser
action,
characteristics of laser beam-concepts of coherence, He-
Ne and
semiconductor lasers (simple ideas), applications.
FIBRE OPTICS
Propagation of light in fibres, numerical aperture,
single
mode and multi mode fibres, applications.
PART-B
WAVE AND OSCILLATIONS
Simple concepts of Harmonic Oscillator, resonance,
quality factor.
E.M. wave theory-review of basic ideas, Maxwell's
equations, simple plane wave equations, simple concepts of
wave guides and co-axial cables, Poynting vector.
DIELECTRICS
Molecular theory, polarization,
displacement,susceptibility, dielectric coefficient,
permitivity & various relations between these, Gauss's
law in the presence of a dielectric, Energy stored in
an electric field.
Behaviour of dielectrics in a.c. field-simple
concepts,
dielectric losses.
SPECIAL THEORY OF RELATIVITY
Michelson-Moreley experiment, Lorentz
transformations, variation of mass with velocity, mass
energy equivalence.
NUCLEAR PHYSICS
Neutron Cross-section, Nuclear fission, Moderators,
Nuclear
reactors, Reactor criticality, Nuclear fusion.
Interaction of radiation with matter-basic concepts,
radiation detectors-ionisation chamber, G.M. Counter,
Scintillation and solid state detectors, cloud chamber
and bubble chamber.
BE 1 / II Semester.
ME- 103 E MANUFACTURING PROCESSES
L T P Class Work
: 50 Marks
4 - - Examination
: 100 Marks
Total
: 150 Marks
Duration of Exam
: 3 Hrs.
Unit I Introduction: Introduction to Manufacturing Processes and their
Classification. Industrial Safety; Introduction, Types of Accidents, Causes
and Common Sources of Accidents, Methods of Safety, First Aid.
Unit II Engineering Materials: General Properties and Applications of
Engineering Materials, Mild Steel, Medium Carbon Steel, High Carbon
Steel, High Speed Steel and Cast Iron.
Unit III Foundry: Introduction to Casting Processes, Basic Steps in Casting
Process, Pattern, Types of Patterns, Pattern Allowances, Risers, Runners,
Gates, Moulding Sand and its composition, Sand Preparation, Molding
Methods, Core Sands and Core Making, Core Assembly, Mold Assembly,
Melting ( Cupola) and Pouring, Fettling, Casting Defects and Remedies.
Unit IV Cold Working ( Sheet Metal Work ): Sheet Metal Operations, Measuring,
Layout Marking, Shearing, Punching, Blanking, Piercing, Forming,
Bending and Joining Advantages and Limitations.
Hot Working Processes: Introduction to Hot Working, Principles of Hot
Working Processes, Forging, Rolling, Extrusion, Wire Drawing..
Unit V Introduction to Machine Tools: Specifications and Uses of commonly
used Machine Tools in a Workshop such as Lathe, Shaper, Planer,
Milling, Drilling, Slotter, Introduction to Metal Cutting. Nomenclature of
a Single Points Cutting Tool and Tool Wear. Mechanics of Chips
Formations, Type of Chips , Use of Coolants in machining.
Unit VI Welding: Introduction to Welding, Classification of Welding Processes,
Gas Welding: Oxy-Acetylene Welding, Resistance Welding; Spot and
Seam Welding, Arc Welding: Metal Arc, TIG & MIG Welding, Welding
Defects and Remedies, Soldering & Brazing.
Unit VII Plant Layout, Objectives of Layout, Types of Plant Layout and their
Advantages.
CH-101-E : CHEMISTRY (COMMON FOR ALL
BRANCHES)
-------- --------------------------------
---
L T P Sessional : 50
Marks
3 1 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hrs.
Unit-1 :
Thermodynamics - Second law, concept of Entropy,
Entropy
change for an ideal gas, free energy and work
functions, Free
energy change, Chemical Potential, Gibb's Helmholtz
equation, Clausius - Clapeyron equation, Related
numerical problems with above topics.
Unit-2 :
Phase-Rule - Terminology, Derivation of Gibb's
Phase Rule
Equation, One Component System (H2O System), Two
Components systems, Eutectic system (Pb-Ag), system with
congruent m.pt. (Zn-Mg), systems with incongruent
m.pt. (Na-K), Applications of above Systems.
Unit-3 :
Water & its treatment : Part I – Sources of water,
impurities in water, hardness of water and its
determination, units of hardness, alkalinity of water and
its determination, Related numerical problems, scale and
sludge formation (composition properties and methods of
prevention).
Unit-4 :
Water and its treatment : Part II – Treatment of
water for domestic use, coagulation, sedimentation,
filtration and dis-infection, water softening, Ion-
exchange process, mixed bed demineralisation, Desalination
(reverse osmosis) (electrodialysis).
Unit-5 :
Corrosion and its prevention - Galvanic &
concentration cell, Dry and wet corrosion,
Electrochemical theory of corrosion, Galvanic
corrosion, pitting corrosion, water-line corrosion,
differential aeration corrosion, stress corrosion,
factors affecting corrosion, Preventive measures (proper
design, Cathodic protection, protective coatings).
Unit-6 :
Lubrication and Lubricants - Friction,
mechanism of
lubrication, classification and properties of
lubricants,
Additives for lubricants, synthetic lubricants, Greases –
Preparation & properties (consistency, drop point) and
uses.
Unit-7 :
Polymers and Polymerization - Organic
polymers,
polymerisation, various types of polymerisation,
effect of
structure on properties of polymers, preparation
properties and
technical applications of thermo-plastics (PVC,PVA),
thermosets
(PF,UF), and elastomers (SBR,GR-N), Silicones,
Introduction to polymeric compsites.
Unit-8 :
Analytical Methods - Thermal methods, Principle,
method and
application of Thermogravimetric analysis, Differential
thermal
analysis and Differential scanning calorimetry ,
(Experimental details are excluded),Spectroscopic
methods, Spectrophotometry, interaction of E.M.
radiations with a molecule and origin of spectrum,
spectroscopic, techniques-vibrational and electronic
spectroscopy (Experimental details are excluded),
conductometric titration, elementary discussion on Flame-
photometry.
CSE -101 E Fundamentals of Computers & Programming in C
L T P Class Work: 50
3 - - Exam:
100
Total:
150
Duration of
Exam: 3 Hrs.
Unit-1: An Overview of Computer System: Anatomy of a digital Computer, Memory Units,
Main and Auxiliary Storage Devices, Input Devices, Output Devices, Classification of
Computers.
Radix number system: Decimal, Binary, Octal, Hexadecimal numbers and their inter-conversions;
Representation of information inside the computers.
Unit-2: Operating System Basics: The user Interface, Running Programmes, Managing files,
Introduction to PC operating Systems: Unix/Linux , DOS, Windows 2000.
Unit-3: Internet basics: : Introduction to the basic concepts of Networks and Data
Communications, How Internet works, Major features of internet, Emails, FTP, Using the
internet.
Unit-4: Programming Languages: Machine-, Assembly-, High Level- Language, Assembler,
Compiler, Interpreter, debuggers, Programming fundamentals: problem definition, algorithms,
flow charts and their symbols, introduction to compiler, interpreter, assembler, linker and loader
and their inter relationship.
Unit-5: C Programming language: C fundamentals, formatted input/ output, expressions,
selection statements, loops and their applications; Basic types, arrays, functions, including
recursive functions, program organization: local and external variables and scope; pointers & arrays.
Unit-6: Strings: strings literals, string variables, I/O of strings, arrays of strings; applications.
Preprocessor: preprocessor directives, macro definition, conditional compilation; Structures, Unions
and Enumerations: Structure variables and operations on structures; Structured types, nested
array structures; unions; enumeration as integers, tags and types.
Declaration: Declaration syntax, storage classes, types qualifiers, declarators, initializers.
Program Design: modules, information hiding, abstract data types, difference between C & C++,
Low level programming: Bitwise operators, Bit fields in structures, other low level techniques.
Unit-7: Standard library: Input / output; streams, file operations, formatted I/O, character I/O,
line I/O, block, string I/O, Library support for numbers and character data, error handling:
EE-101-E ELECTRICAL TECHNOLOGY
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT1. D.C. CIRCUITS :
Ohm‟s Law, Kirchoff‟s Laws, D.C. Circuits, Nodal and Loop methods of analysis.
UNIT2.
a) A.C. CIRCUITS :
Sinusoidal signal, instantaneous and peak values, RMS and average values, phase
angle, polar & rectangular, exponential and trigonometric representations; R,L and C
components, behaviors of these components in A.C. circuits. Concept of complex power,
power factor.
b) TRANSIENT RESPONSE :
Transient response of RL, RC and RLC Circuits with step input.
UNIT3. NETWORK THEOREMS :
Thevenin‟s theorem, Norton‟s theorem, superposition theorem, maximum power
transfer theorem, Reciprocity theorem, Tellegen‟s theorem, Milman's theorem. Star to
Delta & Delta to Star transformation.
UNIT4. SERIES AND PARALLEL A.C. CIRCUITS :
Series and parallel A.C. circuits, series and parallel resonance, Q factor, cut-off
frequencies and bandwidth.
UNIT5. THREE PHASE CIRCUITS :
Phase and line voltages and currents, balanced star and delta circuits, power
equation, measurement of power by two wattmeter method, Importance of earthing.
UNIT6. TRANSFORMERS :
Principle, construction & working of transformer, Efficiency and regulation.
UNIT7. ELECTRICAL MACHINES :
Introduction to D.C. Machines, Induction motor, Synchronous machines.
UNIT8. MEASURING INSTRUMENTS :
Voltmeter, Ammeter, Watt meter, Energy meter.
GES-101-E ENVIRONMENTAL STUDIES
L T P
3 - - Exam. : 75 Marks
Total : 75 Marks
Duration of exam. : 3 Hours
UNIT – I The Multidisciplinary nature of environmental studies, Definition, scope
and importance.
Need for Public awareness
UNIT – II Natural Resources:
Renewable and non-renewable resources:
Natural resources and associated problems.
a) Forest resources: Use and over-exploitation: deforestation, case
studies, Timber exploitation, mining, dams and their effects and forests
tribal people.
b) Water resources: Use and over-utilization of surface and ground
water, floods, drought, conflicts over water, dams-benefits and problems.
c) Mineral resources: Use and exploitation, environmental effects of
extracting and using mineral resources, case studies.
d) Food resources: World food problems, changes, caused by
agriculture and overgrazing, effects of modern agriculture, fertilizer-
pesticide problems, water logging, salinity, case studies.
e) Energy resources: Growing energy needs, renewable and non-
renewable energy sources, use of alternate energy sources; case studies.
f) Land resources: Land as a resource, loand degradation, man
induced landslides, soil erosion and desertification.
Role of an individual in conservation of natural resources.
Equitable use of resources for sustainable lifestyles.
UNIT- III Ecosystems”
Concept of an ecosystem.
Structure and function of an ecosystem.
Producers, consumers and decomposers.
Energy flow in the ecosystem.
Ecological succession.
Food chains, food wbs and ecological pyramids.
Introduction, types, characteristic features, structure and function
of the following eco-system:
a) Forest ecosystem.
b) Grassland ecosystem.
c) Desert ecosystem.
d) Aquatic ecosystems (ponds, streams, lakes, rivers,
oceans, estuaries).
UNIT- IV Biodiversity and its conservations
Introduction – Definition: Genetic, species and ecosystem
diversity.
Biogeographically classification of India.
Value of biodiversity: consumptive use, productive use, social,
ethical, aesthetic and option values.
Biodiversity at global, National and local levels.
India as a mega-diversity nation.
Hot-spots of biodiversity.
Threats to biodiversity: habitat loss, poaching of wildlife, man-
wildlife conflicts.
Endangered and endemic species of India.
UNIT – V Environmental Pollution:
Definition, causes, effects and control, measures of:
a) Air pollution.
b) Water pollution.
c) Soil pollution.
d) Marine pollution.
e) Noise pollution.
f) Thermal Pollution.
g) Nuclear hazards
Solid waster management: Causes effects and control measures of
urban and industrial waster.
Role of an individual in prevention of pollution.
Pollution case studies.
Disaster management: Floods, earthquake, cyclone and landslides.
UNIT – VI Social issues and the Environment:
From unsustainable to sustainable development.
Urban problems related to energy.
Water conservation, rain water harvesting, watershed management.
Resettlement and rehabilitation of people; its problems and
concerns, case studies.
Environmental ethics: Issues and possible solutions.
Climate change, global warming, acid rain, ozone layer depletion,
nuclear accidents and holocaust, Case studies.
Wasteland reclamation.
Consumerism and waste products.
Environment Protection Act.
Air (Prevention and Control of Pollution) Act.
Water (Prevention and Control of Pollution) Act.
Wildlife Protection Act.
Forest Conservation Act.
Issues involved in enforcement of environmental legislation.
Public awareness.
UNIT – VII Human population and the Environment.
Population growth, variation among nations.
Population explosion – Famility Welfare Programme.
Environment and human health.
Human Rights.
Value Education.
HIV/ AIDS.
Woman and Child Welfare.
Role of Information Technology in Environment and human health.
Case Studies.
UNIT –VIII Field Work:
Visit to a local area to document environmental assets – river/
forest/ grassland/ hill/ mountain.
Visit to a local polluted site-Urban/ Rural/ Industrial/ Agricultural.
Study of common plants, insects, birds.
Study of simple ecosystems – pond, river, hill slopes, etc. (Field
work equal to 5 lectures hours).
.
ME- 101 E ELEMENTS OF MECHANICAL ENGINEERING
L T P Sessional : 50
Marks
3 1 - Theory : 100 Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
Unit I Properties of Steam & Boilers:
Formation of steam at constant pressure, Thermodynamics properties of steam, Condition
of steam, Steam tables, Measurement of dryness fraction by throttling calorimeter, Classification
of boilers, Comparison of water and fire tube boilers mounting and accessories with their
functions, Constructional and operational details of Cochran and Babcock and Wilcox boilers,
Problems.
Unit II Steam Turbines and Condensers:
Classification of turbines, Working principle of impulse and reaction turbine,
Compounding of impulse turbine, Comparison of impulse and reaction turbines, Types of
condensers, Cooling ponds and cooling towers, Condenser and vacuum efficiencies.
Unit III I.C. Engines and Gas Turbines:
Introduction, Classification, Constructional details and working of two-stroke and four-
stroke diesel and petrol engines, Otto, Diesel and Dual cycles, Working principle of gas turbine,
Constant pressure gas turbine cycle.
Unit IV Water Turbines, Pumps and Hydraulic Devices:
Introduction, Classification, Construction details and working of Pelton, Francis and
Kaplan turbines, Specific speed and selection of turbines, Classification of water pumps and their
working, Hydraulic jack and lift.
Unit V Simple Lifting Machines:
Definition of machine, Velocity ratio, Mechanical advantage, Efficiency, Laws of
machines, Reversibility of machine, Wheel and axle, Differential pulley block, Single, double and
triple start worm and worm wheel, Single and double purchase winch crabs, Simple and
compound screw jacks. Problems.
Unit VIPower Transmission Methods and Devices:
Introduction to Power transmission, Belt drive, Rope drive, Chain drive, Pulley, Gear
drive, Types of gears, Gear train, Clutches, Types and function of clutches, Types and function of
brakes, Power measurement by dynamometer, Types of dynamometers.
Unit VII Stresses and Strains:
Introduction, Concept & types of Stresses and strains, Poison‟s ratio, stresses and strains
in simple and compound bars under axial loading, Stress-strain diagrams, Hooks law, Elastic
constants & their relationships, Principle stresses & strains and principal- planes, Mohr‟s circle of
stresses. Numerical problems.
Unit VIII Bending Moment & Shear Force:
Definitions, SF and BM diagrams for cantilever and simply supported
beam. Calculation of maximum SF, BM and point of contra-flexure under
the loads of (i) concentrated load (ii) uniformly distributed load (iii)
combination of concentrated and uniformly distributed loads. Problems.
ME-105 E ENGINEERING GRAPHICS AND DRAWING
L T P Sessional : 50
Marks
- - 4 Practical : 100
Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
Unit I Various types of projections, First and Third angle systems of
orthographic projections. Projection of Points in different quadrants.
Unit II Projections of Straight Lines – parallel to one or both reference planes,
contained by one or both planes, perpendicular to one of the planes,
inclined to one plane but parallel to the other planes, inclined to
both the planes, true length of a line and its inclination with reference
planes, traces of a line.
Unit III Projections of Planes – parallel to one reference plane, inclined to
one plane but
perpendicular to the other, inclined to both reference planes.
Unit IV Projections of Polyhedra Solids and Solids of Revolution - in simple
positions with axis perpendicular to a plane, with axis parallel to
both planes, with axis parallel to one plane and inclined to the
other, Projections of sections of Prisms, Pyramids, Cylinders and Cones.
True shape of section. Development of surfaces of various solids.
Unit V Isometric projections - introduction, isometric scale, Isometric views of
plane figures, prisms, pyramids and cylinders.
Unit VI Orthographic drawings of Bolts and Nuts, Bolted Joints, Screw threads,
Screwed Joints.
Unit VII Free Hand Sketching - Orthographic Views from Isometric,
Views of Simple
Machine Components such as Brackets, Bearing Blocks , Guiding
Blocks and
Simple Couplings.
PHY-103-E : PHYSICS LAB.-I
--------- ------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 25
Marks
- - 2 Practical : 25
Marks
Total : 50
Marks
Duration of exam. : 3
Hours
LIST OF EXPERIMENTS
-------------------
The experiments in Ist semester will be based
mainly upon
optics, electrostatics, wave and oscillations which are
the parts
of the theory syllabus of Ist semester.
1. To find the wavelength of sodium light by
Newton's rings
experiment.
2. To find the wavelength of sodium light by Fresnel's
biprism
experiment.
3. To find the wavelength of various colours of white
light
with the help of a plane transmission diffraction
grating.
4. To find the refractive index and cauchy's constants
of a
prism by using spectrometer.
5. To find the wavelength of sodium light by
Michelson
interferometer.
6. To find the resolving power of a telescope.
7. To find the pitch of a screw using He-Ne laser.
8. To find the specific rotation of sugar solution by
using a
polarimeter.
9. To compare the capacitances of two capacitors by
De'sauty
bridge and hence to find the dielectric constant of a
medium.
10. To find the flashing and quenching potentials of
Argon and
also to find the capacitance of unknown capacitor.
11. To study the photoconducting cell and hence to
verify
the inverse square law.
12. To find the temperature co-efficient of resistance by
using
platinum resistance thermometer and Callender and
Griffith
bridge.
13. To find the frequency of A.C. mains by using
sonometer.
14. To find the velocity of ultrasonic waves in non-
conducting
medium by piezo-electric method.
ME- 107 E WORKSHOP PRACTICE
L T P Class Work
: 25 Marks
- - 4 Examination
: 25 Marks
Total
: 50 Marks
Duration of
Exam : 3 Hrs.
List of Experiments / Jobs
1. To study different types of measuring tools used in metrology and determine
least counts of vernier calipers, micrometers and vernier height gauges.
2. To study different types of machine tools ( lathe, shape or planer or slotter,
milling, drilling machines )
3. To prepare a job on a lathe involving facing, outside turning, taper turning,
step turning, radius making and parting-off.
4. To study different types of fitting tools and marking tools used in fitting
practice.
5. To prepare lay out on a metal sheet by making and prepare rectangular tray,
pipe shaped components e.g. funnel.
6. To prepare joints for welding suitable fo r butt welding and lap welding.
7. To perform pipe welding.
8. To study various types of carpentry tools and prepare simple types of at least
two wooden joints.
9. To prepare simple engineering components/ shapes by forging.
10. To prepare mold and core assembly, to put metal in the mold and fettle the
casting.
11. To prepare horizontal surface/ vertical surface/ curved surface/ slots or V-
grooves on a shaper/ planner.
12. To prepare a job involving side and face milling on a milling machine.
NOTE : 1. At least ten experiments/ jobs are to be performed/ prepared by
students in the
semester.
2. At least 8 experiments/ jobs should be performed / prepared
from the above list, remaining two may either be performed/ prepared from the
above list or designed & set by the concerned institution as per the scope of the
syllabus of Manufacturing Processes and facilities available in the Institute.
B.E. I/II Semester
CH-103-E : CHEMISTRY LAB. (COMMON FOR ALL BRANCHES)
-------- -------------- -----------------------
L T P Class Work : 25
Marks
- - 2 Practical : 25
Marks
Total : 50
Marks
Duration of exam. : 3
Hours
LIST OF EXPERIMENTS
-------------------
1. Determination of Ca++ and Mg++ hardness of water using
EDTA
solution.
2. Determination of alkalinity of water sample.
3. Determination of dissolved oxygen (DO) in the given
water
sample.
4. To find the melting & eutectic point for a two
component
system by using method of cooling curve.
5. Determination of viscosity of lubricant by Red
Wood
viscometer (No. 1 & No. 2).
6. To determine flash point & fire point of an oil by
Pensky -
Marten's flash point apparatus.
7. To prepare Phenol-formaldehyde and Urea formaldehyde
resin.
8. To find out saponification No. of an oil.
9. Estimation of calcium in lime stone and dolomite.
10. Determination of concentration of KMnO4
solution
spectrophotomet-erically.
11. Determination of strength of HCl solution by
titrating it
against NaOH solution conductometerically.
12. To determine amount of sodium and potassium in a,
given
water sample by flame photometer.
13. Estimation of total iron in an iron alloy.
Note : At least ten experiments are to be performed
by the
students.
EE-103-E ELECTRICAL TECHNOLOGY LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS
1. To verify KCL and KVL.
2. To verify Thevenin‟s & Norton's Theorems.
3. To Verify maximum power transfer theorem in D.C. Circuit & A.C circuit.
4. To verify reciprocity & Superposition theorems.
5. To study frequency response of a series R-L-C circuit and determine resonant
frequency& Q- factor for various Values of R,L,C.
6. To study frequency response of a parallel R-L-C circuit and determine resonant
frequency & Q -Factor for various values of R,L,C.
7. To perform direct load test of a transformer and plot efficiency Vs load characteristic.
8.To perform direct load test of a D.C. shunt generator and plot load voltage Vs load
current curve.
9.To plot V-curve of a synchronous motor.
10.To perform O.C. and S.C. tests of a three phase induction motor.
11.To study various type of meters.
12.Measurement of power by 3 voltmeter / 3 ammeter method.
13.Measurement of power in a 3 phase system by two watt meter method.
NOTE: 1. At least 10 experiments are to be performed by students in the semester.
2. At least 7 experiments should be performed from the above list, remaining
three experiments may either be performed from the above list or designed and set by the
concerned institution as per the scope of the syllabus of EE-101-E.
CSE -103 E C Programming Lab.
L T P Class Work:
25
- - 2 Exam:
25
Total:
50
Duration of Exam: 3
Hrs.
Representative programming problems:-
1. Write a program to find the largest of three numbers. (if-then-else)
2. Write a program to find the largest number out of ten numbers (for-statement)
3. Write a program to find the average mail height & average female heights in
the class (input is in form of sex code, height).
4. Write a program to find roots of quadratic equation using functions and switch
statements.
5. Write a program using arrays to find the largest and second largest no.
out of given 50 nos.
6. Write a program to multiply two matrices
7. Write a program to read a string and write it in reverse order
8. Write a program to concatenate two strings
9. Write a program to sort numbers using the Quicksort Algorithm.
10. Represent a deck of playing cards using arrays.
11. Write a program to check that the input string is a palindrome or not.
Note: At least 5 to 10 more exercises to be given by the
teacher concerned.
ME- 109 E ELEMENTS OF MECHANICAL ENGINEERING LAB.
L T P Sessional :
50Marks
- - 2 Practical : 100
Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
LIST OF EXPERIMENTS
1. To study Cochran & Babcock & Wilcox boilers.
2. To study the working & function of mountings & accessories in boilers.
3. To study 2-Stroke & 4-Stroke diesel engines.
4. To study 2-Stroke & 4-Stroke petrol engines.
5. To calculate the V.R., M.A. & efficiency of single, double & triple start worm &
worm wheel.
6. To calculate the V.R., M.A. & efficiency of single & double purchase winch
crabs.
7. To find the percentage error between observed and calculated values of stresses in
the members of a Jib crane.
8. To draw the SF & BM diagrams of a simply supported beam with concentrated
loads.
9. To study the simple & compound screw jacks and find their MA, VR &
efficiency.
10. To study the various types of dynamometers.
11. To the constructional features & working of Pelton/Kaplan/Francis.
12. To prepare stress-strain diagram for mild steel & cast iron specimens under
tension and compression respectively on a Universal testing machine.
13. To determine the Rockwell / Brinell /Vickers hardness no. of a given specimen on
the respective machines.
Note: 1. Total ten experiments are to be performed in the Semester.
2. At least seven experiments should be performed from
the above list. Remaining three experiments
should be performed as designed & set by the concerned
Institution as per the scope of the syllabus.
B.E. Semester-II
HUM-102-E COMMUNICATION SKILLS IN ENGLISH
(COMMON FOR ALL BRANCHES)
L T P Class Work :
50 Marks
3 1 - Exam : 100
Marks
Total :
150 Marks
Duration of Exam:
3 Hrs
This course is designed for the students of Engineering and Technology
who need English for specific purposes in specific situations. It aims
at imparting the communication skills that are needed in their academic
and professional pursuits. This is achieved through an amalgamation of
traditional lecture-oriented approach of teaching with the task based
skill oriented methodology of learning.
COURSE CONTENT:
Unit-I
Communicative Grammar: Spotting the errors pertaining to nouns,
pronouns, adjective and adverbs; Concord - grammatical concord,
notional concord and the principle of proximity between subject and
verb.
Unit-II
Lexis: Idioms and phrases; Words often confused; One-Word Substitutes;
Formation of words (suffixes, prefixes and derivatives); Foreign Words
(A selected list)
Unit-III
Oral Communication:
Part-A: Introduction to principal components of spoken English – Word-
stress patterns, Intonation, Weak forms in English
Part-B: Developing listening and speaking skills through various
activities, such as (a) role play activities, (b) Practising short
dialogues (c) Group discussion (d) Debates (e) Speeches (f) Listening
to news bulletins (g) Viewing and reviewing T.V. programmes etc.
Unit-IV
Written Communication:
Developing reading and writing skills through such tasks/activities as
developing outlines, key expressions, situations, slogan writing and
theme building exercises
Reading verbal and non-verbal texts-like cartoons, Graphs and tabulated
data etc.
Unit-V (For Internal Evaluation Only):
Book Review – Herein the students will be required to read and submit a
review of a book (Literary or non-literary) of their own choice. This
will be followed by a presentation of the same in the class
Unit-VI
Technical Writing:
(a) Business Letters, Format of Business letters and Business letter
writing
(b) E-mail writing
(c) Reports, Types of Reports and Format of Formal Reports
(d) Press Report Writing
MATH-102-E MATHEMATICS-II
---------- --------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 50
Marks
3 1 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hours
Part-A
Matrices & its Applications : Rank of a matrix,
elementary transformations, elementary matrices,
inverse using elementary transformations, normal form
of a matrix, linear dependence and in dependence of
vactors, consistency of linear system of equations,
linear and orthogonal transformations, eigen values and
eigen vectors, properties of eigen values, Cayley -
Hamilton theorem and its applications.
Part-B
Ordinary Differential Equations & its Applications :
Exact differential equations. Equations reducible to
exact differential equations. Applications of
Differential equations of first order & first degree
to simple electric circuits, Newton's law of cooling,
heat flow and orthogonal trajectories.
Linear differential equations of second and higher
order. Complete solution, complementary function and
particular integral, method of variation of parameters
to find particular Integral, Cauchy's and
Legender's linear equations, simultaneous linear
equations with constant co-efficients. Applications of
linear differential equations to simple pendulum,
oscillatory electric circuits.
Part-C
Laplace Transforms and its Applications : Laplace
transforms of elementary functions, properties of
Laplace transforms, existence conditions, transforms
of derivaties, transforms of integrals, multiplication
by tn, division by t. Evaluation of integrals by
Laplace transforms. Laplace transform of Unit step
function, unit impulse function and periodic function.
Inverse transforms, convolution theorem, application
to linear differential equations and simultaneous
linear differential equations with constant coefficients.
Partial Differential Equations and Its Applications :
Formation of partial differential equations, Lagrange’s
linear partial differential equation, First order non-
linear partial differential equation, Charpit’s method.
Method of separation of variables and its applications to
wave equation and one dimensional heat equation, two
dimensional heat flow, steady state solutions only.
PHY-102-E : PHYSICS-II (COMMON FOR ALL
BRANCHES)
--------- --------------------------------
----
L T P Sessional : 50
Marks
3 1 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hrs.
PART-A
CRYSTAL STRUCTURE
Space Lattice, unit cell and translation vectors,
Miller
indices, simple crystal structure, Bonding in
solids,
Experimental x-ray diffraction method, Laue method,
powder
Method, Point defects in solids, Elementary idea of quarks
and gluons.
QUANTUM PHYSICS
Difficulties with Classical physics, Introduction to
quantum
mechanics-simple concepts, discovery of Planck's constant,
Group
velocity and phase velocity, Schrodinger wave
equations -
time dependant and time independent Schrodinger
equations, Elementary ideas of quantum statistics.
FREE ELECTION THEORY
Elements of classical free electron theory
and its
limitations, Drude’s Theory of Conduction, quantum theory
of free electrons, Fermi level, Density of states,
Fermi-Dirac distribution function, Thermionic emission,
Richardson's equation.
PART-B
BAND THEORY OF SOLIDS
Origin of energy bands, Kronig, Penney Model
(qualitative),
E-K diagrams, Brillouin Zones, Concept of effective
mass and
holes, Classification of solids into metals,
Semiconductors and insulators, Fermi energy and its
variation with temperature. Hall effect and its
Applications.
PHOTOCONDUCTIVITY AND PHOTOVOLTAICS
Photoconductivity in insulating crystals, variation
with
illumination, effect of traps, applications of
photoconductivity,
photovoltaic cells and their characteristics.
MAGNETIC PROPERTIES OF SOLIDS
Atomic magnetic moments, orbital diamagnetism,
Classical
theory of paramagnetism, ferro magnetism - molecular
fields and domains.
SUPER CONDUCTIVITY
Introduction (experimental survey), Meissner effect,
London equation.
PHY-104-E : PHYSICS LAB.-II
--------- ---------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 25
Marks
- - 2 Practical : 25
Marks
Total : 50
Marks
Duration of exam. : 3
Hours
LIST OF EXPERIMENTS
-------------------
The experiments in Second semester will be
based upon
electricity, Magnetism, Modern Physics and Solid State
Physics
which are the parts of theory syllabus.
1. To find the low resistance by carey - Foster's
bridge.
2. To find the resistance of a galvanometer by Thomson’s
constant diffelction method using a post office box.
3. To find the value of high resistances by
Substitution
method.
4. To find the value of high resistances by Leakage
method.
5. To study the characteristics of a solar cell and to
find the
fill factor.
6. To find the value of e/m for electrons by Helical
method.
7. To find the ionisation potential of Argon/Mercury
using a
thyratron tube.
8. To study the variation of magnetic field with
distance and
to find the radius of coil by Stewart and Gee's
apparatus.
9. To study the characteristics of (Cu-Fe, Cu-
Constantan)
thermo couple.
10. To find the value of Planck's constant by using a
photo
electric cell.
11. To find the value of co-efficient of self-
inductance by
using a Rayleigh bridge.
12. To find the value of Hall Co-efficient of semi-
conductor.
13. To study the V-I characteristics of a p-n diode.
14. To find the band gap of intrinsic semi-conductor
using four
probe method.
15. To calculate the hysteresis loss by tracing a B-H
curve.
MATH-201-E MATHEMATICS-III
---------- ---------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 50
Marks
3 2 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hours
Part-A
Fourier Series and Fourier Transforms : Euler’s
formulae, conditions for a Fourier expansion, change of
interval, Fourier expansion of odd and even functions,
Fourier expansion of square wave, rectangular wave, saw-
toothed wave, half and full rectified wave, half range
sine and consine series.
Fourier integrals, Fourier transforms, Shifting
theorem (both on time and frequency axes), Fourier
transforms of derivatives, Fourier transforms of
integrals, Convolution theorem, Fourier transform of
Dirac-delta function.
Part-B
Functions of Complex Variable : Definition,
Exponential function, Trignometric and Hyperbolic
functions, Logrithmic functions. Limit and
Continuity of a function, Differnetiability and
Analyticity.
Cauchy-Riemann equations, necessary and
sufficient conditions for a function to be analytic,
polar form of the Cauchy-Riemann equations. Harmonic
functions, application to flow problems. Integration
of complex functions. Cauchy-Integral theorem and
formula.
Power series, radius and circle of convergence,
Taylor's Maclaurin's and Laurent's series. Zeroes and
singularities of complex functions, Residues.
Evaluation of real integrals using residues (around unit
and semi circle only).
Part-C
Probability Distributions and Hypothesis Testing :
Conditional probability, Bayes theorem and its
applications, expected value of a random variable.
Properties and application of Binomial, Poisson and
Normal distributions.
Testing of a hypothesis, tests of significance
for large samples, Student’s t-distribution (applications
only), Chi-square test of goodness of fit.
Linear Programming : Linear programming problems
formulation, Solving linear programming problems using
(i) Graphical method (ii) Simplex method (iii) Dual
simplex method.
CSE IIIrd Semester
CSE-201 E Data Structures & Algorithms
(CSE,EL,IT)
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction to Data Structures: Definition of data structures and abstract data
types, Static and Dynamic implementations, Examples and real life applications; The
Stacks : Definition, Array based implementation of stacks, Linked List based
implementation of stacks, Examples : Infix, postfix, prefix representation, Conversions,
Applications.
Unit-2: Queues and Lists: Definition, Array based implementation of Queues / Lists,
Linked List implementation of Queues / Lists, Circular implementation of Queues and
Singly linked Lists, Straight / circular implementation of doubly linked Queues / Lists,
Priority Queues, Applications.
Unit-3: Trees: Definition of trees and Binary trees, Properties of Binary trees and
Implementation, Binary Traversal pre-order, post order, In- order traversal, Binary Search
Trees, Implementations, Threaded trees, Balanced multi way search trees, AVL Trees,
Implementations
Unit-4: Graphs: Definition of Undirected and Directed Graphs and Networks, The
Array based implementation of graphs, Adjacency matrix, path matrix implementation,
The Linked List representation of graphs, Shortest path Algorithm, Graph Traversal –
Breadth first Traversal, Depth first Traversal, Tables : Definition, Hash function,
Implementations and Applications.
Unit-5: Running time: Time Complexity, Big – Oh - notation, Running Times, Best
Case, Worst Case, Average Case, Factors depends on running time, Introduction to
Recursion, Divide and Conquer Algorithm, Evaluating time Complexity.
Unit-6: Sorting Algorithms : Introduction, Sorting by exchange, selection, insertions :
Bubble sort, Straight selection sort, Efficiency of above algorithms,; Shell sort,
Performance of shell sort, Merge sort, Merging of sorted arrays& Algorithms; Quick sort
Algorithm analysis,
Heap sort: Heap Construction, Heap sort, bottom – up, Top – down Heap sort approach;
Searching Algorithms: Straight Sequential Search, Binary Search (recursive & non–
recursive Algorithms)
CSE-203 E Discrete Structures
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Set Theory: Introduction to set theory, Set operations, Algebra of sets, Duality,
Finite and Infinite sets, Classes of sets, Power Sets, Multi sets, Cartesian Product,
Representation of relations, Types of relation, Equivalence relations and partitions ,
Partial ordering relations and lattices
Function and its types, Composition of function and relations, Cardinality and inverse
relations
Unit-2: Propositional Calculus: Basic operations: AND(^), OR(v), NOT(~), Truth
value of a compound statement, propositions, tautologies, contradictions.
Unit–3: Techniques Of Counting: Permutations with and without repetition,
Combination.
Unit-4: Recursion And Recurrence Relation :Polynomials and their evaluation,
Sequences, Introduction to AP, GP and AG series, partial fractions, linear recurrence
relation with constant coefficients, Homogeneous solutions, Particular solutions, Total
solution of a recurrence relation using generating functions.
Unit-5: Algebric Structures Definition and examples of a monoid, Semigroup, Groups
and rings, Homomorphism, Isomorphism and Automorphism, Subgroups and Normal
subgroups, Cyclic groups, Integral domain and fields, Cosets, Lagrange‟s theorem
Unit-6: Graphs And Trees: Introduction to graphs, Directed and Undirected graphs,
Homomorphic and Isomorphic graphs, Subgraphs, Cut points and Bridges, Multigraph
and Weighted graph, Paths and circuits, Shortest path in weighted graphs, Eurelian path
and circuits, Hamilton paths and circuits, Planar graphs, Euler‟s formula, Trees, Spanning
trees, Binary trees and its traversals
EE-217 E Digital and Analog Communication
(CSE,IT)
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Communication system components: Introduction to Communication:
Definition & means of communications; Digital and analog signals: sign waves, square
waves; Properties of signals: amplitude, frequency, phase; Theoretical basis for data
communication: Fourier analysis: Fourier series and Fourier Transform (property, ESD,
PSD and Raleigh) effect of limited bandwidth on digital signal.
Unit-2: Data Transmission System: Physical connections: modulation, amplitude-,
frequency-, phase- modulation; Data encoding: binary encoding (NRZ), Manchester
encoding, differential Manchester encoding.
Transmission Media: Twisted pair-, co-axial-, fiber optic-cables, wireless media
Transmission impairments: attenuation, limited bandwidth of the channels, delay
distortion, noise, data rate of the channels (Nyquist theorem, Shannon limit). Physical
layer interfaces: RS 232, X.21
Unit-3: Standards in data communications: Communication modes: simplex, half
duplex, full duplex; Transmission modes: serial-, parallel-transmission;
Synchronizations: Asynchronous-, synchronous-transmission; Type of services:
connection oriented-, connectionless-services; Flow control: unrestricted simplex
protocol, simplex stop- and -wait protocol, sliding window protocol; Switching systems:
circuit switching; picketing switching: data gram , virtual circuits, permanent virtual
circuits.
Telephone Systems: PSTN, ISDN, asynchronous digital subscriber line.
Multiplexing: frequency division-, time-, wave- division multiplexing
Unit-4: Security in data communications: Transmission errors: feedback-, forward-
error control approaches; Error detection; Parity check, block sum check, frame check
sequences; Error correction: hamming codes, cyclic redundancy check; Data encryption:
secret key cryptography, public key cryptograph; Data compression: run length encoding,
Huffman encoding.
EE-204-E DIGITAL ELECTRONICS
L T P CLASS WORK : 50
3 1 0 EXAM : 100
TOTAL : 150
DURATION OF EXAM : 3 HRS
UNIT 1 FUNDAMENTALS OF DIGITAL TECHNIQUES :
Digital signal, logic gates: AND, OR, NOT, NAND, NOR, EX-OR, EX-NOR, Boolean
algebra. Review of Number systems. Binary codes: BCD, Excess-3, Gray, EBCDIC,
ASCII, Error detection and correction codes.
UNIT 2 COMBINATIONAL DESIGN USING GATES:
Design using gates, Karnaugh map and Quine Mcluskey methods of simplification.
UNIT 3 COMBINATIONAL DESIGN USING MSI DEVICES
Multiplexers and Demultiplexers and their use as logic elements, Decoders, Adders /
Subtractors, BCD arithmetic circuits, Encoders, Decoders / Drivers for display
devices.
UNIT 4 SEQUENTIAL CIRCUITS:
Flip Flops : S-R, J-K, T, D, master-slave, edge triggered, shift registers, sequence
generators, Counters, Asynchronous and Synchronous Ring counters and Johnson
Counter, Design of Synchronous and Asynchronous sequential circuits.
UNIT 5 DIGITAL LOGIC FAMILIES:
Switching mode operation of p-n junction, bipolar and MOS. devices. Bipolar logic
families:RTL, DTL, DCTL, HTL, TTL, ECL, MOS, and CMOS logic families. Tristate
logic, Interfacing of CMOS and TTL families.
UNIT 6 A/D AND D/A CONVERTERS:
Sample and hold circuit, weighted resistor and R -2 R ladder D/A Converters,
specifications for
D/A converters. A/D converters : Quantization, parallel -comparator, successive
approximation, counting type, dual-slope ADC, specifications of ADCs.
UNIT 7 PROGRAMMABLE LOGIC DEVICES:
ROM, PLA, PAL, FPGA and CPLDs.
HUM-201-E ECONOMICS
(COMMON FOR ALL BRANCHES)
L T P Class Work : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
COURSE OBJECTIVE : The purpose of this course is to :
1. Acquaint the student in the basic economic concepts and their operational significance and
2 .Stimulate him to think systematically and objectively about contemporary economic problems.
UNIT-I
Definition of Economics - various definitions, Nature of Economic problem, Production possibility curve
Economic laws and their nature. Relation between Science, Engineering, Technology and Economics.
UNIT-II
Concepts and measurement of utility, Law of Diminishing Marginal Utility, Law of equi-marginal
utility - its practical application and importance.
UNIT-III
Meaning of Demand, Individual and Market demand schedule, Law of demand, shape of demand curve,
Elasticity of demand, measurement of elasticity of demand, factors effecting elasticity of demand, practical
importance & applications of the concept of elasticity of demand.
UNIT-IV
Meaning of production and factors of production; Law of variable proportions, Returns to scale, Internal
and External economics and diseconomies of scale.
Various concepts of cost - Fixed cost, variable cost, average cost, marginal cost, money cost, real
cost opportunity cost. Shape of average cost, marginal cost, total cost etc. in short run and long run.
UNIT-V
Meaning of Market, Types of Market - Perfect Competition, Monopoly, Oligoply, Monoplistic Competition
(Main features of these markets)
Supply and Law of Supply, Role of Demand & Supply in Price Determinition and effect of changes in
demand and supply on prices.
UNIT-VI
Nature and characteristics of Indian economy (brief and elementary introduction), Privatization - meaning,
merits and demerits. Globalisation of Indian economy - merits and demerits. Elementary Concepts of VAT, WTO,
GATT & TRIPS agreement.
IT-201 E PC Lab.
L T P Class Work: 50
- - 3 Exam: 50
Total: 100
Duration of Exam: 3
Hrs.
PC Software: Application of basics of MS Word 2000, MS Excel 2000, MS Power Point
2000, MS Access 2000.
1. To prepare the Your Bio Data using MS Word
2. To prepare the list of marks obtained by students in different subjects and
show with the help of chart/graph the average, min and max marks in each
subject.
3. Preapare a presentation explaining the facilities/infrastructure available in
your college/institute.
4. Create a database of books in the library on a mini scale w.r.t. Computers and
manipulate the database using different forms and reports.
PC Hardware :
1. To check and measure various supply voltages of PC.
2. To make comparative study of motherboards.
3. To observe and study various cables, connections and parts used in computer
communication.
4. To study various cards used in a system viz. display card, LAN card etc.
5. To remove, study and replace floppy disk drive.
6. To remove, study and replace hard disk.
7. To remove, study and replace CD ROM drive.
8. To study monitor, its circuitry and various presents and some elementary fault
detection.
9. To study printer assembly and elementary fault detection of DMP and laser printers.
10. To observe various cables and connectors used in networking.
11. To study parts of keyboard and mouse.
12. To assemble a PC.
13. Troubleshooting exercises related to various components of computer like monitor,
drives, memory and printers etc.
CSE-205 E Data Structures & Algorithms Lab.
L T P Class Work: 50
- - 3 Exam: 50
Total: 100
Duration of Exam: 3
Hrs.
1. Write a program to search an element in a two-dimensional array using linear
search.
2. Using iteration & recursion concepts write programs for finding the element in the
array
using Binary Search Method
3. Write a program to perform following operations on tables using functions only
a) Addition b) Subtraction c) Multiplication d) Transpose
4. Using iteration & recursion concepts write the programs for Quick Sort
Technique
5. Write a program to implement the various operations on string such as length of
string concatenation, reverse of a string & copy of a string to another.
6. Write a program for swapping of two numbers using „call by value‟ and „call by
reference strategies.
7. Write a program to implement binary search tree.
( Insertion and Deletion in Binary search Tree)
8. Write a program to create a linked list & perform operations such as insert, delete,
update, reverse in the link list
9. Write the program for implementation of a file and performing operations such as
insert,
delete, update a record in the file.
10. Create a linked list and perform the following operations on it
a) add a node b) Delete a node
11. Write a program to simulate the various searching & sorting algorithms and
compare their timings for a list of 1000 elements.
12. Write a program to simulate the various graph traversing algorithms.
13. Write a program which simulates the various tree traversal algorithms.
EE-224-E DIGITAL ELECTRONICS LAB
L T P CLASS WORK :
25
0 0 2 EXAM :
25
TOTAL :
50
DURATION OF EXAM :
3 HRS
LIST OF EXPERIMENTS:
1. Study of TTL gates – AND, OR, NOT, NAND, NOR, EX-OR, EX-NOR.
2. Design & realize a given function using K-maps and verify its performance.
3. To verify the operation of multiplexer & Demultiplexer.
4. To verify the operation of comparator.
5. To verify the truth tables of S-R, J-K, T & D type flip flops.
6. To verify the operation of bi-directional shift register.
7. To design & verify the operation of 3-bit synchronous counter.
8. To design and verify the operation of synchronous UP/DOWN decade counter using J
K flip-flops & drive a
seven-segment display using the same.
9. To design and verify the operation of asynchronous UP/DOWN decade counter using
J K flip-flops & drive a
seven-segment display using the same.
10. To design & realize a sequence generator for a given sequence using J-K flip-
flops.
11. Study of CMOS NAND & NOR gates and interfacing between TTL and CMOS
gates.
12. Design a 4-bit shift-register and verify its operation . Verify the operation of a ring
counter and a Johnson
counter.
CSE IV Semester
CSE-202 E Database Management Systems
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit–1:Introduction Overview of database Management System; Various views of data,
data Models, Introduction to Database Languages. Advantages of DBMS over file
processing systems, Responsibility of Database Administrator,
Unit-2: Introduction to Client/Server architecture, Three levels architecture of Database
Systems, E-R Diagram (Entity Relationship), mapping Constraints, Keys, Reduction of
E-R diagram into tables.
Unit-3: File Organisation: Sequential Files, index sequential files, direct files, Hashing,
B-trees Index files.
Unit-4: Relational Model, Relational Algebra & various operations, Relational and Tuple
calculus.
Unit-5: Introduction to Query Languages :QLB , QBE, Structured query language –
with special reference of (SQL of ORACLE), integrity constraints, functional
dependencies & NORMALISATION – (up to 4th Normal forms), BCNF (Boyce – code
normal forms)
Unit-6: Introduction to Distributed Data processing, parallel Databases, data mining &
data warehousing, network model & hierarchical model, Introduction to Concurrency
control and Recovery systems.
CSE-204 E Programming Languages
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction: Syntactic and semantic rules of a Programming language,
Characteristics of a good programming language, Programming language translators
compiler & interpreters , Elementary data types – data objects, variable & constants, data
types, Specification & implementation of elementary data types, Declarations ,type
checking & type conversions , Assignment & initialization, Numeric data types,
enumerations, Booleans & characters.
Unit-2: Structured data objects : Structured data objects & data types , specification &
implementation of structured data types, Declaration & type checking of data structure
,vector & arrays, records Character strings, variable size data structures , Union, pointer
& programmer defined data objects, sets, files.
Unit-3 : Subprograms and Programmer Defined Data Types: Evolution of data type
concept ,abstraction, encapsulation & information hiding , Subprograms ,type definitions,
abstract data types.
Unit–4: Sequence Control: Implicit & explicit sequence control ,sequence control
within expressions, sequence control within statement, Subprogram sequence control:
simple call return ,recursive subprograms, Exception & exception handlers, co routines,
sequence control .
Unit-5: Data Control: Names & referencing environment, static & dynamic scope,
block structure, Local data & local referencing environment, Shared data: dynamic &
static scope. Parameter & parameter transmission schemes.
Unit-6: Storage Management: Major run time elements requiring storage ,programmer
and system controlled storage management & phases , Static storage management , Stack
based storage management, Heap storage management ,variable & fixed size elements.
Unit-7: Programming Languages: Introduction to procedural, non-procedural
,structured, functional and object oriented programming language, Comparison of C &
C++ programming languages.
CSE-206 E Theory of Automata Computation
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Finite Automata and Regular Expressions: Finite State Systems, Basic
Definitions Non-Deterministic finite automata (NDFA), Deterministic finite automata
(DFA), Equivalence of DFA and NDFA Finite automata with E-moves, Regular
Expressions, Equivalence of finite automata and Regular Expressions, Regular
expression conversion and vice versa.
Unit-2: Introduction to Machines: Concept of basic Machine, Properties and limitations
of FSM. Moore and mealy Machines, Equivalence of Moore and Mealy machines,
Conversion of NFA to DFA by Arden‟s Method.
Unit-3: Properties of Regular Sets: The Pumping Lemma for Regular Sets,
Applications of the pumping lemma, Closure properties of regular sets, Myhill-Nerode
Theorem and minimization of finite Automata, Minimization Algorithm.
Unit-4: Grammars: Definition, Context free and Context sensitive grammar, Ambiguity
regular grammar, Reduced forms, Removal of useless Symbols and unit production,
Chomsky Normal Form (CNF), Griebach Normal Form (GNF).
Unit-5: Pushdown Automata: Introduction to Pushdown Machines, Application of
Pushdown Machines
Unit-6: Turing Machines: Deterministic and Non-Deterministic Turing Machines,
Design of T.M, Halting problem of T.M., PCP Problem.
Unit-7: Chomsky Hierarchies: Chomsky hierarchies of grammars, Unrestricted
grammars, Context sensitive languages, Relation between languages of classes.
Unit-8: Computability: Basic concepts, Primitive Recursive Functions.
IT-202 E Object Oriented Programming Using C++
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit–1: Introduction to C++, C++ Standard Library, Basics of a Typical C++ Environment, Pre-
processors Directives, Illustrative Simple C++ Programs. Header Files and Namespaces, library
files.
Unit-2: Object Oriented Concepts : Introduction to Objects and Object Oriented Programming,
Encapsulation (Information Hiding), Access Modifiers: Controlling access to a class, method, or variable
(public, protected, private, package), Other Modifiers, Polymorphism: Overloading,, Inheritance,
Overriding Methods, Abstract Classes, Reusability, Class‟s Behaviors.
Unit–3: Classes and Data Abstraction: Introduction, Structure Definitions, Accessing Members of
Structures, Class Scope and Accessing Class Members, Separating Interface from Implementation,
Controlling Access Function And Utility Functions, Initializing Class Objects: Constructors, Using
Default Arguments With Constructors, Using Destructors, Classes : Const(Constant) Object And Const
Member Functions, Object as Member of Classes, Friend Function and Friend Classes, Using This
Pointer, Dynamic Memory Allocation with New and Delete, Static Class Members, Container Classes
And Integrators, Proxy Classes, Function overloading.
Unit-4: Operator Overloading: Introduction, Fundamentals of Operator Overloading, Restrictions
On Operators Overloading, Operator Functions as Class Members vs. as Friend Functions,
Overloading, <<, >> Overloading Unary Operators, Overloading Binary Operators.
Unit-5: Inheritance: Introduction, Inheritance: Base Classes And Derived Classes, Protected
Members, Casting Base- Class Pointers to Derived- Class Pointers, Using Member Functions,
Overriding Base –Class Members in a Derived Class, Public, Protected and Private Inheritance, Using
Constructors and Destructors in derived Classes, Implicit Derived –Class Object To Base- Class Object
Conversion, Composition Vs. Inheritance.
Unit–6: Virtual Functions and Polymorphism: Introduction to Virtual Functions, Abstract Base
Classes And Concrete Classes, Polymorphism, New Classes And Dynamic Binding, Virtual
Destructors, Polymorphism, Dynamic Binding.
Unit-7: Files and I/O Streams: Files and Streams, Creating a Sequential Access File, Reading Data
From A Sequential Access File, Updating Sequential Access Files, Random Access Files, Creating A
Random Access File, Writing Data Randomly To a Random Access File, Reading Data Sequentially
from a Random Access File. Stream Input/Output Classes and Objects, Stream Output, Stream Input,
Unformatted I/O (with read and write), Stream Manipulators, Stream Format States, Stream Error
States.
Unit-8: Templates & Exception Handling: Function Templates, Overloading Template
Functions, Class Template, Class Templates and Non-Type Parameters, Templates and Inheritance,
Templates and Friends, Templates and Static Members.
Introduction, Basics of C++ Exception Handling: Try Throw, Catch, Throwing an Exception, Catching
an Exception, Rethrowing an Exception, Exception specifications, Processing Unexpected Exceptions,
Stack Unwinding, Constructors, Destructors and Exception Handling, Exceptions and Inheritance.
CSE-208 E Internet Fundamentals
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Electronic Mail: Introduction, advantages and disadvantages, Userids, Pass
words, e-mail addresses, message components, message composition, mailer features, E-
mail inner workings, E-mail management, Mime types, Newsgroups, mailing lists, chat
rooms.
Unit-2 : The Internet: Introduction to networks and internet, history, Working of
Internet, Internet Congestion, internet culture, business culture on internet. Collaborative
computing & the internet. Modes of Connecting to Internet, Internet Service
Providers(ISPs), Internet address, standard address, domain name, DNS, IP.v6.Modems
and time continuum, communications software; internet tools.
Unit-3 : World Wide Web : Introduction, Miscellaneous Web Browser details,
searching the www: Directories search engines and meta search engines, search
fundamentals, search strategies, working of the search engines, Telnet and FTP.
Introduction to Browser, Coast-to-coast surfing, hypertext markup language, Web page
installation, Web page setup, Basics of HTML & formatting and hyperlink creation.
Using FrontPage Express, Plug-ins.
Unit-4: Languages: Basic and advanced HTML, java script language, Client and Server
Side Programming in java script. Forms and data in java script, XML basics.
Unit-5 : Servers : Introduction to Web Servers: PWS, IIS, Apache; Microsoft Personal
Web Server. Accessing & using these servers.
Unit-6: Privacy and security topics: Introduction, Software Complexity, Encryption
schemes, Secure Web document, Digital Signatures, Firewalls.
CSE- 210 E Computer Architecture & Organization
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Basic Principles: Boolean algebra and Logic gates, Combinational logic
blocks(Adders, Multiplexers, Encoders, de-coder), Sequential logic blocks(Latches, Flip-
Flops, Registers, Counters)
Unit-2: General System Architecture: Store program control concept, Flynn‟s
classification of computers (SISD, MISD, MIMD); Multilevel viewpoint of a machine:
digital logic, micro architecture, ISA, operating systems, high level language; structured
organization; CPU, caches, main memory, secondary memory units & I/O; Performance
metrics; MIPS, MFLOPS.
Unit-3: Instruction Set Architecture: Instruction set based classification of processors
(RISC, CISC, and their comparison); addressing modes: register, immediate, direct,
indirect, indexed; Operations in the instruction set; Arithmetic and Logical, Data
Transfer, Control Flow; Instruction set formats (fixed, variable, hybrid); Language of the
machine: 8086 ; simulation using MSAM.
Unit-4: Basic non pipelined CPU Architecture: CPU Architecture types (accumulator,
register, stack, memory/ register) detailed data path of a typical register based CPU,
Fetch-Decode-Execute cycle (typically 3 to 5 stage); microinstruction sequencing,
implementation of control unit, Enhancing performance with pipelining.
Unit-5: Memory Hierarchy & I/O Techniques: The need for a memory hierarchy
(Locality of reference principle, Memory hierarchy in practice: Cache, main memory and
secondary memory, Memory parameters: access/ cycle time, cost per bit); Main memory
(Semiconductor RAM & ROM organization, memory expansion, Static & dynamic
memory types); Cache memory (Associative & direct mapped cache organizations.
Unit-6: Introduction to Parallelism: Goals of parallelism (Exploitation of concurrency,
throughput enhancement); Amdahl‟s law; Instruction level parallelism (pipelining, super
scaling –basic features); Processor level parallelism (Multiprocessor systems overview).
Unit-7: Computer Organization [80x86]: Instruction codes, computer register,
computer instructions, timing and control, instruction cycle, type of instructions, memory
reference, register reference. I/O reference, Basics of Logic Design, accumulator logic,
Control memory, address sequencing, micro-instruction formats, micro-program
sequencer, Stack Organization, Instruction Formats, Types of interrupts; Memory
Hierarchy.
CSE- 212 E Database Management Systems Lab
L T P Class Work: 50
- - 3 Exam: 50
Total: 100
Duration of Exam: 3
Hrs.
I. Create a database and write the programs to carry out the following operation :
1. Add a record in the database
2. Delete a record in the database
3. Modify the record in the database
4. Generate queries
5. Generate the report
6. List all the records of database in ascending order.
II Develop two menu driven project for management of database system:
1. Library information system
(a) Engineering
(b) MCA
2. Inventory control system
(c) Computer Lab
(d) College Store
3. Student information system
(e) Academic
(f) Finance
4. Time table development system
(g) CSE, IT & MCA Departments
(h) Electrical & Mechanical Departments
Usage of S/w:
1. VB, ORACLE and/or DB2
2. VB, MSACCESS
3. ORACLE, D2K
4. VB, MS SQL SERVER 2000
IT-206 E C ++ Programming Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
Q1. Raising a number n to a power p is the same as multiplying n by itself p times. Write a
function called power ( ) that takes a double value for n and an int value for p, and returns
the result as double value. Use a default argument of 2 for p, so that if this argument is
omitted, the number will be squared. Write a main ( ) function that gets values from the
user to test this function.
Q2. A point on the two dimensional plane can be represented by two numbers: an X
coordinate and a Y coordinate. For example, (4,5) represents a point 4 units to the right
of the origin along the X axis and 5 units up the Y axis. The sum of two points can be
defined as a new point whose X coordinate is the sum of the X coordinates of the points
and whose Y coordinate is the sum of their Y coordinates.
Write a program that uses a structure called point to model a point. Define three points,
and have
the user input values to two of them. Than set the third point equal to the sum of the
other two,
and display the value of the new point. Interaction with the program might look like this:
Enter coordinates for P1: 3 4
Enter coordinates for P2: 5 7
Coordinates of P1 + P2 are : 8, 11
Q 3. Create the equivalent of a four function calculator. The program should request the user
to enter a number, an operator, and another number. It should then carry out the specified
arithmetical operation: adding, subtracting, multiplying, or dividing the two numbers. (It
should use a switch statement to select the operation). Finally it should display the result.
When it finishes the calculation, the program should ask if the user wants to do another
calculation. The response can be „Y‟ or „N‟. Some sample interaction with the program
might
look like this.
Enter first number, operator, second number: 10/ 3
Answer = 3.333333
Do another (Y/ N)? Y
Enter first number, operator, second number 12 + 100
Answer = 112
Do another (Y/ N) ? N
Q4. A phone number, such as (212) 767-8900, can be thought of as having three parts: the
area code (212), the exchange (767) and the number (8900). Write a
program that uses a structure to store these three parts of a phone number
separately. Call the structure phone. Create two structure variables of type
phone. Initialize one, and have the user input a number for the other one. Then display
both numbers. The interchange might look like this:
Enter your area code, exchange, and number: 415 555 1212
My number is (212) 767-8900
Your number is (415) 555-1212
Q 5. Create two classes DM and DB which store the value of distances. DM stores distances
in metres and centimeters and DB in feet and inches. Write a program that can read values
for the class objects and add one object of DM with another object of DB.
Use a friend function to carry out the addition operation. The object that stores the
results maybe
a DM object or DB object, depending on the units in which the results are required.
The display should be in the format of feet and inches or metres and cenitmetres
depending on
the object on display.
Q 6. Create a class rational which represents a numerical value by two double values-
NUMERATOR & DENOMINATOR. Include the following public member Functions:
constructor with no arguments (default).
constructor with two arguments.
void reduce( ) that reduces the rational number by eliminating the highest
common factor between the numerator and denominator.
Overload + operator to add two rational number.
Overload >> operator to enable input through cin.
Overload << operator to enable output through cout.
Write a main ( ) to test all the functions in the class.
Q 7. Consider the following class definition
class father {
protected : int age;
public;
father (int x) {age = x;}
virtual void iam ( )
{ cout < < “I AM THE FATHER, my age is : ”<< age<< end1:}
};
Derive the two classes son and daughter from the above class and for each, define iam ( )
to write
our similar but appropriate messages. You should also define suitable constructors for
these
classes.
Now, write a main ( ) that creates objects of the three classes and then calls iam ( ) for
them.
Declare pointer to father. Successively, assign addresses of objects of the two derived
classes to
this pointer and in each case, call iam ( ) through the pointer to demonstrate
polymorphism in
action.
Q 8. Write a program that creates a binary file by reading the data for the students from the
terminal.
The data of each student consist of roll no., name ( a string of 30 or lesser no. of
characters) and marks.
Q9. A hospital wants to create a database regarding its indoor patients. The information to
store include
a) Name of the patient
b) Date of admission
c) Disease
d) Date of discharge
Create a structure to store the date (year, month and date as its members). Create a base
class to
store the above information. The member function should include functions to enter
information
and display a list of all the patients in the database. Create a derived class to store the
age of the
patients. List the information about all the to store the age of the patients. List the
information
about all the pediatric patients (less than twelve years in age).
Q 10. Make a class Employee with a name and salary. Make a class Manager inherit from
Employee. Add an instance variable, named department, of type string. Supply a method to
toString that prints the manager‟s name, department and salary. Make a class Executive
inherit from Manager. Supply a method to String that prints the string “Executive” followed
by the information stored in the Manager superclass object. Supply a test program that tests
these classes and methods.
Q11. Imagine a tollbooth with a class called toll Booth. The two data items are a type
unsigned int to hold the total number of cars, and a type double to hold the total amount of
money collected. A constructor initializes both these to 0. A member function called
payingCar ( ) increments the car total and adds 0.50 to the cash total. Another function, called
nopayCar ( ), increments the car total but adds nothing to the cash total. Finally, a member
function called displays the two totals.
Include a program to test this class. This program should allow the user to push one key
to count
a paying car, and another to count a nonpaying car. Pushing the ESC kay should cause
the
program to print out the total cars and total cash and then exit.
Q12. Write a function called reversit ( ) that reverses a string (an array of char). Use a for loop
that swaps the first and last characters, then the second and next to last characters and so on.
The string should be passed to reversit ( ) as an argument.
Write a program to exercise reversit ( ). The program should get a string from the user,
call
reversit ( ), and print out the result. Use an input method that allows embedded blanks.
Test the
program with Napoleon‟s famous phrase, “Able was I ere I saw Elba)”.
Q13. Create some objects of the string class, and put them in a Deque-some at the head of the
Deque and some at the tail. Display the contents of the Deque using the forEach ( ) function
and a user written display function. Then search the Deque for a particular string, using the
first That ( ) function and display any strings that match. Finally remove all the items from the
Deque using the getLeft ( ) function and display each item. Notice the order in which the items
are displayed: Using getLeft ( ), those inserted on the left (head) of the Deque are
removed in “last in first out” order while those put on the right side are removed in “first in first
out” order. The opposite would be true if getRight ( ) were used.
Q 14. Create a base class called shape. Use this class to store two double type values that could
be used to compute the area of figures. Derive two specific classes called
triangle and rectangle from the base shape. Add to the base class, a member
function get_data ( ) to initialize base class data members and another member
function display_area ( ) to compute and display the area of figures. Make
display_area ( ) as a virtual function and redefine this function in the derived
classes to suit their requirements.
Using these three classes, design a program that will accept dimensions of a triangle or a
rectangle interactively and display the area.
Remember the two values given as input will be treated as lengths of two sides in the
case of
rectangles and as base and height in the case of triangles and used as follows:
Area of rectangle =x*y
Area of triangle =½*x*y
CSE 214 E Internet Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
Exercises involving:
Sending and receiving mails.
Chatting on the net.
Using FTP and Tel net server.
Using HTML Tags (table, form, image, anchor etc.).
Making a Web page of your college using HTML tags.
CSE V Semester
CSE-301 E Principles of Operating System
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction: Introduction to Operating System Concepts (including
Multitasking, multiprogramming, multi user, Multithreading etc)., Types of Operating
Systems: Batch operating system, Time-sharing systems, Distributed OS, Network OS,
Real Time OS; Various Operating system services, architecture, System programs and
calls.
Unit–2: Process Management: Process concept, process scheduling, operation on
processes; CPU scheduling, scheduling criteria, scheduling algorithms -First Come First
Serve (FCFS), Shortest-Job-First (SJF), Priority Scheduling, Round Robin(RR),
Multilevel Queue Scheduling.
Unit–3: Memory Management: Logical & Physical Address Space, swapping,
contiguous memory allocation, non-contiguous memory allocation paging and
segmentation techniques, segmentation with paging; virtual memory management -
Demand Paging & Page-Replacement Algorithms; Demand Segmentation.
Unit–4: File System: Different types of files and their access methods, directory
structures, various allocation methods, disk scheduling and management and its
associated algorithms, Introduction to distributed file system.
Unit–5: Process-Synchronization & Deadlocks: Critical Section Problems,
semaphores; methods for handling deadlocks-deadlock prevention, avoidance &
detection; deadlock recovery.
Unit-6: I/O Systems: I/O Hardware, Application I/O Interface, Kernel, Transforming
I/O requests, Performance Issues.
Unit–7: Unix System And Windows NT Overview
Unix system call for processes and file system management, Shell interpreter, Windows
NT architecture overview, Windows NT file system.
EE-309-E MICROPROCESSORS AND
INTERFACING
L T P CLASS WORK :
50
3 1 0 EXAM :
100
TOTAL :
150
DURATION OF EXAM :
3 HRS
PART A
UNIT1. THE 8085 PROCESSOR :
Introduction to microprocessor, 8085 microprocessor: Architecture, instruction set,
interrupt structure, and assembly language programming.
UNIT2. THE 8086 MICROPROCESSOR ARCHITECTURE:
Architecture, block diagram of 8086, details of sub-blocks such as EU, BIU; memory
segmentation and physical address computations, program relocation, addressing modes,
instruction formats, pin diagram and description of various signals.
UNIT3. INSTRUCTION SET OF 8086:
Instruction execution timing, assembler instruction format, data transfer instructions,
arithmetic instructions, branch instructions, looping instructions, NOP and HLT
instructions, flag manipulation instructions, logical instructions, shift and rotate
instructions, directives and operators, programming examples.
PART B
UNIT4. INTERFACING DEVICE :
The 8255 PPI chip: Architecture, control words, modes and examples.
UNIT 5. DMA :
Introduction to DMA process, 8237 DMA controller,
UNIT6. INTERRUPT AND TIMER :
8259 Programmable interrupt controller, Programmable interval timer chips.
CSE -303 E Computer Graphics
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction to Computer Graphics: What is Computer Graphics, Computer
Graphics Applications, Computer Graphics Hardware and software, Two dimensional
Graphics Primitives: Points and Lines, Line drawing algorithms: DDA, Bresenham‟s;
Circle drawing algorithms: Using polar coordinates, Bresenham‟s circle drawing, mid
point circle drawing algorithm; Filled area algorithms: Scanline: Polygon filling
algorithm, boundary filled algorithm.
Unit-2: Two/Three Dimensional Viewing: The 2-D viewing pipeline, windows,
viewports, window to view port mapping; Clipping: point, clipping line (algorithms):- 4
bit code algorithm, Sutherland-cohen algorithm, parametric line clipping algorithm
(Cyrus Beck).
Polygon clipping algorithm: Sutherland-Hodgeman polygon clipping algorithm. Two
dimensional transformations: transformations, translation, scaling, rotation, reflection,
composite transformation.
Three dimensional transformations: Three dimensional graphics concept, Matrix
representation of 3-D Transformations, Composition of 3-D transformation.
Unit-3: Viewing in 3D: Projections, types of projections, the mathematics of planner
geometric projections, coordinate systems.
Unit-4: Hidden surface removal: Introduction to hidden surface removal. The Z-
buffer algorithm, scanline algorithm, area sub-division algorithm.
Unit-5: Representing Curves and Surfaces: Parametric representation of curves:
Bezier curves, B-Spline curves. Parametric representation of surfaces; Interpolation
method.
Unit-6: Illumination, shading, image manipulation: Illumination models, shading
models for polygons, shadows, transparency. What is an image? Filtering, image
processing, geometric transformation of images.
CSE -305 E Analysis and Design of Algorithms
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Brief Review of Graphs, Sets and disjoint sets, union, sorting and searching
algorithms and
their analysis in terms of space and time complexity.
Unit-2: Divide and Conquer: General method, binary search, merge sort, qick sort,
selection sort, Strassen‟s matrix multiplication algorithms and analysis of algorithms for
these problems.
Unit-3: Greedy Method: General method, knapsack problem, job sequencing with dead
lines, minimum spanning trees, single souce paths and analysis of these problems.
Unit-4: Dynamic Programming: General method, optimal binary search trees, O/I
knapsack, the traveling salesperson problem.
Unit-5: Back Tracking: General method, 8 queen‟s problem, graph colouring,
Hamiltonian cycles, analysis of these problems.
Unit-6: Branch and Bound: Method, O/I knapsack and traveling salesperson problem,
efficiency considerations. Techniques for algebraic problems, some lower bounds on
parallel computations.
Unit-7: NP Hard and NP Complete Problems: Basic concepts, Cook‟s theorem, NP
hard graph and NP scheduling problems some simplified NP hard problems.
CSE- 307 E Web Development
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction to the Internet, The world wide web: The idea of hypertext
and hyper media; How the web works-HTTP, HTML and URLs; How the browser
works-MIME types, plugins and helper applications; The standards-HTML, XML,
XHTML and the W3C.
Hypertext markup language: The anatomy of an HTML document; Marking up for
structure and style: basic page markup, absolute and relative links, ordered and
unordered lists, embedding images and controlling appearance, table creation and use,
frames, nesting and targeting.
Descriptive markup: Meta tags for common tasks, semantic tags for aiding search, the
doubling code and RDF.
Unit-2: Separating style from structure with style sheets: Internal style
specifications within HTML, External linked style specification using CSS, page and
site design considerations.
Client side programming: Introduction to the JavaScript syntax, the JavaScript
object model, Event handling, Output in JavaScript, Forms handling, miscellaneous
topics such as cookies, hidden fields, and images; Applications.
Unit-3: Server side programming: Introduction to Server Side Technologies
CGI/ASP/JSP., Programming languages for server Side Scripting, Configuring the
server to support CGI, applications; Input/ output operations on the WWW, Forms
processing, (using PERL/VBSCRIPT/JavaSCIPT)
Unit-4: Other dynamic content technologies: introduction to ASP & JSP,
Delivering multimedia over web pages, The VRML idea, The Java phenomenon-
applets and servelets, issues and web development.
Unit-5: Introduction to Microsoft .NET Technology and its comparison with the
competing Technologies.
IT-204 E Multimedia Technologies
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Basics of Multimedia Technology: Computers, communication and
entertainment; multimedia an introduction; framework for multimedia systems;
multimedia devices; CD- Audio, CD-ROM, CD-I, presentation devices and the user
interface; multimedia presentation and authoring; professional development tools; LANs
and multimedia; internet, World Wide Web & multimedia distribution network-ATM &
ADSL; multimedia servers & databases; vector graphics; 3D graphics programs;
animation techniques; shading; anti aliasing; morphing; video on demand.
Unit-2: Image Compression & Standards: Making still images; editing and capturing
images; scanning images; computer color models; color palettes; vector drawing; 3D
drawing and rendering; JPEG-objectives and architecture; JPEG-DCT encoding and
quantization, JPEG statistical coding, JPEG predictive lossless coding; JPEG
performance; overview of other image file formats as GIF, TIFF, BMP, PNG etc.
Unit-3: Audio & Video: Digital representation of sound; time domain sampled
representation; method of encoding the analog signals; subband coding; fourier method;
transmission of digital sound; digital audio signal processing; stereophonic &
quadraphonic signal processing; editing sampled sound; MPEG Audio; audio
compression & decompression; brief survey of speech recognition and generation; audio
synthesis; musical instrument digital interface; digital video and image compression;
MPEG motion video compression standard; DVI technology; time base media
representation and delivery.
Unit-4: Virtual Reality: Applications of multimedia, intelligent multimedia system,
desktop virtual reality, VR operating system, virtual environment displays and orientation
making; visually coupled system requirements; intelligent VR software systems.
Applications of environment in various fields.
CSE-309 E Computer Graphics Lab.
L T P Class Work: 50
- - 3 Exam: 50
Total: 100
Duration of Exam: 3
Hrs.
List of programs to be developed
1. Write a program for 2D line drawing as Raster Graphics Display.
2. Write a program for circle drawing as Raster Graphics Display.
3. Write a program for polygon filling as Raster Graphics Display
4. Write a program for line clipping.
5. Write a program for polygon clipping.
6. Write a program for displaying 3D objects as 2D display using perspective
transformation.
7. Write a program for rotation of a 3D object about arbitrary axis.
8. Write a program for Hidden surface removal from a 3D object.
CSE-311 E Web Development & Core JAVA Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
Java programs using classes & objects and various control constructs such as loops etc , and
data structures such as arrays , structures and functions.
Java programs for creating Applets for display of Images ,Texts and Animation
Programs related to interfaces & packages
Input output & Random files programs in java
Java programs using Event driven concept
Programs related to Network Programming
Development of Web site for the college or newspaper agency.
IT-208 E Multimedia Technologies Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
1. Write a program to justify a text entered by the user on both the left and right
hand side. For example, the test “ An architect may have a graphics program to draw
an entire building but be interested in only ground floor”, can be justified in 30
columns as shown below. An architect may have a Graphics programs draw an
Entric building but be interested in only ground floor.
2. Study the notes of a piano and stimulate them using the key board and store them
in a file.
3. Write a program to read a paragraph and store it to a file name suggested by the
author.
4. Devise a routine to produce the animation effect of a square transforming to a
triangle and then to a circle.
5. Write a program to show a bitmap image on your computer screen.
6. Create a web page for a clothing company which contains all the details of that
company and at-least five links to other web pages.
7. Write a program by which we can split mpeg video into smaller pieces for the
purpose of sending it over the web or by small capacity floppy diskettes and
then joining them at the destination.
8. Write a program to simulate the game of pool table.
9. Write a program to simulate the game Mine Sweeper.
10. Write a program to play “wave” or “midi” format sound files.
EE-329-E MICROPROCESSORS AND
INTERFACING LAB
L T P CLASS WORK :
25
0 0 2 EXAM :
25
TOTAL :
50
DURATION OF EXAM :
3 HRS
LIST OF EXPERIMENTS:
1. Study of 8085 Microprocessor kit.
2. Write a program using 8085 and verify for :
a. Addition of two 8-bit numbers.
b. Addition of two 8-bit numbers (with carry).
3. Write a program using 8085 and verify for :
a. 8-bit subtraction (display borrow)
b. 16-bit subtraction (display borrow)
4. Write a program using 8085 for multiplication of two 8- bit numbers by repeated
addition method. Check for minimum number of additions and test for typical data.
5. Write a program using 8085 for multiplication of two 8- bit numbers by bit rotation
method and verify.
6. Write a program using 8085 for division of two 8- bit numbers by repeated subtraction
method and test for typical data.
7. Write a program using 8085 for dividing two 8- bit numbers by bit rotation method
and test for typical data.
8. Study of 8086 microprocessor kit
9. Write a program using 8086 for division of a defined double word (stored in a data
segment) by another double Word division and verify.
10. Write a program using 8086 for finding the square root of a given number and verify.
11. Write a program using 8086 for copying 12 bytes of data from source to destination
and verify.
12. Write a program using 8086 and verify for:
a. Finding the largest number from an array.
b. Finding the smallest number from an array.
13. Write a program using 8086 for arranging an array of numbers in descending order
and verify.
14. Write a program using 8086 for arranging an array of numbers in ascending order
and verify.
15. Write a program for finding square of a number using look-up table and verify. .
16. Write a program to interface a two digit number using seven-segment LEDs. Use
8085/8086 microprocessor and 8255 PPI.
17. Write a program to control the operation of stepper motor using 8085/8086
microprocessor and 8255 PPI.
CSE-313 E Operating Systems Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
Study of WINDOWS 2000 Operating System.
Administration of WINDOWS 2000 (including DNS,LDAP, Directory Services)
Study of LINUX Operating System (Linux kernel, shell, basic commands pipe &
filter commands).
Administration of LINUX Operating System.
Writing of Shell Scripts (Shell programming).
AWK programming.
CSE VI Semester
CSE-302 E Principles of Software Engineering
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction: The process, software products, emergence of software engineering, evolving
role of software, software life cycle models, Software Characteristics, Applications, Software crisis.
Unit-2 : Software project management:Project management concepts, software
process and project metrics Project planning, project size estimation metrics,
project estimation Techniques, empirical estimation techniques, COCOMO- A
Heuristic estimation techniques, staffing level estimation, team structures,
staffing, risk analysis and management, project scheduling and tracking.
Unit-3 : Requirements Analysis and specification requirements engineering, system modeling and
simulation Analysis principles modeling, partitioning Software, prototyping: , Prototyping methods
and tools; Specification principles, Representation, the software requirements specification and
reviews Analysis Modeling: Data Modeling, Functional modeling and information flow: Data flow
diagrams, Behavioral Modeling; The mechanics of structured analysis: Creating entity/ relationship
diagram, data flow model, control flow model, the control and process specification; The data
dictionary; Other classical analysis methods.
Unit-4: System Design: Design concepts and principles: the design process: Design and
software quality, design principles; Design concepts: Abstraction, refinement, modularity,
software architecture, control hierarchy, structural partitioning, data structure, software
procedure, information hiding; Effective modular design: Functional independence, Cohesion,
Coupling; Design Heuristics for effective modularity; The design model; Design documentation.
Architectural Design: Software architecture, Data Design: Data modeling, data structures,
databases and the data warehouse, Analyzing alternative Architectural Designs ,architectural
complexity; Mapping requirements into a software architecture; Transform flow, Transaction
flow; Transform mapping: Refining the architectural design.
Unit-5 : Testing and maintenance: Software Testing Techniques, software testing
fundamentals: objectives, principles, testability; Test case design, white box testing, basis path
testing: Control structure testing: Black box testing, testing for specialized environments
,architectures and applications. Software Testing Strategies: Verification and validation, Unit
testing, Integration testing,; Validation testing, alpha and beta testing; System testing: Recovery
testing, security testing, stress testing, performance testing; The art of debugging, the debugging
process debugging approaches. Software re-engineering , reverse engineering ,restructuring,
forward engineering.
Unit-6 : Software Reliability and Quality Assurance :Quality concepts, Software quality
assurance , SQA activities; Software reviews: cost impact of software defects, defect
amplification and removal; formal technical reviews: The review meeting, review reporting and
record keeping, review guidelines; Formal approaches to SQA; Statistical software quality
assurance; software reliability: Measures of reliability and availability ,The ISO 9000 Quality
standards: The ISO approach to quality assurance systems, The ISO 9001 standard, Software
Configuration Management.
Unit-7: Computer Aided software Engineering: CASE, building blocks,
integrated case environments and architecture, repository.
CSE-304 E Intelligent Systems
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Foundational issues in intelligent systems: Foundation and history of AI, Ai
problems and techniques – AI programming languages, introduction to LISP and
PROLOG- problem spaces and searches, blind search strategies, Breadth first- Depth
first- heuristic search techniques Hill climbing: best first- A * algorithm AO* algorithm-
game tree, Min max algorithms, game playing- alpha beta pruning.
Unit-2: Knowledge representation issues, predicate logic- logic programming, semantic
nets- frames and inheritance, constraint propagation, representing knowledge using rules,
rules based deduction systems.
Unit-3: Reasoning under uncertainty, review of probability, Baye‟s probabilistic
interferences and Dempster shafer theory, Heuristic methods, symbolic reasoning under
uncertainty, Statistical reasoning, Fuzzy reasoning, Temporal reasoning, Non monotonic
reasoning.
Unit-4: Planning, planning in situational calculus, representation for planning, partial
order planning algorithm, learning from examples, discovery as learning, I earning by
analogy, explanation based learning, neural nets, genetic algorithms.
Unit-5: Principles of Natural language processing, rule based systems architecture,
Expert systems, knowledge acquisition concepts, AI application to robotics, and current
trends in intelligent systems.
IT-305 E Computer Networks
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: OSI Reference Model and Network Architecture: Introduction to Computer
Networks, Example networks ARPANET, Internet, Private Networks, Network
Topologies: Bus-, Star-, Ring-, Hybrid -, Tree -, Complete -, Irregular –Topology; Types
of Networks : Local Area Networks, Metropolitan Area Networks, Wide Area Networks;
Layering architecture of networks, OSI model, Functions of each layer, Services and
Protocols of each layer
Unit–2: TCP/IP: Introduction, History of TCP/IP, Layers of TCP/IP, Protocols, Internet
Protocol, Transmission Control Protocol , User Datagram Protocol, IP Addressing, IP
address classes, Subnet Addressing, Internet Control Protocols, ARP, RARP, ICMP,
Application Layer, Domain Name System, Email – SMTP, POP,IMAP; FTP, NNTP,
HTTP, Overview of IP version 6.
Unit-3: Local Area Networks: Introduction to LANs, Features of LANs, Components
of LANs, Usage of LANs, LAN Standards, IEEE 802 standards, Channel Access
Methods, Aloha, CSMA, CSMA/CD, Token Passing, Ethernet, Layer 2 & 3 switching,
Fast Ethernet and Gigabit Ethernet, Token Ring, LAN interconnecting devices: Hubs,
Switches, Bridges, Routers, Gateways.
Unit–4: Wide Area Networks: Introduction of WANs, Routing, Congestion Control,
WAN Technologies, Distributed Queue Dual Bus (DQDB), Synchronous Digital
Hierarchy (SDH)/ Synchronous Optical Network (SONET), Asynchronous Transfer
Mode (ATM), Frame Relay.,Wireless Links.
Unit-5: Introduction to Network Management: Remote Monitoring Techniques:
Polling, Traps, Performance Management, Class of Service, Quality of Service, Security
management, Firewalls, VLANs, Proxy Servers, Introduction to Network Operating
Systems: Client-Server infrastructure, Windows NT/2000.
IT-303 E Systems Programming &System Administration
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Evolution of Components Systems Programming, Assemblers, Loaders,
Linkers, Macros, Compilers. software tools, Text editors, Interpreters and program
generators, Debug Monitors, Programming environment.
Unit-2: Compiler: Brief overview of compilation process, Incremental compiler,
Assembler: Problem statement, single phase and two phase assembler, symbol table;
Loader schemes, compile and go Loader, general loader schemes, absolute loader,
Subroutine linkage, Reallocating loader, Direct linkage Loader, Binders, Linking loader,
overlays.
Unit-3: Macro language and macro-processor, macro instructions, features of
macro facility, macro instruction arguments, conditional macro expansion, macro calls
with macro instruction defining macros.
Unit-4: Theoretical Concept of Unix Operating System: Basic features of operating
system;
File structure: CPU scheduling; Memory management: swapping, demand paging; file
system: block
and fragments, inodes, directory structure; User to user communication.
Unit-5: Getting Started with Unix: User names and groups, logging in; Format of Unix
commands; Changing your password; Characters with special meaning; Unix
documentation; Files
and directories; Current directory, looking at the directory contents, absolute and relative
pathnames,
some Unix directories and files; Looking at the file contents; File permissions; basic
operation on
files; changing permission modes; Standard files, standard output; Standard input,
standard error;
filters and pipelines; Processes; finding out about processes; Stopping background
process; Unix
editor vi.
Unit-6: Test Manipulation: Inspecting files; File statistics; Searching for patterns;
Comparing
files; Operating on files; Printing files; Rearranging files; Sorting files; Splitting files;
Translating
characters; AWK utility.
Unit-7: Shell Programming: Programming in the Borne and C-Shell; Wild cards;
Simple shell
programs; Shell variables; Shell programming constructs; interactive shell scripts;
Advanced
features.
Unit-8: System Administration: Definition of system administration; Booting the
system; Maintaining user accounts; File systems and special files; Backups and
restoration; Role and functions of a system manager.
Overview of the linux. operating system
EE-402-E Wireless Communication
L T P CLASS WORK :
50
3 1 0 EXAM :
100
TOTAL :
150
DURATION OF EXAM :
3 HRS
UNIT 1. INTRODUCTION TO WIRELESS COMMUNICATION SYSTEMS:
Evolution of mobile radio communications, examples of wireless comm. systems, paging
systems, Cordless telephone systems, comparison of various wireless systems.
UNIT 2. MODERN WIRELESS COMMUNICATION SYSTEMS:
Second generation cellular networks, third generation wireless networks, wireless in local
loop, wireless local area networks, Blue tooth and Personal Area networks.
UNIT 3. INTRODUCTION TO CELLULAR MOBILE SYSTEMS:
Spectrum Allocation, basic Cellular Systems, performance Criteria, Operation of cellular
systems, analog cellular systems, digital Cellular Systems.
UNIT 4. ELLULAR SYSTEM DESIGN FUNDAMENTALS:
Frequency Reuse, channel assignment strategies, handoff Strategies, Interference and
system capacity, tracking and grade off service, improving coverage and capacity.
UNIT 5. MULTIPLE ACCESS TECHNIQUES FOR WIRELESS
COMMUNICATION:
Introduction to Multiple Access, FDMA, TDMA, Spread Spectrum multiple Access,
space division multiple access, packet ratio, capacity of a cellular systems.
UNIT 6. WIRELESS NETWORKING:
Difference between wireless and fixed telephone networks, development of wireless
networks, fixed network transmission hierarchy, traffic routing in wireless networks,
wireless data services, common channel signaling, ISDN (Integrated Services digital
Networks), advanced intelligent networks.
UNIT 7. INTELLIGENT CELL CONCEPT AND APPLICATION:
Intelligent cell concept, applications of intelligent micro-cell Systems, in-Building
Communication, CDMA cellular Radio Networks.
EE-310-E DIGITAL SYSTEM DESIGN
L T P CLASS WORK :
50
3 1 0 EXAM :
100
TOTAL :
150
DURATION OF EXAM :
3 HRS
UNIT 1. INTRODUCTION :
Introduction to Computer-aided design tools for digital systems. Hardware description
languages; introduction to VHDL, data objects, classes and data types, Operators,
Overloading, logical operators.Types of delays Entity and Architecture declaration.
Introduction to behavioural, dataflow and structural models.
UNIT 2. VHDL STATEMENTS :
Assignment statements, sequential statements and process, conditional statements, case
statement Array and loops, resolution functions, Packages and Libraries, concurrent
statements.
Subprograms: Application of Functions and Procedures, Structural Modelling,
component declaration, structural layout and generics.
UNIT 3. COMBINATIONAL CIRCUIT DESIGN:
VHDL Models and Simulation of combinational circuits such as Multiplexers,
Demultiplexers, encoders, decoders, code converters, comparators, implementation of
Boolean functions etc.
UNIT 4. SEQUENTIAL CIRCUITS DESIGN :
VHDL Models and Simulation of Sequential Circuits
Shift Registers, Counters etc.
UNIT 5. DESIGN OF MICROCOMPUTER :
Basic components of a computer, specifications, architecture of a simple microcomputer
system, implementation of a simple microcomputer system using VHDL
UNIT 6. DESIGN WITH CPLDs AND FPGAs :
Progr ammable logic devices : ROM, PLAs, PALs, GAL, PEEL, CPLDs and FPGA.
Design implementation using CPLDs and FPGAs
CSE-306 E Intelligent System Lab.
L T P Class Work: 25
- - 2 Exam: 25
Total: 50
Duration of Exam: 3
Hrs.
1. Study of PROLOG.
Write the following programs using PROLOG.
2. Write a program to solve 8 queens problem.
3. Solve any problem using depth first search.
4. Solve any problem using best first search.
5. Solve 8-puzzle problem using best first search
6. Solve Robot (traversal) problem using means End Analysis.
7. Solve traveling salesman problem.
EE-330-E DIGITAL SYSTEM DESIGN LAB
L T P CLASS WORK :
25
0 0 2 EXAM :
25
TOTAL :
50
DURATION OF EXAM :
3 HRS
LIST OF EXPERIMENTS:
1. Design all gates using VHDL.
2. Write VHDL programs for the following circuits, check the wave forms and the
hardware generated
a. half adder
b. full adder
3. Write VHDL programs for the following circuits, check the wave forms and the
hardware generated
a. multiplexer
b. demultiplexer
4. Write VHDL programs for the following circuits, check the wave forms and the
hardware generated
a. decoder
b. encoder
5. Write a VHDL program for a comparator and check the wave forms and the hardware
generated
6 Write a VHDL program for a code converter and check the wave forms and the
hardware generated
7. Write a VHDL program for a FLIP-FLOP and check the wave forms and the hardware
generated
8. Write a VHDL program for a counter and check the wave forms and the hardware
generated
9. Write VHDL programs for the following circuits, check the wave forms and the
hardware generated
a. register
b. shift register
10. Implement any three (given above) on FPGA/CPLD kit
CSE VII Semester
CSE-401 E Advanced Computer Architecture
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit–1: Architecture And Machines: Some definition and terms, interpretation and
microprogramming. The instruction set, Basic data types, Instructions, Addressing and
Memory. Virtual to real mapping. Basic Instruction Timing.
Unit–2: Time, Area And Instruction Sets: Time, cost-area, technology state of the Art,
The Economics of a processor project: A study, Instruction sets, Professor Evaluation
Matrix
Unit-3: Cache Memory Notion: Basic Notion, Cache Organization, Cache Data,
adjusting the data for cache organization, write policies, strategies for line replacement at
miss time, Cache Environment, other types of Cache. Split I and D-Caches, on chip
caches, Two level Caches, write assembly Cache, Cache references per instruction,
technology dependent Cache considerations, virtual to real translation, overlapping the
Tcycle in V-R Translation, studies. Design summary.
Unit–4: Memory System Design: The physical memory, models of simple processor
memory interaction, processor memory modeling using queuing theory, open, closed and
mixed-queue models, waiting time, performance, and buffer size, review and selection of
queueing models, processors with cache.
Unit–5: Concurrent Processors: Vector Processors, Vector Memory, Multiple Issue
Machines, Comparing vector and Multiple Issue processors.
Shared Memory Multiprocessors: Basic issues, partitioning, synchronization and
coherency, Type of shared Memory multiprocessors, Memory Coherence in shared
Memory Multiprocessors.
CSE-403 E Software Project Management
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction to Software Project Management (SPM): Definition of a
Software Project (SP), SP Vs. other types of projects activities covered by SPM,
categorizing SPs, project as a system, management control, requirement specification,
information and control in organization.
Unit-2: Stepwise Project planning: Introduction, selecting a project, identifying project
scope and objectives, identifying project infrastructure, analyzing project characteristics,
identifying project products and activities, estimate efforts each activity, identifying
activity risk, allocate resources, review/ publicize plan.
Unit-3: Project Evaluation & Estimation: Cost benefit analysis, cash flow
forecasting, cost benefit evaluation techniques, risk evaluation. Selection of an
appropriate project report; Choosing technologies, choice of process model, structured
methods, rapid application development, water fall-, V-process-, spiral- models.
Prototyping, delivery. Albrecht function point analysis.
Unit-4: Activity planning & Risk Management: Objectives of activity planning,
project schedule, projects and activities, sequencing and scheduling activities, network
planning model, representation of lagged activities, adding the time dimension, backward
and forward pass, identifying critical path, activity throat, shortening project , precedence
networks.
Risk Management: Introduction, the nature of risk, managing risk, risk identification,
risk analysis, reducing the risks, evaluating risks to the schedule, calculating the z values..
Unit-5: Resource allocation &Monitoring the control: Introduction, the nature of
resources, identifying resource requirements, scheduling resources creating critical paths,
counting the cost, being specific, publishing the resource schedule, cost schedules, the
scheduling sequence.
Monitoring the control: Introduction, creating the frame work, collecting the data,
visualizing progress, cost monitoring, earned value, prioritizing monitoring, getting the
project back to target, change control.
Unit-6: Managing contracts and people: Introduction, types of contract, stages in
contract, placement, typical terms of a contract, contract management, acceptance,
Managing people and organizing terms: Introduction, understanding behavior,
organizational behavior: a back ground, selecting the right person for the job, instruction
in the best methods, motivation, working in groups, becoming a team, decision making,
leadership, organizational structures, conclusion, further exercises..
Unit-7: Software quality: Introduction, the place of software quality in project
planning, the importance of software quality, defining software quality, ISO 9126,
Practical software quality measures, product versus process quality management, external
standards, techniques to help enhance software quality.
Unit-8: Study of Any Software Project Management software: viz Project 2000 or
equivalent
CSE-405-E Compiler Design
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit–1: Introduction To Compilers: Compilers and translators, need of translators,
structure of compiler :its different phases, Compiler construction tools.
Unit–2: Lexical Analysis: Role of lexical analyzer, design of lexical analyzer, regular
expressions , Specification and recognition of tokens, input buffering, A language
specifying lexical analyzer. Finite automata, conversion from regular expression to finite
automata, and vice versa, minimizing number of states of DFA, Implementation of
lexical analyzer.
Unit–3: Syntax Analysis: Role of parsers, context free grammars, definition of parsing.
Unit–4: Parsing Technique: Shift- reduce parsing, operator precedence parsing, top
down par sing, predictive parsing.
Unit–5: LR parsers, SLR, LALR and Canonical LR parser.
Unit–6: Syntax Directed Translations: Syntax directed definition, construction of
syntax trees, syntax directed translation scheme, implementation of syntax directed
translation, three address code, quadruples and triples.
Unit–7: Symbol Table & Error Detection And Recovery: Symbol tables, its contents
and data structure for symbol tables; trees, arrays, linked lists, hash tables. Errors, lexical
phase error, syntactic phase error, semantic error.
Unit–8: Code Optimization & Code Generation: Code generation, forms of objects
code, machine dependent code, optimization, register allocation for temporary and user
defined variables.
CSE-411- E Compiler Design Lab
L T P Class Work: 25
- - 3 Exam:
50
Total:
75 Duration
of Exam: 3Hrs.
1. Practice of LEX/YACC of compiler writing.
2. Write a program to check whether a string belong to the grammar or
not.
3. Write a program to generate a parse tree.
4. Write a program to find leading terminals.
5. Write a program to find trailing terminals.
6. Write a program to compute FIRST of non-terminal.
7. Write a program to compute FOLLOW of non-terminal.
8. Write a program to check whether a grammar is left Recursion and
remove left Recursion.
9. Write a program to remove left factoring.
10. Write a program to check whether a grammar is operator precedent.
11. To show all the operations of a stack.
12. To show various operations i.e. red, write and modify in a text file.
CSE-409 E Visual Programming Lab.
L T P Class Work: 25
- - 3 Exam:
50
Total:
75
Duration of Exam:
3 Hrs.
Study of Visual Basic 6.0.NET and Visual C++ 6.0.NET.
1) Study Windows API‟s. Find out their relationship with MFC classes.
Appreciate how they are helpful in finding complexities of windows
programming.
2) Get familiar with essential classes in a typical (Document- view architecture)
VC++ Program and their relationship with each other.
3) Create an SDI application in VC++ that adds a popup menu to your
application which uses File drop down menu attached with the menu bar as
the pop-up menu. The pop-up menu should be displayed on the right click of
the mouse.
4) Create an SDI application in VC++ using which the user can draw atmost 20
rectangles in the client area. All the rectangles that are drawn should remain
visible on the screen even if the window is refreshed. Rectangle should be
drawn on the second click of the left mouse button out of the two consecutive
clicks. If the user tries to draw more than 20 rectangles, a message should get
displayed in the client area that “ No more rectangles can be drawn”
5) Create an application in VC++ that shows how menu items can be grayed,
disabled and appended at run time.
6) Write a program in VC++ to implement serialization of inbuilt and user
defined objects.
7) Write a program in VC++ to create archive class object from CFile class that
reads and stores a simple structure (record).
8) Make an Active X control in VC++ derived from a standard control.
9) Write a program in VB to implement a simple calculator.
10) Create a simple database in MS Access Database /Oracle and a simple
database application in VB that shows database connectivity through DAO
and ADO.
11) Write a simple program that displays an appropriate message when the illegal
operation is performed using error handling technique in VB.
12) Write a program in VB to create a notepad.
13) Create a DLL in VB.
Bright students may do the following exercises:
14) Write a program in VC++ to implement a simple calculator.
15) Write a program in VC++ to create a static link library and a dynamic link
library.
16) Create a simple database in MS Access Database and a simple database
application in VC++ that shows database connectivity through ADO model.
17) Make an Active X control of your own using VB.
18) With the help of VB, create an object of excel application and implement any
action on it.
CSE-407- E Neural Networks
L T P Class Work: 50
4 - - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Overview of biological neurons: Structure of biological neurons relevant to
ANNs.
Unit-2: Fundamental concepts of Artificial Neural Networks: Models of ANNs;
Feedforward & feedback networks; learning rules; Hebbian learning rule, perception
learning rule, delta learning rule, Widrow-Hoff learning rule, correction learning rule,
Winner –lake all elarning rule, etc.
Unit-3: Single layer Perception Classifier: Classification model, Features & Decision
regions; training & classification using discrete perceptron, algorithm, single layer
continuous perceptron networks for linearlyseperable classifications.
Unit-4: Multi-layer Feed forward Networks: linearly non-seperable pattern
classification, Delta learning rule for multi-perceptron layer, Generalized delta learning
rule, Error back-propagation training, learning factors, Examples.
Unit-5: Single layer feed back Networks: Basic Concepts, Hopfield networks, Training
& Examples.
Unit-6: Associative memories: Linear Association, Basic Concepts of recurrent Auto
associative memory: rentrieval algorithm, storage algorithm; By directional associative
memory, Architecture, Association encoding & decoding, Stability.
Unit-7: Self organizing networks: UN supervised learning of clusters, winner-take-all
learning, recall mode, Initialisation of weights, seperability limitations
CSE VIII Semester
CSE-402 E Distributed Operating System
L T P Class Work: 50
3 1 - Exam: 100
Total: 150
Duration of Exam: 3
Hrs.
Unit-1: Introduction: Introduction to Distributed S ystem, Goals of
Distributed system, Hardware and Software concepts, Design issues.
Communication in distributed system: Layered protocols, ATM networks, Client –
Server model ,Remote Procedure Calls and Group Communication. Middleware and
Distributed Operating Systems.
Unit-2: Synchronization in Distributed System: Clock synchronization, Mutual
Exclusion, Election algorithm, the Bully algorithm, a Ring algorithm, Atomic
Transactions, Deadlock in Distributed Systems, Distributed Deadlock Prevention,
Distributed Deadlock Detection .
Unit-3: Processes and Processors in distributed systems: Threads, System models,
Processors Allocation, Scheduling in Distributed System, Real Time Distributed
Systems.
Unit-4: Distributed file systems: Distributed file system Design, Distributed file system
Implementation, Trends in Distributed file systems.
Distributed Shared Memory: What is shared memory, Consistency models, Page
based distributed shared memory, shared variables distributed shared memory.
Unit-5: Case study MACH: Introduction to MACH, process management in MACH,
communication in MACH, UNIX emulation in MACH.
ADVANCED JAVA
CSE-404-E
L T P Class Work : 50
3 1 0 Exam. : 100
Total : 150
Duration of Exam. : 3 hrs.
UNIT 1: CORE JAVA
Introduction to Java, Data types, variables, operators, Arrays, Control Statements, Classes
& Methods, Inheritance, Exception Handling, Multithreading, Collections, I/O streams,
AVVT & Apolet Programming.
UNIT 2: NETWORKING
Connecting to a Server, Implementing Servers, Sending E-Mail, Making URL
Connections, Advanced Socket Programming
UNIT 3: DATABASE NETWORKING
The Design of JDBC. The Structured Query Language, JDBC Installation, Basic JDBC
Programming Concepts, Query Execution, Scrollable and Updatable Result Sets,
Matadata, Row Sets, Transactions, Advanced Connection Management, Introduction of
LDAP
UNIT 4: DISTRIBUTED OBJECTS
The Roles of Client and Server, Remote Method Invocations, Setup for Remote Method
Invocation, Parameter Passing in Remote Methods Server Object Activation, Java IDL
and CCRA, Remote Method Calls with SOAP
UNIT 5: SWING
Lists, Trees, Tables, Styled Text Components, Progress Indicators, Component
Organizers
UNIT 6: AWT
The Rendering Pipeline, Shapes, Areas, Strokes, Paint, Coordinate Transformations,
Clipping, Transparency and Composition, Rendering Hints, Readers and Writers for
Images, Image Manipulation, Printing. The Clipboard, Drag and Drop
UNIT 7: JAVABEANS COMPONENTS
Beans, The Bean-Writing Process, Using Beans to Build an Application, Naming Patterns
for Bean Components and Events Bean Property Tubes Beaninfo Classes Property
Editors Cuatomizes
UNIT 8: SECURITY
Class Loaders, Bytecode Verification, Security Managers and Permissions, Digital
Signatures, Code Signing, Encryption
CSE-- 406-E Advanced JAVA Lab.
L T P Class Work:
50
- - 3 Exam:
50
Total:
100
Duration of exam: 3
hrs.
Development of programs relating to :
JDBC
Servlets
Beans
RMI
JSP
Electrical & Electronics Engineering (EEE)
Semester IIIrd
HUM-201-E ECONOMICS
(COMMON FOR ALL BRANCHES)
L T P Class Work :
50 Marks
3 1 - Theory :
100 Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
COURSE OBJECTIVE : The purpose of this course is to :
1. Acquaint the student in the basic economic concepts and their operational significance and
2 .Stimulate him to think systematically and objectively about contemporary economic problems.
UNIT-I
Definition of Economics - various definitions, Nature of Economic problem, Production possibility curve
Economic laws and their nature. Relation between Science, Engineering, Technology and Economics.
UNIT-II
Concepts and measurement of utility, Law of Diminishing Marginal Utility, Law of equi-marginal
utility - its practical application and importance.
UNIT-III
Meaning of Demand, Individual and Market demand schedule, Law of demand, shape of demand curve,
Elasticity of demand, measurement of elasticity of demand, factors effecting elasticity of demand, practical
importance & applications of the concept of elasticity of demand.
UNIT-IV
Meaning of production and factors of production; Law of variable proportions, Returns to scale, Internal
and External economics and diseconomies of scale.
Various concepts of cost - Fixed cost, variable cost, average cost, marginal cost, money cost, real
cost opportunity cost. Shape of average cost, marginal cost, total cost etc. in short run and long run.
UNIT-V
Meaning of Market, Types of Market - Perfect Competition, Monopoly, Oligoply, Monoplistic Competition
(Main features of these markets)
Supply and Law of Supply, Role of Demand & Supply in Price Determinition and effect of changes in
demand and supply on prices.
UNIT-VI
Nature and characteristics of Indian economy (brief and elementary introduction), Privatization - meaning,
merits and demerits. Globalisation of Indian economy - merits and demerits. Elementary Concepts of VAT, WTO,
GATT & TRIPS agreement.
MATH-201-E MATHEMATICS-III
---------- ---------------
(COMMON FOR ALL BRANCHES)
L T P Class Work : 50
Marks
3 2 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hours
Part-A
Fourier Series and Fourier Transforms : Euler’s
formulae, conditions for a Fourier expansion, change of
interval, Fourier expansion of odd and even functions,
Fourier expansion of square wave, rectangular wave, saw-
toothed wave, half and full rectified wave, half range
sine and consine series.
Fourier integrals, Fourier transforms, Shifting
theorem (both on time and frequency axes), Fourier
transforms of derivatives, Fourier transforms of
integrals, Convolution theorem, Fourier transform of
Dirac-delta function.
Part-B
Functions of Complex Variable : Definition,
Exponential function, Trignometric and Hyperbolic
functions, Logrithmic functions. Limit and
Continuity of a function, Differnetiability and
Analyticity.
Cauchy-Riemann equations, necessary and
sufficient conditions for a function to be analytic,
polar form of the Cauchy-Riemann equations. Harmonic
functions, application to flow problems. Integration
of complex functions. Cauchy-Integral theorem and
formula.
Power series, radius and circle of convergence,
Taylor's Maclaurin's and Laurent's series. Zeroes and
singularities of complex functions, Residues.
Evaluation of real integrals using residues (around unit
and semi circle only).
Part-C
Probability Distributions and Hypothesis Testing :
Conditional probability, Bayes theorem and its
applications, expected value of a random variable.
Properties and application of Binomial, Poisson and
Normal distributions.
Testing of a hypothesis, tests of significance
for large samples, Student’s t-distribution (applications
only), Chi-square test of goodness of fit.
Linear Programming : Linear programming problems
formulation, Solving linear programming problems using
(i) Graphical method (ii) Simplex method (iii) Dual
simplex method.
EE-201-E ELECTRICAL ENGINEERING MATERIALS AND SEMICONDUCTOR DEVICES
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1 CONDUCTING MATERIALS:
Review of energy bands, description of materials, drift velocity, collision time, Mean
free path, mobility, conductivity, relaxation time, factors affecting conductivity of
materials, types of thermal conductivity, Wiedmann-Franz law, super conductivity,
effect of magnetic field, conducting materials, applications.
UNIT 2 DIELECTRIC MATERIALS:
Behaviour of dielectric materials in static electric field, Dipole moments, Polarization,
Dielectric constant, Polarizability, Susceptibility, mechanisms of polarization, behaviour
in alternating field, dielectric loss, loss tangent, types of dielectric & insulating
materials, electrostriction, Piezo-electricity, Applications.
UNIT 3 MAGNETIC MATERIALS:
Permeability, Magnetic susceptibility, magnetic moment, Magnetization, Dipole
moment, types of magnetic materials, Magnetostriction, eddy current & hysteresis
losses, applications.
UNIT 4 SEMICONDUCTORS:
Review of Si and Ge as semiconducting materials, Continuity Equation, P-N junction,
Drift & Diffusion, Diffusion & Transition capacitances of P-N junction.
UNIT 5 CONSTRUCTION AND CHARACTERISTICS OF DEVICES:
Brief introduction to Planar Technology for device fabrication., metal -semiconductor
junctions (ohmic and non-ohmic), breakdown mechanisms in p-n junction, zener diode,
electrical and optical excitation in diodes, LED, solar cells and photo-detectors.
UNIT 6 BIPOLAR AND MOS DEVICES :
BJT, UJT, JFET, MOSFETS
UNIT 7 POWER DEVICES :
Thyristor, Diac, Triac, GTO, IGBT, VMOS
EE-203-E NETWORK THEORY
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT I TRANSIENT RESPONSE :
Transient Response of RC, RL, RLC Circuits to various excitation signals such as step,
ramp, impulse and sinusoidal excitations using laplace transform.
UNIT 2 NETWORK FUNCTIONS :
Terminal pairs or Ports, Network functions for one-port and two-port networks, poles
and zeros of Network functions, Restrictions on pole and zero Locations for driving
point functions and transfer functions, Time domain behavior from the pole-zero plot.
UNIT 3 CHARACTERISTICS AND PARAMETERS OF TWO PORT NETWORKS :
Relationship of two-port variables, short-circuit Admittance parameters, open circuit
impedance, parameters, Transmission parameters, hybrid parameters, relationships
between parameter sets, Inter-connection of two port networks.
UNIT 4 TOPOLOGY :
Principles of network topology , graph matrices, network analysis using graph theory.
UNIT 5 TYPES OF FILTERS AND THEIR CHARACTERISTICS :
Filter fundamentals, high-pass, low-pass, band-pass, and band-reject Filters.
UNIT 6 NETWORK SYNTHESIS :
Positive real functions, synthesis of one port and two port networks, elementary ideas of
Active networks.
EE-207-E ELECTRICAL MACHINES - I
L T P Theory :100
Marks
3 1 - Class work : 50 Marks
Total :150
Marks
Duration of Exam :3 Hrs.
TRANSFORMERS: Principle, construction of core, winding & tank, operation, testing of single phase
transformer, equivalent circuit, phasor diagram, parameters determination, P.U. representation of
parameters, regulation, losses & efficiency, separation of iron losses.
Various types of connection of three phase transformer, their comparative features, Zig-Zag connection.
Parallel operation of single phase & three phase transformers.
Auto-transformer: Principle, construction, comparison with two winding transformers, application.
Nature of magnetizing current, plotting of magnetising current from B-H curve, Inrush current, harmonics,
effect of construction on input current, connection of three phase transformer.
Phase-Conversion: Three to two phase, three to six phase and three to twelve phase conversions.
Introduction to three winding, tap-changing & phase-shifting transformers.
D.C. MACHINES: Elementary DC machine, principle & construction of D.C. generator, simplex lap and
wave windings, E.M.F. equation, armature reaction, compensating winding, commutation, methods of
excitation, load characteristics, parallel operation. Principle of DC Motors, torque and output power
equations, load characteristics, starting, speed control, braking, testing, efficiency & applications.
EE-209-E ELECTRICAL MEASUREMENTS & MEASURING INSTRUMENTS
L T P Class Work
:50
3 1 0 Exam
:100
Total
:150
Duration of Exam
:3hrs
UNIT-I: UNITS STANDARDS & ERRORS: S.I. units, Absolute standards (International, Primary,
Secondary & Working Standards), True Value, Errors (Gross, Systematic, Random); Static
Characteristic of Instruments (Accuracy, Precision, Sensitivity, Resolution & threshold).
UNIT-II: MEASURING SYSTEM FUNDAMENTALS: Classification of Instruments (Absolute &
Secondary Instruments; Indicating, Recording & Integrating instruments; Based upon Principle of
operation), Generalized Instrument (Block diagram, description of blocks), three forces in
Electromechanical indicating instrument (Deflecting, controlling & damping forces), Comparison
between gravity & spring controls; Comparison of damping methods & their suitability, bearing
supports, pivot-less supports (Simple & taut-band), Scale information, Instrument cases (Covers).
UNIT-III: MEASURING INSTRUMENTS: Construction, operating principle, Torque equation,
Shape of scale, use as Ammeter or as Voltmeter (Extension of Range), Use on AC/DC or both,
Advantages & disadvantages, Errors (Both on AC/DC) of PMMC types, Electrodynamic Type,
Moving iron type (attraction, repulsion & combined types), Hot wire type & Induction type,
Electrostatic type Instruments.
UNIT-IV: WATTMETERS & ENEGRY METERS: Construction, operating principle, Torque
equation, Shape of scale, Errors, Advantages & Disadvantages of Electrodynamic & Induction
type Wattmeters; & single phase induction type Energy meter, Compensation & creep in energy
meter.
UNIT-V: POWER FACTOR & FREQUENCY METERS: Construction, operation, principle, Torque
equation, Advantages & disadvantages of Single phase power factor meters (Electrodynamic &
Moving Iron types) & Frequency meters (Electrical Resonance Type, Ferrodynamic &
Electrodynamic types).
UNIT-VI: LOW & HIGH RESISTANCE MEASUREMENTS: Limitations of Wheatstone bridge;
Kelvin’s double bridge method, Difficulties in high resistance measurements, Measurement of
high resistance by direct deflection, loss of charge method, Megohm bridge & Meggar.
UNIT-VII: A.C. BRIDGES: General balance =n, Ckt. diagram, Phasor diagram, Advantages,
disadvantages, applications of Maxwell’s inductance, inducance-capacitance, Hays, Anderson,
Owens, De-Sauty’s, Schering & Weins bridges, Shielding & earthing.
EE-223-E NETWORK THEORY LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS :
1. Transient response of RC circuit.
2. Transient response of RL circuit.
3. To find the resonance frequency, Band width of RLC series circuit.
4. To calculate and verify "Z" parameters of a two port network.
5. To calculate and verify "Y" parameters of a two port network.
6. To determine equivalent parameter of parallel connections of two port network.
7. To plot the frequency response of low pass filter and determine half-power
frequency.
8. To plot the frequency response of high pass filter and determine the half-power
frequency.
9. To plot the frequency response of band-pass filter and determine the band-width.
10. To calculate and verify "ABCD" parameters of a two port network.
11. To synthesize a network of a given network function and verify its response.
12. Introduction of P-Spice
EE-211-E ELECTRICAL MEASURMENTS & MEASURING INSTRUMENTS LAB
L T P Class Work : 25
0 0 2 Exam : 25
Total : 50
Duration of Exam : 3hrs
LIST OF EXPERIMENTS :
1. To identify the meters from the given lot.
2. To convert & calibrate a D‟Arsonnal type galvanometer into a voltmeter & an ammeter.
3. To calibrate an energy meter with the help of a standard wattmeter & a stop watch.
4. To measure power & p.f. by 3-ammeter method.
5. To measure power & p.f by 3-voltmeter method.
6. To measure power & p.f in 3-phase circuit by 2-wattmeter method.
7. To measure capacitance by De Sauty's bridge.
8. To measure inductance by maxwell's bridge.
9. To measure frequency by Wien's bridge.
10. To measure the power with the help of C.T & P.T.
11. To measure magnitude & phase angle of a voltage by rectangular type potentiometer.
12. To measure magnitude & phase angle of a voltage by polar type potentiometer.
13. To measure low resistance by Kelvin's double bridge.
14. To measure high resistence by loss of charge method.
EE-231-E ELECTRICAL WORKSHOP
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Introduction of tools, electrical materials, symbols and abbreviations.
2. To study stair case wiring.
3. To study house wiring i.e., batten, cleat, casing-caping and conduit wirings.
4. To study fluorescent tube light.
5. To study high pressure mercury vapour lamp (H.P.M.V).
6. To study Sodium lamp.
7. To study repairing of home appliances such as heater, electric iron, fans etc.
8. To study construction of moving iron, moving coil, electrodynamic & induction type
meters.
9. To design & fabricate single phase transformer.
10. To study fuses, relays, contactors, MCBs and circuit breakers.
11. Insulation testing of electrical equipments.
12. To design, fabricate a PCB for a circuit, wire-up and test.
EE-215-E Electrical Machine Lab-I
L T P Practical :50
Marks
- - 3 Class work :50 Marks
Total :100 Marks
Duration of Exam :3 Hrs.
LIST OF EXPERIMENTS
1. To find turns ratio & polarity of a 1-phase transformer.
2. To perform open & short circuit tests on a 1-phase transformer.
3. To perform Sumpner's Back to back test on 1-phase transformers.
4. Parallel operation of two 1-phase transformers.
5. To convert three phase to 2-phase By Scott-connection.
6. To perform load test on DC shunt generator.
7. Speed control of DC shunt motor.
8. Swinburne‟s test of DC shunt motor.
9. Hopkinson‟s test of DC shunt M/Cs.
10. Ward Leonard method of speed control.
Electrical & Electronics Engineering
Semester IVth
HUM-202-E FUNDAMENTALS OF MANAGEMENT
L T P Class Work : 50
Marks
3 1 - Theory :
100 Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
UNIT-I
Meaning of management, Definitions of Management, Characteristics of management, Management Vs.
Administration. Management-Art, Science and Profession. Importance of Management. Development of
Management thoughts.
Principles of Management. The Management Functions, Inter-relationship of Managerial functions.
UNIT-II
Nature and Significance of staffing, Personnel management, Functions of personnel management,
Manpower planning, Process of manpower planning, Recruitment, Selection; Promotion - Seniority Vs. Merit.
Training - objectives and types of training.
UNIT-III
Production Management : Definition, Objectives, Functions and Scope,
Production Planning and Control; its significance, stages in production planning and
control. Brief introduction to the concepts of material management, inventory control; its
importance and various methods.
UNIT-IV
Marketing Management - Definition of marketing, Marketing concept, objectives & Functions of
marketing.
Marketing Research - Meaning; Definition; objectives; Importance; Limitations; Process. Advertising - meaning of
advertising, objectives, functions, criticism.
UNIT-V
Introduction of Financial Management, Objectives of Financial Management,
Functions and Importance of Financial Management. Brief Introduction to the concept of
capital structure and various sources of finance.
MATH-202-E NUMERICAL METHODS
---------- -----------------
(COMMON FOR EE,EL,CHE,EI,IC & ELECTIVE FOR CSE,IT IN 8th
SEM.)
L T P Sessional : 50
Marks
3 1 - Exam. : 100
Marks
Total : 150
Marks
Duration of exam. : 3
Hours
Part-A
Interpolation and curve fitting : Interpolation problem,
Lagrangian polynomials, Divided differences,
Interpolating with a cubic spline, Bezier curves and B-
spline curves, Least square approximations.
Non-Linear Equations : Bisection method, Linear
Interpolation methods, Newton's method, Muller's method,
fixed-point method.
Simultaneous Linear Equations : Elimination method, Gauss
and Gauss-Jordan method, Jacobi's method, Gauss-Seidal
method, Relaxation method.
Numerical Differentiation and Integration : Derivatives
from differences tables, Higher order derivatives,
Extrapolation techniques, Newton-cotes integration
formula, Trapezoidal rule, Simpson's rules, Boole's rule
and Weddle's rule, Romberg's Integration.
Part-B
Numerical Solution of Ordinary Differential Equations :
Taylor series method, Euler and modified Euler
method, Runge-Kutta methods, Milne's method, Adams-
Moulton method, Power method for Eigen values by
iteration.
Numerial Solution of Partial Differential Equations :
Finite difference approximations of partial
derivatives, solution of Laplace equation (Standard 5-
point formula only), one-dimensional heat equation
(Schmidt method, Crank-Nicolson method, Dufort and
Frankel method) and wave equation.
EE-202-E ANALOG ELECTRONICS
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1 SEMICONDUCTOR DIODE :
P-N junction and its V-I Characteristics, P-N junction as a rectifier, Switching
characteristics of Diode.
UNIT 2 DIODE CIRCUITS :
Diode as a circuit element, the load-line concept, half-wave and full wave rectifiers,
clipping circuits, clamping circuits, filter circuits, peak to peak detector and voltage
multiplier circuits.
UNIT 3 TRANSISTOR AT LOW FREQUENCIES:
Bipolar junction transistor : operation, characteristics, Ebers-moll model of transistor,
hybrid model, h-parameters (CE, CB, CC configurations), analysis of a transistor
amplifier circuits using h-parameters, emitter follower, Miller's Theorem , frequency
response of R-C coupled amplifier.
UNIT 4 TRANSISTOR BIASING :
Operating point, bias stability, collector to base bias, self-bias, emitter bias, bias
compensation, thermistor & sensistor compensation.
UNIT 5 TRANSISTOR AT HIGH FREQUENCIES:
Hybrid P model, CE short circuit current gain, frequency response, alpha, cutoff
frequency, gain bandwidth product, emitter follower at high frequencies.
UNIT 6 FIELD EFFECT TRANSISTORS :
Junction field effect transistor, pinch off voltage, volt-ampere characteristics, small
signal model, MOSFET Enhancement & Depletion mode, V-MOSFET.Common
source amplifier, source follower, biasing of FET, applications of FET as a voltage
variable resistor (V V R).
UNIT 7 REGULATED POWER SUPPLIES :
Series and shunt voltage regulators, power supply parameters, three terminal IC
regulators, SMPS.
EE-204-E DIGITAL ELECTRONICS
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1 FUNDAMENTALS OF DIGITAL TECHNIQUES :
Digital signal, logic gates: AND, OR, NOT, NAND, NOR, EX-OR, EX-NOR, Boolean
algebra. Review of Number systems. Binary codes: BCD, Excess-3, Gray, EBCDIC,
ASCII, Error detection and correction codes.
UNIT 2 COMBINATIONAL DESIGN USING GATES:
Design using gates, Karnaugh map and Quine Mcluskey methods of simplification.
UNIT 3 COMBINATIONAL DESIGN USING MSI DEVICES
Multiplexers and Demultiplexers and their use as logic elements, Decoders, Adders /
Subtractors, BCD arithmetic circuits, Encoders, Decoders / Drivers for display
devices.
UNIT 4 SEQUENTIAL CIRCUITS:
Flip Flops : S-R, J-K, T, D, master-slave, edge triggered, shift registers, sequence
generators, Counters, Asynchronous and Synchronous Ring counters and Johnson
Counter, Design of Synchronous and Asynchronous sequential circuits.
UNIT 5 DIGITAL LOGIC FAMILIES:
Switching mode operation of p-n junction, bipolar and MOS. devices. Bipolar logic
families:RTL, DTL, DCTL, HTL, TTL, ECL, MOS, and CMOS logic families. Tristate
logic, Interfacing of CMOS and TTL families.
UNIT 6 A/D AND D/A CONVERTERS:
Sample and hold circuit, weighted resistor and R -2 R ladder D/A Converters,
specifications for
D/A converters. A/D converters : Quantization, parallel -comparator, successive
approximation, counting type, dual-slope ADC, specifications of ADCs.
UNIT 7 PROGRAMMABLE LOGIC DEVICES:
ROM, PLA, PAL, FPGA and CPLDs.
EE-206-E COMMUNICATION SYSTEMS
(EE,EL,EI)
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1. INTRODUCTION TO COMMUNICATION SYSTEMS :
The essentials of a Communication system, modes and media‟s of Communication,
Classification of signals and systems , Fourier Analysis of signals.
UNIT 2. AMPLITUDE MODULATION :
Amplitude modulation, Generation of AM waves, Demodulation of AM waves,
DSBSC, Generation of DSBSC waves, Coherent detection of DSBSC waves, single side
band modulation, generation of SSB waves, demodulation of SSB waves, vestigial
sideband modulation (VSB).
UNIT 3. ANGLE MODULATION :
Basic definitions: Phase modulation (PM) & frequency modulation(FM), narrow
band frequency modulation, wideband frequency modulation, generation of FM waves,
Demodulation of FM waves.
UNIT 4. PULSE ANALOG MODULATION :
Sampling theory, time division (TDM) and frequency division (FDM) multiplexing,
pulse amplitude modulation (PAM), pulse time modulation.
UNIT 5. PULSE DIGITAL MODULATION :
Elements of pulse code modulation, noise in PCM systems, Measure of information,
channel capacity, channel capacity of a PCM system, differential pulse code
modulation (DPCM). Delta modulation (DM)
UNIT 6. DIGITAL MODULATION TECHNIQUES:
ASK, FSK, BPSK, QPSK, M-ary PSK.
UNIT 7. INTRODUCTION TO NOISE:
External noise, Internal noise, S/N ratio, noise figure.
EE-208-E ELECTROMAGNETIC THEORY
L T P
CLASSWORK : 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT-1: STATIC ELECTRIC FIELDS: Coulomb‟s Law, Gauss‟s Law, potential
function, field due to a continuous distribution of charge, equi-potential surfaces, Gauss‟s
Theorem, Poison‟s equation, Laplace‟s equation, method of electrical images,
capacitance, electro-static energy, boundary conditions, the electro-static uniqueness
theorem for field of a charge distribution, Dirac-Delta representation for a point charge
and an infinitesimal dipole.
UNIT-2: STEADY MAGNETIC FIELDS: Faraday Induction law, Ampere‟s Work law
in the differential vector form, Ampere's law for a current element, magnetic field due to
volume distribution of current and the Dirac-delta function, Ampere‟s Force Law,
magnetic vector potential, vector potential (Alternative derivation), far field of a current
distribution, equation of continuity.
UNIT-3: TIME VARYING FIELDS: Equation of continuity for time varying fields,
inconsistency of Ampere‟s law, Maxwell‟s field equations and their interpretation,
solution for free space conditions, electromagnetic waves in a homogeneous medium,
propagation of uniform plane-wave, relation between E & H in a uniform plane-wave,
wave equations for conducting medium, Maxwell‟s equations using phasor notation,
wave propagation in a conducting medium, conductors, dielectrics, wave propagation in
good conductor and good dielectric, depth of penetration, polarization, linear, circular
and elliptical,
UNIT-4: REFLECTION AND REFRACTION OF E M WAVES: Reflection and
refraction of plane waves at the surface of a perfect conductor & perfect dielectric (both
normal incidence as well as oblique incidence), Brewester's angle and total internal
reflection, reflection at the surfaces of a conductive medium, surface impedance,
transmission-line analogy, poynting theorem, interpretation of E x H, power loss in a
plane conductor.
UNIT-5: TRASMISSION LINE THEORY: Transmission line as a distributed circuit,
transmission line equation, travelling ,standing waves , characteristic impedance, input
impedance of terminated line, reflection coefficient, VSWR, Smith's chart and its
applications.
EE-222-E ANALOG ELECTRONICS-LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Study of Half wave & full wave rectifiers.
2. Study of power supply filters.
3. Study of Diode as clipper & clamper.
4. Study of Zener diode as a voltage regulator.
5. Study of CE amplifier for voltage, current & Power gains and input, output
impedances..
6. Study of CC amplifier as a buffer.
7. To study the frequency response of RC coupled amplifier.
8. Study of 3-terminal IC regulator.
9. Study of transistor as a constant current source in CE configuration.
10. Study of FET common source amplifier.
11. Study of FET common Drain amplifier.
12. Graphical determination of small signal hybrid parameters of bipolar junction
transistor.
13. Study & design of a d.c. voltage doubler.
EE-224-E DIGITAL ELECTRONICS LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Study of TTL gates – AND, OR, NOT, NAND, NOR, EX-OR, EX-NOR.
2. Design & realize a given function using K-maps and verify its performance.
3. To verify the operation of multiplexer & Demultiplexer.
4. To verify the operation of comparator.
5. To verify the truth tables of S-R, J-K, T & D type flip flops.
6. To verify the operation of bi-directional shift register.
7. To design & verify the operation of 3-bit synchronous counter.
8. To design and verify the operation of synchronous UP/DOWN decade counter using J
K flip-flops & drive a seven-segment display using the same.
9. To design and verify the operation of asynchronous UP/DOWN decade counter using J
K flip-flops & drive a seven-segment display using the same.
10. To design & realize a sequence generator for a given sequence using J-K flip-
flops.
11. Study of CMOS NAND & NOR gates and interfacing between TTL and CMOS
gates.
12. Design a 4-bit shift-register and verify its operation . Verify the operation of a ring
counter and a Johnson counter.
EE-226-E COMMUNICATION SYSTEMS LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Study of Amplitude Modulation and determination of Modulation index.
2. Study of Frequency Modulation and determination of Modulation index.
3. Study of Phase Modulation.
4. Study of Pulse Amplitude Modulation.
5. Study of Pulse Width Modulation.
6. Study of Pulse Frequency Modulation.
7. Study of Pulse Code Modulation.
8. Study of frequency Shift Keying.
9. Study of ASK and QASK.
10. Study of PSK and QPSK.
11. Project related to the scope of the course.
MATH-204-E NUMERICAL METHODS LAB.
---------- ----------------------
(COMMON FOR EE,EL,CHE,EI)
L T P Class Work : 25
Marks
- - 2 Exam. : 25
Marks
Total : 50
Marks
Duration of exam. : 2
Hours
WRITE DOWN AND EXECUTE THE FOLLOWING PROGRAMS USING
C/C++/MATLAB
1. To find the roots of non-linear equation using
Bisection
method.
2. To find the roots of non-linear equation using
Newton's
method.
3. Curve fitting by least - square approximations.
4. To solve the system of linear equations using
Gauss-
Elimination method.
5. To solve the system of linear equations using Gauss-
Seidal
iteration method.
6. To solve the system of linear equations using Gauss-
Jorden
method.
7. To Integrate numerically using Trapezoidal rule.
8. To Integrate numerically using Simpson's rules.
9. To find the largest eigen value of a matrix by power-
method.
10. To find numerical solution of ordinary
differential
equations by Euler's method.
11. To find numerical solution of ordinary
differential
equations by Runge-Kutta method.
12. To find numerical solution of ordinary
differential
equations by Milne's method.
13. To find the numerical solution of Laplace equation.
14. To find numerical solution of wave equation.
15. To find numerical solution of heat equation.
Electrical & Electronics Engineering (EEE)
Semester V
EE-311-E ELECTRICAL MACHINES - II
L T P Theory : 100
Marks
3 1 - Class work : 50 Marks
Total : 150 Marks
Duration of Exam : 3 Hours
INDUCTION MACHINES
Poly-phase Induction Machine: Constructional features, production of rotating
field, induction motor action, torque production, testing, development of equivalent
circuit, performance characteristics, circle diagram, starting methods, methods of
speed control - stator voltage control, stator resistance control, frequency control,
rotor resistance control, slip power recovery control. double cage and deep bar
motors. grid excited and self excited induction generators.
Single phase Motors: Double revolving field theory, cross field theory, different
types of single phase induction motors, circuit model of single phase induction
motor.
SYNCHRONOUS MACHINES
Principle, construction of cylindrical rotor and salient pole machines, winding, EMF
equation, Armature reaction, testing, model of the machine, regulation --
synchronous reactance method, Rothert‟s mmf method, Potier triangle method.
Output power equation, power angle curve, two reactance theory, slip test, transient
and sub-transient reactances, synchronization, parallel operation. Principles of
synchronous motor, power angle curve, V-curve, starting, damper winding,
synchronous condenser, applications.
EE-303-E ELECTRONIC MEASUREMENT AND
INSTRUMENTATION
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1. OSCILLOSCOPE:
Block diagram, study of various stages in brief, high frequency CRO
considerations. Sampling and storage oscilloscope.
UNIT 2. ELECTRONIC INSTRUMENTS:
Instruments for measurement of voltage, current & other circuit parameters, Q-meters,
R.F. power measurements, introduction to digital meters.
UNIT 3. GENERATION & ANALYSIS OF WAVEFORMS:
Block diagram of pulse generators, signal generators, function generators wave analysers,
distortion analysers, spectrum analyser, Harmonic analyser, introduction to power
analyser.
UNIT 4. FREQUENCY & TIME MEASUREMENT:
Study of decade counting Assembly(DCA), frequency measurements, period
measurements, universal counter, introduction to digital meters.
UNIT 5. DISPLAY DEVICES:
Nixie tubes, LED‟s LCD‟s, discharge devices.
UNIT 6 TRANSDUCERS:
Classification, Transducers of types: RLC photocell, thermocouples etc. basic schemes of
measurement of displacement, velocity, acceleration, strain, pressure, liquid level &
temperature.
UNIT 7 INTRODUCTION TO SIGNAL CONDITIONING:
DC signal conditioning system, AC signal conditioning system, data acquisition and
conversion system
EE-305-E ANALOG ELECTRONIC CIRCUITS
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT1. SINGLE AND MULTISTAGE AMPLIFIERS:
Classification of amplifiers, distortion in amplifiers, frequency response of an amplifier,
step response of an amplifier, pass-band of cascaded stages, RC-coupled amplifier, low
frequency response of RC coupled stage, effect of an emitter bypass capacitor on low
Frequency response, multistage CE amplifier .
UNIT2. FEEDBACK AMPLIFIERS :
Feedback concept, transfer gain with feedback, general characteristics of negative
feedback amplifiers, input resistance, output resistance, voltage series feedback, current
series feedback, current shunt feedback, voltage shunt feedback.
UNIT3. OSCILLATORS:
Sinusoidal oscillators, Barkhausen criteria, R-C phase shift oscillator, generalform of
oscillator circuit, wien-bridge oscillator, crystal oscillator.
UNIT4. POWER AMPLIFIERS:
Class A, B, and C operations; Class A large signal amplifiers, higher order harmonic
distortion, efficiency, transformer coupled power amplifier, class B amplifier : efficiency
& distortion; class A and class B push-pull amplifiers; class C power amplifier.
UNIT5. OPERATIONAL AMPLIFIERS :
Ideal and practical operational amplifiers, inverting and non-inverting amplifier,
differential amplifier, emitter coupled differential amplifier, transfer characteristics of a
differential amplifier, offset error : voltage and current, common mode rejection ratio
(CMRR) .
UNIT6. LINEAR APPLICATIONS OF OPERATIONAL AMPLIFIERS :
Scale changer, phase shifter, adder, voltage to current converter, current to voltage
converter, DC voltage follower, Bridge amplifier, AC coupled amplifier, AC voltage
follower, Integrator, differentiator.
UNIT7. NON-LINEAR APPLICATIONS OF OPERATIONAL AMPLIFIERS :
Comparators, sample & hold circuits, Logarithmic amplifier, anti-log amplifier,
logarithmic multiplier, waveform generators , Miller & Bootstrap sweep generators,
regenerative comparator (Schmitt Trigger), multivibrators, ADC.
EE-315-E POWER SYSTEMS-I
L T P Theory :100
Marks
3 1 - Class work :50 Marks
Total :150 Marks
Duration of Exam :3 Hrs.
1. INTRODUCTION: Structure of a power system, indoor and outdoor substations,
equipment for substations, layout, auxiliary supply.
2. DISTRIBUTION SYSTEMS: Radial, ring mains and network distribution system,
comparison of various types of ac and dc systems.
3. TRANSMISSION LINES: Calculation of line parameters, Ferranti effect, proximity
effect.
4. PERFORMANCE OF LINES: models of short, medium and long transmission lines,
performance of transmission lines, circle diagram, capacity of synchronous
condenser, tuned lines, voltage control.
5. MECHANICAL DESIGN: Sag and stress calculations, effect of ice and wind,
dampers.
6. INSULATORS: Types, insulating materials, voltage distribution over insulator string,
equalizer ring.
7. CABLES: Types of LV and HV cables, grading of cables, capacitance, ratings.
8. CORONA: Phenomenon, critical voltage, power loss, reduction in losses, radio-
interference, HVDC transmission – types of links, advantages and limitations.
EE-317-E POWER ELECTRONICS
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT1. INTRODUCTION :
Role of power electronics, review of construction and characteristics of power diode,
Shottky diode, power transistor, power MOSFET, SCR, DIAC, Triac, GTO, IGBT &
SIT.
UNIT2. SCR:
Ratings and protections, series and parallel connections, R, RC and UJT firing circuit and
other firing circuits based on ICs and microprocessors; pulse transformer and opto-
coupler, commutation techniques.
UNIT3. AC REGULATORS:
Types of regulator, equation of load current, calculation of extinction angle, output
voltage equation, harmonics in load voltage and synchronous tap changer, three phase
regulator.
UNIT4. CONVERTERS :
One, two, three, six and twelve pulse converters, fully and half controlled converters,
load voltage waveforms, output voltage equation, continuous and discontinuous modes of
operation, input power factor of converter, reactive power demand, effect of source
inductance, introduction to four quadrant / dual converter, power factor improvement
techniques, forced commutated converter, MOSFET and transistor based converters.
UNIT5. INVERTERS :
Basic circuit, 120 degree mode and 180 degree mode conduction schemes, modified
McMurray half bridge and full bridge inverters, McMurray -Bedford half bridge and
bridge inverters, brief description of parallel and series inverters, current source inverter
(CSI), transistor and MOSFET based inverters.
UNIT6. CHOPPERS :
Basic scheme, output voltage control techniques, one, two, and four quadrant choppers,
step up chopper, voltage commutated chopper, current commutated chopper, MOSFET
and transistor based choppers.
UNIT7. CYCLOCONVERTERS :
Basic principle of frequency conversion, types of cycloconverter, non-circulating and
circulating types of cycloconverters.
UNIT8. DRIVES:
Introduction to electric drives: DC drives – converter and chopper fed dc drives, ac drives
- stator voltage control, V/f control, rotor resistance control, static Scherbius system and
static Kramer systems.
EE-323-E ELECTRONIC MEASUREMENT AND INSTRUMENTATION-LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Measurement of displacement using LVDT.
2. Measurement of distance using LDR.
3. Measurement of temperature using R.T.D.
4. Measurement of temperature using Thermocouple.
5. Measurement of pressure using Strain Guage.
6. Measurement of pressure using Piezo-Electric Pick up.
7. Measurement of distance using Capacitive Pick up.
8. Measurement of distance using Inductive Pick up.
9. Measurement of speed of DC Motor using Magnetic Pick up.
10. Measurement of speed of DC Motor using Photo Electric Pick up.
EE-321-E POWER ELECTRONICS-LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1. Study of characteristics of diode, thyristor and triac.
2. Study of characteristics of transistor and MOSFET.
3. Study of R and R-C firing circuits.
4. Study of UJT firing circuit.
5. Study of complementary voltage commutation using a lamp flasher.
6. Study of complementary voltage commutation using ring counter.
7. Study of thyristorised d-c circuit breaker.
8. Study of a.c. phase control.
9. Study of full wave converter.
10. Study of dc chopper.
11. Study of series inverter.
12. Study of bridge inverter.
13. Study of single phase cycloconverter.
EE-327-E ELECTRICAL MACHINES-II LAB
L T P Practical : 25 Marks
- - 3 Class work : 25 Marks
Total : 50 Marks
Duration of Exam : 3 Hours
List of Experiments:
1. To perform the open circuit test and block rotor test on 3 phase induction motor and draw the
circle diagram.
2. Speed control of induction motor by rotor resistance control.
3. To conduct the load test to determine the performance characteristics of the I.M..
4. To compute the torque v/s speed characteristics for various stator voltages.
5. To perform the open circuit test and block rotor test on single-phase induction motor and
determine equivalent circuit parameters.
6. To perform load test on a universal motor and determine the performance with dc/ac supply
voltage.
7. Voltage Vs load Characteristics of 3 phase synchronous generator. And draw input vs. Output
power.
8. To perform O.C. test on synchronous generator. And determine the full load regulation of a
three phase synchronous generator by synchronous impedance method
9. Determination of direct axis and quadrature axis reactances of synchronous machines.
10. To plot V- Curve of synchronous motor.
11. To study the parallel operation of synchronous generators.
12. Determination of sequence impedances of synchronous machine for various stator voltages.
Electrical & Electronics Engineering
Semester VI
EE-312-E POWER SYTEMS - II
L T P Theory
:100 Marks
3 1 - Class work :50 Marks
Total :150
Marks
Duration of Exam :3 Hours
1. SYMMETRICAL FAULT ANALYSIS: Transients on a transmission line, short
circuit of synchronous machine at no load and on full load.
2. SYMMETRICAL COMPONENTS: Symmetrical component transformation, phase
shift in star-delta transformation, sequence impedances.
3. UNSYMMETRICAL FAULT ANALYSIS: Single line to ground fault, line to line
fault, double line to ground fault, open conductor fault.
4. CIRCUIT BREAKERS: Theory of arc interruption, circuit breaker, circuit breaker
ratings, restriking voltage transients, current chopping, duties of switch gear,
automatic switch, air circuit breaker, bulk oil, minimum oil, air blast, SF6 CB,
vacuum and DC circuit breakers.
5. PROTECTIVE RELAYS: Nature and causes of faults, consequences, zone of
protection, essential qualities, primary and backup protections, relay classification,
principal types of electromagnetic relays, i.e. attracted armature, induction disc,
induction cup types.
6. RELAY APPLICATION AND CHARACTERISTICS: Over -current, instantaneous
over current, IDMT, directional and differential relays, distance relays, plain
impedance, mho, reactance, offset mho type, transmission line & feeder protection,
introduction, over current, distance, pilot wire and carrier current protection, neutral
grounding.
7. APPARATUS PROTECTION: Transformer, generator, motor and bus zone
protection.
8. STATIC & DIGITAL RELAYS: Classification of static relays, amplitude and phase
comparators, block-spike and block-average comparators , rectifier type relays.
Introduction to digital relay: basic principles. Application of microprocessors and
computers - recent Trends. Travelling wave relay, relaying schemes based on
microwave and optical fiber link.
EE-314-E CONVENTIONAL AND CAD OF ELECTRIC MACHINES
L T P Theory
: 100 marks
4 - - Class Work : 50
marks
Total : 150
marks
Duration of exam.
: 3 hours
1. GENERAL: General features and limitations of electrical machine design. Types of enclosures,
heat dissipation, temperature rise heating and cooling cycles and ratings of machine machines. Cooling
media used.
2. BASIC DESIGN PRINCIPLES: Output equation and output coefficient, Specific
electric and magnetic loading. Effect of size and ventilation.
3. MAGNETIC CIRCUITS: MMF calculation for airgun and iron parts of electrical
machines, gap contraction coefficient. Real and apparent flux densities. Estimation of
magnet current of transformers and rotating machines, no load current of transformers
and induction motors. Leakage flux and reactance calculations for transformers and
rotating machines, Design of field magnet.
4. DETAILED DESIGN: Design of transformer, D.C. machines induction motor and
synchronous machine and their performance calculations.
5. COMPUTER AIDED DESIGN: Computerization of design Procedures. Development
of Computer program and performance prediction. Optimization techniques and their
applications to design Problems.
EE-304-E CONTROL SYSTEM ENGINEERING
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT1. INTRODUCTORY CONCEPTS :
System/Plant model, types of models, illustrative examples of plants and their inputs and
outputs, controller, servomechanism, regulating system, linear time-invariant (LTI)
system, time-varying system, causal system, open loop control system, closed loop
control system, illustrative examples of open-loop and feedback control systems,
continuous time and sampled data control systems. Effects of feedback on sensitivity (to
parameter variations), stability, external disturbance (noise), overall gain etc.
Introductory remarks about non-linear control systems.
UNIT2. MATHEMATICAL MODELLING :
Concept of transfer function, relationship between transfer function and impulse
response, order of a system, block diagram algebra, signal flow graphs : Mason‟s gain
formula & its application, characteristic equation, derivation of transfer functions of
electrical and electromechanical systems. Transfer functions of cascaded and non-
loading cascaded elements. Introduction to state variable analysis and design.
UNIT3. TIME DOMAIN ANALYSIS :
Typical test signals, time response of first order systems to various standard inputs, time
response of 2nd order system to step input, relationship between location of roots of
characteristics equation, w and wn, time domain specifications of a general and an
under-damped 2nd order system, steady state error and error constants, dominant closed
loop poles, concept of stability, pole zero configuration and stability, necessary and
sufficient conditions for stability, Hurwitz stability criterion, Routh stability criterion and
relative stability.
UNIT4. ROOT LOCUS TECHNIQUE :
Root locus concept, development of root loci for various systems, stability
considerations.
UNIT5. FREQUENCY DOMAIN ANALYSIS :
Relationship between frequency response and time-response for 2nd order system, polar,
Nyquist, Bode plots, stability, Gain-margin and Phase Margin, relative stability,
frequency response specifications.
UNIT6. COMPENSATION :
Necessity of compensation, compensation networks, application of lag and lead
compensation, basic modes of feedback control, proportional, integral and derivative
controllers, illustrative examples.
UNIT7. CONTROL COMPONENTS : Synchros, AC and DC techo-generators,
servomotors, stepper motors, & their applications, magnetic amplifier.
EE-318-E ELECTRICAL POWER GENERATION
L T P Theory
: 100
3 1 - Class work : 50
Total : 150
Duration of Exam. : 3 Hrs.
1. INTRODUCTION: Energy sources, their availability, Recent trends in Power
Generation, Interconnected Generation of Power Plants.
2. POWER GENERATION PLANNING: Load forecasting, load curves, load duration
curve, Base load and Peak load Power Plants, connected Load, maximum demand,
demand factor, Group diversity factor, load factor, significance of load factor, plant
factor, capacity factor, selection of unit size, No. of Units, reserves, cost of power
generation, Depreciation, tariff.
3. CONVENTIONAL ENERGY SOURCES: Selection of site, capacity calculations,
classification, Schematic diagram and working of Thermal Power Stations, Hydro
Electric Plant, Nuclear Power Plant and Diesel Power Stations.
4. NON-CONVENTIONAL ENERGY SOURCES: Wind, Solar, Tidal, Ocean, and
Geothermal sources of Energy, fuel cell, Magneto Hydro Dynamic (MHD) system.
5. ELECTRIC ENERGY CONSERVATION & MANAGEMENT: Energy
management, Energy Audit, Energy Efficient Motors, Co-generation.
EE-324-E CONTROL SYSTEM LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS :
1. To study A.C. servo motor and to plot its torque speed characteristics.
2. To study D.C. servo motor and to plot its torque speed characteristics.
3. To study the magnetic amplifier and to plot its load current v/s control current
characteristics for :
(a) series connected mode
(b) parallel connected mode.
4. To plot the load current v/s control current characteristics for self exited mode of
the magnetic amplifier.
5. To study the synchro & to:
(a) Use the synchro pair (synchro transmitter & control transformer) as an error
detector.
(b)Plot stator voltage v/s rotor angle for synchro transmitter i.e. to use the synchro
transmitter as position transducer.
6. To use the synchro pair (synchro transmitter & synchro motor) as a torque trans
mitter.
7. (a) To demonstrate simple motor driven closed loop position control system.
(b) To study and demonstrate simple closed loop speed control system.
8. To study the lead, lag, lead-lag compensators and to draw their magnitude and
phase plots .
9. To study a stepper motor & to execute microprocessor or computer-based control
of the same by changing number of steps, direction of rotation & speed.
10. To implement a PID controller for level control of a pilot plant.
11. To implement a PID controller for temperature control of a pilot plant.
12. To study the MATLAB package for simulation of control system design.
EE-326-E CONVENTIONAL AND CAD OF ELECTRIC MACHINES -LAB
L T P
2 Class Work : 25
marks
Exam : 25
marks
Total : 50
marks
Duration of exam.
: 3 hours
This will pertain the syllabus of theory Paper CONVENTIONAL AND CAD OF
ELECTRIC MACHINES.
EE-328-E POWER SYSTEMS LAB
L T P Practical : 25 marks
- - 2 Class work : 25 marks
Total : 50 marks
Duration of exam. : 3 hours
1. To draw the operating characteristcs of IDMT relay.
2. To draw the operating characteristcs of differential relay.
3. To study Bucholtz relay.
4. Testing of transformer oil.
5. To find ABCD parameters of a model of transmission line.
6. To observe the Ferranti effect in a model of transmission line.
7. To study the plain impedance relay and plot its tripping characteristics.
8. To study the MHO relay and plot its tripping characteristics
9. To study the power control by phase shifting transformer.
10. To plot annual/monthly/daily load demand of nearby area.
11. To draw single line diagram of distribution system of HVPNL of near by area of
the college concerned.
12. To design 11 KV substation.
Electrical & Electronics Engineering
Semester VII
EE-401-E DATA COMMUNICATION
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1 DIGITAL COMMUNICATION :
Introduction, digital communication, Shannon limit for information capacity, digital radio, digital
amplitude modulation, frequency shift keying (FSK), phase shift keying (PSK), quadrature amplitude
modulation (QAM), band width efficiency, carrier recovery, differential phase shift keying,(DPSK), clock
recovery, probability of error & bit error rate, trellis encoding.
UNIT 2 DATA COMMUNICATIONS:
Introduction, history of data communication, standard organization for data
communication, data communication circuits, data communication codes, error control,
synchronization, data communications hardware, serial interfaces: RS-232, RS-449 &
RS-530, CCITT X.21, parallel interfaces: centronics parallel interfaces. the telephone
network: DDD network, private- line service, the telephone circuit, data modems:
synchronous modems, asynchronous modems, modem synchronization.
UNIT 3 DATA COMMUNICATIONS PROTOCOLS AND NETWORK CONFIGURATIONS :
Introduction, open system interconnection (OSI), data transmission mode, asynchronous protocols,
synchronous protocols, public data network, integrated services digital network (ISDN), local area
networks, token pass ring, Ethernet.
UNIT 4 MULTIPLEXING :
Introduction, time division multiplexing, T1 digital carrier system, CCITT time division
multiplexed carrier systems, CODECS, COMBO chips, line encoding, T-CARRIERS,
frame synchronization, bit interleaving VS word interleaving, frequency division
multiplexing, AT&T‟s FDM hierarchy, composite base band signal, formation of a
master group.
UNIT 5 INTERNET AND TCP/IP:
Introduction, history, use of Internet, accessing the Internet, Internet addresses, security
on the internet, authentication, firewalls, intranet and extranet, TCP/IP reference model,
domain name service, world wide web.
EE-403-E ELECTRIC DRIVES
L T P Theory : 100 marks
3 1 - Class work : 50
Total : 150
Duration of exam. : 3 hours
1. ELECTRICAL DRIVES: Introduction, Classification, advantages, Characteristics
of Electric Motors, choice of electrical drive machines, status of ac and dc drives.
2. CONTROL OF ELECTRICAL DRIVES: Modes of operation, closed loop control of
drives, sensing of current and speed, Microprocessor based control of electric drives
3. DYNAMICS OF ELECTRICAL DRIVES: Fundamental torque equations, multi-
quadrant operation, equivalent values of drive parameters, load torque components,
types of loads.
4. SELECTION OF MOTOR POWER RATING: Heating and cooling, determination of
motor rating, continuous, short time and intermittent duty rating, load equalization
and determination of moment of inertia of the flywheel.
5. DC MOTOR DRIVES: Starting, Acceleration control, braking, transient analysis,
Converter fed dc drive & chopper fed dc drive.
6. INDUCTION MOTOR DRIVES: Starting, Acceleration control, braking, transient
analysis, Static control techniques- stator frequency control, stator voltage control,
rotor resistance control. Static Scherbius system & static Kramer system, vector
control.
7. PMBLDC & PMSAC DRIVES: Permanent Magnet Brushless D C drive, Permanent
Magnet Sine-fed drives, Switched Reluctance Machine Drives.
EE-411-E POWER SYSTEM OPERATION AND
CONTROL
Theory
:100 marks
L T P Class
work :50 marks
3 1 - Total marks
:150 marks
1. AUTOMATIC GENERATION CONTROL: Load frequency control (single area
case), load frequency control and economic dispatch, optimal load frequency control,
Load Management.
2. ECONOMIC LOAD DESPATCH: Introduction, Optimal Operation of Generators of
Bus bar, Unit Commitment, Reliability Considerations, Optimal Generation Schedule
Hydro thermal optimal scheduling.
3. POWER SYSTEM STABILITY: Steady state, transient & dynamic stabilities, equal area
criteria, effect of fault clearing time on transient stability, dynamics of synchronous machine,
factors affecting transient stability.
4. AUTOMATIC VOLTAGE CONTROL & EXCITATION SYSTEMS: AVRs, role of
AVR on transient stability of system, type 0 & 1 excitation system, power system
stabilizers.
5. VOLTAGE STABILITY: Basic concept, Voltage collapse, Modelling & prevention.
EE-407-E DIGITAL SIGNAL PROCESSING
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT1. DISCRETE-TIME SIGNALS:
Signal classifications, frequency domain representation, time domain representation,
representation of sequences by Fourier transform, properties of Fourier transform,
discrete time random signals, energy and power theorems.
UNIT2. DISCRETE-TIME SYSTEMS : Classification, properties, time invariant
system, finite impulse Response (FIR) system, infinite impulse response (IIR) system.
UNIT3. SAMPLING OF TIME SIGNALS:
Sampling theorem, application, frequency domain representation of sampling,
reconstruction of band limited signal from its samples. discrete time processing of
continuous time signals, changing the sampling rate using discrete time processing.
UNIT4. Z-TRANSFORM :
Introduction, properties of the region of convergence, properties of the Z-transform,
inversion of the Z-transform, applications of Z-transform.
UNIT5. BASICS OF DIGITAL FILTERS : Fundamentals of digital filtering,
various types of digital filters, design techniques of digital filters : window technique for
FIR, bi-linear transformation and backward difference methods for IIR filter design,
analysis of finite word length effects in DSP, DSP algorithm implementation
consideration. Applications of DSP.
UNIT6. MULTIRATE DIGITAL SIGNAL PROCESSING:
Introduction to multirate digital signal processing, sampling rate conversion, filter
structures, multistage decimator and interpolators, digital filter banks.
EE-421-E DATA COMMUNICATION LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
1) To study different types of transmission media
2) To study Quadrature Phase Shift Keying Modulation.
3) To study Quadrature Amplitude Modulation.
4) To Study !6 Quadrature Amplitude Multiplexing.
5) To Study Serial Interface RS-232 and its applications.
6) To study the Parallel Interface Centronics and its applications.
7) To configure the modem of a computer.
8) To make inter-connections in cables for data communication in LAN.
9) To install LAN using Tree topology.
10) To install LAN using STAR topology.
11) To install LAN using Bus topology.
12) To install LAN using Token-Ring topology
13) To install WIN NT
14) To cofigure a HUB/Switch.
EE-413-E ELECTRIC DRIVES LAB
L T P Practical : 25
marks
- - 2 Class work : 25 marks
Total : 50
marks
Duration of exam. : 3 hours
1. Speed control of dc motor using dc chopper.
2. Speed control of dc motor using single- phase converter.
3. Speed control of dc motor using 3- phase converter.
4. Speed control of dc motor using single- phase dual converter.
5. Inverter fed single-phase induction motor drive.
6. CSI fed induction motor drive.
7. Speed control of single- phase induction motor using ac regulator.
8. Regenerative braking of dc motor using single- phase converter.
9. Speed control of single-phase induction motor using cycloconverter.
10. Static rotor resistance control method.
EE-427-E DIGITAL SIGNAL PROCESSING
LAB
L T P CLASS WORK
: 25
0 0 2 EXAM :
25
TOTAL
: 50
DURATION OF EXAM
: 3 HRS
LIST OF EXPERIMENTS:
Perform the experiments using MATLAB:
1. To represent basic signals (Unit step, unit impulse, ramp, exponential, sine and
cosine).
2. To develop program for discrete convolution.
3. To develop program for discrete correlation.
4. To understand stability test.
5. To understand sampling theorem.
6. To design analog filter(low-pass, high pass, band-pass, band-stop).
7. To design digital IIR filters(low-pass, high pass, band-pass, band-stop).
8. To design FIR filters using windows technique.
9. To design a program to compare direct realization values of IIR digital filter
10. To develop a program for computing parallel realization values of IIR digital filter.
11. To develop a program for computing cascade realization values of IIR digital filter
12. To develop a program for computing inverse Z-transform of a rational transfer
function.]
Electrical & Electronics Engineering (EEE)
Semester VIII
EE-406-E ADVANCED CONTROL SYSTEMS
L T P Theory : 100 marks
3 1 - Class work : 50 marks
Total : 150 marks
Duration of exam. : 3 hours
UNIT 1. STATE VARIABLE TECHNIQUES: State variable representation of systems
by various methods. Solution of state equations-state transition matrix. Transfer function
from state variable model. Controllability & observability of state variable model.
UNIT 2. SECOND ORDER SYSTEMS & STATE PLANE: Phase portrait of linear
second systems. Method of isoclines, phase portrait of second order system with non-
linearities, limit cycle, singular points.
UNIT 3. DESCRIBING FUNCTION ANALYSIS: Definition, limitations, use of
describing function for stability analysis , describing function of ideal relay, relay with
hysteresis & dead zone, saturation/coulomb friction & backlash,
UNIT 4. LINEAR APPROXIMATION OF NONLINEAR SYSTEMS: Taylor series,
Liapunov‟s 2nd method.
UNIT 5. SAMPLED DATA SYSTEMS: Sampling process, impulse modulation,
mathematical analysis of sampling process, application of Laplace transform, Shannon‟s
theorem, reconstruction of sampled signal zero order & first order hold, Z-transform,
definition, evaluation of Z-transform, Inverse Z-transform, pulse transfer function,
limitations of Z-transform, state variable formulation of discrete time systems. Solution
of discrete time state equations, stability, definition, the Schur-Cohn stability criterion,
Jury‟s test of stability of extension of Routh-Hurwitz criterion to discrete time systems.
EE-408-E COMPUTER APPLICATION TO POWER SYSTEM
L T P Theory :100
marks
3 1 - Class work :50 marks
Total :150 marks
Duration of exam. :3 hours
PART-A: LOAD FLOW STUDIES: Introduction, Bus Admittance Matrix, Formation of
Y Bus, Tree graph, Cotree, Primitive network, Bus Incidence matrix, Formulation of Y
Bus using singular transformation, Load flow equations Approximate Load flow study,
Cious-Seidel method for Load flow Study, Algorithm and flow, Chart for Computer
application to Load flow studies, using G-I method, Newton-Rophson method for Load
flow studies, Algerthm and flow chart for Computer Application to Load flow studies
using N.R. Method. Decenpted Load flow Studies, Fast Decenpted Load flow.
Comparison between G-S & N.R. Methods. Load flow Study of Distribution System.
PART-B: DIGITAL TECHNIQUES IN FAULT CALCULATIONS: Review of
symmetrical components, Sequence networks for synchronous machines, transforms and
transmission Lines. Bus Impedene matrix, Altorithn for formulation of Bus. All types of
modifications Short circuit Studies : Single line to ground fault, Line to Line fault,
Double line to Ground fault and symmetrical fault. Consideration of Prefault currents.
PART-C: COMPUTER CONTROL & AUTOMATION: Introduction to energy control
centres, various states of a power system, SCADA Systems and RTU. Introduction to
the MATLAB Power System block Set. Introduction of the features of EMTP.
EE-410-E COMPUTER APPLICATIONS TO POWER SYSTEMS
ANALYSIS LAB
L T P Practical :50 marks
- - 2 Class work :50 marks
Total :100 marks
Duration of exam. : 3 hours
1. Draw the flow chart and develop the computer program for the formation of the Y Bus of a
generalized network.
2. Draw the flow chart and develop the computer program for the formation of the Z Bus of a
generalized network.
3. To plot the swing curve and observe the stability.
4. To perform load flow study using Gaus Shiedel method.
5. Perform short circuit study for any type of fault.
6. To observe transmission losses and efficiency with variations in power for the
given example.
7. Design of distribution system
8. To study the features of EMTP
9. To study the MATLAB Power System block set features.
EE-432-E EXTRA HIGH VOLTAGE AC/ DC
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
1. Break Down Mechanism of Gaseous Materials :
Mechanism of Breakdown of gases, Townsend’s first Ionization Co-efficient, Townsend’s second Ionization Co-efficient,
Townsend’s Breakdown Mechanism, Streamer Theory of Breakdown in gases, Paschen’s law.
2. Breakdown in Liquid and Solid Dielectrics:
Suspended Particle Theory, Cavity Breakdown, Electro-convection Breakdown, Breakdown in solid Dielectrics, Intrinsic
Breakdown, Electromechanical Breakdown, Breakdown due to Treeing and Tracking, Thermal Breakdown,
Electrochemical Breakdown
3. Generation of High Voltage AC. and D.C
Half wave and Full wave Rectifier, Cockroft Walton Voltage Multiplier Circuit, Ripple in Multiplier Circuit, Electrostatic
Vandegraff Generator, Generation of High Alternative Voltage, Cascade Transformer, Resonant Transformer, Generation
of High Frequency A.C. High Voltage
4. Generation of Impulse Voltages and Currents:
Standard Impulse Wave Shapes, Impulse Generator Circuit, Multistage Impulse Generator, Marx’s Circuit, Generation of
Switching Surges, Impulse Current Generation, Tripping and Control of Impulse Generator
5. Measurement of High Voltage and Current:
Sphere-Gap, Uniform field Spark gap, Rod Gap, Electrostatic Voltmeter, Generating Voltmeter, Impulse Voltage
Measurement using Voltage divider, Measurement of high DC, AC and Impulse Current.
6. High Voltage Testing of Electrical Equipments:
Testing of line Insulator, Testing of Cable, Testing of Bushings, Testing of Power Capacitor, Testing of Power
Transformers, Testing of Circuit Breaker.
7. Transients & Insulation Co-ordination in Power System:
Over Voltage due to disturbances in D.C & A.C. System, Lightening surges, Switching Surges, Insulation Co-ordination in
Power System, Surge Arrestor, Application of surge Arrestor.
EE-434-E ADVANCED INSTRUMENTATION
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
1. INTRODUCTION: Functional block diagram of generalized Instrumentation system. Input-output configuration,
specifications under steady & transient state & their performance characteristics.
2. REVIEW OF SENSORS AND TRANSDUCERS: Temperature, pressure, displacement, velocity, acceleration,
strain and torque type.
3. SIGNAL CONDITIONING: Current & voltage sensitive bridges, Blumlein Bridges, Shielding & grounding,
Instrumentation Amplifier & its Characteristics, Linearizing circuits, Wave form and frequency conversion, Acitve filters,
A/D & D/A converters; Balanced modulators & demodulators.
4. NOISE: Characteristics & Measurements of signal in the presence of noise.
5. MICROCONTROLLER BASED INSTRUMENTATION SYSTEM: Interfacing of 8051 Microcontroller with (a) ADC and
DAC, (b) Alphanumeric Devices (Sixteen-segment Display, Dot Matrix Displays, LCD Display).
IC-404-E FUZZZY CONTROL SYSTEM
L T P CLASS WORK
: 50
3 1 0 EXAM :
100
TOTAL
: 150
DURATION OF EXAM
: 3 HRS
UNIT 1 INTRODUCTION:
Fuzzy control from an industrial perspective, knowledge-based controllers, knowledge
representation in KBC‟s.
UNIT 2 THE MATHEMATICS OF FUZZY CONTROL:
Vagueness, fuzzy logic versus probability theory, fuzzy sets, their properties &
operations on fuzzy sets, fuzzy relations & operations on fuzzy relations, the Extension
Principle, Fuzzy propositions, The Compositional Rule of Inference, Different
implications, Representing a set of rules.
UNIT 3 FKBC DESIGN PARAMETERS:
The PKBC architecture, choice of variables & content of rules, Derivation of rules,
choice of membership functions, choice of scaling factors, choice of fuzzification
procedure, choice of defuzzification procedure, comparison and evaluation of
defuzzification methods.
UNIT 4 NONLINEAR FUZZY CONTROL:
The Control Problem, The FKBC as a Non-Linear Transfer Element, Types of FKBC
such as PID-like FKBC, Sliding Mode FKBC, Sugeno FKBC.
UNIT 5 ADAPTIVE FUZZY CONTROL:
Design & Performance Evaluation, Approaches to Design such as membership function
tuning using gradient descent, membership function tuning using performance criteria,
the self-organizing
controller, model based controller.
UNIT 6 STABILITY OF FUZZY CONTROL SYSTEMS:
The State space approach, Stability and robustness indices, input-output stability, circle
criterion, the conicity criterion.
EE-438-E RECENT TRENDS IN DEREGULATED POWER SYSTEMS
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
1. Deregulation of the Electricity Supply Industry:
Background of deregulation and the current situation, Benefits from a competitive Electricity Market, After effects of
Deregulation.
2. Power System Operation in Competitive Environment
Role of Independent System operator, Operational Planning activities of ISO, operational planning activities of Genco.
3. Transmission open Access and Pricing Issues
Power Wheeling, Transmission Open Access, Cost component in Transmission, Pricing of Power Transmissions,
Security Management in Deregulated environment, Congestion management in Deregulation.
4. Reliability and Deregulation
Reliability Analysis, Optimal Power Flow as a Basic Tool, Unit Commitment, Formation of Power Pools.
EE- 466-E UTILIZATION OF ELECTRIC POWER AND TRACTION
Theory marks : 100 marks
L T P Class work : 50
marks
4 - - Total marks : 150marks
Duration of exam. : 3 hours
UNIT 1. ILLUMINATION:
Basic laws of illumination, light sources and their characteristics, sources of light, design
of lighting schemes, incandescent lamp, sodium lamp, mercury lamp and fluorescent
lamp, comparison of various lamps.
UNIT 2. ELECTRIC HEATING :
Principle and application of resistance, induction and dielectric heating.
UNIT 3. ELECTRIC WELDING :
Resistance welding, arc welding, welding generator and welding transformer, properties
of arcing electrode.
UNIT 4. ELECTROLYTIC PROCESS:
Principles and applications of electrolysis. Faraday‟s law of electrolysis, electroplating,
charging and discharging. Capacity and efficiency of battery, defects in battery.
UNIT 5. ELECTRIC TRACTION:
Advantages of electric traction, requirements of an ideal traction system, train movement,
mechanism of train movement, traction motors, traction motor control, multi unit control,
braking of electric motors, thyristor control of electric traction.
EE- 442-E High Voltage Engineering
L T P Theory :100
marks
4 - - Class work : 50 marks
Total :150 marks
Duration of exam. : 3 hours
1. Introduction: Recent trends in high voltage transmission.
2. Conduction and breakdown: Conduction & breakdown in gases, liquids and
solid dielectrics, insulator breakdown, insulation characteristics of
long air gaps.
3. Voltage gradients on conductors: Electrostatic fields of sphere gaps, fields of
line charges and their properties, charge-potential relations for
multi-conductor lines, surface voltage gradients on conductors,
distribution of voltage gradient on sub conductors of bundle.;
4. Corona: Corona and corona loss, corona loss formula, attenuation of travelling
waves due to corona, audible noise-generation and characteristics,
corona pulses--their generation and properties, properties of pulse,
radio interference.
5. Lightening: Lightening phenomenon, lightning stroke mechanism, principle of
lightning protection, tower foot resistance, insulator flash over and
withstand voltage, lightning arresters and their characteristics.
6. H.V. testing and Lab equipments : Standard wave-shapes for testing, wave-
shaping circuits: principles and theory; impulse generator,
generation of ac high voltage for testing, generation of direct
voltage, measurement of high voltage, general layout of H.V.
Laboratory.
EE-444-E ELECTRICAL POWER QUALITY
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
1. INTRODUCTION TO ELECTRICAL POWER QUALITY: Definition of Power Quality, Power Quality Issues,
Power Quality v/s Equipment Immunity, Electric Power Quality Standards.
2. POWER FREQUENCY DISTURBANCES: Common Power Frequency Disturbances, Voltage Sag, Isolation
Transformers, Voltage Regulators, Static Uninterruptible Power Source Systems.
3. ELECTRICAL TRANSIENTS: Types and Causes of Transients, Atmospheric Causes, Switching Loads On or Off,
Interruption of Fault Circuits, Capacitor Bank Switching, Motor Start Transient, Power Factor Correction, Capacitor
Switching Transient.
4. HARMONICS: Definition of Harmonics, Causes of Voltage and Current Harmonics. Individual and Total Harmonic
Distortion, Effect of Harmonics on Power System Devices, Guidelines for Harmonic Voltage and Current Limitation,
Harmonic Current Mitigation.
5. MEASURING & SOLVING POWER QUALITY PROBLEMS: Power Quality Measurement Devices, Harmonic Analyzers,
Transient-Disturbance Analyzers, Oscilloscopes, Data Loggers and Chart Recorders, True RMS Meters, Power Quality
Measurements.
EE-446-E ARTIFICIAL INTELLIGENCE
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
UNIT-1: FOUNDATIONAL ISSUES IN ARTIFICIAL INTELLIGENCE: Foundation and history of AI, AI problems and
techniques, AI programming languages, introduction to LISP and PROLOG, problem spaces and searches, blind search strategies,
Breadth first- Depth first - heuristic search techniques, Hill climbing, best first - A* algorithm, AO* algorithm- game tree, Min max
algorithms, game playing- alpha beta pruning.
Unit-2: KNOWLEDGE REPRESENTATION: Issues, predicate logic, logic programming, semantic nets, frames and
inheritance, constraint propagation, representing knowledge using rules, rules based deduction systems.
Unit-3: APPROXIMATE REASONING: Reasoning under uncertainty, review of probability, Baye’s probabilistic inferences and
Dempster Shafer theory, Heuristic methods, symbolic reasoning under uncertainty, Statistical reasoning, Fuzzy reasoning, Temporal
reasoning, Non-monotonic reasoning.
Unit-4: PLANNING & LEARNING: Planning in situational calculus, Representation for planning, Partial order planning
algorithm, Learning from examples, Discovery as learning, Learning by analogy, Explanation based learning, Introductory remarks
on learning by Neural Networks and Genetic Algorithms.
Unit-5: APPLICATIONS: Rule based systems architecture, Expert systems, Knowledge acquisition concepts, AI application
to robotics, and current trends in intelligent systems.
IC-405-E COMPUTER BASED INSTRUMENTATION
AND CONTROL
LTP Theory : 100 Marks
3 1 - Class Work : 50 Marks
Total : 150 Marks
Duration of Exam : 3Hrs
UNIT 1. INTRODUCTION:
Necessity and functions of computers. Level of automation and economy of computer
control. Centralized computer control Vs distributed computer control.
UNIT 2. COMPUTER ARCHITECTURE:
Micro and mini computer, functional models of I.O. system .
UNIT 3. INTERFACING:
Sampling; Multiplexing; A/D and D/A converters, interfacing with different types of
transducers - Analog / Digital, Electrical and non electrical selection of sensors; Micro
computer interfacing standard buses Serial buses; Serial data communication protocols.
UNIT 4. STRUCTURAL STUDY OF AUTOMATIC PROCESS CONTROL:
Fundamental of automatic process control, building block of automatic system, direct and
distributed digital control system. Programmable controllers.
UNIT 5. PERSONAL COMPUTER IN REAL LIFE ENVIRONMENT:
Introduction, personal computer: system and facility, PC bus and signals, interrupts,
interfacing PC with outer world, PC in RTE, Real time application of IBM PC PC based
distributed control system
UNIT 6. PROGRAMMING AND APPLICATION:
Modeling and simulation for plant automation, PLC Architecture and programming of
PLC, industrial control application: cement plant, thermal power plant , water treatment
plant, steel plant,
EE-450-E POWER MANAGEMENT
L T P
3 1 - Exam. : 100
Sessionals : 50
Total : 150
Duration of exam. : 3 hrs.
1. INTRODUCTION:
Power Scenario, Power Development, Planning, Power resources, Environment- Power matters Plan, Pre-feasibility and
feasibility studies, State relations for Power etc.
2. RESOURCES:
Resources, Geophysical study, Seismic Considerations, Environmental Restraints, Resettlement and Rehabilitation.
3. PROCUREMENT:
Contracting and Procurement, Consulting Services, Types of Contracts, Project Management, Organization and
Economy Management, Organizational Planning and Time Scheduling, Project Cost Control.
4. ENGINEERING:
Engineering & General Layout of Equipments, Generator, Transformer and Switch Gear and Control Equipment,
Construction Methods, Operation and Maintenance Principle, Maintenance organization and planning, Availability, life
cycle cost & future development. Visits to sites.
5. POWER SECTOR:
Power sector structure in different states, Regulatory Regime in those states, Power utilities in Haryana, Grid
management, Power financing, Visit to sites.
6. POWER STATION:
Management of Fuel, water Resource Electricity deviend scenario storage and handling, Pricing, Contract etc., Human
resource management. Visit to sites.
7. RISK & HAZARD:
Introduction to risk, rules and regulation Aspects of Risk & Hazard Health & risk assessment visit to site.
8. ELECTRICITY INDUSTRY STRUCTURE & SAFETY REGULATIONS BILL & ETC.:
State and Central Power boards / Power corporations.
Mechanical Engineering
Semester IIIrd
MATH-201-E : MATHEMATICS-III
L T P Class Work : 50 Marks
3 1 - Exam. : 100 Marks
Total : 150 Marks
Duration of exam. : 3 Hours
Part-A
Fourier Series and Fourier Transforms : Euler‟s formulae, conditions for a Fourier expansion,
change of interval, Fourier expansion of odd and even functions, Fourier expansion of square
wave, rectangular wave, saw-toothed wave, half and full rectified wave, half range sine and
consine series.
Fourier integrals, Fourier transforms, Shifting theorem (both on time and frequency axes), Fourier
transforms of derivatives, Fourier transforms of integrals, Convolution theorem, Fourier
transform of Dirac-delta function.
Part-B
Functions of Complex Variable : Definition, Exponential function, Trignometric and
Hyperbolic functions, Logrithmic functions. Limit and Continuity of a function,
Differnetiability and Analyticity.
Cauchy-Riemann equations, necessary and sufficient conditions for a function to be
analytic, polar form of the Cauchy-Riemann equations. Harmonic functions, application to
flow problems. Integration of complex functions. Cauchy-Integral theorem and fourmula.
Power series, radius and circle of convergence, Taylor's Maclaurin's and Laurent's series.
Zeroes and singularities of complex functions, Residues. Evaluation of real integrals using
residues (around unit and semi circle only).
Part-C
Probability Distributions and Hypothesis Testing : Conditional probability, Bayes theorem and
its applications, expected value of a random variable. Properties and application of Binomial,
Poisson and Normal distributions.
Testing of a hypothesis, tests of significance for large samples, Student‟s t-distribution
(applications only), Chi-square test of goodness of fit.
Linear Programming : Linear programming problems formulation, Solving linear programming
problems using (i) Graphical method (ii) Simplex method (iii) Dual simplex method.
HUM-201-E ECONOMICS
L T P Class Work : 50 Marks
3 1 - Theory : 100 Marks
Total : 150 Marks
Duration of Exam. : 3 Hrs.
COURSE OBJECTIVE : The purpose of this course is to :
1. Acquaint the student in the basic economic concepts and their operational significance and
2 .Stimulate him to think systematically and objectively about contemporary economic
problems.
UNIT-I
Definition of Economics - various definitions, Nature of Economic problem, Production
possibility curve Economic laws and their nature. Relation between Science, Engineering,
Technology and Economics.
UNIT-II
Concepts and measurement of utility, Law of Diminishing Marginal Utility, Law of equi-
marginal utility - its practical application and importance.
UNIT-III
Meaning of Demand, Individual and Market demand schedule, Law of demand, shape of
demand curve, Elasticity of demand, measurement of elasticity of demand, factors effecting
elasticity of demand, practical importance & applications of the concept of elasticity of
demand.
UNIT-IV
Meaning of production and factors of production; Law of variable proportions, Returns to
scale, Internal and External economics and diseconomies of scale.
Various concepts of cost - Fixed cost, variable cost, average cost, marginal cost,
money cost, real cost opportunity cost. Shape of average cost, marginal cost, total cost etc.
in short run and long run.
UNIT-V
Meaning of Market, Types of Market - Perfect Competition, Monopoly, Oligoply, Monoplistic
Competition (Main features of these markets)
Supply and Law of Supply, Role of Demand & Supply in Price Determinition and effect of
changes in demand and supply on prices.
UNIT-VI
Nature and characteristics of Indian economy (brief and elementary introduction), Privatization
- meaning, merits and demerits. Globalisation of Indian economy - merits and demerits.
Elementary Concepts of VAT, WTO, GATT & TRIPS agreement.
ME- 201 E THERMODYNAMICS
Sessional : 50
Marks
L T P Theory : 100
Marks
3 1 - Total : 150
Marks
Duration of Exam. : 3 hrs.
Unit I Basic Concepts: Macroscopic and Microscopic Approaches, Thermodynamic
Systems, Surrounding and Boundary, Thermodynamic Property – Intensive and
Extensive, Thermodynamic Equilibrium, State, Path, Process and Cycle, Quasi-
static, Reversible and Irreversible Processes, Working Substance. Concept of
Thermodynamic Work and Heat, Equality of Temperature, Zeroth Law of
Thermodynamic and its utility. Problems.
Unit II First Law of Thermodynamics: Energy and its Forms, Energy and 1st law of
Thermodynamics, Internal Energy and Enthalpy, PMMFK, Steady flow energy
equation, 1st Law Applied to Non- flow process, Steady Flow Process and
Transient Flow Process, Throttling Process and Free Expansion Process.
Problems.
Unit III Second Law of Thermodynamics: Limitations of First Law, Thermal Reservoir,
Heat Source and Heat Sink, Heat Engine, Refrigerator and Heat Pump, Kelvin-
Planck and Clausius Statements and their Equivalence, PMMSK. Carnot Cycle,
Carnot Heat Engine and Carnot Heat Pump, Carnot Theorem and its Corollaries,
Thermodynamic Temperature Scale. Entropy, Clausius Inequality, Principle of
Entropy Increase, Temperature Entropy Plot, Entropy Change in Different
Processes, Introduction to Third Law of Thermodynamics. Problems.
Unit IV Availability and Irreversibility: High and Low Grade Energy, Availability and
Unavailable Energy, Loss of Available Energy Due to Heat Transfer Through a
Finite Temperature Difference, Dead state of a system, Availability of a Non-
Flow or Closed System, Availability of a Steady Flow System, Helmholtz and
Gibb‟s Functions, Effectiveness and Irreversibility, Second law efficiencies of
processes & cycles. Problems.
Unit V Pure Substance: Pure Substance and its Properties, Phase and Phase
Transformation, Vaporization, Evaporation and Boiling, Saturated and Superheat
Steam, Solid – Liquid – Vapour Equilibrium, T-V, P-V and P-T Plots During
Steam Formation, Properties of Dry, Wet and Superheated Steam, Property
Changes During Steam Processes, Temperature – Entropy (T-S) and Enthalpy –
Entropy (H-S) Diagrams, Throttling and Measurement of Dryness Fraction of
Steam. Problems.
Unit VI Ideal and Real Gases: Concept of an Ideal Gas, Basic Gas Laws, Characteristic
Gas Equation, Avogadro‟s law and Universal Gas Constant, P-V-T surface of an
Ideal Gas. Vander Waal‟s Equation of state, Reduced Co-ordinates,
Compressibility factor and law of corresponding states. Mixture of Gases, Mass,
Mole and Volume Fraction, Gibson Dalton‟s law, Gas Constant and Specific
Heats, Entropy for a mixture of non-reactive gases. Problems.
Unit VII Thermodynamic Relations: Maxwell Relations, Clapeyron Equation,
Relations for changes in Enthalpy and Internal Energy & Entropy,
Specific Heat Capacity Relations, Joule Thomson coefficient & inversion
curve.
ME- 203 E STRENGTH OF MATERIALS –I
Sessional
: 50 Marks
L T P Theory
: 100 Marks
3 1 - Total
: 150 Marks
Duration of
Exam. : 3 Hrs.
Unit 1 Simple Stresses & Strains: Concept & types of Stresses and strains, Poison‟s ratio,
stresses and strain in simple and compound bars under axial loading, stress strain diagrams,
Hooks law, elastic constants & their relationships, temperature stress & strain in simple &
compound bars under axial loading, Numerical.
Unit II Compound Stresses & Strains: Concept of surface and volumetric strains, two
dimensional stress system, conjugate shear stress at a point on a plane, principle
stresses & strains and principal- planes, Mohr‟s circle of stresses, Numerical.
Unit III Shear Force & Bending Moments: Definitions, SF & BM diagrams for cantilevers,
simply supported beams with or without over-hang and calculation of maximum
BM & SF and the point of contra-flexure under (i) concentrated loads, (ii)
uniformly distributed loads over whole span or a part of it, (iii) combination of
concentrated loads and uniformly distributed loads, (iv) uniformly varying loads
and (v) application of moments, relation between the rate of loading, the shear
force and the bending moments, Problems.
Unit IV Torsion Of Circular Members: Torsion of thin circular tube, Solid and hollow
circular shafts, tapered shaft, stepped shaft & composite circular shafts, combined
bending and torsion, equivalent torque, effect of end thrust. Numericals.
Unit V Bending & Shear Stresses in Beams: Bending stresses in beams with derivation &
application to beams of circular, rectangular, I,T and channel sections, composite
beams, shear stresses in beams with combined bending, torsion & axial loading of
beams. Numericals.
Unit VI Columns & Struts: Column under axial load, concept of instability and buckling,
slenderness ratio, derivation of Euler‟s formulae for the elastic buckling load,
Eulers, Rankine, Gordom‟s formulae Johnson‟s empirical formula for axial loading
columns and their applications, eccentric compression of a short strut of
rectangular & circular sections, Numerical.
Unit VII Slope & Deflection: Relationship between bending moment, slope & deflection,
Mohr‟s theorem, moment area method, method of integration, Macaulay‟s method,
calculations for slope and deflection of (i) cantilevers and (ii) simply supported
beams with or without overhang under concentrated load, Uniformly distributed
loads or combination of concentrated and uniformly distributed loads, Numerical.
Unit VIII Fixed Beams: Deflections, reactions and fixing moments with SF & BM
calculations & diagrams for fixed beams under (i) concentrated loads, (ii)
uniformly distributed load and (iii) a combination of concentrated loads &
uniformly distributed load.
ME 205 E ENGINEERING MECHANICS
L T P Sessional :50
Marks
3 1 - Theory :100
Marks
Total marks :150
Marks
Duration of exam: 3
Hrs
Unit-I Review of Basic Force Systems: Dimensions and units of mechanics,
idealization
of mechanics, laws of mechanics, vector algebra review, moment of a
force about a point and axis, the couple and couple moment, addition and
subtraction of couples, moment of a couple about a line, translation of a
force to a parallel position, resultant of a force system, Problems (vector
method).
Unit-II Equilibrium: Introduction, free body diagram, control volumes, general
equations of equilibrium, two point equivalent loading, static in-
determinacy, simple truss, method of joints, method of sections, co-planer
cable-loading a function of x, coplanar cables- loading the weight of
the cable itself. Problems.
Unit-III Properties of Surfaces & Moments and Products of inertia : First
moment of an area and the centroid, principal axes, formal definition
of inertia quantities, relation between mass-inertia terms and area-
inertia terms, translation of coordinate axes, transportation properties of
the inertia terms, a brief introduction to tensors, the inertia of ellipsoid and
principal moments of inertia, Problems (vector method).
Unit-IV Kinematics of Particles and Rigid Bodies: Velocity and acceleration
in path and cylindrical coordinates, motion of a particle relative to a pair of
translating axes, translation and rotation of rigid bodies, Chasles
theorem, moving references, velocity and acceleration for different
references, inertia and coriolis forces. Problems(vector method).
Unit-V Particle Dynamics, Energy Methods & Momentum Methods: Newton's law
for rectangular coordinates & cylindrical coordinates, rectifier
translation, central force motion, Newton's law for path variables, work
energy equations, work energy equations for a systems of particles, linear and
angular momentum equations for a systems of particles. Problems(vector
method).
Unit-VI Variational Mechanics: Hamiton principle, Lagrange equations, principle of
virtual work, methods of minimum potential energy, stability.
ME- 207 E MACHINE DRAWING
Theory : -
L T P Sessional :
50 Marks
1 - 4 Total
: 50 Marks
PART-A
Introduction to BIS Specification SP : 46 – 1988 Code of Engineering
drawing – Limits , fits and Tolerance ( Dimensional and Geometrical tolerance ) ,
Surface finish representation.
Gear: Gear terminology, I.S. convention representation of assembly of spur
gears, helical gears, bevel gears , worm and worm wheel.
PART-B
Orthographic views from isometric views of machine parts / components.
Dimensioning, Sectioning. Exercises on Coupling, Crankshaft, Pulley,
Piston and Connecting rod , Cotter and Knuckle joint. Riveted Joint and
Welded Joint.
PART-C
Assembly drawing with sectioning and bill of materials from given detailed
drawings of assemblies : Lathe Tail stock , Machine vice , Pedestal
bearing , Steam stop valve , Drill jigs and Milling fixture.
EE-213-E ELECTRONICS ENGINEERING
L T P Class Work
: 50
3 1 - Exam
: 100
Total
: 150
Duration of
Exam : 3hrs
UNIT – I : DIODES :
P-N junction, P-N junction as a rectifier, V-I characteristics, Breakdown diodes, Light emitting
diodes, Load – Line concept, Clipping, Clamping, Rectifiers.
UNIT – II : TRANSISTORS :
Operation and Characteristics of a Transistor, Common Emitter, Common Collector and Common
Base Configurations of a transistor, Biosing and Transistor as an amplifier and oscilletor..
UNIT – III : OP-AMPS :
Basic Characteristics of an OP-AMP, Applications of OP-AMP ( Inverter, Non-Inverter,
Integrator, Differentiator, Logarithmic amplifier, Square wave generator).
UNIT – IV : POWER AMPLIFIERS :
Class A, Class B and Class C Amplifiers.
UNIT – V : STABILISED POWER SUPPLIES :
Regulated power supply, series voltage regulator.
UNIT – VI : DIGITAL GATES :
Binary numbers, OR, AND, NAND, NOR, NOT, EX-OR Gates.
ME- 209 E STRENGTH OF MATERIAL-I LAB
Sessional
: 25 Marks
Exam
: 25 Marks
L T P Total
: 50 Marks
- - 2 Duration of exam
: 3 Hrs.
List of Experiments :
1. To study the Brinell hardness testing machine & perform the Brinell hardness
test.
2. To study the Rockwell hardness testing machine & perform the Rockwell
hardness test.
3. To study the Vickers hardness testing machine & perform the Vickers
hardness test.
4. To study the Erichsen sheet metal testing machine & perform the Erichsen
sheet metal test.
5. To study the Impact testing machine and perform the Impact tests (Izod &
Charpy).
6. To study the Universal testing machine and perform the tensile test.
7. To perform compression & bending tests on UTM.
8. To perform the sheer test on UTM.
9. To study the torsion testing machine and perform the torsion test.
10. To draw shear Force, Bending Moment Diagrams for a simply Supported
Beam under Point and Distributed Loads.
11. To determine Mechanical Advantage and Efficiency of Single and Double
Purchase Winch Crab.
12. To determine Mechanical Advantage and Efficiency of Worm and Worm
Gear of Single, Double and Triple start.
13. To determine Mechanical Advantage, Efficiency of Simple and Compound
Screw Jack.
14. To find Moment of Inertia of a Fly Wheel.
EE-219-E ELECTRONICS ENGINEERING LAB
L T P Class Work
: 25
0 0 2 Exam
: 25
Total
: 50
Duration of
Exam : 3hrs
LIST OF EXPERIMENTS :
1. Study of V-I Characteristics of Diode.
2. Study of a Clipping and Clamping circuits.
3. Study of a Half wave rectifier.
4. Study of a Full wave rectifier.
5. Study and Analysis of a Transistor in Common Emitter Configuration.
6. Study of OP-AMP as Inverter and Comparator.
7. Study of OP-AMP as Differentiator.
8. Study of OP-AMP as Integrator.
9. Study of OP-AMP as Square wave generator.
10. Realization of Truth Tables of AND, OR, NOT Gates.
11. Realization of Truth Tables of NAND, NOR and EX-OR Gates.
ME – 211 E COMPUTER AIDED DRAFTING LAB.
L T P Sessional :
50 Marks
- - 2 Practical :
50 Marks
Total :
100 Marks
Duration of Exam :
4 hrs.
The students will be required to carry out the following exercises using educational
soft-wares
(AutoCad-2002, I-DEAS, Pro-Engineer etc).
1. Setting up of drawing environment by setting drawing limits, drawing units,
naming the drawing, naming layers, setting line types for different layers using
various type of lines in engineering drawing, saving the file with .dwg extension.
2. Layout drawing of a building using different layer and line colors indicating all
Building details. Name the details using text commands, Make a title Block.
3. To Draw Orthographic projection Drawings (Front, Top and side) of boiler safety
valve giving name the various components of the valve.
4. Make an Isometric dimensioned drawing of a connecting Rod using isometric grid
and snap.
5. Draw quarter sectional isometric view of a cotter joint.
6. Draw different types of bolts and nuts with internal and external threading in
Acme and square threading standards. Save the bolts and nuts as blocks suitable
for insertion.
7. Draw 3D models by extruding simple 2D objects, dimension and name the
objects.
8. Draw a spiral by extruding a circle.
Mechanical Engineering (ME)
Semester IV
HUM-202-E FUNDAMENTALS OF MANAGEMENT
L T P Class Work : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam. : 3 Hrs.
UNIT-I
Meaning of management, Definitions of Management, Characteristics of management, Management Vs.
Administration. Management-Art, Science and Profession. Importance of Management. Development of
Management thoughts.
Principles of Management. The Management Functions, Inter-relationship of Managerial functions.
UNIT-II
Nature and Significance of staffing, Personnel management, Functions of personnel management,
Manpower planning, Process of manpower planning, Recruitment, Selection; Promotion - Seniority Vs. Merit.
Training - objectives and types of training.
UNIT-III
Production Management : Definition, Objectives, Functions and Scope,
Production Planning and Control; its significance, stages in production planning and
control. Brief introduction to the concepts of material management, inventory control; its
importance and various methods.
UNIT-IV
Marketing Management - Definition of marketing, Marketing concept, objectives & Functions of
marketing.
Marketing Research - Meaning; Definition; objectives; Importance; Limitations; Process. Advertising - meaning of
advertising, objectives, functions, criticism.
UNIT-V
Introduction of Financial Management, Objectives of Financial Management,
Functions and Importance of Financial Management. Brief Introduction to the concept of
capital structure and various sources of finance.
ME-202 E MANUFACTURING TECHNOLOGY
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3 Hrs
Unit I Metal Casting Processes: Advantages and limitations, sand mold making
procedure. Patterns and Cores: Pattern materials, pattern
allowances, types of pattern, color coding. Molding materials: Molding
sand composition, sand preparation, sand properties and testing, Sand
molding processes
Unit II Cores: Types of cores, core prints, chaplets, and chills. Gating systems:
Gates and gating systems risers. Melting practice: Cupola, charge
calculations. Casting cleaning and casting defects, Fettling, defects in
castings and their remedies, methods of testing of castings for their
soundness.
Unit III Special Casting Processes: Shell molding, precision investment casting,
permanent mold casting, die casting, centrifugal casting,
continuous casting,
Unit IV Metal Forming Processes: Nature of plastic deformation, hot working and
cold working .Principles of rolling, roll passes, roll pass sequences.
Forging: Forging operations, smith forging, drop forging, press forging,
forging defects.
Unit V Extrusion and other processes: Extrusion principle, hot extrusion, cold
extrusion, wire drawing, swaging, tube making. Sheet metal operations:
Press tools operations, hearing action, drawing dies, spinning, bending,
stretch forming, embossing and coining.
Unit VI Gas and Arc Welding: Classification: oxy- acetylene welding equipment
and techniques. Electric arc welding: Electrodes, manual metal arc
welding, inert gas shielded arc welding, tungsten inert gas welding (TIG),
metal inert gas welding(MIG), submerged arcwelding (SAW).
Unit VII Resistance Welding: Principles, resistance spot welding, resistance
seam welding, upset welding, flash welding,
Unit VIII Other Welding Processes: Introduction thermit welding, electro slag
welding, electron beam
welding, forge welding, friction welding, diffusion welding, brazing and
soldering.
ME- 204 E MATERIAL SCIENCE
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3 Hrs
Unit I Crystallography: Review of crystal structure, space lattice, crystal planes
and crystal directions, co-ordination number, number of atoms per unit
cell, atomic packing factor, Numericals related to crystallography.
Unit II Imperfection in metal crystals: Crystal imperfections and their
classifications, point defects, line defects, edge & screw dislocations,
surface defects, volume defects & effects of imperfections on metal
properties.
Unit III Solid solutions and phase diagram: Introduction to single and multiphase
solid solutions and types of solid solutions, importance and objectives of
phase diagram, systems, phase and structural constituents, cooling curves,
unary & binary phase diagrams, Gibbs‟s phase rule, Lever rule, eutectic
and eutectoid systems, peritectic and peritectoid systems, iron carbon
equilibrium diagram and TTT diagram.
Unit IV Heat Treatment: Principles, purpose, classification of heat treatment
processes, annealing, normalizing, stress relieving, hardening, tempering,
carburizing, nitriding, cyaniding, flame and induction hardening.
Allotropic transformation of iron and steel, Properties of austenite, ferrite,
pearlite, martensite.
Unit V Deformation of Metal: Elastic and plastic deformation, mechanism of
plastic deformation, twinning, conventional and true stress strain curves
for polycrystalline materials, yield point phenomena, strain ageing, work
hardening, Bauschinger effect, season cracking. Recovery, re-
crystallization and grain growth.
Unit VI Failures of metals: Failure analysis, fracture, process of fracture, types of
fracture, fatigue, characteristics of fatigue, fatigue limit, mechanism of
fatigue, factors affecting fatigue.
Unit VII Creep & Corrosion: Definition and concept, creep curve, mechanism of
creep, impact of time and temperature on creep, creep fracture, creep
testing and prevention against creep. Corrosion: Mechanism and effect of
corrosion, prevention of corrosion.
Unit VIII Plastic, Composite and Ceramics: Polymers, formation of polymers,
polymer structure and crystallinity, polymers to plastics types, reinforced
particles-strengthened and dispersion strengthened composites. Ceramic
materials: Types of ceramics, properties of ceramic, ceramic forming
techniques, mechanical behavior of ceramic.
ME- 206 E STRENGTH OF MATERIALS-II
Sessional
: 50Marks
L T P Theory
: 100 Marks
3 1 - Total
: 150 Marks
Duration of
Exam: 3Hrs.
Unit I Strain Energy & Impact Loading: Definitions, expressions for strain energy stored in a
body when load is applied (i) gradually, (ii) suddenly and (iii) with impact, strain energy of
beams in bending, beam deflections, strain energy of shafts in twisting, energy methods in
determining spring deflection, Castigliano‟s & Maxwell‟s theorems, Numericals.
Unit II Theories of Elastic Failure: Various theories of elastic failures with derivations and
graphical representations, applications to problems of 2- dimensional stress system
with (i) Combined direct loading and bending, and (ii) combined torsional and
direct loading, Numericals.
Unit III Unsymmetrical Bending: Properties of beam cross section, product of inertia,
ellipse of inertia, slope of the neutral axis, stresses & deflections, shear center and
the flexural axis Numericals.
Unit IV Thin Walled Vessels : Hoop & Longitudinal stresses & strains in cylindrical &
spherical vessels & their derivations under internal pressure, wire would cylinders,
Numericals.
Unit V Thick Cylinders & Spheres : Derivation of Lame‟s equations, radial & hoop
stresses and strains in thick, and compound cylinders and spherical shells
subjected to internal fluid pressure only, wire wound cylinders, hub shrunk on solid
shaft, Numericals.
Unit VI Rotating Rims & Discs: Stresses in uniform rotating rings & discs, rotating discs of
uniform strength, stresses in ( I) rotating rims, neglecting the effect of spokes, (ii)
rotating cylinders, hollow cylinders & solids cylinders. Numericals.
Unit VII Bending of Curved Bars : Stresses in bars of initial large radius of curvature, bars
of initial small radius of curvature, stresses in crane hooks, rings of circular &
trapezoidal sections, deflection of curved bars & rings, deflection of rings by
Castigliano‟s theorem stresses in simple chain link, deflection of simple chain
links, Problems.
Unit VIII Springs: Stresses in open coiled helical spring subjected to axial loads and twisting
couples, leaf springs, flat spiral springs, concentric springs, Numericals.
ME- 208 E FLUID MECHANICS
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3
Hrs.
Unit I Fluid Properties and Fluid Statics: Concept of fluid and flow, ideal and
real fluids, continuum concept, properties of fluids, Newtonian and non-
Newtonian fluids. Pascal‟s law, hydrostatic equation, hydrostatic forces
on plane and curved surfaces, stability of floating and submerged bodies,
relative equilibrium. Problems.
Unit II Fluid Kinematics: Eulerian and Lagrangian description of fluid flow;
stream, streak and path lines; types of flows, flow rate and continuity
equation, differential equation of continuity in cylindrical and polar
coordinates, rotation, vorticity and circulation, stream and potential
functions, flow net. Problems.
Unit III Fluid Dynamics: Concept of system and control volume, Euler‟s equation,
Bernoulli‟s equation, venturimeter, orifices, orificemeter, mouthpieces,
kinetic and momentum correction factors, Impulse momentum relationship
and its applications. Problems.
Unit IV Potential Flow: Uniform and vortex flow, flow past a Rankin half body,
source, sink, source-sink pair and doublet, flow past a cylinder with and
without circulation. Problems.
Unit V Viscous Flow: Flow regimes and Reynold‟s number, Relationship
between shear stress and pressure gradient, uni-directional flow between
stationary and moving parallel plates, movement of piston in a dashpot,
power absorbed in bearings. Problems.
Unit VI Flow Through Pipes: Major and minor losses in pipes, Hagen-Poiseuilli
law, hydraulic gradient and total energy lines, series and parallel
connection of pipes, branched pipes; equivalent pipe, power transmission
through pipes. Problems.
Unit VII Boundary Layer Flow: Boundary layer concept, displacement, momentum
and energy thickness, von-karman momentum integral equation, laminar
and turbulent boundary layer flows, drag on a flat plate, boundary layer
separation and control. Streamlined and bluff bodies, lift and drag on a
cylinder and an airfoil, Problems.
Unit VIII Turbulent Flow: Shear stress in turbulent flow, Prandtl mixing length
hypothesis, hydraulically smooth and rough pipes, velocity distribution in
pipes, friction coefficients for smooth and rough pipes. Problems.
ME- 210 E ENERGY CONVERSION
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3
Hrs.
Unit I Fuels and Combustion: Classification of fuels- solid, liquid & gaseous
fuels, Combustion equations, Stochiometric air-fuel ratio, Excess air,
Exhaust gas analysis, Orsat apparatus. Enthalpy and internal energy of
combustion, Enthalpy of formation, Adiabatic flame temperature, Gibb‟s
and Helmholtz functions, Calorific values of fuel, Problems.
Unit II Steam Boilers and Draft: Classification, comparison between fire and
water tube boilers, Essentials of a good boiler, Constructional and
operational details of Locomotive& Lancashire Boilers, High pressure
boilers- Benson, Lamont, Loeffler and Velox boilers, Boiler mountings
and accessories, Boiler performance, Natural& Artificial drafts, Chimney
height, Maximum draft and chimney efficiency, Boiler heat balance sheet,
Problems.
Unit III Vapour Power Cycles: Carnot and Rankine vapour cycles, effect of
operating conditions on thermal efficiency of Rankine cycle, Rankine
cycle with superheat, reheat and regeneration, Binary vapour cycle,
Problems..
Unit IV Flow Through Nozzles: Velocity and heat drop, mass discharge through
a nozzle, critical pressure ratio and its significance, effect of friction and
nozzle efficiency, supersaturated flow, design pressure ratio, Problems.
Unit V Steam Turbines: Classification, Impulse Turbine- Flow through blades,
velocity diagram, power output and efficiency, maximum blade efficiency
of single stage impulse turbine, blade friction, compounding of impulse
turbine. Reaction Turbine-Flow through impulse reaction blades, degree
of reaction, velocity diagram, power output, efficiency and blade height,
comparison of impulse and impulse reaction turbines. Losses in steam
turbines, stage efficiency, overall efficiency and reheat factor. Governing
of steam turbines, Problems.
Unit VI Steam Condensers: Elements of a condensing plant, types of condensers,
comparison of jet and surface condensers. Condenser vacuum, sources of
air leakage & its disadvantages, vacuum efficiency and condenser
efficiency, Problems.
Unit VII Air Compressors: Working of a single stage reciprocating air compressor;
calculation of work input; Volumetric efficiency; Isothermal efficiency;
Advantages of multi stage compression; Two stage compressor with Inter-
cooling; Perfect Inter cooling; Optimum intercooler pressure, Problems.
ME- 212 E MATERIAL SCIENCE LAB.
L T P
- - 2
Sessional : 25 Marks
Theory : 25 Marks
Total : 50 Marks
Duration of Exam: 3 Hrs
List of Experiments:
1. To study crystal structures of a given specimen.
2. To study crystal imperfections in a given specimen.
3. To study microstructures of metals/ alloys.
4. To prepare solidification curve for a given specimen.
5. To study heat treatment processes (hardening and tempering) of steel specimen.
6. To study microstructure of heat-treated steel.
7. To study thermo-setting of plastics.
8. To study the creep behavior of a given specimen.
9. To study the mechanism of chemical corrosion and its protection.
10. To study the properties of various types of plastics.
11. To study Bravais lattices with the help of models.
12. To study crystal structures and crystals imperfections using ball models.
ME- 214 E FLUID MECHANICS LAB
Sessional : 25 Marks
Practical/Viva : 25 Marks
L T P Total : 50 Marks
- - 2 Duration of Exam. : 3 Hrs.
List of Experiments:
1. To determine the coefficient of impact for vanes.
2. To determine coefficient of discharge of an orificemeter.
3. To determine the coefficient of discharge of Notch ( V and Rectangular types ).
4. To determine the friction factor for the pipes.
5. To determine the coefficient of discharge of venturimeter.
6. To determine the coefficient of discharge, contraction & velocity of an orifice.
7. To verify the Bernoullis Theorem.
8. To find critical Reynolds number for a pipe flow.
9. To determine the meta-centric height of a floating body.
10. To determine the minor losses due to sudden enlargement, sudden contraction and
bends.
11. To show the velocity and pressure variation with radius in a forced vertex flow.
ME- 216 E ENERGY CONVERSION LAB
Sessional : 25 Marks
Practical/Viva : 25 Marks
L T P Total : 50 Marks
- - 2 Duration of Exam. : 3 Hrs.
List of Experiments:
1. To study low pressure boilers and their accessories and mountings.
2. To study high pressure boilers and their accessories and mountings.
3. To prepare heat balance sheet for given boiler.
4. To study the working of impulse and reaction steam turbines..
5. To find dryness fraction of steam by separating and throttling calorimeter.
6. To find power out put & efficiency of a steam turbine.
7. To find the condenser efficiencies.
8. To study and find volumetric efficiency of a reciprocating air compressor.
9. To study cooling tower and find its efficiency.
10. To find calorific value of a sample of fuel using Bomb calorimeter.
11. Calibration of Thermometers and pressure gauges.
ME- 218 E MANUFACTURING PRACTICE
L T P
- - 3
Sessional : 25
Marks
Practical/Viva : 25
Marks
Total : 50
Marks
Duration of Exam : 3 Hrs
I) List of Experiments:
1. To make a pattern for a given casting with all the necessary allowances, parting
line, running system details. Prepare the mold and make the casting. Investigate
the casting defects and suggest the remedial measures.
2. To make a component involving horizontal and vertical welding and study the
welding defects and suggests their remedies.
3. To prepare a job on surface grinder/cylindrical grinder and measure the various
parameters of the finished piece.
4. To cut external threads on a lathe.
5. Manufacture and assembly of a unit consisting of 2 to 3 components to have the
concept of tolerances and fits (shaft and bush assembly or shaft, key and bush
assembly or any suitable assembly).
6. Leveling of machine tools and testing their accuracy.
7. Disassembly and assembly of small assemblies such as tail stock, bench vice,
screw jack etc.
8. Development and manufacture of complex sheet-metal components such as
funnel etc.
9. Multi slot cutting on milling machine by indexing.
10. Drilling and boring of a bush.
11. Modeling of 3D runner system and creation of drawing for manufacturing of the
casting patterns.
12. Development of blank size for complex sheet metal components using CAD/CAE
software and compare results with manual calculation method.
Mechanical Engineering (ME)
Semester V
ME-301 E KINEMATICS OF MACHINES
Sessional : 50
Marks
Theory : 100
Marks
L T P Total : 150
Marks
3 1 - Duration of Exam : 3
Hrs.
Unit I Introduction: mechanism and machines, kinematic links, kinematic pairs,
kinematic chains, plane and space mechanism, kinematic inversion,
equivalent linkages, four link planar mechanisms, mobility and range of
movement, straight line mechanisms, steering mechanisms, pantograph,
problems.
Unit II Kinematic Analysis of Plane Mechanisms: displacement analysis, general
plane motion, instantaneous center of velocity, graphical and analytical
methods of velocity and acceleration analysis, problems.
Unit III Cams: classification of cams and followers, disc cam nomenclature,
construction of displacement, velocity and acceleration diagrams for
different types of follower motions, analysis of follower motions,
determination of basic dimension, synthesis of cam profile by graphical
and analytical approaches, cams with specified contours, tangent and
circular are cams, problems.
Unit IV Gears: fundamental law of gearing, involute spur gears, characteristics of
involute action, Interference and undercutting, center distance variation,
involutometry, non standard gear teeth, helical, spiral bevel and worm
gears, problems.
Unit V Gear Trains: synthesis of simple, compound and reverted gear trains,
analysis of epicylic gear trains, problems.
Unit VI Kinematic synthesis of Mechanisms. Type, number and dimensional
synthesis, function generation, path generation and body guidance two and
three position synthesis of four bar and slider crank mechanisms by
graphical and analytical methods, Freudenstein‟s equation, precision
positions, structural error; Chebychev spacing, transmission angle,
problems.
Unit VII Kinematics of Spatial Mechanisms: introduction, link coordinate system,
homogeneous transformation matrix, loop closure equation, kinematics of
robotic manipulators, problems.
ME- 303 E MACHINE DESIGN -I
Sessional
: 50 Marks
L T P Theory
: 100 Marks
3 2 - Total
: 150 Marks
Duration of
Exam : 4 hrs.
Unit I Design Philosophy: Problem identification- problem statement, specifications,
constraints, Feasibility study-technical feasibility, economic & financial feasibility, societal &
environmental feasibility, Generation of solution field (solution variants), Brain storming,
Preliminary design, Selection of best possible solution, Detailed design, Selection of Fits and
tolerances and analysis of dimensional chains.
Unit II Selection of Materials: Classification of Engg. Materials, Mechanical properties of
the commonly used engg. Materials, hardness, strength parameters with reference
to stress-strain diagram, Factor of safety.
Unit III Mechanical Joints: ISO Metric Screw Threads, Bolted joints in tension,
Eccentrically loaded bolted joints in shear and under combined stresses, Design of
power screws, Design of various types of welding joints under different static load
conditions.
Unit IV Riveted Joints, Cotter & Knuckle Joints: Design of various types of riveted joints
under different static loading conditions, eccentrically loaded riveted joints, design
of cotter and knuckle joints.
Unit V Belt rope and chain drives: Design of belt drives, Flat & V-belt drives, Condition
for Transmission of max. Power, Selection of belt, design of rope drives, design of
chain drives with sprockets.
Unit VI Keys, Couplings & Flywheel: Design of Keys – Flat, Kennedy Keys, Splines,
Couplings design – Rigid & Flexible coupling, turning Moment diagram,
coefficient of fluctuation of energy and speed, design of flywheel – solid disk &
rimmed flywheels.
Unit VII Clutches: Various types of clutches in use, Design of friction clutches – Disc.
Multidisc, Cone & Centrifugal, Torque transmitting capacity.
Unit VIII Brakes: Various types of Brakes, Self energizing condition of brakes, Design of
shoe brakes – Internal & external expanding, band brakes, Thermal Considerations
in brake designing.
ME- 305 E FLUID MACHINES
Sessional : 50
Marks
L T P Theory : 100
Marks
3 1 - Total : 150
Marks
Duration of Exam : 3
Hrs.
Unit I Impact of free jets: Impulse – momentum principle, jet impingement - on a
stationary flat plate, inclined plate and a hinged plate, at the center of a
stationary vane, on a moving flat plate, inclined plate, a moving vane and a
series of vanes, Jet striking tangentially at the tip of a stationary vane and
moving vane(s), jet propulsion of ships. Problems
Unit II Impulse Turbines: Classification – impulse and reaction turbines, water wheels,
component parts, construction, operation and governing mechanism of a Pelton
wheel, work done, effective head, available head and efficiency of a Pelton
wheel, design aspects, speed ratio, flow ratio, jet ratio, number of jets, number of
buckets and working proportions, Performance Characteristics, governing of
impulse turbines. Problems
Unit III Francis Turbines: Component parts, construction and operation of a Francis
turbine, governing mechanism, work done by the turbine runner, working
proportions and design parameters, slow, medium and fast runners, degree of
reaction, inward/outward flow reaction turbines, Performance Characteristics,
Problems.
Unit IV Propeller and Kaplan turbines: Component parts, construction and operation of a
Propeller, Kaplan turbine, differences between the Francis and Kaplan turbines,
draft tube - its function and different forms, Performance Characteristics,
Governing of reaction turbine, Introduction to new types of turbine, Deriaz (
Diagonal ), Bulb, Tubular turbines, Problems.
Unit V Dimensional Analysis and Model Similitude: Dimensional homogeneity,
Rayleigh‟s method and Buckingham‟s π-theorem, model studies and similitude,
dimensionless numbers and their significance. Unit quantities, specific speed and
model relationships for turbines, scale effect, cavitations – its causes, harmful
effects and prevention, Thomas cavitation factor, permissible installation height,
Problems.
Unit VI Centrifugal Pumps: Classification, velocity vector diagrams and work done,
manometric efficiency, vane shape, head capacity relationship and pump losses,
pressure rise in impeller, minimum starting speed, design considerations, multi-
stage pumps. Similarity relations and specific speed, net positive suction head,
cavitation and maximum suction lift, performance characteristics. Brief
introduction to axial flow, mixed flow and submersible pumps, Problems.
Unit VII Reciprocating Pumps: Construction and operational details, discharge
coefficient, volumetric efficiency and slip, work and power input, effect of
acceleration and friction on indicator diagram (pressure – stroke length plot),
separation, air vessels and their utility, rate of flow into or from the air vessel,
maximum speed of the rotating crank, characteristic curves, centrifugal vs
reciprocating pumps, brief introduction to screw, gear, vane and radial piston
pumps, Problems.
Unit VIII Hydraulic systems: Function, construction and operation of Hydraulic
accumulator, hydraulic intensifier, hydraulic crane, hydraulic lift and hydraulic
press, Fluid coupling and torque converter, Hydraulic ram, Problems.
ME- 307 E INTERNAL COMBUSTION ENGINES & GAS
TURBINES
Sessional : 50
Marks
L T P Theory : 100
Marks
3 1 - Total : 150
Marks
Duration of Exam :
3 Hrs.
UNIT – I Air Standard Cycles: Internal and external combustion engines;
classification of I.C. Engines, Cycles of operation in four stroke and two
stroke I.C. Engines, Wankel Engines, Assumptions made in air standard
cycle; Otto cycle; diesel cycle, dual combustion cycle, comparison of
Otto, diesel and dual combustion cycles; sterling and Ericsson cycles; air
standard efficiency, specific work output, specific weight; work ratio;
mean effective pressure; deviation of actual engine cycle from ideal cycle.
Problems.
UNIT – II Carburetion, fuel Injection and Ignition systems: Mixture requirements
for various operating conditions in S.I. Engines; elementary carburetor,
Requirements of a diesel injection system; types of inject systems; petrol
injection, Requirements of ignition system; types of ignition systems
ignition timing; spark plugs. Problems.
UNIT – III Combustion in I.C. Engines : S.I. engines; Ignition limits; stages of
combustion in S.I. Engines; Ignition lag; velocity of flame propagation;
detonation; effects of engine variables on detonation; theories of
detonation; octane rating of fuels; pre-ignition; S.I. engine combustion
chambers, Stages of combustion in C.I. Engines; delay period; variables
affecting delay period; knock in C.I. engines, Cetane rating; C.I. engine
combustion chambers.
UNIT – IV Lubrication and Cooling Systems: Functions of a lubricating system,
Types of lubrication system; mist, wet sump and dry sump systems;
properties of lubricating oil; SAE rating of lubricants, engine performance
and lubrication, Necessity of engine cooling; disadvantages of
overcooling; cooling systems; air-cooling, water cooling; radiators.
UNIT – V Engine Testing and Performance: Performance parameters: BHP, IHP,
mechanical efficiency, brake mean effective pressure and indicative mean
effective pressure, torque, volumetric efficiency; specific fuel
consumption (BSFC, ISFC), thermal efficiency; heat balance; Basic
engine measurements; fuel and air consumption, brake power, indicated
power and friction power, heat lost to coolant and exhaust gases;
performance curves. Problems.
UNIT – VI Air pollution from I.C. Engine and Its remedies: Pollutants from S.I.
and C.I. Engines, Methods of emission control; alternative fuels for I.C.
Engines; the current scenario on the pollution front.
UNIT – VII Rotary Compressors: Root and vane blowers; Static and total head
values; Centrifugal compressors- Velocity diagrams, slip factor, ratio of
compression, pressure coefficient, pre-whirl; Axial flow compressor-
Degree of reaction, polytropic efficincy, surging, choking and stalling,
performance characteristics, Problems.
UNIT – VIII Gas Turbines: Brayton cycle; Components of a gas turbine plant; open
and closed types of gas turbine plants; Optimum pressure ratio;
Improvements of the basic gas turbine cycle; multi stage compression with
inter-cooling; multi stage expansion with reheating between stages;
exhaust gas heat exchanger, Applications of gas turbines. Problems.
ME- 309 E MANUFACTURING SCIENCE
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3
Hrs
Unit I Mechanism of Metal Cutting: Deformation of metal during machining,
nomenclature of lathe, milling tools, mechanics of chip formation, built-up
edges, mechanics of orthogonal and oblique cutting, Merchant cutting
force circle and shear angle relationship in orthogonal cutting, factors
affecting tool forces. Cutting speed, feed and depth of cut, surface finish.
Temperature distribution at tool chip interface. Numericals on cutting
forces and Merchant circle.
Unit II Cutting Tool Materials & Cutting Fluids: Characteristics of tool materials,
various types of cutting tool materials, coated tools, cutting tool selection,
Purpose and types of cutting fluids, basic actions of cutting fluids, effect
of cutting fluid on tool life, selections of cutting fluid.
Unit III Tool Wear and Machinability: Types of tool wear, tool life, factors
governing tool life,
Machinability: Definition and evaluation. Economics of machining.
Numericals on tool life.
Unit IV Gear Manufacturing: Introduction, methods of manufacture. Gear
generation and forming: Gear cutting by milling, single point form tool,
gear hobbing and shaping. Gear finishing operations: Gear shaving, gear
burnishing, gear grinding, lapping.
Unit V Unconventional Machining Processes: Abrasive jet machining: Principles,
applications, process parameters. Ultrasonic machining: Principles,
applications, analysis of process parameters. Electro-chemical machining
and grinding: Principles, classifications, choice of electrolytes,
applications. Electric discharge machining: Principles, selection of tools
materials and dielectric fluid. Electron beam machining: Generation of
electron beam, relative merits and demerits. Laser beam machining:
Principles and applications.
Unit VI Jigs & Fixtures: Introduction, location and location devices, clamping and
clamping devises, Drill Jigs, Milling Fixtures.
Unit VII Manufacturing Accuracy: Product cycle in manufacturing, part print
analysis, location
principles, tolerance stacking, accuracy of machining, operation selection,
tolerance analysis.
Unit VIII Metrology & Machine Tools Testing: Tolerances, limits and fits, methods
of linear measurement and angular measurement, Go and No Go gauges.
Introduction to Machine tools testing, measuring instruments used for
testing, test procedures, acceptance tests of machine tools.
ME – 311 E APPLIED NUMERICAL TECHNIQUES AND COMPUTING
L T P Sessional marks : 50
3 1 - Theory marks : 100
Total marks : 150
Duration of exam : 3
hrs
UNIT – I ERRORS IN NUMERICAL CALCULATIONS
Introduction, Numbers and their accuracy, Absolute, relative and percentage errors and
their analysis, General error formula.
UNIT – II INTERPOLATION AND CURVE FITTING
Taylor series and calculation of functions, Introduction to interpolation, Lagrange
approximation, Newton Polynomials, Chebyshev Polynomials, Least squares line, curve
fitting, Interpolation by spline functions.
UNIT – III NUMERICAL DIFFERENTIATION AND INTEGRATION
Approximating the derivative, Numerical differentiation formulas, Introduction to
Numerical quadrature, Newton-Cotes formula, Gaussion Quadrature.
UNIT – IV SOLUTION OF NONLINEAR EQUATIONS
Bracketing methods for locating a root, Initial approximations and convergence criteria,
Newton- Raphson and Secant methods, Solution of problems through a structural
programming language such as C or Pascal.
UNIT – V SOLUTION OF LINEAR SYSTEMS
Direct Methods, Gaussian elimination and pivoting, Matrix inversion, UV factorization,
Iterative methods for linear systems, Solution of problems through a structured
programming language such as C or Pascal.
UNIT – VI EIGEN VALUE PROBLEMS
Jacobi, Given‟s and Householder‟s methods for symmetric matrices, Rutishauser method
for general matrices, Power and inverse power methods.
UNIT – VII SOLUTION OF DIFFERENTIAL EQUATIONS
Introduction to differential equations, Initial value problems, Euler‟s methods, Heun‟s
method, Runge-Kutta methods, Taylor series method, Predictor-Corrector methods,
Systems of differential equations, Boundary valve problems, Finite-difference method,
Solution of problems through a structured programming language such as C or Pascal.
UNIT – VIII PARTIAL DIFFERENTIAL EQUATIONS, EIGENVALUES AND EIGENVECTORS
Solution of hyperbolic, parabolic and elliptic equations, The eigenvalue problem, The
power method and the Jacobi‟s method for eigen value problems, Solution of problems
through a structural programming language such as C or Pascal.
ME- 313 E KINEMATICS OF MACHINES LAB
Sessional : 25
Marks
L T P Practical : 25
Marks
- - 2 Total : 50
Marks
Duration of Exam :
3 Hrs.
List of Experiments :
1. To study various types of Kinematic links, pairs, chains and Mechanisms.
2. To study inversions of 4 Bar Mechanisms, Single and double slider crank
mechanisms.
3. To plot slider displacement, velocity and acceleration against crank rotation for
single slider crank mechanism.
4. To find coefficient of friction between belt and pulley.
5. To study various type of cam and follower arrangements.
6. To plot follower displacement vs cam rotation for various Cam Follower
systems.
7. To generate spur gear involute tooth profile using simulated gear shaping
process.
8. To study various types of gears – Helical , cross helical worm, bevel gear.
9. To study various types of gear trains – simple, compound, reverted,
epicyclic and differential.
10. To find co-efficient of friction between belt and pulley.
11. To study the working of Screw Jack and determine its efficiency.
12. Create various types of linkage mechanism in CAD and simulate for motion
outputs and study the relevant effects.
13. Creation of various joints like revolute, planes, spherical, cam follower and
study the degree of freedom and motion patterns available.
14. To design a cam profile by using the requirement graph using on-line
engineering handbook and verify the same using a 3D mechanism on CAD.
ME- 315 E FLUID MACHINES LAB.
L T P Sessional : 25 Marks
- - 2 Practical : 25 Marks
Total : 50 Marks
Duration of Exam.: 3 Hrs.
List of Experiments :
1. To study the constructional details of a Pelton turbine and draw its fluid flow
circuit.
2. To draw the following performance characteristics of Pelton turbine-
constant head, constant-speed and constant efficiency curves.
3. To study the constructional details of a Francis turbine and draw its fluid flow circuit.
4. To draw the constant head, constant speed and constant efficiency
performance characteristics of Francis turbine.
5. To study the construction details of a Kaplan turbine and draw its fluid flow circuit.
6. To draw the constant head, speed and efficiency curves for a Kaplan turbine.
7. To study the constructional details of a Centrifugal Pump and draw its characteristic
curves.
8. To study the constructional details of a Reciprocating Pump and draw its
characteristics curves.
9. To study the construction details of a Gear oil pump and its performance curves.
10. To study the constructional details of a Hydraulic Ram and determine its various
efficiencies..
11. To study the constructional details of a Centrifugal compressor.
12. To study the model of Hydro power plant and draw its layout.
ME- 317 E I.C. ENGINES & GAS TURBINES LAB
Sessional : 25 Marks
Practical : 25 Marks
L T P Total : 50 Marks
- - 2 Duration of Exam. : 3 Hrs.
List of Experiments :
1. To study the constructional details & working principles of two-stroke/ four stroke
petrol engine.
2. To study the constructional detail & working of two-stroke/ four stroke diesel
engine.
3. Analysis of exhaust gases from single cylinder/multi cylinder diesel/petrol engine
by Orsat
Apparatus.
4. To prepare heat balance sheet on multi-cylinder diesel engine/petrol engine.
5. To find the indicated horse power (IHP ) on multi-cylinder petrol engine/diesel
engine by
Morse Test.
6. To prepare variable speed performance test of a multi-cylinder/single cylinder
petrol engine/diesel engine and prepare the curves (i) bhp, ihp,fhp, vs speed ( ii)
volumetric efficiency & indicated specific specific fuel consumption vs speed.
7. To find fhp of a multi-cylinder diesel engine/petrol engine by Willian‟s line
method & by
motoring method.
8. To perform constant speed performance test on a single cylinder/multi-cylinder
diesel engine & draw curves of (i) bhp vs fuel rate, air rate and A/F and (ii) bhp vs
mep, mech efficiency & sfc.
9. To measure CO & Hydrocarbons in the exhaust of 2- stroke / 4-stroke petrol
engine.
10. To find intensity of smoke from a single cylinder / multi-cylinder diesel engine.
11. To draw the scavenging characteristic curves of single cylinder petrol engine.
12. To study the effects of secondary air flow on bhp, sfc, Mech. Efficiency &
emission of a two-stroke petrol engine.
ME- 319 E APPLIED NUMERICAL TECHNIQUES AND COMPUTING LAB.
L T P Sessional
marks : 25
- - 2 Practical
marks : 25
Total marks
: 50
Duration of
exam : 3 hrs
The students will be required to carry out the following exercises, that are
based on the theory course ME-311 Numerical Methods and Computing,
with the help of MATLAB software / Pascal / C / C++ on personal computer.
1. Solution of Non-linear equation in single variable using the method of successive
bisection.
2. Solution of Non-Linear equation in single variable using the Newton Raphson,
Secant, Bi – Section and Modified Eualer‟s, method.
3. Solution of a system of simultaneous algebraic equations using the Gaussian
elimination procedure.
4. Solution of a system of simultaneous algebraic equations using the Gauss-Seidel
iterative method.
5. Solution of a system of simultaneous algebraic equations using the Gauss-Seidel
iterative method employing the technique of successive relaxation.
6. Numerical solution of an ordinary differential equation using the Euler‟s method.
7. Numerical solution of an ordinary differential equation using the Runge - Kutta
4th order method.
8. Numerical solution of an ordinary differential equation using the Predictor –
corrector method.
9. Numerical solution of a system of two ordinary differential equation using
Numerical intergration.
10. Numerical solution of an elleptic boundary value problem using the method of
Finite Differences.
ME – 321 E PRACTICAL TRAINING – I
At the end of fourth semester each student would undergo six weeks Practical
Training in an industry/ Professional organization / Research Laboratory with the
prior approval of the Director-Principal/ Principal of the concerned college and
submit a written typed report along with a certificate from the organization. The
report will be a evaluated during V Semester by a Board of Examiners to be
appointed by the Director-Principal/ Principal of the concerned college who will
award one of the following grades:
Excellent : A
Good : B
Satisfactory : C
Not satisfactory : F
A student who has been awarded „F‟ grade will be required to repeat the
practical training.
Mechanical Engineering (ME)
Semester VI
ME- 302 E DYNAMICS OF MACHINES
Sessional : 50
Marks
Theory : 100
Marks
L T P Total : 150
Marks
3 1 - Duration of Exam : 3 Hrs.
Unit I Static and Dynamic Force Analysis : Static force analysis of planer
mechanisms, dynamic force analysis including inertia and frictional forces
of planer mechanisms.
Unit II Dynamics of Reciprocating Engines : engine types, indicator diagrams,
gas forces, equivalent masses, inertia forces, bearing loads in a single
cylinder engine, crankshaft torque, engine shaking forces.
Unit III Balancing of Rotating Components : static balance, dynamic balance,
balancing of rotating masses, two plane balancing, graphical and
analytical methods, balancing of rotors, balancing machines, field
balancing.
Unit IV Balancing of Reciprocating Parts : Balancing of single cylinder engine,
balancing of multi cylinder; inline, radial and V type engines, firing order.
Unit V Governors : introduction, types of governors, characteristics of centrifugal
governors, gravity controlled and spring controlled centrifugal governors,
hunting of centrifugal governors, inertia governors.
Unit VI Dynamometers : types of dynamometers, Prony brake, rope brake and
band brake dynamometers, belt transmission dynamometer, torsion
dynamometer, hydraulic dynamometer.
Unit VII Gyroscope : gyroscopes, gyroscopic forces and couples, gyroscopic
stabilization, ship stabilization, stability of four wheel and two wheel
vehicles moving on curved paths.
ME- 304 E MACHINE DESIGN –II
Sessional :
50 Marks
L T P Theory
: 100 Marks
3 2 - Total
: 150 Marks
Duration of
Exam : 4 hrs.
Unit I Design for Production ; Erogonomic and value engineering considerations in
design, Role of processing in design, Design considerations for casting, forging and
machining. Variable Loading : Different types of fluctuating/ variable stresses, Fatigue
strength considering stress concentration factor, surface factor, size factor, reliability
factor etc., Fatigue design for finite and infinite life against combined variable stresses
using Goodman and Soderberg‟s Criterion, Fatigue design using Miner‟s equation,
Problems.
Unit II Shafts : Detailed design of shafts for static and dynamic loading, Rigidity
and deflection consideration.
Unit III Springs : Types of Springs, Design for helical springs against tension and
their uses, compression and fluctuating loads, Design of leaf springs,
Surging phenomenon in springs, Design Problem.
Unit IV Bearings : design of pivot and collar bearing , Selection of ball and roller
bearing based on static and dynamic load carrying capacity using load-life
relationship, Selection of Bearings from manufacturer‟s catalogue, types of
lubrication – Boundary, mixed and hydrodynamic lubrication, Design of
journal bearings using Raimondi and Boyd‟s Charts, Lubricants and their
properties, Selection of suitable lubricants, Design Problems.
Unit V Gears : Classification, Selection of gears, Terminology of gears, Force
analysis, Selection of material for gears, Beam & wear strength of gear
tooth, Form or Lewis factor for gear tooth, Dynamic load on gear teeth -
Barth equation and Buckingham equation and their comparison, Design of
spur, helical, bevel & worm gear including the Consideration for maximum
power transmitting capacity, Gear Lubrication, Design Problems.
ME –306E HEAT TRANSFER
L T P Sessional
: 50 Marks
3 1 - Theory
: 100 Marks
Total :
150 Marks
Duration of
Exam :3 Hrs.
UNIT I Basics and Laws : Definition of Heat Transfer, Reversible and irreversible
processes, Modes of heat flow, Combined heat transfer
system and law of energy conservation.
UNIT II Steady State Heat Conduction : Introduction, I-D heat conduction
through a plane wall, long hollow cylinder, hollow sphere,
Conduction equation in Cartesian, polar and
spherical co-ordinate systems, Numericals.
UNIT III Steady State Conduction with Heat Generation : Introduction, 1 – D heat
conduction with heat sources, Extended surfaces ( fins),
Fin effectiveness 2-D heat conduction , Numericals.
UNIT IV Transient Heat Conduction : Systems with negligible internal resistance,
Transient heat conduction in plane walls, cylinders,
spheres with convective boundary conditions, Chart
solution, Relaxation Method, Numericals.
UNIT V Convection: Forced convection-Thermal and hydro-dynamic boundary
layers, Equation of continuity, Momentum and energy equations, Some
results for flow over a flat plate and flow through tube, Fluid friction and
heat transfer ( Colburn analogy ), Free convection from a vertical flat
plate, Empirical relations for free convection from vertical and horizontal
o\planes & cylinders, Numericals.
UNIT VI Thermal Radiation: The Stephen-Boltzmann law, The black body
radiation, Shape factors and their relationships, Heat exchange between
non black bodies, Electrical network for radiative exchange in an
enclosure of two or three gray bodies, Radiation shields, Numericals.
UNIT VII Heat Exchangers: Classification, Performance variables, Analysis of a
parallel/counter flow heat exchanger, Heat exchanger effectiveness,
Numericals.
UNIT VIII Heat Transfer with Change of Phase: Laminar film condensation on a
vertical plate, Drop-wise condensation, Boiling regimes, Free convective,
Nucleate and film boiling, Numericals.
ME- 308 E AUTOMATIC CONTROLS
L T P Sessional Marks : 50
3 1 - Theory Marks : 100
Total Marks : 150
Duration of Exam : 3 hrs.
Unit I Introduction And Applications: Types of control systems ; Typical Block
Diagram : Performance Analysis; Applications – Machine Tool Control,
Boiler Control, Engine Governing, Aerospace Control, Active Vibration
Control; Representation of Processes & Control Elements – Mathematical
Modeling. Block Diagram Representation, Representation of Systems or
Processes, Comparison Elements; Representation of Feedback Control
systems – Block Diagram & Transfer Function Representation,
Representation of a Temperature, Control System, Signal Flow Graphs,
Problems.
Unit II Types of Controllers : Introduction : Types of Control Action; Hydraulic
Controllers; Electronic Controllers; Pneumatic Controllers; Problems.
Unit III Transient And Steady State Response: Time Domain Representation;
Laplace Transform Representation; System with Proportional Control;
Proportional – cum – Derivative control; Proportional – cum – Integral
Control; Error Constants; Problems.
Unit IV Frequency Response Analysis: Introduction; Closed and Open Loop
Transfer Function; Polar Plots; Rectangular Plots; Nichols Plots:
Equivalent Unity Feed Back Systems; Problems.
Unit V Stability Of Control Systems : Introduction; Characteristic Equation;
Routh‟s Criterion; Nyquists Criterion, Gain & Phase Margins: Problems.
Unit VI Root Locus Method : Introduction; Root Ioci of a Second Order System;
General Case; Rules for Drawing Forms of Root Ioci; Relation between
Root Locus Locations and Transient Response; Parametric Variation;
Problems.
Unit VII Digital Control System : Introduction; Representation of Sampled Signal;
Hold Device; Pulse Transfer Function; Block Diagrams; Transient
Response; Routh‟s Stability Criterion; Root Locus Method; Nyquists
Criterion; Problems.
Unit VIII State Space Analysis Of Control Systems: Introduction; Generalized State
Equation; Techniques for Deriving System State – Space Equations;
Transfer Function from State Equations; Solution of State Vector
Differential Equations; Discrete Systems; Problems.
ME – 310 E MEASUREMENTS AND INSTRUMENTATION
L T P Sessional
: 50 Marks
3 1 - Theory
: 100 Marks
Total marks
: 150 Marks
Duration of
Exam: 3 Hrs.
Unit I Instruments and Their Representation : Introduction, Typical Applications
of Instrument Systems, Functional Elements of a Measurement System,
Classification of Instruments, Standards and Calibration.
Unit II Static and Dynamic characteristics of Instruments : Introduction,
Accuracy, Precision, Resolution, Threshold, Sensitivity, Linearity,
Hysteresis, Dead Band, Backlash, Drift, Formulation of Differential
Equations for Dynamic Performance- Zero Order, First Order and Second
order systems, Response of First and Second Order Systems to Step,
Ramp, Impulse and Harmonic Functions.
Unit III Transducer Elements : Introduction, Analog and Digital Transducers,
Electromechanical; Potentiometric, Inductive Self Generating and Non-
Self Generating Types, Electromagnetic, Electrodynamic, Eddy Current,
Magnetostrictive, Variable Inductance, Linearly Variable Differential
Transformer, Variable Capacitance, Piezo-Electric Transducer and
Associated Circuits, Unbonded and Bonded Resistance Strain Gages.
Strain Gage Bridge circuits, Single Double and Four Active Arm Bridge
Arrangements, Temperature Compensation, Balancing and Calibration,
Ionisation Transducers, Mechano Electronic Transducers, Opto-Electrical
Transducers, Photo Conductive Transducers, Photo Volatic Transducers,
Digital Transducers, Frequency Domain Transducer, Vibrating String
Transducer, Binary codes, Digital Encoders.
Unit IV Intermediate, Indicating and Recording Elements : Introduction
Amplifiers, Mechanical, Hydraulic, Pneumatic, Optical, Electrical
Amplifying elements, Compensators, Differentiating and Integrating
Elements, Filters, Classification of Filters, A-D and D-A Converters,
Digital Voltmeters (DVMs), Cathode Ray Oscillo scopes (CROs),
Galvanometric Recorders, Magnetic Tape recorders, Data Acquisition
Systems, Data Display and Storage.
Unit V Motion, Force and Torque Measurement : Introduction, Relative motion
Measuring Devices, Electromechanical, Optical, Photo Electric, Moire-
Fringe, Pneumatic, Absolute Motion Devices, Seismic Devices, Spring
Mass & Force Balance Type, Calibration, Hydraulic Load Cell, Pneumatic
Load Cell, Elastic Force Devices, Separation of Force Components,
Electro Mechanical Methods, Strain Gage, Torque Transducer, Toque
Meter.
Unit VI Pressure and Flow Measurement : Pressure & Flow Measurement,
Introduction : Moderate Pressure Measurement, Monometers, Elastic
Transducer, Dynamic Effects of Connecting Tubing, High Pressure
Transducer, Low Pressure Measurement, Calibration and Testing,
Quantity Meters, Positive Displacement Meters, Flow Rate Meters,
Variable Head Meters, Variable Area Meters, Rotameters, Pitot-Static
Tube Meter, Drag Force Flow Meter, Turbine Flow Meter, Electronic
Flow Meter, Electro Magnetic Flow meter. Hot-Wire Anemometer.
Unit VII Temperature Measurement : Introduction, Measurement of Temperature,
Non Electrical Methods – Solid Rod Thermometer, Bimetallic
Thermometer, Liquid-in-Glass thermometer, Pressure Thermometer,
Electrical Methods – Electrical Resistance Thermometers, Semiconductor
Resistance Sensors (Thermistors), Thermo–Electric Sensors,
Thermocouple Materials, Radiation Methods (Pyrometry), Total Radiation
Pyrometer, Selective Radiation Pyrometer.
Unit VIII Basic Statistical Concepts : Types of Measured Quantities (Discrete and
Continuous), Central Tendency of Data, Mode, Median, Arithmetic Mean,
Best Estimate of true Value of Data, Measures of Dispersion, Range,
Mean Deviation, Variance, Standard Deviation, Normal Distribution,
Central Limit Theorem, Significance Test, Method of Least Squares,
Graphical Representation and Curve Fitting of Data.
ME- 312 E INDUSTRIAL ENGINEERING
Sessional : 50 Marks
L T Theory : 100 Marks
3 1 - Total : 150 Marks
Duration of Examination: 3
Hrs
UNIT - I
Definition of Industrial Engineering: Objectives, Method study, Principle of motion economy,
Techniques of method study - Various charts, THERBLIGS, Work measurement - various
methods, time study PMTS, determining time, Work sampling, Numericals.
UNIT - II
Productivity & Workforce Management :Productivity - Definition, Various methods of
measurement, Factors effecting productivity, Strategies for improving productivity,
Various methods of Job evaluation & merit rating, Various incentive payment schemes,
Behavioural aspects, Financial incentives.
UNIT - III
Manufacturing Cost Analysis: Fixed & variable costs, Direct, indirect & overhead costs, &
Job costing, Recovery of overheads, Standard costing, Cost control, Cost variance Analysis -
Labour, material, overhead in volume, rate & efficiency, Break even Analysis, Marginal costing
& contribution, Numericals.
UNIT - IV
Materials Management : Strategic importance of materials in manufacturing industries, Relevant
costs, Inventory control models - Economic order quantity (EOQ), Economic batch quantity
(EBQ) with & without shortage, Purchase discounts, Sensitivity analysis, Inventory control
systems - P,Q,Ss Systems, Service level, Stock out risk, determination of order point &
safety stock, Selective inventory control - ABC, FSN, SDE, VED and three dimensional,
Numericals.
UNIT - V
Quality Management: Definition of quality, Various approaches, Concept of quality
assurance systems, Costs of quality, Statistical quality Control (SQC), Variables & Attributes,
X, R, P & C - charts, Acceptance sampling, OC - curve, Concept of AOQL, Sampling plan -
Single, Double & sequential, Introduction to TQM & ISO - 9000.
UNIT - VI
Production Planning & Control (PPC) : Introduction to Forecasting - Simple &
Weighted moving average methods, Objectives & variables of PPC, Aggregate planning -
Basic Concept, its relations with other decision areas, Decision options - Basic & mixed
strategies, Master production schedule (MPS), Scheduling Operations Various methods for line
& intermittent production systems, Gantt chart, Sequencing - Johnson algorithm for n-Jobs-2
machines, n- Jobs-3 machines, 2 Jobs n-machines, n-Jobs m-machines Various means of
measuring effectiveness of PPC, Introduction to JIT, Numericals.
UNIT - VII
Management Information Systems (MIS) : What is MIS ? Importance of MIS, Organizational
& information system structure, Role of MIS in decision making, Data flow diagram,
Introduction to systems analysis & design, Organizing information systems.
UNIT – VIII
Product Design and Development: Various Approaches, Product life cycle, Role 3S‟s –
Standardization, Simplification, Specialization, Introduction to value engineering and analysis,
Role of Ergonomics in Product Design.
ME- 314 E DYNAMICS OF MACHINE LAB
Sessional
: 25 Marks
L T P Practical
: 25 Marks
- - 2 Total
: 50Marks
Duration of
Exam : 3 hrs.
List of Experiments :
1. To perform experiment on Watt and Porter Governors to prepare performance
characteristic Curves, and to find stability & sensitivity.
2. To perform experiment on Proell Governor to prepare performance characteristic
curves, and to find stability & sensitivity.
3. To perform experiment on Hartnell Governor to prepare performance
characteristic Curves, and to find stability & sensitivity.
4. To study gyroscopic effects through models.
5. To determine gyroscopic couple on Motorized Gyroscope.
6. To perform the experiment for static balancing on static balancing machine.
7. To perform the experiment for dynamic balancing on dynamic balancing
machine.
8. Determine the moment of inertial of connecting rod by compound pendulum
method and tri-flair suspension pendulum.
ME- 316 E HEAT TRANSFER LAB.
L T P Sessional
: 50 Marks
- - 3 Practical
: 50 Marks
Total
: 100 Marks
Duration of
Exam : 3Hrs.
II) List of Experiments :
1. To determine the thermal conductivity of a metallic rod.
2. To determine the thermal conductivity of an insulating power.
3. To determine the thermal conductivity of a solid by the guarded hot plate
method.
4. To find the effectiveness of a pin fin in a rectangular duct natural convective
condition and plot temperature distribution along its length.
5. To find the effectiveness of a pin fin in a rectangular duct under forced
convective and plot temperature distribution along its length.
6. To determine the surface heat transfer coefficient for a heated vertical tube
under natural convection and plot the variation of local heat transfer
coefficient along the length of the tube. Also compare the results with those of
the correlation.
7. To determine average heat transfer coefficient for a externally heated
horizontal pipe under forced convection & plot Reynolds and Nusselt numbers
along the length of pipe. Also compare the results with those of the
correlations.
8. To measure the emmisivity of the gray body (plate) at different temperature
and plot the variation of emmisivity with surface temperature.
9. To find overall heat transfer coefficient and effectiveness of a heat exchange
under parallel and counter flow conditions. Also plot the temperature
distribution in both the cases along the length of heat of heat exchanger.
10. To verify the Stefen-Boltzmann constant for thermal radiation.
11. To demonstrate the super thermal conducting heat pipe and compare its
working with that of the best conductor i.e. copper pipe. Also plot temperature
variation along the length with time or three pipes.
12. To study the two phases heat transfer unit.
13. To determine the water side overall heat transfer coefficient on a cross-flow
heat exchanger.
14. Design of Heat exchanger using CAD and verification using thermal analysis
package eg. I-Deas etc.
ME- 318 E MEASUREMENTS & INSTRUMENTATION LAB.
Sessional : 25 Marks
L T P Practical : 25 Marks
- - 2 Total : 50 Marks
Duration of Exam : 3 Hrs.
List of Experiments :
1. To Study various Temperature Measuring Instruments and to Estimate their
Response times.
(a) Mercury – in glass thermometer
(b) Thermocouple
(c) Electrical resistance thermometer
(d) Bio-metallic strip
2. To study the working of Bourdon Pressure Gauge and to check the calibration
of the gauge in a dead-weight pressure gauge calibration set up.
3. To study a Linear Variable Differential Transformer (LVDT) and use it in a
simple experimental set up to measure a small displacement.
4. To study the characteristics of a pneumatic displacement gauge.
5. To measure load (tensile/compressive) using load cell on a tutor.
6. To measure torque of a rotating shaft using torsion meter/strain gauge torque
transducer.
7. To measure the speed of a motor shaft with the help of non-contact type pick-
ups (magnetic or photoelectric).
8. To measure the stress & strain using strain gauges mounted on simply
supported beam/cantilever beam.
9. To measure static/dynamic pressure of fluid in pipe/tube using pressure
transducer/pressure cell.
10. To test experimental data for Normal Distribution using Chi Square test.
11. To learn the methodology of pictorial representation of experimental data and
subsequent calculations for obtaining various measures of true value and the
precision of measurement using Data acquisition system/ calculator.
12. Vibration measurement by Dual Trace Digital storage Oscilloscope.
13. To find out transmission losses by a given transmission line by applying
capacitive /inductive load.
14. Process Simulator.
Mechanical Engineering
Semester VII
ME- 401 E AUTOMOBILE ENGINEERING
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam : 3Hrs.
Unit I Introduction to Automobiles : Classification, Components, Requirements
of Automobile Body; Vehicle Frame, Separate Body & Frame, Unitised
Body, Car Body Styles, Bus Body & Commercial Vehicle Body Types;
Front Engine Rear Drive & Front Engine Front Drive Vehicles, Four
Wheel Drive Vehicles, Safety considerations; Safety features of latest
vehicle; Future trends in automobiles.
Unit II Clutches : Requirement of Clutches – Principle of Friction Clutch – Wet
Type & Dry Types; Cone Clutch, Single Plate Clutch, Diaphragm Spring
Clutch, Multi plate Clutch, Centrifugal Clutches, Electromagnetic Clutch,
Over Running Clutch; Clutch Linkages.
Unit III Power Transmission : Requirements of transmission system; General
Arrangement of Power Transmission system; Object of the Gear Box;
Different types of Gear Boxes; Sliding Mesh, Constant Mesh, Synchro-
mesh Gear Boxes; Epi-cyclic Gear Box, Freewheel Unit. Overdrive unit-
Principle of Overdrive, Advantage of Overdrive, Transaxle, Transfer cases.
Unit IV Drive Lines, Universal Joint, Differential and Drive Axles: Effect of
driving thrust and torque reactions; Hotchkiss Drive, Torque Tube Drive
and radius Rods; Propeller Shaft, Universal Joints, Slip Joint; Constant
Velocity Universal Joints; Front Wheel Drive; Principle, Function,
Construction & Operation of Differential; Rear Axles, Types of load
coming on Rear Axles, Full Floating, Three quarter Floating and Semi
Floating Rear Axles.
Unit V Suspension Systems : Need of Suspension System, Types of Suspension;
factors influencing ride comfort, Suspension Spring; Constructional details
and characteristics of leaf springs.
Unit VI Steering System : Front Wheel geometry & Wheel alignment viz. Caster,
Camber, King pin Inclination, Toe-in/Toe-out; Conditions for true rolling
motions of Wheels during steering; Different types of Steering Gear
Boxes; Steering linkages and layout; Power steering – Rack & Pinion
Power Steering Gear, Electronics steering.
Unit VII Automotive Brakes, Tyres & Wheels : Classification of Brakes; Principle
and constructional details of Drum Brakes, Disc Brakes; Brake actuating
systems; Mechanical, Hydraulic, Pneumatic Brakes; Factors affecting
Brake performance, Power & Power Assisted Brakes; Tyres of Wheels;
Types of Tyre & their constructional details, Wheel Balancing, Tyre
Rotation; Types of Tyre wear & their causes.
Unit VIII Emission Control System & Automotive Electrical : Sources of
Atmospheric Pollution from the automobile, Emission Control Systems –
Construction and Operation of Positive Crank Case Ventilation ( PVC)
Systems, Evaporative Emission Control, Heated Air Intake System, Exhaust
Gas Recirculation ( ECR ) Systems, Air Injection System and Catalytic
Converters; Purpose construction & operation of lead acid Battery,
Capacity Rating & Maintenance of Batteries; Purpose and Operation of
Charging Systems, Purpose and Operations of the Starting System; Vehicle
Lighting System.
ME-403 E REFRIGERATION & AIR CONDITIONING
L T P Sessional : 50
Marks
3 1 - Theory
:100Marks
Total :150
Marks
Duration of Exam :
3Hrs.
Unit I Introduction: Definition of refrigeration & air conditioning;
Necessity; Methods of refrigeration; Unit of refrigeration;
Coefficient of performance (COP), Fundamentals of air-
conditioning system; Refrigerants- Definition, Classification,
Nomenclature, Desirable properties, Comparative study, secondary
refrigerants, Introduction to eco-friendly Refrigerants; Introduction
to Cryogenics.
Unit II Air Refrigeration System: Carnot refrigeration cycle. Temperature.
Limitations; Brayton refrigeration or the Bell Coleman air refrigeration
cycle; Necessity of cooling the aero plane; Air craft refrigeration systems,
Simple cooling and Simple evaporative types, Boot strap and Boot strap
evaporative types, Regenerative type and Reduced Ambient type system,
Comparison of different systems, problems.
Unit III Vapour Compression (VC) Refrigeration Systems: (A) Simple Vapour
Compression (VC) Refrigeration systems-Limitations of Reversed Carnot
cycle with vapour as the refrigerant; Analysis of VC cycle considering
degrees of sub cooling and superheating; VC cycle on p-v, t-s and p-h
diagrams; Effects of operating conditions on COP; Comparison of VC cycle
with Air Refrigeration cycle.
(B) Multistage Ref. Systems- Necessity of compound compression,
Compound VC cycle , Inter-cooling with liquid sub –cooling and / or water
inter cooler: Multistage compression with flash inter-cooling and / or water
inter-cooling; systems with individual or multiple expansion valves;
Individual compression system with individual or multiple expansion
valves; Individual compression systems with individual or multiple
expansion valves but with and without intercoolers.
Unit IV Other Refrigeration Systems: (A) Vapour Absorption Refrigeration
Systems – Basic Systems, Actual COP of the System, Performance, Relative
merits and demerits; Properties of aqua ammonia; Electrolux Refrigeration;
Problems.
(B) Steam Jet Refrigerating System- Introduction, Analysis, Relative merits
and demerits, Performance Applications, Problems.
(C) Cascade Refrigerating Systems-Necessity Selection of Pairs of
refrigerants for the system, Concept of cascade temperature, Analysis,
Multistaging, Comparison with V.C. systems, Applications, Problems.
Unit V Psychrometry of Air & Air Conditioning Processes: Properties of moist
Air-Gibbs Dalton law, Specific humidity, Dew point temperature, Degree of
saturation, Relative humidity, Enthalpy, Humid specific heat, Wet bulb
temp., Thermodynamics wet bulb temp., Psychrometric chart; Psychrometry
of air-conditioning processes, Mixing Process, Basic processes in
conditioning of air; Psychrometric processes in air washer, Problems.
Unit VI Air- Conditioning Load Calculations: Outside and inside design conditions;
Sources of heating load; Sources of cooling load; Heat transfer through
structure, Solar radiation, Electrical applications, Infiltration and ventilation,
Heat generation inside conditioned space; Apparatus selection; Comfort
chart, Problems.
Unit VII Air Conditioning Systems with Controls & Accessories: Classifications,
Layout of plants; Equipment selection; Air distribution system; Duct systems
Design; Filters; Refrigerant piping; Design of summer air-conditioning and
Winter air conditioning systems; Temperature sensors, Pressure sensors,
Humidity sensors, Actuators, Safety controls; Accessories; Problems.
Unit VIII Refrigeration and Air Conditioning Equipments: Type of compressors and
their performance curves; Types of Condensers, Heat transfer in condensers;
Types of expansion devices; types of evaporators, Cooling and Dehumidifying
coils, Problems.
ME- 405 E OPERATIONS RESEARCH
L T P Sessional : 50 Marks
3 1 - Theory : 100 Marks
Total : 150 Marks
Duration of Exam : 3 Hrs.
Unit I Introduction: Definition, role of operations research in decision-making,
applications in industry. Concept on O.R. model building –Types &
methods.
Unit II Linear Programming (LP): Programming definition, formulation,
solution- graphical, simplex Gauss-Jordan reduction process in simplex
methods, BIG-M methods computational, problems.
Unit III Deterministic Model: Transportation model-balanced & unbalanced,
north west rule, Vogel‟s Method, least cost or matrix minimal, Stepperg
stone method, MODI methods, degeneracy, assignment, traveling
salesman, problems.
Unit IV Advanced Topic Of LP: Duality, PRIMAL-DUAL relations-its solution,
shadow price, economic interpretation, dual-simplex, post-optimality &
sensitivity analysis, problems.
Unit V Waiting Line Models: Introduction, queue parameters, M/M/1 queue,
performance of queuing systems, applications in industries, problems.
Unit VI Project Line Models: Network diagram, event, activity, defects in
network, PERT & CPM, float in network, variance and probability of completion
time, project cost- direct, indirect, total, optimal project cost by crashing of network,
resources leveling in project, problems.
Unit VII Simulation: Introduction, design of simulation, models & experiments,
model validation, process generation, time flow mechanism, Monte Carlo methods-
its applications in industries, problems.
Unit VIII Decision Theory: Decision process, SIMON model types of decision
making environment- certainty, risk, uncertainty, decision making with
utilities, problems.
ME 407- E MECHANICAL VIBRATIONS
L T P Sessional : 50
Marks
3 1 - Theory : 100
Marks
Total : 150
Marks
Duration of Exam: 3
Hrs.
Unit I Fundamentals : Importance of Study of Vibrations, Classifications of
Vibrations, Free and Forced, Undamped and Damped, Linear and Non-
linear, Deterministic and Random, Harmonic Motion, Vector and
Complex Number Representations, Definitions and Terminology, Periodic
Functions, Harmonic Analysis, Fourier Series Expansion.
Unit II Free and Damped Vibrations : Single Degree of Freedom system,
D‟Alemberts Principal, Energy Methods, Rayleighs Method, Application
of these Methods, Damped Free Vibrations, Logarithmic Decrement,
Under Damping, Critical and Over Damping, Coulomb Damping.
Unit III Harmonically Excited Vibrations : Forced Damped Harmonic Vibration
of Single Degree of Freedom Systems, Rotating Unbalance, Rotor
Unbalance, Critical Speeds and Whirling of Rotating Shafts, Support
Motion, Vibration Isolation, Energy Dissipated by Damping, Equivalent,
Viscous Camping, Structural Damping Sharpness of Resonance, Vibration
Measuring Instruments.
Unit IV Transient Vibrations : Impulse Excitation, Arbitrary Excitation, Response
to Step Excitions, Base Excitation Solution by Laplace Transforms, Response
Spectrum, Runge-Kutta Method.
Unit V Two Degrees of Freedom Systems : Introduction to Multi-Degree of
Freedom Systems, Normal Mode Vibrations, Coordinate Coupling,
Principal Coordinates, Free Vibrations in Terms of Initial Conditions,
Forced Harmonic Vibrations, Vibration Absorber, Centrifugal Vibration
Absorber, Vibration Damper.
Unit VI Multi degrees of Freedom Systems and Numerical Methods Introduction,
Influence Coefficients, Stiffness Matrix, Flexibility Matrix, Natural
Frequencies and Normal Modes, Orthogonality of Normal Modes,
Dunkerley‟s Equation, Method of Matrix Iteration, The Holzer Type
Problem, Geared and Branched Systems, Beams.
Unit VII Normal Mode Vibration of Continuous System: Vibrating String,
Longitudinal Vibrations of Rod, Torsional Vibrations of Rod, Lateral Vibrations of
Beam.
ME- 409- E AUTOMOBILE ENGINEERING LAB
Sessional : 25
Marks
L T P Practical : 25
Marks
- - 2 Total : 50
Marks
Duration of Exam :
3Hrs.
List of Experiments :
1. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Engine Systems & Sub Systems.
(a) Multi-cylinder : Diesel and Petrol Engines.
(b) Engine cooling & lubricating Systems.
(c) Engine starting Systems.
(d) Contact Point & Electronic Ignition Systems.
2. To study and prepare report on the constructional details, working principles and
operation of the following Fuels supply systems:
(a) Carburetors
(b) Diesel Fuel Injection Systems
(c) Gasoline Fuel Injection Systems.
3.. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Clutches.
(a) Coil-Spring Clutch
(b) Diaphragm – Spring Clutch.
(c) Double Disk Clutch.
4. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Transmission systems.
(a) Synchromesh – Four speed Range.
(b) Transaxle with Dual Speed Range.
(c) Four Wheel Drive and Transfer Case.
(d) Steering Column and Floor – Shift levers.
5. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Drive Lines & Differentials.
(a) Rear Wheel Drive Line.
(b) Front Wheel Drive Line.
(c) Differentials, Drive Axles and Four Wheel Drive Line.
6. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Suspension Systems.
(a) Front Suspension System.
(b) Rear Suspension System.
7. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Steering Systems.
(a) Manual Steering Systems, e.g. Pitman –arm steering, Rack & Pinion
steering.
(b) Power steering Systems, e.g. Rack and Pinion Power Steering System.
(c) Steering Wheels and Columns e.g. Tilt & Telescopic steering Wheels,
Collapsible Steering Columns.
8. To study and prepare report on the constructional details, working principles and
operation of the following Automotive Tyres & wheels.
(a) Various Types of Bias & Radial Tyres.
(b) Various Types of wheels.
9. To study and prepare report on the constructional details, working principles and
operation of the Automotive Brake systems.
(a) Hydraulic & Pneumatic Brake systems.
(b) Drum Brake System.
(c) Disk Brake System.
(d) Antilock Brake System.
(e) System Packing & Other Brakes.
10. To study and prepare report on the constructional details, working principles and
operation of Automotive Emission / Pollution control systems.
11. Modeling of any two automotive systems on 3D CAD using educational
softwares (eg. 3D modeling package/Pro Engineering/I-Deas/ Solid edge etc.)
12. Crash worthiness of the designed frame using Hypermesh and LS-Dyna solver or
other software.
ME- 411- E REFRIGERATION & AIR CONDITIONING LAB.
L T P Sessional : 50
Marks
- - 3 Practical : 50
Marks
Total : 100
Marks
Duration of Exam :
3Hrs.
III) List of Experiments :
1. To study the vapour compression Refrigeration System and determine its
C.O.P. and draw P-H and T-S diagrams.
2. To Study the Mechanical heat pump and find its C.O.P.
3. To study the Air and Water heat pump and find its C.O.P.
4. To study the cut- sectional models of Reciprocating and Rotary
Refrigerant compressor.
5. To study the various controls used in Refrigerating & Air Conditioning
systems.
6. To study the Ice- plant, its working cycle and determine its C.O.P and
capacity.
7. To study the humidification, heating, cooling and dehumidification
processes and plot them on Psychrometric charts.
8. To determine the By-pass factor of Heating & Cooling coils and plot them
on Psychrometric charts on different inlet conditions.
9. To determine sensible heat factor of Air on re-circulated air-conditioning
set up.
10. To study the chilling plant and its working cycle.
Note : 1. At least ten experiments are to be performed in the semester.
2. At least seven experiments should be performed form the above list.
Remaining three experiments may either be performed from the above
list or as designed & set by the concerned institute as per the scope of the
syllabus.
ME- 413- E PROJECT
L T P Sessional : 100
Marks
- - 6 Practical : 100
Marks
Total : 200
Marks
Duration of Exam :
3Hrs.
Project involving design/ fabrication/ testing computer simulation/ case
studies etc. which is commenced in VIIth Semester, will be completed in VIIIth
Semester and will be evaluated through a panel of examiners consisting of HOD of the
concerned department, project coordinator and one external examiner to be appointed
by the University.
The student will be required to submit three copies of his/her project
report to the office of the concerned department for record (one copy each for the deptt.
Office, participating teacher and college library).
Project coordinator will be assigned the project load of 2 hrs., per week
while the participating teachers will be assigned 1 hr. load for the same.
ME – 415- E PRACTICAL TRAINING – II
At the end of sixth semester each student would undergo six weeks
Practical Training in an Industry/ Professional / Organization/ Research Laboratory
with the prior approval of the Director-Principal/ Principal of the concerned college
and submit a written typed report along with a certificate from the organization.
The report will be a evaluated during VII Semester by a Board of Examiners to be
appointed by the Director-Principal/ Principal of the concerned college who will
award one of the following grades:
Excellent : A
Good : B
Satisfactory : C
Not satisfactory : F
A student who has been awarded „F‟ grade will be required to repeat the
practical training.
Mechanical Engineering
Semester VIII
ME- 402 E COMPUTER AIDED DESIGN
Sessional : 50 Marks
L T P Theory : 100 Marks
3 1 - Total : 150 Marks
Duration of Exam : 3 Hrs.
UNIT – I Introduction: Introduction to CAD/CAM, Historical developments,
Industrial look at CAD/CAM, Introduction to CIM; Basics of geometric
and solid modeling, explicit, implicit, intrinsic and parametric equations,
coordinate systems.
UNIT – II Transformations: Introduction, transformation of points and line, 2-D
rotation, reflection, scaling and combined transformation, homogeneous
coordinates, 3-D scaling, shearing, rotation, reflection and translation,
combined transformations, orthographic and perspective projections,
reconstruction of 3-D objects.
UNIT – III Curves: Algebraic and geometric forms, tangents and normal, blending
functions reparametrization, straight lines, conics, cubic splines, Bezier
curves and B-spline curves.
UNIT – IV Surfaces: Algebraic and geometric forms, tangents and normal, blending
functions, reparametrization, sixteen point form, four curve form, plane
surface, ruled surface, surface of revolution, tabulated cylinder, bi-cubic
surface, bezier surface, B-spline surface.
UNIT – V Solids: Solid models and representation scheme, boundary representation,
constructive solid geometry, sweep representation, cell decomposition,
spatial occupancy enumeration.
UNIT – VI Automation and Numerical Control: Introduction, fixed,
programmable and flexible automation, types of NC systems, MCU and
other components, NC manual part programming, coordinate systems, G
& M codes, Part program for simple parts, computer assisted part
programming.
UNIT – VII Group Technology: Part families, part classification and coding,
production flow analysis, Machine cell design, Advantages of GT
UNIT – VIII Flexible Manufacturing Systems & Computer aided process planning:
Introduction, FMS components, types of FMS, FMS layouts, planning for
FMS, advantages and applications Coventional process planning, types of
CAPP, Steps in variant process planning, planning for CAPP.
ME- 404 E POWER PLANT ENGINEERING
Sessional Marks : 50
L T P Theory Marks : 100
3 1 - Total Marks : 150
Duration of Exam
:3 Hrs.
Unit I Introduction: Energy resources and their availability, types
of power plants, selection of the plants, review of basic
thermodynamic cycles used in power plants.
Unit II Hydro Electric Power Plants : Rainfall and run-off
measurements and plotting of various curves for estimating
stream flow and size of reservoir, power plants design,
construction and operation of different components of
hydro-electric power plants, site selection, comparison with
other types of power plants.
Unit III Steam Power Plants: Flow sheet and working of modern-thermal power
plants, super critical pressure steam stations, site selection, coal storage,
preparation, coal handling systems, feeding and burning of pulverized fuel,
ash handling systems, dust collection-mechanical dust collector and
electrostatic precipitator.
Unit IV Combined Cycles: Constant pressure gas turbine power
plants, Arrangements of combined plants ( steam & gas
turbine power plants ), re-powering systems with gas
production from coal, using PFBC systems, with organic
fluids, parameters affecting thermodynamic efficiency of
combined cycles. Problems.
Unit V Nuclear Power Plants: Principles of nuclear energy, basic nuclear
reactions, nuclear reactors-PWR, BWR, CANDU, Sodium graphite, fast
breeder, homogeneous; gas cooled. Advantages and limitations, nuclear
power station, waste disposal.
Unit VI Power Plant Economics: load curve, different terms and
definitions, cost of electrical energy, tariffs methods of
electrical energy, performance & operating characteristics
of power plants- incremental rate theory, input-out put
curves, efficiency, heat rate, economic load sharing,
Problems.
Unit VII Non-Conventional Power Generation: Solar radiation
estimation, solar energy collectors, low, medium & high
temperature power plants, OTEC, wind power plants, tidal
power plants, geothermal power plants.
Unit VIII Direct Energy Conversion Systems: Fuel cell, MHD power
generation-principle, open & closed cycles systems,
thermoelectric power generation, thermionic power
generation.
ME- 406- E COMPUTER AIDED DESIGN LAB
Sessional : 50 Marks
L T P Theory : 50 Marks
- - 3 Total : 100 Marks
Duration of Exam: 3 Hrs
The students will be required to carry out the following exercises using
software packages (e.g. 3D modeling package/ Pro Engineer/ I-Deas/ Solid
Edge etc.).
1. Implement simple programmes for the graphics representation of
a. Transformation and projections.
b. Conic Sections, cubic splines, and B-splines.
c. Surfaces- Bilinear, Bicubic surface patch and Bezier surface.
2. CAD Modelling Assignments.
a. Construction of simple machine parts and components.
b. Modelling of machine components.
i. Surface of a Diffuser section, Propeller.
ii. Gear blank and other mechanical parts.
iii. Mechanical assembly of parts.
ME-408- E INDEPENDENT STUDY SEMINAR
L T P Sessional : 50
Marks
- - 4 Total : 50
Marks
The student will select a topic in emerging areas of Mech. Engg. and study
independently. He will give a seminar talk on the same before the committee
constituted by the head of the dept. The committee should comprise of at least
three faculty members from Thermal, Production & Design specializations.
The Master of Business Administration (MBA) is a two-year full-time
programme. The course structure of the programme is given hereunder:-
Semester – I
Course Course Title Division of Marks Duration
Code of Exams
Ext. Int. Total
CP – 101 Management process & 70 30 100 3 Hrs.
organizational behavior
CP – 102 Business Statistics 70 30 100 3 Hrs.
CP – 103 Managerial Economics 70 30 100 3 Hrs.
CP – 104 Business Environment 70 30 100 3 Hrs.
CP – 105 Business Communication 70 30 100 3 Hrs.
CP – 106 Accounting for Managers 70 30 100 3 Hrs.
CP – 107 Computer Applications in T 50 - 100 3 Hrs.
Management P 50
CP – 108 Seminar * - 50 50
T = Theory P=Practical
* The Seminar Will be presented by each student on any topic relating to
Indian Ethos and Values and current Socio- Economic context.
Semester – II
CP – 201 Management Science 70 30 100 3 Hrs.
CP – 202 Marketing Management 70 30 100 3 Hrs.
CP – 203 Human Resource Management 70 30 100 3 Hrs.
CP – 204 Financial Management 70 30 100 3 Hrs.
CP – 205 Business Research 70 30 100 3 Hrs.
Methodology
CP – 206 Production and Operations 70 30 100 3 Hrs.
Management
CP – 207 E-Commerce 70 30 100 3 Hrs.
CP – 208 Comprehensive Viva-Voce 50 - 50
Summer training
At the end of second semester, all students will have to undergo
summer training of 6-8 weeks with an industrial, business or
service organization by taking up a project study. The condition of
successfully completing the programmes shall not be deemed to
have been satisfied unless a students undergoes summer training
under the supervision of the department in the organizations as
approved by the department / faculty from time to time. Each
student will be required to submit a project report to the
department for the work under taken during this period within one
month of the commencement of the third semester for the purpose
of evaluation in the third semester.
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