draft course plan report for circulation

KERALA TECHNOLOGICAL UNIVERSITY

B.Tech Course Plan

K E R A L A T E C H N O L O G I C A L U N I V E R S I T Y

B.Tech Course Plan 2015

Kerala Technological University CET Campus, Thiruvananthapuram

Kerala -695016 India Phone +91 471 2598122, 2598422

Fax +91 471 2598522 Email: [email protected]

Table of Contents

Code Subject Page

MA 101 Calculus

PH 100 Engineering Physics

CY 100 Engineering Chemistry

BE 103 Engineering Mechanics

BE 101-01 Introduction to Civil Engineering

BE 101-02 Introduction to Mechanical Engineering Not received

BE 101-03 Introduction to Electrical Engineering

BE 101-04 Introduction to Electronics Engineering

BE 101-05 Introduction to Computer Sciences and Engineering

BE 101-06 Introduction to Chemical Engineering

BE 105 Introduction to Sustainable Engineering

CE 100 Basics of Civil Engineering

ME 100 Basics of Mechanical Engineering Not received

EE 100 Basics of Electrical Engineering

EC 100 Basics of Electronics

PH 110 Engineering Physics Lab

CY 110 Engineering Chemistry Lab

CE 110 Civil Engineering Workshop

ME 110 Mechanical Engineering Workshop Not received

EE 110 Electrical Engineering Workshop

EC 110 Electronics Engineering Workshop

CS 110 Computer Science Workshop Not received

CH 110 Chemical Engineering Workshop Not received

CE 110 Civil Engineering Workshop (other branches)

ME 110 Mechanical Engineering Workshop (other branches) Not received

EE 110 Electrical Engineering Workshop (other branches) Not received

EC 110 Electronics Engineering Workshop (other branches) Not received

I Language lab/ Bridge courses/ Remedial prog./ MicroProjects Not received

J Entrepreneurship/ TBI/ NCC/ NSS/ Physical Edn. Etc Not received

MA102 Mathematics II Not received

BE 102 Engineering Graphics

BE 104 Design and Engineering Not received

D R A F T S Y L L A B U S F O R F I R S T & S E C O N D S E M E S T E R

1 | P a g e

MODULE

COURSE NO: MA 101 L-T-P: 3-1-0

COURSE NAME: CALCULUS CREDITS: 4

CONTENT HRS END SEM. MARK %

I

Single Variable Calculus and Infinite series(Book I sec.7.2, 7.4, 7.7,

7.8, 10.4 to 10.8)

Introduction. Exponential and Logarithmic functions. Graphs and

Applications involving exponential and Logarithmic functions. Hyperbolic

functions and inverses-derivatives and integrals. Basic ideas of infinite

series and convergence. Convergence tests-comparison, ratio, root and

integral tests (without proof). Geometric series and p-series. Alternating

series, conditional and absolute convergence, Leibnitz test. Maclaurins

series-Taylor series - radius of convergence. Indeterminate forms.

(Sketching, plotting and interpretation of Exponential, Logarithmic and

Hyperbolic functions using suitable software. Demonstration of

convergence of series by mathematical software)

15%

II

Three dimensional space (Book I sec.12.1, 12.7, 12.8)

Rectangular coordinates in three space-graphs in three space, cylindrical

surfaces - Quadric surfaces, Graphing of quadric surfaces Translation,

reflection and identification of quadric surfaces, cylindrical and spherical

coordinates-constant surfaces-converting coordinates-equations of surfaces

in cylindrical and spherical coordinates.

15%

FIRST INTERNAL EXAM

III

Functions of several variables (Book I sec. 14.1 to 14.5 and 14.8)

Introduction- Functions of two or more variables graphs of functions of

two variables- level curves and surfaces sketching of level curves and level

surfaces, Limits and continuity - Partial derivativesPartial derivatives of

functions of more than two variables - higher order partial derivatives -

differentiability, local linearity and differentials - chain rule Maxima and

Minima of functions of two variables - extreme value theorem (without

proof)-relative extrema. (Sketching, plotting and interpretation of

functions of two variables, level curves and surfaces using mathematical

software.

15%

IV Calculus of vector valued functions(Book I-13.1-13.6, 14.6,14.7, 14.9)

Introduction to vector valued functions- calculus of vector valued

functions-limits and continuity-tangent lines derivative of dot and cross

product- integrals of vector valued functions-change of parameter-arc

15%


2 | P a g e

length-unit tangent-normal-binormal-curvature-motion along a curve

velocity-acceleration. Directional derivative and gradient-tangent planes

and normal vectors-Lagrange multiplier method extremum problem with

constraint (vector approach)

SECOND INTERNAL EXAM

V

Multiple integrals and Applications (Book I-sec. 15.1, 15.2, 15.3 to

15.5, 15.7, 15.8)

Double integrals Double integrals in non-rectangular coordinates-

reversing the order of integration-area calculated as a double integral-

Double integrals in polar coordinates- triple integrals-volume calculated

as a triple integral- triple integrals in cylindrical and spherical coordinates-

converting triple integrals from rectangular to cylindrical coordinates -

converting triple integrals from rectangular to spherical coordinates -

change of variables in triple integrals-Jacobians (applications of results

only)

20%

VI

Vector integration(Book I sec. 16.1, 16.2, 16.3, 16.4, 16.5, 16.7, 16.8)

Vector field- divergence- curl, line integrals - work as a line integral,

independence of path-conservative vector field, Greens theorem

(without proof- only for simply connected region in plane), surface

integrals divergence theorem (without proof), Stokes theorem (without

proof)

20%

END SEMESTER EXAM


3 | P a g e

MODULE

COURSE NO: PH 100 L-T-P: 3-1-0

COURSE NAME: ENGINEERING PHYSICS CREDITS: 4

CONTENT HRS END SEM. MARK %

I

Harmonic Oscillations: Differential equation of damped harmonic

oscillation, forced harmonic oscillation and their solutions- Resonance, Q

factor, Sharpness of resonance- LCR circuit as an electrical analogue of

Mechanical Oscillator.

Waves: One dimensional wave- differential equation and solution.. Three

dimensional wave- differential equation & solution. Transverse vibrations

of a stretched string.

9 15%

II

Crystal Structure: Space lattice. Unit cell and lattice parameters. Crystal

systems. Coordination number and packing factor with reference to simple

cubic, body centered cubic and face centered cubic crystals. Directions and

planes. Miller indices. Interplanar spacing in terms of Miller indices.

Superconductivity: Superconducting phenomena. Meissner effect. Type-I

and Type-II superconductors. BCS theory (qualitative). High temperature

superconductors- Josephson Junction SQUID- Applications of

superconductors.

9 15%

FIRST INTERNAL EXAM

III

Interference: Coherence. Interference in thin films and wedge shaped

films. Newtons rings. Interference filters. Antireflection coating.

Diffraction Fresnel and Fraunhofer diffraction. Fraunhofer diffraction at

a single slit. Fraunhofer diffraction at a circular aperture (qualitative).

Rayleighs criterion for resolution. Resolving power of telescope and

microscope. Plane transmission grating. Grating equation. Resolving

power and dispersive power of grating.

Polarization of Light: Types of polarized light. Double refraction. Nicol

Prism. Retardation plates. Quarter wave plate and half wave plate.

Production and analysis of circularly and elliptically polarized light.

Laurents Half shade Polarimeter- Kerr Cell -Polaroids & applications.

9 15%


4 | P a g e

IV

Quantum Mechanics: Failure of classical physics, Pair production,

uncertainty principle and its applications- properties of matter waves,

wave packets, formulation of Schrdinger equation, physical meaning of

wave function, Eigen values and functions Expectation values, time

dependent and time-independent Schrdinger equation, quantization of

energy bound states, application of time-independent Schrdinger

equation to free particle, infinite well. Quantum mechanical Tunnelling

(Qualitative ) Electron microscope

Statistical Mechanics: Macrostates and Microstates. Phase space. Basic

postulates of Maxwell- Boltzmann, Bose-Einstein and Fermi Dirac

statistics. Distribution equations in the three cases (no derivation). Density

of states. Derivation of Plancks formula. Free electrons in a metal as a

Fermi gas. Fermi energy.

9 15%


V

Intensity of sound- Loudness-Absorption coefficient - Reverberation and

reverberation time- Significance of reverberation time-Sabines

formula(No derivation) -Factors affecting acoustics of a building-

Production of ultrasonic waves- Magnetostriction oscillator- Piezoelectric

oscillator-Detection of ultrasonics- Thermal and piezoelectric methods-

NDT methods using ultrasonics

9 20%

VI

Photonics: Basics of all solid state lamps-LED -Photodetectors- Thermal

detectors, photoconductors, Junction photodiodes, APD, phototransister,

Solar cells- I-V characteristics and spectral response. Fibre Optic

communication- basic principle-Industrial, medical and technological

applications of optical fibre. Fibre optic sensors - Intensity modulation

and interference type sensors-Polarisation modulation type sensors.

Sagniac and fibre gyro, temperature, pressure, force and chemical sensors.

Laser: Properties of Lasers, Absorption, Spontaneous and stimulated

emission, Population inversion, Einsteins coefficients, Working principle

of laser, Optical resonant cavity. Ruby Laser, Helium-Neon Laser,

Semiconductor Laser (qualitative). Applications of laser, holography

(Recording and reconstruction)

9 20%

END SEMESTER EXAM


5 | P a g e

MODULE


COURSE NAME: ENGINEERING CHEMISTRY

CREDITS: 4

CONTENT HRS

END SEM.

MARK %

I

Spectroscopy:

Introduction, Beer Lamberts Law, UV-visible spectroscopy Principle,

Instrumentation and applications; IR spectroscopy Principle and

applications; 1H NMR spectroscopy Principle, chemical shift spin-

spin splitting and applications including MRI.

9 15%

II

Electrochemistry

Types of electrodes SHE, Calomel electrode, Glass electrode,

Electrochemical series and its applications including Decomposition

potential and Overvoltage, Nernst equation and its application

Potentiometric titration Acid-base and redox titration, Lithium ion cell

and Fuel cell.

8 15%

FIRST INTERNAL EXAM

III

Instrumental Methods

Thermal analysis Principle, instrumentation and applications of TGA

and DTA. Chromatographic methods Basic principles, column, TLC.

Instrumentation and principles of GC and HPLC.

Conductivity Measurement of conductivity

8 15%

IV

Chemistry of Engineering Materials

Copolymers BS, ABS Structure and Properties. Conducting Polymers

Polyaniline, Polypyrrole, OLED Preparation, Structure and Properties.

Advanced Polymers Kevlar, Polybutadiene rubber and silicone rubber.

Nanomaterials Definition, Classification, Chemical methods of

preparation (Any 2 methods), Properties and Applications Carbon Nano

Tubes and fullerenes.

9 15%


V

Fuels and Lubricants

Fuels Calorific Value, HCV and LCV Determination of calorific value

of a solid and liquid fuel by Bomb calorimeter Dulongs formula and

Numericals. Liquid fuel Petrol and Diesel Cetane number Biodiesel

Natural gas.

Lubricant Introduction, solid, semisolid and liquid lubricants. Properties

9 20%


6 | P a g e

of lubricants Viscosity Index, Flash point, Fire point, Cloud point, Pour

point and Aniline point.

VI

Water Technology

Types of hardness, Estimation of Hardness EDTA method, Water

softening methods Ion exchange process Principle. Polymer ion

exchange - Reverse Osmosis - Disinfection method by chlorination and

UV - Dissolved oxygen, BOD and COD.

Sewage water Treatment Trickling Filter and UASB process.

9 20%

END SEMESTER EXAM


7 | P a g e

MODULE

COURSE NO: BE 103 L-T-P: 3-1-0

COURSE NAME: ENGINEERING MECHANICS

CREDITS: 4

CONTENT HRS

END SEM.

MARK %

I

PART A - STATICS

Fundamental concepts and laws of mechanics - Rigid body- Principle of

transmissibility of forces - Co-planar force system

Force system - Moment of a force - Principle of moments - resultant of

force and couple system.

Equilibrium of a rigid body - Conditions for equilibrium in two

dimensions - Free body diagram - Equations of equilibrium - Two and

three force members

10 15%

II

Equilibrium of a rigid body in three dimension - Free body diagram -

Equations of equilibrium - constraints for a rigid body.

Properties of surfaces Centroid and Second moment of area

(Derivations of simple geometric figures not required) - Parallel and

perpendicular axis theorem - radius of gyration - Basic concept of

Product moment of inertia and mass moment of inertia - Theorems of

Pappus and Guldinus

10 15%

FIRST INTERNAL EXAM

III

Friction - Characteristics of dry friction - Problems involving Ladder

and Wedges

Principle of virtual work - Definition of work and virtual work -

Principle of virtual work for a particle and rigid body - Principle of

virtual work for a system of connected rigid bodies.

10 15%

IV

PART B - DYNAMICS

General curvilinear motion - Rectangular and cylindrical components -

Normal and tangential components - Absolute and relative motion and

analysis of two particles - Combined motion of translation and rotation -

Instantaneous centre - Motion of connecting rod

Newtons second law - D Alemberts principle - Application to

connected bodies.

8 15%


V Torque - Angular impulse - Angular momentum - Newtons second law

in rotational motion 8 20%


8 | P a g e

Centripetal and centrifugal forces - Planar kinematics of rigid body -

Rotation about a fixed axis.

VI

Work, power and energy - Work-energy principle - Power and efficiency

- Conservative forces and potential energy - Conservation of energy -

Impulse - momentum method

Mechanical vibration - Free vibration-Simple harmonic motion - Spring

mass model Period Stiffness - Frequency

8 20%

END SEMESTER EXAM


9 | P a g e

MODULE

COURSE NO: BE 101 - 01 L-T-P: 2-1-0

COURSE NAME: INTRODUCTION TO CIVIL ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

CIVIL ENGINEERING AS A PROFESSION: General Introduction

to Civil Engineering - History of Civil Engineering- Various disciplines of

civil engineering - Relevance of civil engineering in the overall

infrastructural development of the country

Definition of a structure - Types of structures buildings, towers,

chimneys, bridges, dams, retaining walls, weirs, roads, railway lines,

runways, sewage treatment plant, water purification plant (Introduction

only, details not needed)

Introduction to National Building code Definition of buildings - Types

of buildings Group A to I as per NBC (brief discussion only)

2

2

2

15%

II

BUILDING PLANNING: Site selection for buildings Site plan

Components of a building and their functions

Building regulations: Orientation of a building Positioning of doors

and windows open space requirements size of rooms Preparation

of plan of a single storeyed building in a given site plan (with the aid of

an example of a simple residential building)

Introduction to the various building area calculation terms - Computation

of plinth area / built up area, Floor area / carpet area, for a simple single

storeyed building with a sit out, drawing cum dining room, one bedroom

and a kitchen (Plan to be provided)

Site clearance - Setting out of a building

1

1

3

2

1

15%

FIRST INTERNAL EXAM

III

BUILDING MATERIALS I: Bricks and tiles: Composition of good

brick earth, Classification of bricks / tiles, Qualities of good brick, field

test & Laboratory test performed on bricks. Manufacture of bricks

and tiles (brief discussion only).

Stone: Classifications of stone, Qualities of good building stone

quarrying dressing uses of common building stones

Timber: Properties uses classification seasoning defects in

timber preservation

Smart materials : A brief discussion on the concept of smart materials

used in the Civil Engineering field

3

2

2

1

15%


10 | P a g e

IV

BUILDING MATERIALS II: Cement: Basic ingredients and

Manufacturing process of Portland cement, grades of cement

Aggregates Fine and Coarse aggregates -properties uses

Cement mortar and concrete types and preparation only

Steel types properties uses market forms

2

3

1

15%


V

BUILDING CONSTRUCTION I: Stone masonry - Types

Details of Ashlar, Random rubble, Coarse rubble and Dry Rubble

masonry only.

Brick Masonry-Types masonry (Brief) - Bond Introduction to all

types of bond -English bond in detail (1, 1 and 2 brick walls)

Comparison of stone and brick masonry

3

4

1

20%

VI

BUILDING CONSTRUCTION II: Floors and flooring materials

different types and selection of floors and floor coverings

Roofs and roof coverings different types of roofs suitability

types and selection of roofing materials

Plastering need method of cement plastering

Painting types, characteristics and uses of paints

Method of painting new and old woodwork new and old metal work

Whitewashing Preparation of whitewash Preparation of surface

Colour washing

Distempering Properties of distempers Process of distempering

1

2

1

2

1

1

20%

END SEMESTER EXAM


11 | P a g e

MODULE

COURSE NO: BE 101 - 03 L-T-P: 2-1-0

COURSE NAME: INTRODUCTION TO ELECTRICAL ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Fundamental Concepts of Circuit Elements and Circuit

variables:

Electromotive force, potential and voltage. Resistors, Capacitors,

Inductors- terminal v-i relations. Electromagnetic Induction

Faradays laws, Lenzs law, statically and dynamically induced emf,

self and mutual inductance, coupling coefficient. Real and Ideal

independent voltage and current sources, V-I relations. Passive

sign convention

6 15%

II

Basic Circuit Laws: Kirchhoff's current and voltage laws,

analysis of resistive circuits - mesh, node analysis, super mesh

and super node analysis. Star delta transformation

Magnetic Circuits: Magneto motive force, flux, reluctance,

permeability-comparison of electric and magnetic circuits analysis

of series and parallel magnetic circuits, magnetic circuits with air-

gaps.

9 15%

FIRST INTERNAL EXAM

III

Alternating current fundamentals: Frequency, Period, RMS

and average values, peak factor and form factor of periodic

waveforms (pure ac and composite waveforms). Phasor

Concepts, Complex representation (exponential, polar and

rectangular forms) of sinusoidal voltages and currents, phasor

diagrams, Complex impedance - series and parallel impedances.

Phasor analysis of RL, RC, RLC circuits.

9 15%

IV

Complex Power: Concept of power factor - active, reactive

power and apparent power. Admittances- Admittances in series

and parallel.

Resonance in series and parallel circuits- Energy, bandwidth

and quality factor, variation of impedance and admittance in

series and parallel resonant circuits.

6 15%



12 | P a g e

V Three-phase systems: Star and delta connections, three-phase

three wire and three-phase four-wire systems, analysis of

balanced and unbalanced star and delta connected loads, power

in three-phase circuits.

6 20%

VI

Wiring systems: Basic concepts of wiring (conduit wiring only),

service mains, meter board and distribution board.

Earthing: Earthing of installations - necessity of earthing, plate

& pipe earthing.

Protective devices: protective fuses, MCB, ELCB.

6 20%

END SEMESTER EXAM


13 | P a g e

MODULE

COURSE NO: BE 101 - 04 L-T-P: 2-1-0

COURSE NAME: INTRODUCTION TO ELECTRONICS ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Evolution of Electronics, Impact of Electronics in industries and

in society

Resistors, Capacitors: types, specification. common values,

marking ,colour coding

Inductors and Transformers: types, specification

Electro mechanical components

1

3

1

1

15%

II

Diodes: Intrinsic and extrinsic semiconductors, PN junction

diode, barrier potential, characteristics, Effect of temperature.

Equivalent circuit of a diode. Piece wise linear model

Specification parameters of diodes and numbering

Zener diode, characteristics, working principle of LED, photo

diode

3

1

2

15%

FIRST INTERNAL EXAM

III

Bipolar Junction Transistors: Structure, typical doping,

working, concept of different configurations. Detailed study of

input and output characteristics of common base and common

emitter configuration, current gain, comparison of three

configurations.

Concept of load line and operating point. Need for biasing and

stabilization, voltage divider biasing, Transistor as amplifier,

switch.

Specification parameters of transistors and type numbering

3

2

1

15%

IV

Junction Field Effect Transistors: Structure, principle of

operation, characteristics, comparison with BJT

MOSFET: Structure, principle of operation of Enhancement

type MOSFET, Current voltage characteristics, Depletion-type

MOSFET.

Principle of operation of Photo transistor, UJT, SCR

1

2

3

15%



14 | P a g e

V

Diode circuits and power supplies: Series and parallel diode

circuits, Clippers, Clampers, Voltage multiplier

Half-wave and full wave (including bridge) rectifiers, Derivation

of Vrms, Vdc, ripple factor, peak inverse voltage, rectification

efficiency in each case, capacitor filter, working and design of a

simple zener voltage regulator.

Block diagram description of a DC Power supply

3

3

20%

VI

Electronic Measurements and measuring Instruments:

Generalized performance parameters of instruments

Principle and block diagram of analog and digital multimeter,

Block diagram of CRO, Measurements using CRO, Principle and

block diagram of DSO, function generator.

Testing of Electronic components

1

4

1

20%

END SEMESTER EXAM


15 | P a g e

MODULE

COURSE NO: BE 101 - 05 L-T-P: 2-1-0

COURSE NAME: INTRODUCTION TO COMPUTER SCIENCES & ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Introduction to digital computer Von Newman concept A

simple model of computer with acquisition of data, storage of data,

processing of data, output of processed data. Details of functional units

of a computer. Storage primary storage and secondary storage.

Introduction to programming languages:- types of programming

languages - high level language , assembly language and machine

language System software - Operating systems objectives of operating

systems, compiler, assembler and interpreter (concepts only).

8 15%

II

Problem Solving strategies Problem analysis formal definition of

problem Solution top- down design breaking a problem into

sub problems- overview of the solution to the sub problems by writing

step by step procedure (algorithm) - representation of procedure by

flowchart - Implementation of algorithms use procedures to achieve

modularity.

Examples for algorithms and flow charts - at least 10 problems

(starting with non numerical examples, and numeric problems like

factorial, largest among three numbers, largest among N, Fibonacci etc)

must be discussed in detail.

8 15%

FIRST INTERNAL EXAM

III Introduction to C language Pre processor directives header files

data types and qualifiers. Operators and expressions. Data input and

output control statements.

8 15%

IV Functions Function definition and function prototype. Function

call by value and call by reference. Scope rules and storage classes.

Recursive functions examples.

10 15%


V Arrays , and strings - structures unions enumerated data type

Examples of two dimensional array - matrix operations etc 9 20%

VI Pointers array of pointers structures and pointers. Memory

allocation functions. Bitwise operations. Data files formatted,

unformatted and text files. Command line arguments examples

12 20%

END SEMESTER EXAM


16 | P a g e

MODULE

COURSE NO: BE 101 - 06 L-T-P: 2-1-0

COURSE NAME: INTRODUCTION TO CHEMICAL ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Introduction to Chemical Engineering: history of Chemical

Engineering, role of Chemical Engineering a broad overview;

chemical industries in India; introduction to Chemical Engineering

profession; introduction to chemical plant operation; process

development and process design.

6 15%

II Basic concepts: units and dimensions, systems of units, conversion and

conversion factors of units, concept of mole, weight percent, mole

percent, normality, molarity, molality, vapor pressure, partial pressure,

concept of ideal gas and equations of state.

7 15%

FIRST INTERNAL EXAM

III

Overview of unit operations such as distillation, evaporation,

absorption, adsorption, extraction, crystallization, drying, leaching, size

separation and size reduction. Overview of unit processes like

saponification, polymerization, biodiesel formation and

hydrogenation.

8 15%

IV

Modes of heat transfer-principles of conduction, convection and

radiation. Fluid flow- laminar and turbulent flow. Introduction to

centrifugal pump, Introduction to double pipe heat exchanger.

Classification of chemical reactions, order of reaction, rate equation,

Arrhenius equation, conversion and yield, batch reactor, mixed reactor

and plug flow reactor.

8 15%


V

Block diagram, process flow diagram for DCDA process for Sulphuric

acid manufacture, basic concepts of P&I diagram. Introduction to

process instrumentation and control: common methodologies of

measurements, measuring instruments: thermocouple, venturimeter,

U-tube manometer, elements of feedback control loop, introduction

to control of a distillation column.

7 20%

VI Introduction to safety in chemical process industries basic concepts,

Case study: Bhopal gas tragedy. Introduction to Environmental

Engineering - basic concepts, Typical wastewater, air and solid waste

6 20%


17 | P a g e

management system. Case study: Effect of Aerial Spraying of

Endosulfan on Residents of Kasargod, Kerala. Challenges of Chemical

Engineer need for sustainable alternatives for processes; products

with environment friendly life-cycle. Introduction to novel materials

and their development

END SEMESTER EXAM


18 | P a g e

MODULE


COURSE NAME: SUSTAINABLE ENGINEERING

CREDITS: 3

CONTENT HRS

END

SEM.

MARK %

I

Sustainability, Introduction, Need for sustainability, Concept of

sustainability, Tools for sustainability- Life cycle assessment, MFA, ISO

14000, SWOT analysis, Rules and regulations, Water act, air act,

Environment act, responsibility of industries, industrial ecology,

sustainability indicators, Risk assessment, Environment impact

assessment, stages of EIA.

15%

II

Water, sources, rain water harvesting, surface water harvesting, ground

water harvesting, roof water harvesting, pollutants, types, persistent

organic pollutants, sources of pollutants, Analysis of pollutants,

Physical, Chemical, Biological parameters, Eutrophication, marine

pollution, oil pollution

Wastewater, Methods of treatment, sustainable wastewater treatment

methods, Constructed wetlands, Reed beds, Oxidation ponds, Energy

from wastewater

15%

FIRST INTERNAL EXAM

III

Solid waste pollution, classification, sources, effects, methods of

disposal, Zero waste concept, waste minimization, source reduction,

recycle and reuse of solid waste, examples of solid waste management

Hazardous wastes, Characteristics of hazardous wastes, hazardous

waste management, e wastes, plastic wastes, pollution and disposal

practices

15%

IV

Air pollution, sources of air pollution, classification of air pollutants,

global effects of air pollution, climate change, global warming

potential, ozone layer depletion, carbon accounting

Automobile air pollution, Control of air pollutants, Indoor air

pollution,

Noise pollution, effects, control measures

15%


V Energy sources, Conventional and renewable energy, solar energy,

various methods of using solar energy, Bioenergy, Biofuels, 20%


19 | P a g e

Biomethanation, aerobic and anaerobic conversions, biohydrogen

production, wind energy, basics and power analysis, wind power

estimation techniques, wind turbine generators, site selection, viability

of wind farm, Energy audit

VI Green buildings, Intelligent buildings, green materials for building

construction, material selection for sustainable design, methods for

increasing energy efficiency of buildings, Sustainable cities, case

studies in sustainable engineering

20%

END SEMESTER EXAM


20 | P a g e

MODULE

COURSE NO: CE 100 L-T-P: 2-1-0

COURSE NAME: BASICS OF CIVIL ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Introduction to Civil Engineering: General Introduction to Civil

Engineering - Various disciplines of civil engineering - Relevance of

civil engineering in the overall infrastructural development of the

country

Site selection for residential and industrial buildings Site plan

Components of a residential building and their functions

Special features of an industrial building office, workshop, software

development office, factory, electronic equipment service centre,

power house (Depending on the branch the faculty has to introduce

the problem and Students have to visit one such building of relevance

and make a detailed report of the same and submit)

2

1

2

2

15%

II

BUILDING PLANNING: Building regulations: Orientation of

a building Positioning of doors and windows open space

requirements size of rooms Preparation of plan of a single

storeyed building in a given site plan (with the aid of an example of a

simple residential building)

Introduction to the various building area terms - Computation of

plinth area / built up area/ Floor area / carpet area, for a simple

single storeyed building with a sit out, drawing cum dining room, one

bedroom and a kitchen (Plan to be provided)

Site clearance - Setting out of a building

4

2

2

15%

FIRST INTERNAL EXAM

III

SURVEYING: Principles and objects of surveying

Horizontal measurements Tape only, Types of tapes, Accessories

used in surveying, Tape corrections - problems, Ranging (direct

ranging only)

Levelling: Definitions, principles of levelling, Instruments used in

levelling (brief discussion only), Level field book, Reduction of levels -

problems on levelling (height of collimation only)

Modern surveying instruments A brief discussion of Electronic

distance meter, digital level, total station, GPS

1

3

3

1

15%


21 | P a g e

IV

BUILDING MATERIALS: Bricks: Composition of good brick

earth, Manufacture of bricks (brief discussion only), Qualities and

dimensions of a good brick

Cement: Ingredients of Portland cement, setting time of cement,

grades of cement

Steel: Use of steel in building construction, steel as reinforcement in

concrete, market forms of steel

Mortar and concrete: Definition - Types and preparation (brief

discussion only) Basic concept of smart materials used for building

construction

2

1

2

1

15%


V

BUILDING CONSTRUCTION: Foundations: Necessity of

foundations, Bearing capacity of soil - Definition only; Functions of

foundations, Types of foundations - shallow and deep foundations

(sketches only)

Brick masonry: header, stretcher, English bonds Elevation and

plan (one brick thick walls only);

Roofs: functions of roofs types of roofs flat and sloping - types of

modern roofing materials

Floors: functions of floors types of floors types of modern

flooring materials

Decorative finishes: Plastering - Definition, Purpose and Method

of plastering, Painting - Definition, Purpose, types of paints

commonly used types only, preparation of plastered, wooden and

metal surfaces for painting (brief discussion only)

2

2

1

1

3

20%

VI

BASIC INFRASTRUCTURE AND SERVICES: Elevators,

escalators, ramps, air conditioning, sound proofing Civil engineering

aspects only

Towers, Chimneys, Water tanks (brief discussion only)

Roads - Classification of rural and urban Roads, Traffic signs and road

marking - Traffic Signals

Sources of Water - Water Supply - Quality of Water - Wastewater

Treatment

2

1

2

2

20%

END SEMESTER EXAM


22 | P a g e

MODULE

COURSE NO: EE 100 L-T-P: 2-1-0

COURSE NAME: BASICS OF ELECTRICAL ENGINEERING

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Elementary concepts of electric circuits: Kirchhoffs laws, constant

voltage and current sources, constant power and energy concepts,

formation of network equations by node voltage and mesh current

methods.

Matrix representation - solution of network equations by matrix

methods, star-delta conversion (Analysis of resistive networks only).

6 15%

II

Magnetic circuits: MMF, field strength, flux density, reluctance,

energy stored in magnetic

Circuits.

Electromagnetic induction: Faradays laws, Lenzs law-statically

induced and dynamically Induced emfs- self-inductance and mutual

inductance.

Alternating current fundamentals: Generation of alternating

voltages, waveforms frequency, period, average and RMS values and

form factor.

9 15%

FIRST INTERNAL EXAM

III

AC Circuits

Phasor representation of alternating quantities- rectangular, polar and

exponential forms. Analysis of simple ac circuits - concept of

impedance. Power and power factor in ac circuits- active, reactive and

apparent power. Solution of RL, RC and RLC circuits.

Three phase systems: Generation of three phase voltages-

advantages of three phase systems, star and delta connection, three

wire and four wire systems, relation between line and phase voltages,

line and phase currents. Expressions for power in three phase circuits.

9 15%

IV

Generation of power: Block schematic representation of generating

stations- hydroelectric, thermal and nuclear power plants. Renewable

energy sources solar.

Power transmission and distribution: Typical electrical power

transmission scheme, need for high voltage transmission, substation

equipments, primary and secondary transmission and distribution

systems.

6 15%


23 | P a g e


V

Transformers: construction of single phase and three phase

transformers (core type only) EMF equation, losses and efficiency.

Electric Machines: D.C. Motors, Universal motor single phase and

three phase Motors application.

6 20%

VI

Tariff: Different types of LT and HT consumers, tariff schemes -

uniform tariff and differential tariff.

Wiring systems: Basic concepts of wiring (conduit wiring only),

service mains, meter board and distribution board. Earthing of

installations - necessity of earthing, plate & pipe earthing, protective

fuses, MCB, ELCB.

Lamps: Different types of lamps - Incandescent lamps, fluorescent,

mercury vapour, sodium vapour, metal halide and LED lamps.

6 20%

END SEMESTER EXAM


24 | P a g e

MODULE


COURSE NAME: BASICS OF ELECTRONICS CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

Evolution of Electronics, Impact of Electronics in industry and in

society

Resistors, Capacitors: types, specification. Common values, marking,

colour coding

Inductors and Transformers: types, specification

Electro mechanical components

1

3

1

1

10%

II

PN Junction diode: Principle of operation, V-I characteristics,

principle of working of Zener diode, Photo diode, LED and Solar cell.

Bipolar Junction Transistors: Structure, Principle of operation, input

and output characteristics of common emitter configuration

Diodes and transistors: types, specification, marking

2

2

2

20%

FIRST INTERNAL EXAM

III

Rectifiers and power supplies: Block diagram description of a dc

power supply ,Half wave and full wave (including bridge) rectifier,

capacitor filter, working of simple zener voltage regulator

Amplifiers and Oscillators: Circuit diagram and working of

common emitter amplifier, Block diagram of Public Address system,

concepts of feedback, working principles of oscillators, circuit diagram

& working of RC phase shift oscillator.

3

3

15%

IV

Analogue Integrated circuits: Functional block diagram of

operational amplifier, ideal operational amplifier, inverting and non

inverting amplifier, comparator.

Electronic Instrumentation: Principle and block diagram of digital

multimeter, principle of digital storage oscilloscope, principle and

block diagram of function generator.

3

3

15%


V

Radio communication: principle of AM & FM, frequency bands

used for various communication systems, block diagram of super

heterodyne receiver

Radar system: Principle, block diagram of pulsed radar,

Satellite communication: concept of geo-stationary satellite, satellite

transponder, advantages, principle of Global Positioning System

3

1

2

20%


25 | P a g e

VI

Mobile communication: basic principles of cellular communications,

concepts of cells, frequency reuse, principle and block diagram of

GSM.

Optical communication: block diagram of the optical

communication system, principle of light transmission through fiber,

advantages

Entertainment Electronics Technology: working principle of

Colour television, basic principles of cable TV, CCTV system, basic

principles of HDTV, LCD & LED displays.

2

1

3

20%

END SEMESTER EXAM


26 | P a g e


COURSE NAME: ENGINEERING PHYSICS LAB CREDITS: 1

COURSE OBJECTIVES:

This course imparts to the students, a basic knowledge in physics with an understanding of fundamental

concepts. (Any 9 experiments- The numbers given in the bracket are the item number of the kit available with

Indosaw.

CONTENTS

Basics

1. Study of application of Cathode Ray Oscilloscope (CRO) for Frequency and Amplitude measurements.

2. Temperature measurement Thermocouple

3. Measurement of strain using strain gauge and Wheatstones bridge.

Waves, Oscillations and Ultrasonics.

4. Wave length and velocity measurement of ultrasonic waves in a liquid using ultrasonic diffractometer

5. The LCR Circuit Forced and damped harmonics oscillations.

Interference

6. Wave length measurement of a monochromatic source of light using Newtons Rings method.

7. Diameter of a thin wire or thickness of a thin strip of paper using air wedge method.

Diffraction

8. To determine the slit or pinhole width. (Indosaw DIODE LASER KIT SA006/SN611)

9. To measure wavelength using a millimeter scale as a grating. (Indosaw DIODE LASER KIT

SA006/SN611)

10. Determination the wavelength of He-Ne laser using diffraction grating. (Indosaw SK172)

11. To determine the resolving power of a telescope. (Indosaw SED1005)

12. Determination of dispersive power and resolving power of a plane transmission grating.

Polarisation

13. Laurets Half Shade Polarimeter (Indo saw SK018) -To observe the rotation of the plane of

polarization of monochromatic light by sugar solution and henceto determine the concentration of

solution of optically active substance.

14. Kerr Effect ( Indo saw SK019/SK019A) - To demonstrate the kerr effect in nitrobenzene solution and


27 | P a g e

to measure the light intensity as a function of voltage across the kerr cell using photo detector.

15. To measure the light intensity of plane polarised light as a function of the analyzer position. ( Indosaw

SK073A)

Laser & Photonics

16. To determine the speed of light in air using laser (Indosaw SK077)

17. Calculate the numerical aperture and study the losses that occur in optical fiber cable. ( Indosaw

OPTICAL FIBER KIT SEA92)

18. Determination the particle size of lycopodium powder. (Indosaw SK172)

19. I-V characteristics of solar cell

20. To measure Plancks constant using photo electric cell.

REFERENCES:

Website: http://www.indosawedu.com

END INTERNAL EXAM


28 | P a g e


COURSE NAME: ENGINEERING CHEMISTRY LAB CREDITS: 1

CONTENTS

(Any 8 experiments)

1. Estimation of Total Hardness EDTA method.

2. Estimation of Iron in Iron ore.

3. Estimation of Copper in Brass.

4. Estimation of dissolved oxygen by Winklers method.

5. Estimation of chloride in water.

6. Preparation of Urea formaldehyde and Phenol-formaldehyde resin.

7. Determination of Flash point and Fire point of oil by Pensky Martin Apparatus.

8. Determination of wavelength of absorption maximum and colorimetric estimation of Fe3+ in solution.

9. Analysis of IR spectra of any three organic compounds.

10. Analysis of 1H NMR spectra of any three organic compounds.

11. Calibration of pH meter and determination of pH of a solution.

12. Verification of Nernst equation for electrochemical cell.

13. Potentiometric titrations: acid base and redox titrations

14. Conductivity measurements of salt solutions.

15. Flame photometric estimation of Na+ to find out the salinity in sand.

END INTERNAL EXAM


29 | P a g e


COURSE NAME: CIVIL ENGINEERING WORKSHOP CREDITS: 1

CONTENTS

1. Setting out of a building: The student should set out a building (single room only) as per the given building

plan using tape and cross staff (1 session)

2. Building area computation: The student should prepare a rough sketch of a given single storeyed building

and by taking linear measurements compute plinth area and carpet area of the given building. Should

comment on the same with respect to local building regulations. (1 session)

3. Construct a wall of height 500mm and wall thickness 1 bricks and 2 bricks using English bond (No mortar

required) - corner portion length of side walls a minimum of 600mm (2 sessions)

4. Testing of building materials: The student should do the compression testing of any three construction

materials and compare the strength (brick, hollow block, laterite block, cement concrete cube, stone block, and

so on) (1 session)

5. Computation of Centre of gravity and Moment of inertia of a given rolled steel section. (1 session)

6. Preparation of a building model: Assignment: The students in batches should prepare and submit a building

model for a given plinth area in a given site plan constrained by a boundary wall. The minimum requirements

of a residential building viz., drawing cum dining room, one bed room and a kitchen should be included. The

concept of an energy efficient building should also be included in the model.

END INTERNAL EXAM


30 | P a g e


COURSE NAME: CIVIL ENGINEERING WORKSHOP

(OTHER BRANCHES) CREDITS: 1

CONTENTS

1. Setting out of a building: The student should set out a building (single room only) as per the given building

plan using tape and cross staff (1 session)

2. Building area computation: The student should prepare a rough sketch of a given single storeyed building

and by taking linear measurements compute plinth area and carpet area of the given building. Should

comment on the measurement with respect to local building regulations. (1 session)

3. Construct a wall of height 500mm and wall thickness 1 brick using English bond (No mortar

required) - corner portion length of side walls at least 600mm (1 session)

4. Horizontal and elevation measurements: Find the area of an irregular polygon set out on the field and find

the level difference between any two corner points (1 session)

5. Computation of Centre of gravity and Moment of inertia of a given rolled steel section. (1 session)

6. Preparation of a building model: Home assignment 1: The students in batches should prepare and submit a

building model for a given plinth area in a given site plan constrained by a boundary wall. The minimum

requirements of a residential building viz., drawing cum dining room, one bed room and a kitchen should be

included. The concept of an energy efficient building should also be included in the model.

7. Report preparation: Home assignment 2: The student should collect the construction details of an industrial

building, prepare and submit a detailed report with neat illustrations.

(ME stream workshop / factory

CS / IT stream - software development office

EC / AE stream - electronic equipment service centre

EEE stream power house)

END INTERNAL EXAM


31 | P a g e


COURSE NAME: ELECTRICAL ENGINEERING WORKSHOP CREDITS: 1

CONTENTS

Unit Major learning outcome Topics and subtopics

1.Power supply

arrangements

1.1 Familiarity with supply

arrangements and their

limitations.

1.2 Knowledge of standard

voltages and their tolerances.

1.3 Safety aspects of

electrical systems

1.1 Standard voltages and frequency for

electric supply

1.2 Protective measures employed in electrical

systems

1.3 First aid practices against electric shock

1.4 Standard symbols and schematic diagrams

1.5 Segregation of light and power circuits

2.Wiring

accessories and

safety

measures

2.1 knowledge about the

types of wires and cables

2.2 Identify different

accessories used in wiring

2.3 Familiarize Tools used

for wiring practice

2.4 Use energy conservation

concepts in electrical systems

2.1 Wiring materials and accessories

2.2 Types of wiring and their relative

advantages

2.3 Tools used in electrical installations

2.4 Different types of light sources and their

relative merits

2.5 Fuses, low voltage circuit breakers

2.6 Electrical safety, types of earthing and their

importance

3.Wiring

practice

3.1 Be able to wire simple

lighting circuits for domestic

buildings

3.2 Distinguish between light

and power circuits

3.3 Understand the

importance of protective

measures in wiring systems

3.1Wiring of simple light circuits for

controlling light, fan , 6A socket or call bell

points (in exposed PVC conduit wiring)

3.2 Wiring of light /fan circuits using two way

switches

3.3 Wiring of fluorescent lamp circuits

3.4 Wiring of power circuits for controlling a

power device using power sockets

3.5 Wiring of Godown/Tunnel/Hospital

circuits

3.6 Wiring of power distribution arrangement

using a single phase MCB distribution board

and energy meter

4.Electrical

parameter

measurements

4.1 To be familiar with

different electrical parameter

measurements

4.2 Able to know the current

4.1 Voltage measurement in a simple electrical

circuit.

4.2 Current measurement in a simple electrical

circuit.


32 | P a g e

and power in a circuit. 4.3 Determination of power in a simple

electrical circuit using wattmeter & calculation

of power factor.

Suggested list of exercises/ practical session

The exercises shall be properly designed and implemented with an attempt to develop different types of

skills leading to the achievement of the competency.

S.

No.

Unit

No.

Exercise/Practical Hr

1 II Identify different types of cables/wires and switches and their uses. 2

2 II Identify different types of fuses &fuse carriers, MCB and ELCB

with ratings and its usage.

2

3 III Wiring of simple light circuit for controlling light/fan

point.(conduit wiring)

2

4 III Wiring of light/fan circuit using 2 way switches (Staircase wiring) 2

5 III Wiring of fluorescent lamps and light sockets(6A) 2

6 III Wiring of Power circuit for controlling a power device (16A socket) 2

7 III Wiring of Godown circuit 2

8 III Wiring of Tunnel circuit 2

9 III Wiring of Hospital circuit 2

10 III Wiring of single phase distribution board with ELCB and meter

board

2

11 IV Measurement of supply voltage and voltage across a given R & L

Circuit

2

12 IV Current measurement in two parallel limps in a circuit 2

13 IV Measurement of power voltage & current in a single phase circuit

using wattmeter, voltmeter and ammeter. Calculate the power factor

of the circuit.

2+2

END INTERNAL EXAM


33 | P a g e

MODULE


COURSE NAME: ENGINEERING GRAPHICS

CREDITS: 3

CONTENT HRS

END SEM.

MARK %

I

1 sheet

Introduction to Engineering Graphics: Drawing instruments - BIS code

of practice for general engineering drawing. Construction of Conic

sections - Construction of Cycloid, Involutes and Helix (For internal

work assessment only, not for University Examination)

Scales-Plain scales-Diagonal Scales-Forward and Backward Vernier

Scales.

4 15%

II

2 sheets

Orthographic projections of points and lines:-Projections of points in

different quadrants-Projections of straight lines inclined to one of the

reference planes-straight lines inclined to both the planes. True length

and inclination of lines with reference planes using line rotation OR

plane rotation methods Traces of lines.

12 15%

FIRST INTERNAL EXAM

III

2 sheets

Orthographic projections of solids:-Projections of simple solids* in

simple positions, axis inclined to one of the reference planes and axis

inclined to both the reference planes-use change of position method

OR auxiliary method.

12 15%

IV

2 sheets

Sections and developments of solids:-Sections of simple solids* in

simple vertical positions with section plane perpendicular to one of

the reference planes True shapes of sections-use change of position

method OR auxiliary method. Developments of surfaces of these

solids.

10 15%


V

2 sheets

Isometric Projections:-Isometric projections and views of plane

figures, simple *& truncated simple solids* in simple potion including

sphere and hemisphere and their combinations. Box method OR co-

ordinate system method.

6 20%


34 | P a g e

Perspective projections:-Perspective projections of simple solids* by

visual ray method OR vanishing point method

VI

1 sheet

Introduction to Computer Aided Drafting - Preparation of

engineering drawings by using any software capable of drafting and

modeling. (For internal work assessment only, not for University

Examination)

Intersection of surfaces:-Intersection of prism in prism & cylinder in

cylinder- Axis bisecting at right angles only.

*Triangular, Square, Pentagonal and Hexagonal Prisms and Pyramids,

Cone and Cylinders

6 20%

END SEMESTER EXAM

draft course plan report for circulation

Documents

engineering mechanics

engineering graphics

civil engineering workshop

chemical engineering

basics of civil engineering

engineering physics

sustainable engineering

engineering chemistry