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2. BIJU PATNAIK UNIVERSITY OF TECHNOLOGY, ORISSA
ROURKELA
Course Structure & Syllabus for 1st year(2008-admission batch) B.Tech Programme
1st Semester
2nd Semester
Theory Contact Hours
Code Subject L-T-P Credit
BS1101 Mathematics-I 3- 1- 0 4
BS1102 Physics – I
Or 3- 0- 0 3
BS1103 Chemistry-I
BE2101 Basic Electronics
Or 3- 0- 0 3
BE2102 Basic Electrical Engineering
BE2103 Thermodynamics
Or 3- 0- 0 3
BE2104 Mechanics
HM3101 Communicative English 2- 0- 0 2

3. BE2105 Programming in ‘C’ 3- 0- 0 3
Theory Credits 18
Practical/ Sessional
BE7101 Engineering Drawing
Or 0- 0- 3 2
BE7102 Workshop Practice
BE7103 Physics Laboratory
Or 0- 0- 3 2
BE7104 Chemistry Laboratory
BE7105 Basic Electronics Laboratory
Or 0- 0- 3 2
BE7106 Basic Electrical Engg. Lab
BE7107 ‘C’ Programming Laboratory 0- 0- 3 2
HM7101 Communicative English Lab. 0- 0- 3 2
Practical/Sessional Credits 10
Theory Contact Hours
Code Subject L-T-P Credit
BS1104 Mathematics-II 3- 1- 0 4

4. BS1103 Chemistry-I
Or 3- 0- 0 3
BS1102 Physics – I
BE2102 Basic Electrical Engineering
Or 3- 0- 0 3
BE2101 Basic Electronics
BE2104 Mechanics
Or 3- 0- 0 3
BE2103 Thermodynamics
HM3102 Business Comm.in English 2- 0- 0 2
BE2106 Data Structure using ‘C’ 3- 0- 0 3
Theory Credits 18
Practical/ Sessional
BE7102 Workshop Practice
Or 0- 0- 3 2
BE7101 Engineering Drawing
BE7104 Chemistry Laboratory
Or 0- 0- 3 2
BE7103 Physics Laboratory
BE7106 Basic Electrical Engg. Lab
Or 0- 0- 3 2
BE7105 Basic Electronics Laboratory

5. HM7102 Business Communicative Lab. 0- 0- 3 2
BE7108 Data Structure using ‘C’ Lab 0- 0- 3 2
Practical/ Sessional Credits 10
TOTAL SEMESTER CREDITS 28
TOTAL SEMESTER CREDITS 28
TOTAL CUMULATIVE CREDITS 28
TOTAL CUMULATIVE CREDITS 28

6. BS1103 CHEMISTRY – I (3-0-0)
Module – I
(To develop basic concepts of quantum mechanics and its applications in bonding)
Structure & Bonding: Dual nature of matter, Schrodinger equation (need not be
derived), interpretation of wave
functions, molecular orbital theory of diatomic molecules, metallic bonding.
(No. of Lectures = 7)
Phase rule: Phase diagram of one & two component systems,H2O, S, Cd-Bi and Fe-C
systems.
(No. of Lectures = 5)
Solid State: Crystal systems, Bravais lattices, closed packed structures, ionic
solids, and crystal defects including
Schottky and Frenkel defects.
(No. of Lectures=4)
Module – II
(To develop basic concepts about the rates of reactions and catalysis)
1. Reaction Kinetics & Catalysis:
Rate law, Order & Molecularity, Determination of order of reaction, Kinetics of
Zero, 1st and 2nd order
reactions, Collision theory, theory of absolute reaction rates, Energy of
activation, Homogeneous &
Heterogeneous catalysis (a general idea)
(No. of Lectures= 7 )
2. Electrochemistry: Electrochemical cells, EMF, Measurement of EMF, Relation
between EMF & free
energy change of cell reactions, Electrode potentials and measurements with

7. reference to standard
hydrogen electrode, calomel electrodes, determination of pH, dry cells, storage
cells and fuel cells.
(No. of Lectures= 7)
Module – III
(Applications of thermodynamic principles to chemical systems)
1. Chemical thermodynamics: Thermo chemistry, Thermo-chemical calculations based on
Hess’s law and
Born-Haber cycle, second law of thermodynamics, Entropy.
2. The free energy concepts, applications to gases, Gibbs Helmholtz equation, free
energy change and
criterion of spontaneity and equilibrium of chemical reactions, chemical
equilibrium, Maxwell’s
relations.
(No of Lectures= 9)
Text Books:
1. Physical Chemistry by G.M. Barrow, 6th edition, Tata McGraw Hill, New Delhi.
2. Physical Chemistry by P.W. Atkins, 5th / 6th edition Oxford.
Reference Books:
1. Principles of Physical Chemistry by Puri, Sharma and Pathania.

8. 2. Physical Chemistry by Bahl and Tuli.
3. Engineering Chemistry by Jain and Jain (15th edition).
4. Physical Chemistry-Thomas Engel, Philip Reid by Pearson Education.
BE7104 Chemistry Laboratory (0-0-3)
(Any ten experiments may be done)
1. Determination of amount of sodium hydroxide and sodium carbonate in a mixture.
2. Determination of total hardness of water by EDTA method.
3. Estimation of calcium in limestone.
4. Determination of percentage of available chlorine in a sample of bleaching
powder.
5. Preparation of Phenolphthalein.
6. Preparation of Aspirin.
7. Preparation of buffer solution and determination of pH of a buffer solution.
8. Standardization of KMnO4 using sodium oxalate.
9. Determination of Ferrous iron in Mohr’s salt by potassium permanganate.
10. Determination of partition coefficients of iodine between benzene and water.
11. Determination of rate constant of acid catalysed hydrolysis reaction.
12. Determination of concentration of a coloured substance by spectrophotometer.
13. Determination of dissolved Oxygen in a sample of water.
14. Determination of Viscosity of a lubricating oil by Red wood viscometer.
15. Determination of Flash point of a given oil by Pensky_Marten’s flash point
approach.
BS1102 PHYSICS – I (1st year)
Module – I (15 hrs)
Unit- I
Oscillation and Waves
The aim of this unit is to familiarize the students with basic features of
different oscillatory systems waves in general. The topics included in this

9. unit should be treated qualitatively.
Lectures
6 hrs
(a)
(b)
(c)
Oscillatory systems: Simple harmonic oscillation, damped harmonic
oscillation, forced vibration, resonance, coupled oscillation.
Waves as periodic variation quantity in space and time, wave equation,
longitudinal and transverse waves, progressive and stationary waves,
examples of different types of waves.
Reflection and transmission of waves at boundary of two media.
Unit - 2
Interference
The principle of superposition of waves is extended to the interference of
light of waves. Some systems for production of observable interference
patterns are covered.
Lectures
4 hrs
(a)
Superposition of waves: Two beam superposition, Multiple-beam
superposition, coherent and incoherent superposition.
(b)
Two source interference pattern (Young’s double slit), Intensity distribution.

11. (c)
Newton’s rings: Determination of wavelength of light, refractive index of
liquid.
Unit - 3
Diffraction
Diffraction of light waves at some simple obstacles are to be covered
in this unit. Both Fresnel and Fraunhofer pattern are included.
Lectures
5 hrs
(a )
Huygen’s principle, Fresnel and Fraunhofer diffraction, zone plate.
(b)
Fraunhofer diffraction due to a single slit.
(c )
Plane transmission grating- diffraction spectra, determination of wave
length of light, dispersion.
Module : II ( 13 hour)
Unit- 4
Polarization

12. The unit covers elementary features of polarization of light waves.
Lectures
5 hrs
(a)
Polarization of transverse waves, plane, circular and elliptically
polarized light. Polarization by reflection, refraction and scattering.
(b)
Double refraction; Nicol prism, Quarter – wave plate, half – wave
plate- construction and use.
(c)
Production and analysis of circular and elliptically polarized light.
(d)
Optical rotation, sacharimeter-construction and use.
Unit – 5
Electromagnetism- Student will be familiarized with some basic
used in vector calculus prior to development of Maxwell’s
electromagnetic wave equations. No proof of theorems and laws
included in this unit expected- statement and interpretation should
sufficient.
Lectures
4 hrs
(a)

13. Vector calculus: gradient, divergence, curl of vector field, Gauss
divergence theorem, Stoke’s theorem, Green’s theorem.
(b)
Gauss’s law of electrostatics in free space and in a medium, electric
displacement( D) magnetic Induction (B) and magnetic Intensity (H),
Amperes circuital law, displacement current, Faraday’s law of
electromagnetic induction.
(c )
Maxwell’s electromagnetic equation in differential form and in integral
form.
Unit - 6
Electromagnetic waves: Some aspects of propagation of em waves
are to be covered. Electromagnetic energy density, poynting vector,
poynting theorem, vector potential and scalar potential,
electromagnetic wave equation for E and B, transverse nature and
speed of em waves in ionized media.
Lectures
4 hrs
Module III ( 8 hours)
Unit - 7
Quantum Physics : This unit deals with elementary concepts of
quantum physics formulation to deal with physical systems.

14. Lectures
4 hrs
(a)
Need for Quantum physics-Historical overviews, Particle aspects of
radiation-Black body radiation, photoelectric effect, Compton
scattering, pair production.( No derivation), Wave aspect of particles-
matter wave, de Broglie Hypothesis, Heisenberg Uncertainty
principles- Statement, Interpretation and example.

15. (b )
Basic features of Quantum mechanics- Transition from deterministic
to probabilistic, States of system- Wave function, probability density,
superposition principle, observables and operators, expectation
values. Schrodinger equation-Time dependent and time independent,
wave packets.
Unit – 8
Application of Quantum Mechanics- This unit deals with applications
of quantum Mechanics to specific problems solutions of one-
dimensional problems, free particles- continuous states, Potential
steps- Boundary conditions, reflection, transmission., Potential
Barrier-Tunneling, Infinite deep potential well-energy eigen values,
eigen functions.
Lectures
4 hrs
Text Books:
1. Physics-I for engineering degree students-B.B. Swain and P.K.Jena
2. Concepts in Engineering Physics-I Md. N. khan
Reference Books:
1. Engineering Physics- K.P.Mishra and P. Pattojoshi
2. Optics- A. K. Ghatak
3. Geometrical and Physical optics- P.K.Chakraborty
4. Electricity and Magnetism : E.M. Purecell
5. Introduction to Electrodynamics- David J. Griffiths
6. Concepts of Modern Physics – Arthur Beiser

16. 7. Relativity and Quantum Mechanics- P.K.Palanisamy
8. Quantum Mechanics- M.Das and P.K.Jena
BE7103 PHYSICS LABORATORY (0-0-3)
A Student is expected to perform ten experiments from the list given below.
1. Determination of Young’s modulus by Searle’s methods.
2. Determination of Rigidity modulus by static methods.
3. Determination of surface tension by capillary rise method.
4. Determination of acceleration due to gravity by Bar / Kater’s pendulum.
5. Determination of thermal conductivity by Lee’s method.
6. Determination of wave length of light of light by Newton’s rin apparatus.
7. Determination of grating element of a diffraction grating.
8. Plotting of characteristic curves of a PN junction diode.
9. Plotting of characteristic curves of BJT.
10. Varification of laws of verification of strings using sonometer.
11. Determination of wavelength of laser source by diffraction rating methods.
12. Study of Hall effect.

17. 13. Study of RC circuit.
14. Study of a power source- output imedence.
15. Study of a Photoemission.
BE2104 Mechanics (3-0-0)
Module I (13 Hours)
Concurrent forces on a plane – Composition and resolution of forces and equilibrium
of concurrent
coplanar forces, Method of projections, Methods of moment, Friction.
Parallel forces in a plane- Two parallel forces, General case of parallel forces,
Center of parallel forces
in a plane and center of gravity- centroids of composite plane figure and curves,
Distributed parallel
forces in a plane. General case of forces in a plane- composition of forces in a
plane and equilibrium of
forces in a plane.
Module II (13 Hours)
Plane trusses- method of joints and method of sections, Principle of virtual work –
equilibrium of ideal
systems.
Moments of Inertia- Plane figure with respect to an axis in its plane and
perpendicular to the plane-
parallel axis theorem, Moment of Inertia of material bodies.
Rectilinear Translation- Kinematics- Principles of Dynamics- D’Alemberts
Principles.
Module III (14 Hours)
Momentum and impulse, Work and Energy- impact

18. Curvilinear translation- Kinematics- equation of motion- projectile- D’Alemberts
Principle in curvilinear
motion, Moment of momentum, Work- Energy in curvilinear motion.
Kinetics of Rotation of rigid body
Text Books:
1. Engineering Mechanics by S Timoshenko, D.H Young and J.V.Rao, Revised 4th
edition (Special
Indian Edition), McGraw Hill.
Reference Books:
1. Fundamental of Engineering Mechanics(2nd Edition) by S. Rajesekharan & G.Sankara
Subramanium, Vikash Publishing House Pvt. Ltd.
2. Engineering Mechanics by Shames and Rao, Pearson Education.
3. Engineering Mechanics, Statics and Dynamics by Boresi and Schmidt, Thomson.
4. Engineering Mechanics by I.S.Gunjal, Laxmi publications.
5. Engineering Mechanics by K.L.Kumar, Tata McGraw Hill
6. Engineering Mechanics by Kumaravelan, Scitech

19. BE2103 Thermodynamics (3-0-0)
Module – I (9Hours)
1. Basic concepts and definition: Scope of Thermodynamics, Macroscopic and
Microscopic approaches;
Definition of Fixed mass (closed systems) and Control volume(open system),
Properties (extensive and
Intensive), State and its representation on a property diagram, Process and its
representation, Cyclic
process (or cycle) and its representation, Characteristics of properties (point and
path
function);Reversible and Irreversible processes; Thermal, mechanical and Chemical
equilibrium,
Thermodynamic equilibrium, Zeroth
Law of Thermodynamics and temperature, Measurement of temperature and calibration
of
thermometers, the ideal gas temperature scale, Measurement of pressure, Bourdon
pressure gage and
manometers, gage and absolute pressure.
2. Ideal gages and their P-V-T relations, Gas mixtures
3. Energy Transfer: Work Transfer (definition and calculation), Different modes of
work, Displacement
Work for various process, Heat Transfer; Modes of heat transfer, Basic laws in
conduction, convection
and radiation, combined modes of heat transfer with examples.
Module-II(13 hours)
4. First Law of Thermodynamics:
i Formal statement (using cyclic processes), First law for processes of fixed
masses(closed
systems) and introduction of internal energy as a thermodynamics property,
Introduction of enthalpy
as a thermodynamic property; Definition of specific heats and their use in
calculation of internal
energy and enthalpy with emphasis on ideal gages.
ii Application of First Law to control volumes; Nozzle, Diffuser, Compressor,
Turbine, Throttling
device, Heat Exchanger.(only steady flow need be considered)

20. 5. Second Law of Thermodynamics: Kelvin- Planck and Clausius statements of Second
Law,
Reversible and irreversible engines and their efficiency, Entropy concepts and the
principle of
entropy increase.
6.
Module-III(13 hours)
7. Properties of pure substances:
p-v, p-T, T-S, h-S diagram for steam, different types of steam, Introduction to
steam
tables with respect to specific volume, pressure, temperature, enthalpy and entropy
8. Application of thermodynamics:
Air compressors, steam power plant, Refrigerators and Heat pump, I.C. Engines
(Brief
Description of different components of above mentioned systems and working
principles with
Schematic diagram only)
Text Books:
1. Engineering Thermodynamics by P.K.Nag, Publisher: TMH
2. Basic Engineering Thermodynamics by Rayner Joel, Pearson Education

21. Reference Books:
1. Engineering Thermodynamics by Van Wylen and Sontang, John Wiley
2. Engineering Thermodynamics by M.Achuthan, Publisher: PHI
3. Applied Thermodynamics by Eastop and McConkey, Publisher: Pearson
4. Fundamental of Engineering Thermodynamics by E. Rathakrishnan, publisher. PHI
5. Engineering Thermodynamics by Russel and Adebiyi, publisher, Oxford
6. Steam Tables in SI Units by Ramalingam, Scitech.
BE7101 Engineering Drawing (0-0-3)
Sheet Lay-out & Sketching, Line Drawing, Lettering & Dimensioning; Concept of
Orthographic
Projection, First-angle Projection, Projections of Points, Projection of straight
line, Projection of planes,
Projection of Solids, Intersection of surfaces, Development of surfaces, Isometric
Projection, Sectional
Views of solids, Full section, Introduction to computer-Aided Drafting.
Text Books:
1. Engineering Drawing by N.D.Bhatt & V.M.Panchal, Charotar publishing House, Anand
2. Engineering Drawing with an Introduction to AutoCAD by Dhanjay A. Johle, Tata
McGraw Hill
Reference Books:
1. Machine Drawing by Junarkar, Pearson Education.
2. Machine Drawing (Includes AutoCAD) by Ajeet Singh, Tata McGraw Hill.
3. Machine Drawing with AutoCAD by Pohit and Ghosh, Pearson Education.
4. Text Book on Engineering Drawing by Narayana / Kannaiah, Scitech.
5. Engineering Drawing by Shah and Rana, Pearson Education
6. Engineering Drawing and Graphics using AutoCAD by T.Jeyapoovan, Vikas Publishing
7. Engineering Drawing and Graphics by K.Venugopal, New Age International.

22. BE7102 Workshop Practice (0-0-3)
Fitting Practice: Use of hand tools in fitting, preparing a male and female joint
of M.S. or making a paper
weight of M.S.
Welding Practice : Gas welding & Electric Arc welding Practice.
A joint such as a Lap joint, a T-joint or a Butt joint is to be prepared or to make
furniture.
Machining:
(i) Stepped cylindrical Turning of a job and Thread-cutting in lathe.
(ii) Shaping
(iii) Milling

23. Reference:
1. Elements of Workshop Technology, Vol. I and II by Hajra choudhary, Khanna
Publishers
2. Workshop Technology by WAJ Chapman, Viva Books
3. Workshop Manual by Kannaiah/ Narayana, Scitech
BE2101 - Basic Electronics
(3 – 0 – 0; Credits: 3; Contact Hours: 3)
Theory
MODULE – I (11 hours)
1. Introduction to Electronics: Signals, Frequency spectrum of signals, Analog and
digital signals, Amplifiers,
Digital logic inverters. (1.1 to 1.4 and 1.7 of Sedra and Smith) (1 Lectures)
2. The Operational Amplifier (Op-Amp): The ideal Op-Amp, Inverting and non-
inverting configurations,
Difference amplifier, CMRR, Application of Op-Amp (Instrumentation amplifier,
Summing amplifier,
Integrator and Differentiator). (2.1 to 2.4 and 2.8 of Sedra and Smith) (3
Lectures)
3. Semiconductor Diodes: Introduction, Physical operation of p-n junction diodes,
Characteristics of p-n
junction diodes, Zener diode, Rectifier circuits (half-wave, full-wave, bridge and
peak rectifiers), Diode
clipper and clamper circuits, Light emitting diodes. (3.7, 3.2, 3.4 to 3.6 and 3.8
of Sedra and Smith) (4
Lectures)
4. Bipolar Junction Transistors (BJTs): Simplified structure and physical operation
of n-p-n and p-n-p
transistors in the active region, Current-voltage characteristics of BJT, BJT as an
amplifier and as a switch.
(5.1 to 5.3 of Sedra and Smith) (3 Lectures)
MODULE – II (11 hours)
5. Bipolar Junction Transistors (BJTs): BJT Circuits at DC, Biasing in BJT
amplifier circuits, Small Signal
Operation of BJT: Simplified hybrid-p model and its application to single stage BJT
amplifiers (Common-
Emitter, Common-Base and Common-Collector configurations). (5.4 to 5.7 of Sedra and
Smith) (4
Lectures)
6. Feedback Amplifiers and Oscillators: General feedback structure, Properties and
advantages of negative

24. feedback, Basic principles of sinusoidal oscillators, The Barkhausen criterion, Op-
Amp Oscillator circuits
(Wien-Bridge oscillator, RC phase-shift oscillator and Crystal oscillator). (8.1,
8.2 and 13.1 to 13.3 of Sedra
and Smith) (4 Lectures)
7. Electronic Instruments: Basic principle of Oscilloscope, Function of the sweep
generator, Block diagrams
of oscilloscope, Simple CRO, Measurement of frequency and phase by Lissajous
method, Application of
oscilloscope for measurement of voltage, period and frequency, Block diagram of
standard signal generator,
AF sine and square wave generator, and Function generator.( 7.2 to 7.5, 7.20,7.26,
7.30, 8.5, 8.7 and 8.8 of
Kalsi) (3 Lectures)

25. MODULE – III (10 hours)
Digital Electronic Principles: Introduction, Binary digits, Logic levels and
Digital waveforms, Introduction to basic
logic operation, Number system, Decimal numbers, Binary numbers, Decimal-to-Binary
conversion, Simple binary
arithmetic. (1.2, 1.3 and 2.2 to 2.4 of Floyd and Jain) (2 Lectures)
8. Logic Gates and Boolean Algebra: The inverter, The AND, OR, NAND NOR, Exclusive-
OR and
Exclusive-NOR gate, Boolean operations and expressions, Laws and Rules of Boolean
algebra,
DeMorgan’s theorem, Boolean analysis of logic circuits, Standard forms of Boolean
expressions, Boolean
expression and truth table. (3.1 to 3.6 , 4.1 to 4.7 of Floyd and Jain) (4
Lectures)
9. Combinational Logic and Their Functions: Basic combinational logic circuits,
Implementation of
combinational logic, The universal properties of NAND and NOR gates, Basic adders,
Multiplexers and
Demultiplexers., Elementary treatment of Latches, Basic concepts of Memory (RAMs)
(5.1 to 5.4, 6.2, 6.4,
6.8, 6.9, 7.1 and 10.2 of Floyd and Jain) (4 Lectures)
Text Books:
1. Microelectronic Circuits (Fifth Edition), Adel S. Sedra and Kenneth C. Smith,
Oxford University Press,
YMCA Library Building Jai Singh Road, New Delhi – 110 001.
2. Digital Fundamentals (Eighth Edition), Thomas L. Floyd and R.P. Jain, Pearson
Education, 482 FIE,
Patparganj, Delhi – 110 092.
3. Electronic Instrumentation, H.S. Kalsi, Tata McGraw-Hill Publishing Company
Limited, New Delhi.
Reference Books:
4. Electronic Devices (Seventh Edition), Thomas L. Floyd, Pearson Education, 482
FIE, Patparganj, Delhi –
110 092 (Selected Portions).
5. Electronic Devices and Circuit Theory (Ninth Edition), Robert L. Boylestad and
Louis Nashelsky, Pearson
Education, 482 FIE, Patparganj, Delhi – 110 092.
6. Electronics Principles (7th Edition), Albert Malvono and David J. Bates, Tata
McGraw-Hill Publishing
Company Limited, New Delhi.
BE7105 - Basic Electronics Laboratory

26. (0 – 0 – 3; Credits: 2; Contact Hours: 3)
(At least 8 experiments including experiments 1 to 7 and any one from experiments 8
to 10)
1. Familiarization of electronic components and devices (Testing of semiconductor
diodes and transistors
using digital multimeter)
2. Study and use of Oscilloscope, signal generator to view waveforms and measure
amplitude and frequency
of a given waveform.

27. 3. V-I characteristics of semiconductor diode and determining its DC and AC
resistance.
4. Studies on half-wave and full-wave rectifier circuits without and with capacitor
filter; recording of the
waveforms and measurement of average and rms values of the rectifier output.
5. V-I characteristic of an n-p-n or p-n-p transistor, DC biasing the transistor in
common-emitter configuration
and determination of its operating point (i.e., various voltages and currents).
6. Studies on Op-Amp applications (Inverting, non-inverting integrating and
differentiating configurations);
recording of the input-output waveforms.
7. Studies on Logic gates (Truth table verification of various gates).
8. Gain-frequency response studies of a BJT common-emitter RC coupled amplifier.
9. Studies and experiments using MUX-DEMUX ICs.
10. Study on CMOS logic inverter.
BS1101 - MATHEMATICS-I (3-1-0)
(1st Sem)
Module -1 (15 Hours)
Differential Equation: First order differential equations, Separable equation,
exact differential equation, Linear
differential equation, Bernoulli’s equation and application to Electrical circuits.
Linear differential equation of
second and higher order, Homogeneous equation with constant co-efficient, Euler-
Cauchy equations, Solution by
undetermined co-effficient, Solutions by variation of parameters, Modeling of
electric circuits
Module-II (15Hours )
Calculus: Asymptote, Curvature
Series solution of differential equations, Power series method, Legendres equation
and Lagenders polynomials,
Bessels equation , Bessels function and its application
Module-III (15 Hours )

28. Linear algebra, Matrices, Vectors, Determinants, System of linear equations, eigen
values and eigen vectors,
Symmetric and skew-symmetric matrices, Orthogonal matrices, Complex matrices,
Hermitian and skew-hermitian
matrices, Unitary matrices and similarity of matrices.
Text Books :
1. Differential Calculus by Santi Narayan and Mittal, Chapters 14, 15
Publisher: S. Chand
2. Advanced Engineering Mathematics by E. Kreyszig

29. Publisher: John Willey & Sons Inc- 8th Edition
Chapter 1( 1.1 to 1.6),
Chapter 2(2.1 to 2.12)
Chapter 4( 4.1 to 4.3, 4.5, 4.6
Chapter 6( 6.1 to 6.6)
Chapter 7( 7.1 to 7.5)
Reference Books:
1. Higher Engineering Mathematics by B. V. Ramana
Publisher: TMH
2. Mathematical Methods by Potter Goldberg
Publisher: PHI
BS1104 MATHEMATICS-II (3-1-0)
(2nd Sem)
Module – I (15 Hours )
Laplace transformation and its use in getting solution to differential equations,
Convolution , Integral
equations
Fourier series, Fourier expansion of functions of any period, Even and odd
functions, Half range
expansion
Module – II (15 Hours )
Fourier transform and Fourier Integral, Gamma, Beta functions, error function

30. Vector differential calculus: vector and scalar functions and fields, Derivatives,
Curves, tangents and arc
length, gradient, divergence, curl
Module – III (15 Hours )
Vector integral calculus: Line Integrals, Green Theorem, Surface integrals, Gauss
theorem and Stokes
theorem
Text Book
1. Advanced Engineering Mathematics by E. Kreyszig
Publisher: John Willey & Sons Inc- 8th Edition
Chapter 5( 5.1 to 5.7),
Chapter 8(8.4, 8.5, 8.9 to 8.11)
Chapter 9( 9.1 to 9.9)
Chapter 10( 10.1 to 10.4, 10.8 to 10.10)
Reference Books:
3. Higher Engineering Mathematics by B. V. Ramana
Publisher: TMH
4. Mathematical Methods by Potter and Goldberg
Publisher: PHI

31. HM 3101 English Communication Skills (2-0-0)
(Theory)
Module-I The elements of communication ( 6 hours )
1.1 the importance of communication through English at the present time
1.2 the process of communication and factors that influence communication :
sender, receiver, channel, code, topic, message, context, feedback, ‘noise’,
filters and barriers
1.3 the importance of audience and purpose
1.4 the information gap principle : given and new information ; information
overload
1.5 verbal and non-verbal communication : body language
1.6 comparing general communication and business communication
Module-II The sounds of English ( 14 hours )
2.1 vowels, diphthongs, consonants, consonant clusters
2.2 the International Phonetic Alphabet (IPA) ; phonemic transcription
2.3 problem sounds
2.4 syllable division and word stress
2.5 sentence rhythm and weak forms
2.6 contrastive stress in sentences to highlight different words
2.7 intonation : falling, rising and falling-rising tunes
2.8 varieties of Spoken English : Standard Indian, American and British

32. (Note : This unit should be taught in a simple, non-technical manner, avoiding
technical terms as far
as possible. )
Module-III Review of English grammar (10 hours )
3.1 stative and dynamic verbs
3.2 the auxiliary system ; finite and non-finite verbs
3.3 time, tense and aspect
3.4 voice: active and passive
3.5 modality
3.7 negation
3.8 Interrogation ; reported and tag questions
3.9 conditionals
3.10 concord
3.11 Phrasal verbs
(Note The teaching of grammar should be treated as a diagnostic and remedial
activity and integrated
with communication practice. The areas of grammar in which errors are common should
receive special
attention when selecting items for review. Teaching need not be confined to the
topics listed above.))
Books recommended:
1. An Introduction to Professional English and Soft Skills by B.K.Das et al.,
Cambridge University Press.
(Facilitated by BPUT).

33. HM 7101 Communicative Practice Lab -I (0-0-3)
(1ST Sem)
Lab sessions will be devoted to practice activities based on all three modules of
theory.
a. phonemic transcription 5 hours
Students will be trained to find out the correct pronunciation of words with the
help of a dictionary, to
enable them to monitor and correct their own pronunciation.
i transcription of words and short sentences in normal English orthography
(writing)
into their IPA equivalents ;
ii transcription of words presented orally ;
iii conversion of words presented through IPA symbols into normal orthography
iv syllable division and stress marking (in words presented in IPA form)
b. Listening 10 hours
i listening with a focus on pronunciation (ear-training) : segmental sounds,
stress,
weak forms, intonation
Students should be exposed, if possible, to the following varieties of English
during listening practice :
Standard Indian, British and American.
c. Speaking 15 hours

34. i pronunciation practice (for accent neutralization), particularly of problem
sounds, in
isolated words as well as sentences
ii practising word stress, rhythm in sentences, weak forms, intonation
ii reading aloud of dialogues, poems, excerpts from plays, speeches etc. for
practice
in pronunciation
d. Grammar and usage 12 hours
The focus will be on the elimination of common errors. Some writing activities
(e.g. writing of short
paragraphs on assigned topics) can be used to identify these errors.
Project Work
Students will be required to produce and submit by the end of Semester 1 a 350-500
word project report
on a topic of their choice. The project should involve data collection, analysis
and reporting. Ten marks
(out of the 100 marks allocated for the Lab test ) will be set apart for the
project.

35. HM 3102 Business Communication (2-0-0)
(2nd Sem.)
Module - I The Elements of Business Communication (10 hours)
1.1 patterns of communication in the business world: upward, downward,
horizontal, grapevine etc
1.2 internal and external channels of communication; formal and informal
channels.
1.3 Introduction to cross-cultural communication.
1.4 avoiding gender, racial and other forms of bias in communication
1.5 common forms of oral and written communication in the business world:
Oral presentations, interviews and group discussions
Memos, reports, summaries and abstracts, e-mails
Module-II Reading and writing (15 hours)
2.1 the importance of developing reading skills
2.2 the sub-skills of reading :
a. understanding the main idea and supporting details
b. reading between the lines : inferential reading
c. understanding the writer’s point of view
d. making predictions
e. guessing the meanings of unfamiliar words
f. skimming and scanning
g. note-making

36. 2.3 the importance of writing skills
2.4 the differences between speech and writing
2.5 the qualities of effective writing : coherence, cohesion, logical structuring
and organization,
clarity of language, stylistic variation etc.
2.6 the writing process : pre-writing, drafting, re-writing
2.7
Module -III Soft skill development (5 hours)
4.1 soft skills: becoming a good leader and team-player
4.2 inter-relating soft skills and communication skills
Books recommended:
1 Business Communication Today by Bovee et al ( Pearson)
2 Business Communication by Meenakshi Raman and Prakash Singh (Oxford)
3 Crash Course in Personal Development by Brian Clegg ( Kogan Page)
4 Activities for Developing Emotional Intelligence by Adele B.Lynn (HRD Press)
5 Lateral Thinking by Edward De Bono (Penguin)

37. HM 7102 Communicative Practice Lab -II ( 0-0-3 )
(2nd Sem)
a. Communication Practice 30 hours
i Speaking : oral communication in social and 10 hours
work-related situations, e.g.:
Greeting an acquaintance/ friend, introducing oneself, introducing a friend to
another friend, breaking off a conversation politely, leave-taking;
making and responding to inquiries; expressing an opinion;
expressing agreement/ disagreement, contradicting/ refuting an argument;
expressing pleasure, sorrow, regret, anger, surprise, wonder, admiration,
disappointment etc.
Narrating or reporting an event;
Describing people, objects, places, processes etc.
Ordering / directing someone to do something
Making requests; accepting / refusing a request
Expressing gratitude; responding to expressions of gratitude
Asking for or offering help; responding to a request for help
Asking for directions (e.g. how to reach a place, how to operate a device etc.)
and
giving directions
asking for and granting/ refusing permission
prohibiting someone from doing something
suggesting, advising, persuading, dissuading, making a proposal
praising, complimenting, felicitating
expressing sympathy (e.g. condolence etc.)
Complaining, criticizing, reprimanding
ii Reading 10 hours

38. Students will be given practice in reading and comprehending 6-8 simple passages of
100-300 words
each, on topics of general as well as professional interest. The texts will be
supported by suitable
exercises designed to foster comprehension skills and vocabulary enrichment,
together with study skills
(note making) and reference skills (using a dictionary).
Practice will be provided in the important sub-skills of reading which are
introduced in
Module 2 of the theory component.
iii Writing 10 hours
Writing short paragraphs on given topics or topics of one’s choice; social and
business letters; reports; applications ; resumes ; summaries
The principles of ‘Process Writing’ should be used to teach writing skills.
i pre-writing : generating ideas, brain-storming, idea mapping, outlining
ii writing : generating a first draft ; reviewing, redrafting, editing
iii post-writing : making a presentation ; discussion and feedback, preparing
the final draft
b. Soft skills practice 10 hours
Activities designed to highlight leadership and ‘team’ skills ; Group discussion

39. BE 2102 - BASIC ELECTRICAL ENGINEERING (3-0-0)
This is a foundation course aimed at explaining the basic and underlying principles
of Electrical
circuits, Electro-mechanical devices used for Generation, Transmission,
Distribution, Utilization and
Measurement of electric energy.
MODULE-I
(12 Lectures)
1. Introduction: Ideal and Practical Sources, Source Conversion, Induced EMF,
Energy Stored in
Inductor & Capacitor, Electric Power. (1)
2. DC Networks: Laws and Theorems applicable to DC networks (KCL & KVL, Node
voltage &
Mesh current analysis, Delta-Star & Star-Delta conversion, Superposition principle,
Thevenin &
Norton theorem), Transients in R-L and R-C circuits with DC excitation. (4)
3. Magnetic Circuits: Introduction to Electromagnetism, B-H curve, Permeability,
Reluctance,
Solution of simple magnetic circuits, Hysteresis and Eddy current loss. (3)
4. D.C. Machines: Construction, Classification and Principle of operation of DC
machines, EMF
equation of DC generator, Speed Equation of DC Motor. (3)
MODULE-II
(12 Lectures)
5. Single-Phase AC Circuits: Single-phase EMF Generation, Waveform and Phasor
representation, Average and Effective value of sinusoids, Peak factor & Form
factor, Complex
Impedance and Power using j-operator, Power factor. (5)
6. Three-Phase AC Circuits: Comparison between single-phase and three-phase
systems,
Three-phase EMF Generation, Line and Phase quantities in star and delta networks,
Power
and its measurement in three-phase balanced circuits. (3)
7. Single-Phase Transformers: Construction and principle of operation, EMF
Equation,
Transformation ratio, Practical and Ideal transformers, Transformer losses, Brief
idea on
transformer phasor diagram and transformer rating. (3)

40. MODULE-III
(12 Lectures)
8. Induction Motors: Introduction to Three-phase and Single-phase Induction Motors,
Concept of
Slip, Slip-Torque characteristics (no derivations). (2)
9. Measuring Instruments: Introduction, PMMC Ammeters and Voltmeters with extension
of
range, Moving-Iron Ammeters and Voltmeters, Study of Digital Voltmeters and Multi-
meters, Dynamometer type Wattmeter, Energy meter. (6)
10. Power Systems: Brief idea about various generating plants (Thermal, Hydel, and
Nuclear),
Transmission, Distribution and Utilization of Electric Energy. (3)
Text Books:
1. Prasanta Kumar Satpathy, “Basic Electrical Engineering”, Oxford University Press
(Printed in India), First Published-2008, Second Impression-2008.
Reference Books:
2. Hughes, “Electrical & Electronic Technology”, Ninth Edition (Revised by J Hiley,
K
Brown, and I Smith), Pearson Education, First Impression-2007.
3. Nagsarkar & Sukhija, “Basic Electrical Engineering”, Oxford University Press
(Printed in
India), First Published-2005, Third Impression-2006..
4. Rajendra Prasad, “Fundamentals of Electrical Engineering”, Prentice-Hall of
India, 2nd
Printing-2006.

41. BE 7106 - BASIC ELECTRICAL ENGINEERING LABORATORY (3-1-0)
Select any 8 experiments from the list of 10 experiments :
1. Connection and measurement of power consumption of a fluorescent lamp.
2. Measurement of armature and field resistances of a DC compound machine.
3. Starting and speed control of a DC shunt motor by (a) field flux control method,
and (b)
armature voltage control method.
4. V-I characteristics of incandescent lamps and time-fusing current
characteristics of a
fuse.
5. Connection and testing of a single-phase energy meter.
6. Starting of three-phase induction motor by star-delta starter.
7. Determination of open circuit characteristics (OCC) of DC shunt generator.
8. Calculation of current, voltage and power in series R-L-C circuit excited by
single-phase
AC supply and calculation of power factor.
9. Calculation of no load losses of a single-phase transformer.
10. Study of single-phase induction motors/ fan motors.

42. BE 2105 PROGRAMMING IN ‘C’ (3-0-0)
Module – I [12 Hours]
Algorithm, flowchart, Structured Programming Approach, structure of C program
(header files, C pre-
processor, standard library functions, etc.),identifiers, basic data types and
sizes, Constants, variables,
arithmetic, relational and logical operators, increment and decrement operators,
conditional operator, bit-
wise operators, assignment operators, expressions, type conversions, conditional
expressions,
precedence and order of evaluation. Input-output statements, statements and blocks,
if and switch
statements, loops:-while, do-while and for statements, break, continue, goto,
programming examples.
Module – II [12 Hours]
Designing structured programs: - Functions, parameter passing, storage classes-
extern, auto, register,
static, scope rules, user defined functions, recursive functions. Arrays- concepts,
declaration, definition,
accessing elements, and functions, two-dimensional and multi-dimensional arrays,
applications of
arrays. pointers- concepts, initialization of pointer variables, pointers and
function arguments, address
arithmetic, Character pointers and functions, pointers to pointers, pointers and
multidimensional arrays,
dynamic memory management functions, command line arguments,
Module – III [12 Hours]
Derived types- structures- declaration, definition and initialization of
structures, accessing structures,
nested structures, arrays of structures, structures and functions, pointers to
structures, self referential
structures, unions, typedef, bit fields, C program examples. Input and output –
concept of a file, text files
and binary files, streams, standard I/O, Formatted I/O, file I/O operations, error
handling, C program
examples.

43. Text Books:
1. Balagurusamy : “C Programming” Tata McGraw-Hill
2. P. Dey & M. Ghosh, “Computer Fundamental & Programming in C”- Oxford University
Press
3. Deitel -“C How to programme” PHI publication/ Pearson Publication
Reference Books:
1. Y. Kanitkar – “Let us C” BPB Publisher
2. H. Schildt – “C the complete Reference” McGraw-Hill
3. Schaum Series- “C Programming” - Gotterfried

44. BE7107 – ‘C’ PROGRAMMING LAB (0-0-3)
( Minimum 10 programs to be done covering 8 Experiments)
Experiment No. 1
a) Write a C program to find the sum of individual digits of a positive integer.
b) A Fibonacci sequence is defined as follows: the first and second terms in the
sequence are 0 and 1.
Subsequent terms are found by adding the preceding two terms in the sequence. Write
a C program to
generate the first n terms of the sequence.
c) Write a C program to generate all the prime numbers between 1 and n, where n is
a value supplied
by the user.
Experiment No. 2
a) Write a C program to calculate the following Sum:
Sum=1-x2/2! +x4/4!-x6/6!+x8/8!-x10/10!
b) Write a C program to find the roots of a quadratic equation.
Experiment No. 3
a) Write C programs that use both recursive and non-recursive functions
i) To find the factorial of a given integer.
ii) To find the GCD (greatest common divisor) of two given integers.
iii) To solve Towers of Hanoi problem.
Experiment No. 4
a) Write a C program to find both the larges and smallest number in a list of
integers.
b) Write a C program that uses functions to perform the following:
i) Addition of Two Matrices

45. ii) Multiplication of Two Matrices
Experiment No. 5
a) Write a C program that uses functions to perform the following operations:
i) To insert a sub-string in to given main string from a given position.
ii) To delete n Characters from a given position in a given string.
b) Write a C program to determine if the given string is a palindrome or not
Experiment No. 6
a) Write a C program to construct a pyramid of numbers.
b) Write a C program to count the lines, words and characters in a given text.
Experiment No.7
a) Write a C program that uses functions to perform the following operations:
i) Reading a complex number
ii) Writing a complex number
iii) Addition of two complex numbers
iv) Multiplication of two complex numbers
(Note: represent complex number using a structure.)

46. Experiment No. 8
a) Write a C program which copies one file to another.
b) Write a C program to reverse the first n characters in a file.
(Note: The file name and n are specified on the command line.)
Book:- PVN. Varalakshmi, Project Using C Scitech Publisher
BE 2106 DATA STRUCTURE (3-0-0)
Module – I
[12 hours]
Introduction to data structures: storage structure for arrays, sparse matrices,
Stacks and Queues:
representation and application. Linked lists: Single linked lists, linked list
representation of stacks and
Queues. Operations on polynomials, Double linked list, circular list.
Module – II
[12 Hours]
Dynamic storage management-garbage collection and compaction, infix to post fix
conversion, postfix
expression evaluation. Trees: Tree terminology, Binary tree, Binary search tree,
General tree, B+ tree,
AVL Tree, Complete Binary Tree representation, Tree traversals, operation on Binary
tree-expression
Manipulation.
Module –III

47. [12 Hours]
Graphs: Graph terminology, Representation of graphs, path matrix, BFS (breadth
first search), DFS
(depth first search), topological sorting, Warshall’s algorithm (shortest path
algorithm.) Sorting and
Searching techniques – Bubble sort, selection sort, Insertion sort, Quick sort,
merge sort, Heap sort,
Radix sort. Linear and binary search methods, Hashing techniques and hash
functions.
Text Books:
1. Gilberg and Forouzan: “Data Structure- A Pseudo code approach with C” by Thomson
publication
2. “Data structure in C” by Tanenbaum, PHI publication / Pearson publication.
3. Pai: ”Data Structures & Algorithms; Concepts, Techniques & Algorithms ”Tata
McGraw Hill.
Reference Books:
1. “Fundamentals of data structure in C” Horowitz, Sahani & Freed, Computer Science
Press.
2. “Fundamental of Data Structure” ( Schaums Series) Tata-McGraw-Hill.

48. BE 7108 DATA STRUCTURE LAB (0-0-3)
(Minimum 10 experiments to be done)
Experiment No.1
Write a C program to perform matrix multiplication using array.
Experiment No.2
(a) Write a C program to create a stack using an array and perform
(i) push operation (ii) pop operation
(b) Write a C program to create a queue and perform
i) Push ii) pop iii) Traversal
Experiment No. 3
Write a C program that uses Stack operations to perform the following:
i) Converting infix expression into postfix expression
ii) Evaluating the postfix expression
Experiment No. 4
Write a C program that uses functions to perform the following operations on
Single linked list:
i) Creation ii) Insertion iii) Deletion iv) Traversal in both ways
Experiment No. 5
Write a C program that uses functions to perform the following operations on
Double linked list:

49. i) Creation ii) Insertion iii) Deletion
Experiment No. 6
Write a C program that uses functions to perform the following operations on
Binary Tree:
i) Creation ii) Insertion iii) Deletion
Experiment No. 7
Write C programs that use both recursive and non recursive functions to perform
the Linear search
operation for a Key value in a given list of integers:
i) Linear search
Experiment No. 8
Write C program that use both recursive and non recursive functions to perform the
Binary search
operation for a Key value in a given list of integers:
Experiment No.9
Write a C program that implement Bubble Sort method to sort a given list of
integers in descending
order.
Experiment No.10
Write a C program that implement Quick Sort method to sort a given list of
integers in ascending order:
Book:- “Data structure using C” by Sudipta Mukherjee, TMH Publication