SYLLABUS

     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.

Module – II

(No. of Lectures=4)

(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 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.

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.

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 unit should be treated qualitatively.

Lectures

Hours

(a) (b)

Oscillatory systems: Simple harmonic oscillation, damped harmonic oscillation, forced vibration, resonance, coupled oscillation.

Waves as periodic variation quantity in space and time, wave equation, Reflection and transmission of waves at boundary of two media.

3 hrs

3 hrs

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.

(a)         Superposition  of   waves:   Two   beam   superposition,  Multiple-beam  superposition, coherent and incoherent superposition.

(b)         Two  source  interference  pattern,  Intensity  distribution,  Biprism,  Determination  of wavelength of light. Newton’s rings: Determination of wavelength of light, refractive index of liquid.

2 hrs

2hrs

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.

(a )      Huygen’s principle, Fresnel and Fraunhofer diffraction, zone plate.                            2 hrs

(b)         Fraunhofer diffraction due to a single slit, Plane transmission grating- diffraction spectra, determination of wave length of light.                                                              3hrs

Module : II                                ( 11 hour)

Unit- 4  Polarization

The unit covers elementary features of polarization of light waves.

(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, Optical rotation

(Only concepts)

2 hrs

2 hrs

1 hrs

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.

(a)        Vector calculus: gradient of scalar field, divergence, curl of vector field (Only Physical significance) Gauss divergence theorem, Stoke’s theorem, Green’s theorem (Only Statements)

(b)        Gauss’s law of electrostatics in free space and in a medium(Only statements) electric displacement( D)magnetic Induction (B),Amperes circuital law (Only statements),                           displacement    current,    Faraday’s    law    of    electromagnetic induction(Only statements).

2 hrs

2 hrs

(c )

Maxwell’s electromagnetic equation in differential form and in integral form(Only statements). Electromagnetic energy density, poynting vector, poynting theorem, vector potential and scalar potential, electromagnetic wave equation for E and B, transverse nature of EM waves.     4-2

2 hrs

Module III                                   ( 10 hours)

Unit - 6 Quantum Physics : This unit deals with elementary concepts of quantum physics formulation to deal with physical systems.

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

(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.

3 hrs

4 hrs

Unit – 7 Application of Quantum Mechanics- This unit deals with applications of quantum Mechanics to specific one-dimensional problems (Sketch, Schrodinger equation for different regions, Boundary conditions, final expressions and physical interpretations only,  no derivations).

Free particles- continuous states, Potential steps- Reflections, transmissions, Potential Barrier-Tunneling, Infinite deep potential well-energy eigen values, eigen functions.

3 hrs

Text Books :

1.  Engineering Physics by D.R. Joshi, Mc Graw Hill

2.  Engineering Physics by H.K. Malik and A.K. Singh, Mc Graw Hill.

Reference Book:

1.  Quantum Mechanics by Powel & Craseman.

2.  Optics- A. K. Ghatak

3.  Electricity & Magnetism : E.M. Purecell

4.  Introduction to Electrodynamics- David J. Griffiths, PHI Publication

5.  Concepts of Modern Physics – Arthur Beiser.

6.  Engineering Physics- K.P.Mishra and P. Pattojoshi, Scitech Pub.

7.  Concepts in Engineering Physics-I  Md. N. khan, Alok Publication.

8.  Physics-I for engineering degree students-B.B. Swain and P.K.Jena.

9.  An Introduction to Machanics by D.Klippner & R. Kolenkow, TMH

 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.

(a)        Vector calculus: gradient of scalar field, divergence, curl of vector field (Only Physical significance) Gauss divergence theorem, Stoke’s theorem, Green’s theorem (Only Statements)

(b)        Gauss’s law of electrostatics in free space and in a medium(Only statements) electric displacement( D)magnetic Induction (B),Amperes circuital law (Only statements),                           displacement    current,    Faraday’s    law    of    electromagnetic induction(Only statements).

2 hrs

2 hrs

(c )

Maxwell’s electromagnetic equation in differential form and in integral form(Only statements). Electromagnetic energy density, poynting vector, poynting theorem, vector potential and scalar potential, electromagnetic wave equation for E and B, transverse nature of EM waves.     4-2

2 hrs

Module III                                   ( 10 hours)

Unit - 6 Quantum Physics : This unit deals with elementary concepts of quantum physics formulation to deal with physical systems.

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

(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.

3 hrs

4 hrs

Unit – 7 Application of Quantum Mechanics- This unit deals with applications of quantum Mechanics to specific one-dimensional problems (Sketch, Schrodinger equation for different regions, Boundary conditions, final expressions and physical interpretations only,  no derivations).

Free particles- continuous states, Potential steps- Reflections, transmissions, Potential Barrier-Tunneling, Infinite deep potential well-energy eigen values, eigen functions.

3 hrs

Text Books :

1.  Engineering Physics by D.R. Joshi, Mc Graw Hill

2.  Engineering Physics by H.K. Malik and A.K. Singh, Mc Graw Hill.

Reference Book:

1.  Quantum Mechanics by Powel & Craseman.

2.  Optics- A. K. Ghatak

3.  Electricity & Magnetism : E.M. Purecell

4.  Introduction to Electrodynamics- David J. Griffiths, PHI Publication

5.  Concepts of Modern Physics – Arthur Beiser.

6.  Engineering Physics- K.P.Mishra and P. Pattojoshi, Scitech Pub.

7.  Concepts in Engineering Physics-I  Md. N. khan, Alok Publication.

8.  Physics-I for engineering degree students-B.B. Swain and P.K.Jena.

9.  An Introduction to Machanics by D.Klippner & R. Kolenkow, TMH

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.

(a)        Vector calculus: gradient of scalar field, divergence, curl of vector field (Only Physical significance) Gauss divergence theorem, Stoke’s theorem, Green’s theorem (Only Statements)

(b)        Gauss’s law of electrostatics in free space and in a medium(Only statements) electric displacement( D)magnetic Induction (B),Amperes circuital law (Only statements),                           displacement    current,    Faraday’s    law    of    electromagnetic induction(Only statements).

2 hrs

2 hrs

(c )

Maxwell’s electromagnetic equation in differential form and in integral form(Only statements). Electromagnetic energy density, poynting vector, poynting theorem, vector potential and scalar potential, electromagnetic wave equation for E and B, transverse nature of EM waves.     4-2

2 hrs

Module III                                   ( 10 hours)

Unit - 6 Quantum Physics : This unit deals with elementary concepts of quantum physics formulation to deal with physical systems.

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

(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.

3 hrs

4 hrs

Unit – 7 Application of Quantum Mechanics- This unit deals with applications of quantum Mechanics to specific one-dimensional problems (Sketch, Schrodinger equation for different regions, Boundary conditions, final expressions and physical interpretations only,  no derivations).

Free particles- continuous states, Potential steps- Reflections, transmissions, Potential Barrier-Tunneling, Infinite deep potential well-energy eigen values, eigen functions.

3 hrs

Text Books :

1.  Engineering Physics by D.R. Joshi, Mc Graw Hill

2.  Engineering Physics by H.K. Malik and A.K. Singh, Mc Graw Hill.

Reference Book:

1.  Quantum Mechanics by Powel & Craseman.

2.  Optics- A. K. Ghatak

3.  Electricity & Magnetism : E.M. Purecell

4.  Introduction to Electrodynamics- David J. Griffiths, PHI Publication

5.  Concepts of Modern Physics – Arthur Beiser.

6.  Engineering Physics- K.P.Mishra and P. Pattojoshi, Scitech Pub.

7.  Concepts in Engineering Physics-I  Md. N. khan, Alok Publication.

8.  Physics-I for engineering degree students-B.B. Swain and P.K.Jena.

9.  An Introduction to Machanics by D.Klippner & R. Kolenkow, TMH

Module I (13 Hours)

BE2104     Mechanics   (3-0-0)

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.

moduleII

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

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

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)

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

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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.

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.

Machinin  g  :

(i)       Stepped cylindrical Turning of a job and Thread-cutting in lathe. (ii)      Shaping

(iii)      Millin

 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-π 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 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)

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