Branch: Civil Engineering. Year: Second. Semester: Fourth ...bbec.ac.in/wp-content/uploads/2015/08/4th-Sem-all.pdf · MA 411 (CE & Ch.E) ADVANCED MATHEMATICS AND NUMERICAL ANALYSIS

Branch: Civil Engineering. Year: Second. Semester: Fourth

Total marks: 1150 Total Periods: 35 Total Credits: 33

TA: Teachers assessment. CT: Class Test. ESE: End Semester Examination.

SL.

NO.

COURSE

NO.

SUBJECT PERIOD EVALUATION SCHEME

Theory L T P Sessional

Examination

ESE Subject

Total

Credit

TA CT Total

1. MA 411 Advanced Mathematics & Numerical Analysis. 3 1 30 20 50 100 150 4

2. HU 402 Sociology and Accountancy. 3 1 30 20 50 100 150 4

3. HU 403 Communication Skill. 2 15 10 25 50 75 2

4. CE 412 Theory of Structures-II. 3 1 30 20 50 100 150 4

5. CE 413 Advanced Surveying. 3 1 30 20 50 100 150 4

6. CE 414 Hydraulics and Hydraulic Machines. 3 1 30 20 50 100 150 4

7. CE 415 Engineering Geoscience. 3 1 30 20 50 100 150 4

8. CE 416 General Proficiency. 25 25 1

Practical/Drawing/Design

9. CE 413 L Advanced Surveying. 3 30 20 50 50 2

10. CE 414 L Hydraulics and Hydraulic Machines. 3 30 20 50 50 2

11. CE 415 L Engineering Geoscience. 3 30 20 50 50 2

Total 20 6 9

MA 411 (CE & Ch.E)

ADVANCED MATHEMATICS AND NUMERICAL ANALYSIS

Theory – 100 marks.

Sessional – 50 marks.

Time – 3 Hours.

Unit-I: Partial differential equations: 25 Marks.

Formation of partial differential equations, equation solvable by direct integration, linear and non-

linear equations of first order, homogenous linear equation with constant coefficients solution of heat

equation, wave equation and Laplace equation.

Unit-II: Calculus of Complex variables: 20 Marks.

Analytic functions, C-R equations, Conjugate functions, Harmonic functions, orthogonal systems,

formation of analytic function, Conformal mapping, Integration of a Complex function, Cauchy’s

integral theorem, Power series representation of complex functions, Laurent’s series, singularities,

Residue theorem.

Unit-III: Numerical Analysis: 35 Marks.

Solution of non-linear equations (Newton-Raphson method, Bisection method, Regula-falsi method),

Solution of linear algebraic equations (Gauss elimination method, Gauss-siedel method, Gauss

Jordan method), Solution of ordinary differential equations (Taylor’s series method, Runge Kutta

method).

Interpolations and approximation: operators: ∆, E, ∂.

Gregory- Newton’s forward and backward formula, Langrange’s interpolation formula & Bessel’s

formula with remainder terms or errors, Chebyshev polynomial approximation.

Numerical Integration: Trapezoidal Rule, Simpson’s Rule and Gaussian quadrature.

Unit-IV: Optimization Methods: 20 Marks.

Optimization by calculus: unconstrained function of a signal variable, unconstrained function of

multiple variables, Functions with equality constraints, Functions with inequality constraints.

Text/References:

1. Complex variable & applications : Churchil : Mc Graw Hills.

2. Elements of P.D.Es. : I. M. Snedon : S. Chand & Co.

3. Numerical methods in Science and Engineering : S. Rajasekaran : Wheeler.

4. Numerical methods with Computer programs in C++: Pallab Ghosh : Prentice Hall.

5. Numerical methods. : M. K. Jain & S. R. K. Iyengar: Wiley.

6. A Text Book on Engineering Mathematics. : Bali, Saxena, Iyengar: Laxmi Publications.

7. Operation Research. : Prem Kumar Gupta : S. Chand.

8. Advanced Engineering Mathematics. : Peter V O’Neil : Thomson Books.

9. Analysis of Descret Physical systems.: Koenig, Y. Toked & H. K. Kesavan: Mc Graw Hill.

Linear Programming: L P Problems and their solutions by Simplex method.

HU 402: SOCIOLOGY AND ACCOUNTANCY

Part A. Sociology and Industrial Relations

Theory: 50 Sessional: 25

1. Concept of the state. Origin and Development of the State. The individual and the State. 2. Social Institutions and Social Groups. Non-governmental Organizations and Panchayati Raj

Institutions; local communities and alternate social Groups-characteristics, functions and purposes;

3. Social structure. Social differentiation; Role, Status, Power and Authority; Social differentiation. Social order and social problems.

4. Social Change: Meaning and nature of social change; factors effecting social change; Technology and social change; Social and economic displacement. Labour and Labour Relations; Organised and unorganized labor; Problems associated with labour. Labour problems: absenteeism, labour turnover, displacement and obsolescence.

5. Human resources: Meaning and development; Relation with industrial and economic needs. Industrial productivity. Workers participation in Management.

6. Man Power Planning: Definition and Objectives. Characteristics of Man Power Planning. Manpower Demand and Supply forecasting.

7. Industrial disputes- settlement of Industrial disputes. Trade Unionism in India. Labour legislation in India- Indian Factories Act, 1948. Payment of Wages Act, I 936.workmens Compensation Act, 1923.

8. Social Security: concept of social security. Provision for Social security in India. Recommended readings:

1. Rao, C.N. Sankara, Sociology. 2. Sarma, RN, Principles of Sociology. 3. Mukherjee, R.K, Indian Working Class. 4. Saxena, R.N, Labour Problems and Social Welfare.

Part B. Accountancy

Theory: 50 S Sessional: 25

1. Dual aspect concept of Accounts, classification of Accounts, cardinal rules for Debit and Credit, Journal, Ledger, Balancing of Account.

2. Subsidiary books, types of Cashbook, Imprest, Petty cash book, Bank reconciliation statement. 3. Trial balance; Trading and Manufacturing account; Profit and Loss account; balance sheet with

adjustments. 4. Concepts of Capital expenditure and Revenue expenditure; Bad debt and doubtful debt, Reserve

capital and Liabilities; Outstanding expenses; Prepaid expenses, Marshalling of Balance sheet, Liquidity and Profitability of assets.

5. Cost accounting- concept, benefits and distinction between cost accounting and financial accounting- various elements of cost, cost sheet, overhead cost, Job and process costing.

6. Depreciation — concept and importance. Methods of charging depreciation on fixed assets used in industries.

Recommended readings:

1. Shukla, MC., Grewal T.S., and Gupta, SC: Advanced Accounts; S. Chand & Co. New

Delhi.

2. Agarwala A. N. Agarwala K. N~ Higher Sciences of Accountancy: Kitab Mahal Allahabad.

3. Rajpurohit R. S., Bissa, and others: Financial Accounting.

4. Cost Accounts- M.C. Shukla.

HU 403: COMMUNICATION SKILLS

Theory- 50 marks.

Sessional-25 marks.

Time: 1½ Hours.

1) Group Discussion: aspects; preparation; facing group discussions.

2) Communication: Aspects, Issues and Vitals.

3) Body Language: Studying body language; its orientation.

4) The art of listening: Active listening; hearing and listening; good listening; Barriers to

listening.

5) Negotiation- The act of negotiation. Truths about negotiation; hurdles in negotiation.

RECOMMENDED BOOKS:

1. Essentials of Business Communication : Pal and Rorualling; Sultan Chand and Sons.

2. The Essence of Effective Communication: Ludlow and Panthon; PHI.

3. A Practical English Grammar by Thomson and Marlinet.

4. Spoken English by V Sasikumar and PV Dhamija; Tata McGraw Hill.

5. English Conversation Practice by Grount Taylor; Tata McGraw Hill.

6. Developing Communication Skills by Krishna Mohan and Meera Banerji:

MacMillan India Ltd., Delhi.

CE 412: THEOTY OF STRACTURES-II

Theory-100 marks.

Sessional-50 marks.

Time- 3 Hours.

1. Fixed beams:

Beans fixed at one end freely supported at the other, both ends fixed subjected to

concentrated load, uniformly distributed load, couple and condition.

2. Continuous Beam:

Three moment theorem. Continuous beams with fixed end, overhang & sinking supports.

3. Flexibility co-efficient of structural:

Force method (consistent deformation methods) applied to beams and frames.

4. Elastic theory of arches:

Two hinged arch-circular and parabolic, Yielding of support, rib shortening, fixed arch-

elastic center method and column analogy method;

5. Suspension girder bridge: Analysis of two hinged and three hinged stiffening girder.

6. Approximate Analysis of frame:

Introduction to moment distribution for beams, Method of substitute frame, Portal and

cantilever method of analysis of building frames for lateral loads.

7. Concept of structural stability:

Equilibrium and energy methods for critical loads of simple struts, Introduction to buckling

of portal frame.

8. Dams and Retaining wall:

Different types of Dams, Stability analysis of Dam, Different types of retaining wall,

Analysis for with and without surcharge.

CE 413: ADVANCED SURVEYING

Theory-100 marks.

Sessional-50 marks.

Practical-50 marks.

Time- 3 Hours.

Triangulation: Object, classification of triangulation systems, Reconnaissance-selection of stations, intervisibility

and height, signals and towers, phase of signal, Base line measurement, Extension of base,

Measurement of horizontal angles, satellite station-reduction to center.

Adjustment of computation: Error and precision, Laws of accidental error, General principle of least squares, Laws of weight,

Determination of probable error, Distribution of error to field measurements.

Determination of most probable values- Normal equation, method of correlates. Triangulation

adjustment- station and figure adjustment, Adjustment of chain of triangles and geodetic

quadrilateral.

Electronic Distance Measurement:

Electromagnetic Waves-important characteristics, Distance measurement by transit time and phase

difference, Carrier waves, method of modulation, Electro- optical E.D.M. instruments, Infrared

EDM instruments, Microwave EDM instruments, Target-component and characteristics.

Introduction to Electronic theodolite and Total Station.

Trilateration:

Use, advantages, Triangulation Vs Trilateration, check angle, zenith angle and reduction of slope

distance from vertical angle and elevations, adjustments of trilateration.

Photogrammetry:

Types of aerial photograph, components of an aerial camera, photo- coordinates measurements, scale

of a vertical photograph, horizontal length and direction of a line. Flight planning. Determination of

elevation-method of relief displacement. Stereoscopic observation-parallax, principle of floating

point, use of stereometer and stereoscope. Stereoscopic plotting instruments. Introduction to

Terrestrial photogrammetry.

Map projections:

Basis of map projection, ideal map projection, introduction to orthographic, polyconic and transverse

mercator projection.

Satellite remote sensing:

Electromagnetic energy, electromagnetic spectrum, atmospheric window, active and passive remote

sensing, practical remote sensing system, types of data products. Visual interpretation of hardcopy

data, principle of digital classification.

CE 413 L :ADVANCED SURVEYING (PRACTICAL)

Practical-50 marks.

Time- 3 Hours.

To carry out open traverse with theodolite for route alignment.

To set out simple Circular curve. (horizontal & vertical)

Determination of height of an inaccessible point by Trigonometrical Levelling.

To carryout open Traverse with Total station.

To carryout closed Traverse with Micro-optic Theodolite.

To carryout Longitudinal and Cross-sectional leveling using Automatic Level.

CE 414: HYDRAULICS AND HYDRAULIC MACHINES

Theory-100 marks.

Sessional-50 marks.

Practical- 50 marks.

Time- 3 Hours.

Viscous flow:

Viscosity- dynamic and kinematic; Equation of motion- Navier- Stokes equation; Laminar flow in

circular pipes- Hagen Poiseuille equation, flow between parallel plates- Couette flow, plane

Poisouille flow.

Turbulent flow:

Eddy viscosity, Pandtle mixing length theory, velocity distribution over smooth and rough surfaces.

Boundary Layer Theory:

Boundary layer thickness- displacement, momentum and energy thickness, Laminar and turbulent

boundary layer along a flat plate- momentum integral equation; Laminar sub-layer.

Flow around Submerged Bodies:

Drag and lift, pressure and friction drag on sphere, cylinder and disc. Separation of flow -Kerman

vortex street, lift-cylinder with circulation, Magnus effect, Drag and Lift coefficients.

Smooth and rough pipes, variation of friction factor, moody’s diagram, pipe

network analysis-Hardy Cross method, water hammer in pipes- rigid and elastic water column

theories, gradually and instantaneous closure of valves, surge tank.

Open Channel flow: Normal depth, specific energy, critical depth and critical velocity, prismatic and non-prismatic

channel section, types of bed slope. Gradually varied flow-surface profile, equation of gradually

varied flow-direct step method, backwater curve, rapidly varied flow-hydraulic jump in horizontal

rectangular channel, depth and length of jump, loss of energy.

Impact of Jet: Impulse momentum principal, momentum of momentum, force of jet on fixed, hinged and moving

plate, including curved plate, water wheel and radically rotating curved vanes.

Turbines:

Classification, Impulse and reaction turbines, work done, power and efficiencies, Pelton wheel,

Francis turbine, Kalpan and Propeller turbine, draft tube, unit quantities, specific speed.

Pumps: Centrifugal pump- velocity triangle, work done, manometric head, efficiency, minimum starting

speed, multi stage pump.

Reciprocating pump-discharge, indicator diagram, effects of acceleration and friction, Air vessels.

Other Machines:

Hydraulic Ram, Accumulator, Intensifier, Hydraulic Press and jack.

Advanced pipe flow:

CE 414L :HYDRAULICS AND HYDRAULIC MACHINES

Total Marks: 50

1. Determination of the sequent depths in Hydraulic Jumps.

2. Experiment on the impact of Jets.

3. Determination of critical velocity in pipe flow cases.

CE 415:ENGINEERING GEOSCIENCE

Theory-100 marks.

Sessional-50 marks.

Practical- 50 marks.

Time- 3 Hours.

Introduction to Earth Science, Earth materials, Earth Sciences in Civil Engineering.

Geological function of wind, running water and glacior modification of landscapes.

Brief outline of the rock-forming minerals, their physical properties-selected rock- forming minerals from-

quartz, feldspar pyroxene, mica garnet, olivine and amphibole groups. Their economic importance clay

minerals-classification, structure.

Mode of formation of igneous, metamorphic and sedimentary rocks- their occurrences, forms, texture and

structure, classifications and mineralogical compositions, geological and Engineering properties of granite,

gabore, rhyelite, diorit, dolorite, granodierite, pegmatits, basalt, conglemorate, sand-stone, lime-stone, shale,

phyllite, schist, gnoise, amphibolite, quartzite and marblo.

Primary and Secondary structures of rocks, influence of stereos and strain on rocks and resulting deformation-

folds, faults, joints-causes of formation, classification, Engineering significance, unconformities, overlap

outlier and inlier.

Fundamental principles of stratigraphy, standard stratigraphic column. General review of the geological

history of India with particular reference to procambrian, gendwana and tertiary group. Elementary principles

relating to geological and geophysical methods of prospecting. Their utility in the field of Civil Engineering.

Geosciences bases investigations of sites for dams, reservoirs, tunnels, highways and bridges. Land-slide

causes, types, types and effects on Engineering construction-prevention.

Surface and underground water, surfaces, accumulation and migration of water table, ground water survey

and ground water provinces, Cartesian water, classification of aquifers.

Earthquake: Types, causes, Earthquake waves, magnitude and intensity effect on engineering constructions-

precaution seismic belts of India.

Construction materials: Building and road, rock quarrying with special reference to rock blasting and few

related problems. Rock boring and simple idea of R.Q.D. (rock quality designation) and some related

problems.

Laboratory works: Megascopic studies of some important minerals and rocks. Problems of dip and strits and

completion of outcrops. Borehole correlation problems. Geological maps and geological sections. Study of

top-sheets.

Mechanical Engineering

4th

Semester BE(ME) SL.No Course

No


Theory

L

T

P

Sessional/Exam.

TA CT Total

ESE Subject

Total

Credit

1 MA 401 Mathematics – IV 3 1 0 30 20 50 100 150 4

2 HU 402 Sociology and Accountancy 3 1 0 30 20 50 100 150 4

3 HU 403 Communication Skill 2 0 0 15 10 25 50 75 2

4 EE 404 Electro Technology – II 3 1 0 30 20 50 100 150 4

5 ME 425 Mechanics of Material-MHG 3 1 0 30 20 50 100 150 4

6 ME 426 Fluid Mechanics – I-AJB 3 1 0 30 20 50 100 150 4

7 ME 427 Material Science-AB 3 0 2 30 20 50 100 150 4

8 ME 428 General Proficiency 25 25 1

Practical/ Drawing/Design

9 EE 404L Electro Technology – II 0 0 3 50 50 2

10 ME 425L Mechanics of Materials 0 0 3 50 50 2

11 ME 426L Fluid Mechanics 0 0 3 50 50 2

Total 20 5 11 1150 33

Total marks : 1150 Total Periods: 36 Total Credits : 33

TA : Teachers Assessment CT: Class test ESE : End Semester examination

MA 401 Mathematics IV (Common to ME,EE,INE,CS,IPE)

Theory: 100

Sessional: 50

Time: 3 hours

Unit 1: Series Solutions 25 Marks

Power series solution of initial value problems, Power series solution using recurrence relations, singular points and the method of

Frobenius, solution of Bessel’s equation and Bessel’s functions, solution of Legendre’s equation and Legendre Polynomials, orthogonal

set of functions, Strum-Liouville Problem, eigen values and eigen functions of singular problems, Bessel’s functions as eigen functions

of singular problem, Legendre Polynomials as eigen functions of singular problems, eigen function expansions.

Unit 2: Partial Differential Equations 25 Marks

Basic concepts, formation of partial differential equations, equation solvable by direct integration, linear and non-linear equations of first

order. Homogenous linear equations with constant coefficients, solutions of heat equations, wave equations, transmission line equations

and Laplace equations.

Unit 3: Tensor Analysis 20 Marks

Curvilinear coordinates, unit vectors in curvilinear system, representation of as vector F in terms of unit base vectors, contravariant and

covariant components of F, arc length and volume element in orthogonal curvilinear coordinates. Transformations of coordinates.

Definition of tensors, fundamental operations with tensors, Symmetric and skew-Symmetric tensors, Riemannian space and metric

tensor, Conjugate tensor, Christoffel symbols.

Unit 4: Calculus of Complex Variables 20 Marks

Analytic functions, C-R equations, conjugate functions, Harmonic functions, orthogonal systems.

Formation of analytic functions, conformal mapping, integration of a complex functions, Cauchy’s Integral Theorem, power series

representation of complex functions, Laurent’s Series, singularities, Residue Theorem.

Unit 5: Z-Transform 10 Marks

Definition, properties, Z-transform of some basic sequences, Z-transforms of some basic discrete functions, Shifting theorems.

Text books and References:

1. Advanced Engg. Maths, E. Kreyszig. Wiley Eastern Ltd.

2. Advanced Engg. Maths, Peter V. O. Neil. Thomson Books.

3. A Text Book on Engg. Maths, Bali, Tyenger. Laxmi Publishers.

4. Higher Engg. Maths, B.S. Grewal. Khanna Publishers.

5. Linear Algebra and it’s Applications, Gilbert Strang. Thomson Books.

6. Calculus, James Stewart. Thomson Books.

7. Laplace Transform, Spiegel. Thomson Books.

8. Elements of Partial Differential Equations, I. M. Snedon. S. Chand and Co.

9. Text book of Vector Calculus by Shanti Narayan, S. Chand and Co.

10. Function of Complex Variables by Shanti Narayan, S. Chand and Co. EE 404: ELECRO-TECHNOLOGY-II (ME & CHE) ( 3 – 1 – 2 )

Theory Marks:100 Sessional Marks: 50 Laboratory Marks : 50 Time = 3 hours

1. Analog Electronics: Bi-polar transistor (BJT) – PNP and NPN types. Construction and working principle. Identifying the leads of the transistor. Transistor as an amplifier. Transistor configurations – CB, CE and CC. Characteristic of CE configuration. α and β factors and their relation. Biasing of transistor.. Operating point. Load line analysis. Performance of the transistor amplifier – input and output resistance, effective collector load, voltage gain and power gain. Graphical representation of working of the single stage amplifier. Field Effect Transistor (FET) ─ construction and working principle. Difference between BJT and FET. 2. Digital Electronics:

Digital signals. Basic building blocks in digital electronics – NOT, AND and OR gates. The NAND, NOR and EX-OR gates. Boolean algebra, DeMorgan’s theorems. Number system and codes – the decimal, the binary, octal and hexadecimal number systems: conversion from one another. Combinational logic design : - standard representation of logical functional in SOP and POS forms. Logic design in SOP form – truth table to logic equation to realization using gates. Reduction of logic equations. Introduction to half adder, full adder, BCD to 7 segments display decoder. ADC, DAC(to be treated as black boxes) 3. Introduction to feed back control systems: - (For Mechanical Engineering students only) Open-loop and closed-loop systems; examples of control systems; definition of linear, non-linear, time-variant, time-invariant, continuous and discrete control systems; characteristics of closed-loop (feedback) control systems, positive and negative feedback systems; transfer function-concept and properties, poles, zeros, pole-zero map and characteristic equation. Formulation of differential equations for dynamic systems; transfer functions of linear systems; construction of block diagram of control systems, determination of transfer function using block diagram reduction technique. Time response of control systems- the unit step, unit ramp and unit acceleration test inputs, First and second order systems. Transient response of under-damped second order systems, Steady state errors. Introduction to stability analysis of feedback control systems; Routh-Hurwitz’s stability criterion. Frequency response analysis of second order systems, relation between time response and frequency response, Bode plot. 4. Transducers – (For Chemical Engineering students only) Functional elements. Mechanical and electrical transducers. Primary and secondary transducers, active and passive transducers. Inverse transducer_ piezo electric transducers. Basic requirements of transducers.

Temperature transducers – thermistor, thermocouple, characteristics of thermocouple transducers, Resistance-Temperature detector (RTD); Solid state sensor – transistor used as a temperature sensor.

Pressure transducers- elastic element used as pressure sensors – membranes, thin plates corrugated diaphragms, capsules, bellows, Bourdon tube. Transducers types – LVDT type, variable capacitance type, strain gauge type. Displacement transducers –LVDT, RVDT, variable capacitance. Digital transducers.

Flow transducers – restriction flew transducers, obstruction flow transducers, and magnetic transducers. 5. Electric Heating and Welding: Advantage of electric heating. Resistance heating –direct and indirect type. Heating elements. Temperature control. Electric arc furnace – direct type, indirect type, power supply, and heat control. Induction Heating – principle, skin effect, depth of penetration; induction furnace – different types. Dielectric Heating – principle and applications. Electric welding - arc welding, dc generator for arc welding, welding transformer, Resistance welding. Books:

1) Ogata, K.: Modern Control Engineering (PHI). 2) Shawaney, A. K.: Electrical Measurements and Measuring Instruments (Dhanpat Rai) 3) Jain, R. P.: Digital Electronics 4) Mehta, V. K.: Principles of Electronics (S. Chand & Co.). 5) Partab, H.: Art and Science of Utilization of Electrical Energy 6) Elgerd, E.: Utilization of electrical energy

ME 425 MECHANICS OF MATERIALS (3-1-3) (for ME)

Theory – 100 marks Sessional – 50 marks Lab – 50 Time – 3 hrs.

1. Complex stresses and strains:

a) Two-dimensional stress systems : Stresses on oblique planes due to two direct and shear stresses. Principal stresses, Mohr’s cycle for

stresses. Strain on oblique planes, Mohr’s cycle for strain. Strain Rosette.

b) Three-dimensional stress system: Principal stresses, direct and shear stresses on octahedral planes. Mohr’s cycle for tri-axial stress

systems. Simple cases.

2. Stresses due to combined bending and torsion of circular shaft.

3. Thick cylinder: Lame’s equation, Longitudinal and shear stress, stresses due to shrunk fit.

4. Stresses in discs of rotation.

5. Stresses in curved beams: Stresses in crane hooks, rings.

6. Stresses in circular helical spring.

7. Deflection of beams: Integration method, Energy methods, Theorem of Castigliano.

Maxwell Bette reciprocal theorem.

Books:

1. Elements of strength of materials by Timoshenko

2. Strength of materials by D S Bedi

3. Mechanics of materials by J P Denhartog.

ME 426: FLUID MECHANICS – I (3-1-3) (for ME)

Theory 100 marks Sessional 50marks Laboratory 50marks Time 3 hours

Unit I : Introductions Significance of flow properties, Classification of fluids based on variation of viscosity, Continuum, No slip

condition of viscous liquids.

Unit II : Fluid Statics Fundamental equation in vectorial form, pressure at a point, constant density and temperature solution, unit

and scales of pressure measurement, pressure measuring devices, Hydrostatic force on a horizontal plane, Vertical plane, inclined and

rough surface, Buoyancy stability of floating and submerged bodies, Metacentre and Metacentric height.

Unit III : Kinematics of Fluids Flow field and description of fluid motion, Material derivative and acceleration, streamline, path

line, streakline, stream tube, steady and unsteady flow, uniform and non uniform flow, Rotational and Irrotational flows, Translation,

Vorticity, Stream function, Velocity potential function, Flow net.

Unit IV : Elementary Flows in a two dimensional plane Introduction, Uniform flow, Source and Sink, Vortex Flow, Free and

Forced Vortex, Doublet, Continuity equation and its analysis based on integral form.

Unit V : Dynamics of Fluid Flow Euler’s equation of motion and its Vectorial approach. Euler’s equation along a streamline,

analytical and Vectorial approach of Bernoull’s equation, General Energy equation and momentum equation and vectorial approach,

application of Bernoulli’s equation to real fluid flow, Dynamic forces on plain and curved surfaces due to impingement of liquid jets.

Unit VI : Flow Measurement Concept of static and stagnation pressures, application of Pitot tube in Flow Measurements, Pitot Static

tube, Hot wire anemometer, venturimeter, Loss of head in a venturimeter, Orificemeter and its classification, the phenomenon of jet

contractions, Hydraulic co-efficient of an Orifice, Factors affecting the Orifice co-efficients.

Unit VII : Dimensional Analysis and its applications Introduction, Dimensionless numbers and its significance, Fluid flow

problems, drag in immersed bodies.

Unit VIII : Fluid Frictions Critical Reynold’s numbers, relation of Shear stress and pressure gradient, Steady laminar flow through

circular pipes, flow between parallel plates, Couette flow,

Occurrence of back flow.

Reference Books :

1. Fluid Mechanics ------ Dr. A. K. Jain.

2. Fluid Mechanics ------ Dr. J. Lal

3. Fluid Mechanics and machines ----- V. L. Streeter.

ME 427: Materials Science (3-0-2) (for ME)

Theory: 100 Sessional: 50 Time: 3hrs.

Unit-I

Introduction to Materials Science and Engineering- Classification of engineering materials. Brief review of Crystal Structures-

Crystal Directions and Planes. The Bragg Law of X-ray diffraction, Powder method and structure determination.

Bonding in solids- Specifically Metallic Bonding. Solid solutions and Intermetallic Compounds. Solidification of metals and

alloys- Nucleation and grain growth-Nucleation kinetics- Recovery, recrystallisation and grain growth.

Phase diagrams- Gibbs phase rule- Binary phase diagrams- Eutectic and eutectoid peritectic and peritectoid systems. Fe-C

equilibrium diagram- TTT diagram

Unit –III

Principles of heat treatment and general heat treatment processes. Case hardening, surface hardening, precipitation hardening and

maraging. Heat treatment of steels.

Unit-IV

Mechanical properties of materials and testing- Tensile, compressive, impact, hardness, fatigue and creep testing. Non-destructive

testing.

Unit-II

Work hardening, Bauchinger’s effect, preferred orientation, elastic after affect and season’s cracking.

Unit-V

Lattice defects, Deformation by slip, Slip by dislocation movement, Critical resolved shear stress for slip, Deformation of single

crystals, Deformation by twinning, Stacking faults, deformation of polycrystalline materials.

Unit-VI

Diffusion, oxidation and Corrosion.

Diffusion types- Mechanisms and Laws of diffusion- Variables affecting diffusion.

Oxides types- Mechanism of film growth and rate of growth- protective oxides- Selective oxidations- Benefits and adverse

effects- Control of oxidation.

Factors influencing corrosion- Mechanisms, Types, Electrochemical and Galvanic corrosion, Passivation and Polarisation, Liquid

metal corrosion, Rusting of Iron.

Unit- VII

Electronic properties of materials- Conductors, semiconductors and insulators.

Magnetism and magnetization- diamagnetism, paramagnetism and ferromagnetism. Dielectric materials.

Unit- VIII

General introduction to engineering alloys- Tool and Die steels, Heat and Scale resistant steels, Babbitt materials, Cu-based, Al-

based and Ni-based alloys. Composites.

Books:

1. Materials Science and Engineering – V. Raghavan, PHI

2. Materials Science – Van Black, Prentice Hall International

3. Materials Science – A.K. Gupta and R.C Gupta

4. Physical Metallurgy Principle – V. Raghavan, PHI

5. Mechanical Metallurgy – George E. Dieter, McGraw Hill Book Company

Branch: Electrical EngineeringBranch: Electrical EngineeringBranch: Electrical EngineeringBranch: Electrical Engineering Year: SecondYear: SecondYear: SecondYear: Second Semester: Semester: Semester: Semester:

FourthFourthFourthFourth

Sl

No.

Course No. Subject

Period Evaluation Scheme

Theory L T P Sessional Examination

ESE Subject

Total

Credit

TA CT Total

1. MA 401 Mathematics -IV 3 1 30 20 50 100 150 4

2. HU 402 Sociology and Accountancy 3 1 30 20 50 100 150 4

3. HU 403 Communication Skill 2 15 10 25 50 75 2

4. EE 441 Analog Electronics 3 1 30 20 50 100 150 4

5. EE 442 Electrical Machines-I 3 1 30 20 50 100 150 4

6. EE 443 Electrical Measurements and Measuring

Instruments

3 1 30 20 50 100 150 4

7. EE 444 Data Structure 3 1 30 20 50 100 150 4

8 EE 445 General Proficiency 25 25 1


8. EE 441 Analog Electronics 3 25 25 50 50 2


Instruments

3 25 25 50 50 2

10. EE 444 Data Structure 3 25 25 50 25 2

TOT

AL 20 6 9 270 205 475 675 1150 33

Total Marks: 1150 Total Periods: 35 Total Credits: 33

TA: Teachers’ Assessment CT: Class Test ESE: End Semester

Examination

EE 441: Analog Electronics (EE/IE) (3 – 1 – 3) Theory Marks =100

Sessional Marks = 50 Laboratory Marks = 50 Time = 3 hours

1. Bond Model of silicon crystal: Intrinsic carrier concentration, Effect of doping on carrier concentration. Holes and electrons, Majority and Minority carriers, Mobility and diffusion constants. Passage of current through semi-conducting material – drift and diffusion process. Recombination and carrier life time. Effect of temperature.

2. The p-n junction, Basic construction: Abrupt junction and graded junctions, Symmetric and asymmetrically doped devices. Built-in field and depletion region approximation. Study of volt-amp characteristics. Low level injection approximation. Analysis of current flow through a diode. Dynamic behavior of diode and the capacitances associated with a diode device, Effect of temperature on the current. Current models of a diode piecewise linear static model and dynamic incremental model. Practical circuits employing diodes: diode gates and switches and power rectifying circuits. Power filters.

3. The Bipolar junction Transistor: Basic construction and the physical behavior of the device. Low level injection condition. Forward Active Region (FAR) and the study of the flow of carriers through the BJT control valve action. Volt-amp curves, base with modulation and early voltage. Static circuit models. Ebers-moll equations for the currents of a B.J.T. for all bias conditions. A simple amplifier circuit and biasing methods. The common base, common emitter and the common collector connections. Small signal operation of the transistor amplifier, incremental models for the B.J.T. the hybrid II model. Analysis of amplifiers with the help of incremental models, simplified low frequency operation. Gain, input and output impedances of amplifiers. Some ideas about high speed analysis such as Miller effect and dominant pole approximation determination of the hybrid II parameters, introductory ideas about two port y and h-parameter analysis.

4. Multiple stage transistor amplifiers: PNP and NPN combinations. Voltage and current biasing methods. Gain calculation. Frequency response of amplifiers. High power circuits and their efficiencies. Some ideas about distortion.

5. Feed-back in amplifiers: The usefulness of this concept. Negative and Positive fee-back. Their effects on the performance of amplifiers. Positive feed-back to produce oscillations and simple oscillator circuit, RC and LC oscillators with simple analysis. Introduction to device fabrication methods and some ideas about I.C.S. and the way they are made. Simple descriptions of processes such as diffusion, photolithography, ion implantation, metallization and crystal growing techniques.

6. Simple IC layout: Use of SPIC for computer aided analysis of electronic circuits (not for university examination).

Books: 1. Electronic Principles Physics, Models and Circuits – Paul E. Gray and Campbell L Searle 2. Integrated Electronics – Millman- Halkias (PHI) EE 444: DATA STRUCTURE (EE/IE): L T P (3- 1- 3) Theory Marks= 100 Sessional Marks=50

Laboratory Marks = 50 Time= 3 hours

Continuous data structure: Arrays, stacks and queues

Non-Continuous data structure:

Linear linked lists, binary search trees, balanced trees.

Sorting and Searching, Searching hash techniques.

Heap data structures and dynamic storage allocation techniques. File organization techniques. **Note: The C and C++ languages shall be used to describe the algorithms and data structure. Some basic features of project oriented languages shall be covered in the course.

Books/References: 1. M.A.Weiss-Data Structures & Algorithms Analysis in C++ , Addition Wesley. 2. L. Tannenbaum- Data Structures Using C , PHI. 3. Lipshutz- Theory and problems of Data Structure, McGraw Hill. 4. Neil Graham- Learning with C++, McGraw Hill. L T P EE 442: Electrical Machines - I (EE) ( 3 – 1 – 0)

Theory Marks =100 Sessional Marks = 50 Time = 3 hours

1. Electro-mechanical Energy Conversion:

Principle of energy conversion, Field magnets and induced e.m.f. and torque in rotating machines, Simple commuter and slip rings for supply and collection of current, Magnetically coupled circuits, principles of operation of transformer, voltage and current ratios.

2. D C Machines:

Constructional features, Details of Lap and Wave windings. Methods of excitations – shunt, series and compound. E M F equation, Armature reaction, Inter-poles and compensation windings, Commutation, Characteristic curves of D C Machines, Efficiency and Regulation, Parallel operation.

3. D C Motors:

Speed and Torque characteristic curves of shunt, series and compound motors, Starting of D C motors – Starters and grading of starting resistance, Speed control, Choice of motors for different duties, Losses and efficiency, Testing – Swinburne’s test, Back to back test, Retardation test and Brake test.

4. Transformer:

Construction – shell type and core type, single phase and poly phase. Emf equation and output equation, Magnetic circuit, leakage flux and leakage reactance, Phasor diagram, per unit values of resistance and reactance, Open circuit and short tests, back to back test, Regulation, losses and efficiency, maximum efficiency, all-day efficiency, Auto-transfer, 3-phase transformer, Phase transformation and connections. Parallel operation of transformer, Vector grouping, Harmonics.

5. Poly-phase Induction Motors:

Constructional features – slip ring and squirrel cage motors. Rotating magnetic field and operation of poly-phase induction motors, Equivalent circuit and phasor diagram. Torque and Power, Speed-torque curves – effects of rotor resistance, Deep-bar and double cage rotors, Performance calculation from circle diagram, Method of speed control, Losses and efficiency, Applications, Induction generator and induction regulator, Starting of induction motor. Books:

1. Langsdrof : Theory of Alternating Current Machines( McGraw Hill) 2. Kingsley, Fitzereld : Electric Machinery ( McGraw Hill) 3. Say : Preformance and Design of Alternating Current Machine.

L T P EE 443: Electrical Measurements and Measuring Instruments (EE/IE) (3 – 1 -2)

Theory Marks =100 Sessional Marks = 50 Laboratory Marks = 50

Time = 3 hours 1. Characteristic of instruments and measuring systems: Static characteristic – accuracy, sensitivity, reproducibility, drift, static error and dead zone. Dynamic characteristic- response to step and sinusoidal signals. Errors occurring in measurement. 2. Measuring Instruments: Electro-dynamic, rectifier and induction type ammeters and voltmeters – construction, operation, errors and compensation, Electro-dynamic and induction type watt meters, Single phase induction type energy meter. MC and MI type power factor meters. Electrodynamometer type frequency meter, Synchroscope. 3. Measurement of resistance: Wheaston bridge method – sensitivity of the Wheaston Bridge – precautions to be taken while making precision measurements, Limitations, Carey-Foster slid Wire Bridge. Measurement of low resistance – Kelvin’s Double Bridge. Measurement of high resistance – direct deflection method. Measurement of volume and surface receptivity. Loss of charge method. Measurement of insulation resistance with power on. 4. Potentiometers: D. C. potentiometer – basic principle. Laboratory type potentiometer. Methods of standardization. Applications- calibration of ammeters and voltmeters, measurement of resistance and power - calibration of watt meters. Volt ratio box, A. C. potentiometers – difference between A. C. and D. C. potentiometers. Types - polar and co-ordinate type. Application of A. C. potentiometer. 5. A. C. Bridge:

General principle, Balance equation. Sources and Detectors used in A. C. Bridges. Balance condition and Phasor diagrams of Maxwell’s bridge, Anderson’s bridge, Owen’s bridge, De Sauty’s bridge, Low voltage Schering Bridge, Heavy-side mutual inductance Bridge. 6. Magnetic Measurement: Magnetic hysteresis, alternating current magnetic testing, separation of iron losses. Measurement of iron losses by the watt meter method, Cambell’s bridge method and the Oscillographic method. 7. Instrument Transformer: Use of instrument transformers – ratio, burden. Theory and operation of CTs and PTs – errors and compensation – CT testing – mutual inductance method, Silbee’s method. PT testing – comparison method. Power and energy measurement using CTs and PTs. Effect of reverse polarity connection of one of the CTs on 3-phase energy meter. 8. C.R.O.: Basic construction, main parts, principle of operation, Applications. (Thurst has to be to use C.R.O. through suitably designed laboratory experiments) 9. Galvenometers: Ballastic, D’Arsonval, Vibration Books: 1. Golding and Widdis – Electrical Measurements and measuring instruments. 2. A.K. Sawhney – Electrical and Electronic Measurements and Instr

Branch: Chemical Year: Second year Semester: Fourth

Sl.

No.

Course

No.

Subject Periods Evaluation Scheme

Theory L T P Sessional Exam ESE Subject

Total

Credit

TA CT Total

1 MA 411 Advanced Maths & numerical

analysis 3 1 30 20 50 100 150 4

2 HU 402 Sociology and Accountancy 3 1 30 20 50 100 150 4

3 HU 403 Communication Skills 2 15 10 25 50 75 2

4 EE 404 Electro Technology-II 3 1 30 20 50 100 150 4

5 CH 485 Process Calculations 3 1 30 20 50 100 150 4

6 CH 486 Energy Engineering 3 1 30 20 50 100 150 4

7 CH 487 Fluid Flow Operations 3 1 30 20 50 100 150 4

Practicals/Drawing/Design

8 EE 404 L Electro Technology-II Lab 3 30 20 50 50 2

9 CH 486L Energy Engineering 3 30 20 50 50 2

10 CH 487L Fluid Flow Operations 3 30 20 50 50 2

11 CH 488 General Proficiency 25 25 1

Total 20 6 9


TA: teachers assessment CT: Class Test ESE: End Sem Exam

MA 411 ADVANCED MATHEMATICS AND NUMERICAL ANALYSIS

HU 402 Sociology And Accountancy (3-1-0)

HU 403 Communication skills (2-0-0)

EE 404: ELECRO-TECHNOLOGY-II (ME & CHE)

CH 485: Process Calculations

L – T – P

3 – 1 – 0

Time : 3 Hrs

Theory : 100 marks

Sessional : 50 marks

Material balance in Unit Operations: basic material balance Principles, material balance without Chemical reaction. Bypass, recycle,

purging.

Material balance with Chemical reaction.

Reaction Equilibrium, equilibrium Constant.

Energy Balance: thermo physics: Law of conservation of Energy, Components of energy Balance Equations, Heat Capacity, Enthalpy

Change of Phase Changes, steam tables, Heat of mixing, energy balance in cyclic Processes, energy Balance in Non-flow processes,

energy balance in flow processes.

Energy balance: thermo chemistry: Heat effects accompanying chemical reactions, effect of temperature on standard Heat of reaction.

Introduction to Computer Aided Process Calculations: Degrees of Freedom and Specifications, Use of Spreadsheets, Tearing and

Iterative Techniques in Flow sheeting.

TEXTBOOKS:

1. O.A.Hougen, K. M. Watson and R. A. Ragatz,"Chemical Process Principles", Vol-I,CBS Publishers and Distributors, New Delhi, 1995.

2. D. Himmelblau, '"Basic Principles and Calculations in Chemical Engineering", 5th

Edn.,Prentice Hall of India Ltd.,N.Delhi,1994.

3. K V narayanan and B Lakshmikutty, Stoiciometry and Proces Calculations

4. V.Venkataramani and N.Anantharaman,"Process Calculations",Prentice Hall of India Ltd.,N.Delhi,2003.

CHE 486 : ENERGY ENGINEERING L – T – P

3 – 1 – 2

Time :3 Hrs.

Theory : 100 marks.

Sessional : 50 marks.

Practical : 50 marks.

1. Introduction: energy crisis, present position in India and the work. Remedial measures. energy resources, Survey, classification and scope of

utilization

2. SOLID FUELS: Types of solid fuels, classification of coal, origin of coal, Coal composition : Proximate & Ultimate analysis of coal.,

calorific value of solid fuel : Gross and net calorific value and their determination by Bomb calorimeter, processing of coal, cleaning of coal, coal

carbonization, recovery of by-products from coal carbonization, pulverized coal, cal Gasification & Liquefaction.

3. LIQUID FUELS: Types of Liquid Fuels., Origin of Petroleum, Composition and classification of Petroleum. Petroleum processing :

Distillation, Reforming ,Cracking, Properties and testing of petroleum products including determination of calorific values of liquid fuel by Bomb

calorimeter, Important petroleum products, Petroleum refining in India, Coal tar fuel, liquid fuel from coal, (F-T process and Bergius process),

Alcohols, Shale oil etc.

4. GASEOUS FUELS : Types of gaseous fuels, manufacture of producer gas, water gas, coal gas, carouretted water gas from coal, LPG, SNG, CNG

etc., oil gasification.

Gross and net calorific value of gaseous fuel and their experimental determination, Junker’s gas calorimeter, Boy’s gas calorimeter.

5. INTRODUCTION TO VARIOUS CAMOUSTION EQUIPMENTS

6. Alternative energy resources: Hydroelectricity, solar energy, energy from biomass, Animal and vegetable waste conversion, Biomass

gasification, utilization of municipal solid waste as a renewable source of energy, Geothermal energy, Wind, Tidal energy.

Its production and future prospects in India.

7. CALCULATIONS.: for combustion of solid, liquid & gaseous fuels, for calorific value of solid, liquid & gaseous fuels.

PRACTICALS :

Proximate analysis of coal. Determination of calorific value of solid & liquid fuel by Bomb calorimeter. Determination of calorific value of

gaseous fuel by Junkar’s Gas calorimeter. Determination of flash point by Abel’s apparatus. Determination of flash point by Pensky-Marten

apparatus. Determination of flash point & fire point by Cleveland apparatus. Analysis of flue gas by Orsat apparatus. Determination of

viscosity by Redwood – I & II Viscometers.

BOOKS

Fuel & Combustion by S. Sarkar.

Combustion Engineering & Fuel Technology by A.K. Saha.

Solid, liquid & gaseous fuels by Brame & King.

Fuel Combustion energy Technology, S N Saha, Dhanpat Rai Publication

CH 487 FLUID FLOW OPERATION L – T – P

3 – 1 – 2

Time : 3 hrs

Theory : 100 marks

Sessional : 50 marks

Practicals 50 Marks

1. INTRODUCTION :Properties of fluids, compressible and incompressible fluids, Normal forces on fluids, Dimensional analysis.

2. FLUID STATICS : Principle of hydrostatic equilibrium, barometric equation, pressure management manometer.

3. FLUID FLOW PHENOMENA : Velocity field, laminar flow, velocity gradient and rate of shear, Eddie viscosity, viscosity and momentum flux,

shear stress field, Newtonian and non-Newtonian fluids, Binghham model, Ostwald-de Waele model of non-Newtonian fluid, turbulent flow, Reynold’s

experiments, flow in boundary layer, laminar and turbulent flow in boundary layer, transition from laminar to turbulent flow – Reynold’s number,

boundary layer separation and wake formation.

4. BASIC EQUATION OF FLUID FLOW :Stream lines and stream tubes, average velocity, mass velocity, integral equation of flow – Euler’s

equation of motion, momentum equation for one dimensional flow under steady state condition, the Bernoulli’s equation, its application to pumps, blowers,

turbines etc.

5. FLOW OF INCOMPRESSIBLE FLUID IN CONDUITS :Flow of incompressible fluids in pipes, boundary layer formation in straight tube,

laminar flow of Newtonian fluids, Hagen-Poisseuille equation, laminar flow of non-Newtonian fluids, velocity distribution for turbulent flow, average

velocity, relation between maximum and average velocity, application of dimensional analysis to fluid flow problems – friction factor, pipe roughness, loss

of head due to friction, bends, fittings etc.

6. FLOW PAST IMMERSED BODIES : Drag, Drag-co-efficient , turbulence, friction in flow through bed of solids – Kozeny-Carman equation,

Blake-Plummer equation, motion of particles through fluids, equation for one dimensional motion of particle through fluid.

7. FLUIDIZATION : Mechanism of fluidization, bath fluidization, minimum porosity, maximum bed density, bed height, pressure drop in

fluidized bed, uses of fluidization.

8. TRANSPORTATION AND METERING OF FLUIDS : Orifice meter, Venturimeter, Pitot tube, Rotameter and Weir-its principle, theory and

application. Classification and performance of pump, compressor, blower, selection and specification.

9. COMPRESSIBLE FLUIDS :Continuity equation, total energy balance, mechanical energy balance, ideal gas equation, process compressible

fluids.

Practicals:

1. Experiment on Reynold’s apparatus

2. Experiment on turbulent flow apparatus

3. Flow characteristics through venture meter, orifice meter

4. Verification of Bernoulle’s equation.

5. Determination of friction factor at different floe rates for SS aluminum, copper pipe

6. Frictions losses in pipes, bends, fittings etc.

BOOKS:

Unit Operation of Chemical Engg. by – Mccabe and Smith.

Chemical Engg. Vol-I by – Coulson and Richardson.

Introduction to Chemical Engg. by – Badger and Banchero.

4th

Semester

Theory : 6.5 X 100 = 650

Sessional : 6.5 X 50 = 325

Practicals : 3 X 50 = 150

General Proficiency :25

Total :1150

Branch: ETE Year: Second year

Sl.

No. Course No. Subject

Periods Evaluation Scheme

L T P Sessional Marks

ESE Total

Marks Credit

TA CT Total

1 MA401 Mathematics-IV 3 1 30 20 50 100 150 4

2 ET 464 Electronic Circuits 3 1 30 20 50 100 150 4

3 ET 465 Signals & Systems 3 1 30 20 50 100 150 4

4 ET 466 Network Theory-II 3 1 30 20 50 100 150 4

5 IE 651 Electrical Machines 3 1 30 20 50 100 150 4

6

HU 402

HU 403

Sociology and Accountancy

Comm Skill

3 1 75 150 225 4


7 ET464L Electronic Circuits 3 30 20 50 50 2

8 ET465L Signals & Systems 3 30 20 50 50 2

9 EE455L Electrical Machines 3 30 20 50 50 2


Total 18 6 9


TA: teachers assessment CT: Class Test ESE: End Semester Exam

ET 464 Electronic Circuits

Theory: 100

Sessional: 50

Time: 3 hours

Bipolar amplifiers

Basic circuit-common base, common emitter and common collector topology. Biasing of single stage amplifiers- single power

supply and bipolar power supply. Multiple stage amplifiers biasing schemes with emphasis on direct coupling. NPN and PNP

connections. Hand calculation of bias current and voltages. Simulation of such circuits on SPICE.

Hybrid π small signal equivalent circuit

Computation of input resistance, output resistance and gain of amplifiers at low to high frequencies. High frequency response.

Simulation on SPICE. Some idea about time domain response and determining of transient response on SPICE.

Compound Configurations

Study of the differential pair, current sources, voltage sources, the Darlington and Cascode connections. Large signal output stages.

Application of Op-Amps.

Feedback amplifiers

Basic principles-advantages. Frequency response and stability of feedback amplifiers. Frequency

compensation.

Oscillators

Principles. The Hartley, Colpitt, Wien- bridge and phase shift oscillators. Determination of

frequency of oscillation and criteria for oscillations to occur.

Text Books/references:

1. P.E. Gray and Campbell L.Searle- Electronic Principles. Published by McGraw- Hill Book Company.

2. Paul R. Gray and R.G.Mayer- Analog Integrated Circuits Published by John Wiley and Sons, international edition.

3. Handouts to be supplied by the instructor.

ET 465 Signals and Systems

Theory: 100

Sessional: 50

Time: 3 hours

Introduction

Definitions, continuous and discrete-time signals. Systems and their classifications.

LTI systems

Continuours-time LTI systems - the convolution integral. Discrete time LTI systems – the convolution sum. Properties of LTI systems.

Systems described by differential and difference equations.

Fourier analysis of continuous time case

Response of LTI systerr-ss to complex exponential waveforms. Representations of periodic signals by the Fourier series. Representation

of periodic signals by Fourier transforms. Properties of Fourier transforms. System analysis by Fourier transforms.

Fourier analysis of discrete time case

Response of LTI systems to complex exponential waveforms. Discrete time Fourier series discrete time Fourier transform and their

properties. Analysis of systems.

Sampling

The sampling theorem Effects of undersampling. Spectrum of sampled signal.

Laplace transform

Definition and properties Methods of inversion. Application to LTI system analysis.

Z – transform

Definition. The region of convergence. Properties of z-transform. Inversion of Z- transforms. Application to system analysis.

Random signals and systems

Random variabies. Distribution and density functions. Statisticai averages. Different probabi'ity distribution models. Random processes.

Ensemble averages and correlation. Stationary and ergodic processes. Spectral density and its correlation functions Response of linear

random inputs.

ET 466 Network Theory-II

Theory: 100

Sessional: 50

Time: 3 hours

Network Topology

Graph of a network: Planar and non-planer graph, concept of incidence matrix, path, tree, circuits, fundamental circuits, cut-set,

fundamental cut-set tie-set schedule. Introduction to equation formulation.

Network Functions

Network functions of two-port networks. Driving point impedances and admittances. Poles and Zeros- their significance.

Determination of time domain behavior from pole-zero plots. Frequency characteristics of networks from network functions.

Magnitude and phase plots.

Network Synthesis

Elements of realizability theory. Hurwitz polynomial. Positive real functions. Basic technique used in syntheses of networks.

Synthesis of one port network with two kinds of elements-LC, RC or RL.

Transmission Lines

Lumped and distributed models. π and T models. Generalized equation of a transmission line at audio and radio frequencies.

Characteristic impedance and propagation constant. Group velocity and phase velocity. Distortion less lines. Reflection and

transmission coefficient. Standing wave and standing wave ratio. Line impedance and admittance. Smith chart.

Filter Theory

Filter fundamentals. Low pass, high pass, band pass filters. Pass and stop bands. K and M derived topology. Butterworth and

Chebyshev approximations. The Op-Amp as a basic circuit block. Active filters and some ideas about switched capacitor filters.

Attenuators & equalizers

Symmetrical and asymmetrical attenuators. T types, π type and lattice type attenuators. Two and four terminal equalizers, Full series,

Full shunt, Bridged T and lattice equalizers.


1. W.H.Hyatt and J.E.Kemmerly-Engineering Circuit Analysis. McGraw-Hill.

2. J.A.Edminister-Electrical Circuits. McGraw-Hill Schaum series.

3. Smrajit Ghosh- Network Theory. Analysis and Synthesis(PHI).

IE 651 Electrical Machines

Theory: 100

Sessional: 50

Time: 3 hours

D.C. Machines

Constructional features and principles of operation. Shunt, series and compound generators and motors. Performance characteristics.

Starting, speed control and braking of motors. Choice of d.c. motors for different applications.

Transformers Constructional features and principle of operation. Equivalent circuit.

Induction Motors Principle of operation of 3Φ induction motor. Equivalent circuit and circle diagram. Torque- speed characteristics. Methods of starting speed control and braking. Single phase motors- methods of

starting.

Synchronous Generators and Motors Principle of operation and simple equivalent circuit of a synchronous generator. Parallel operation and synchronization of generators.

Synchronous motor- methods of stating.

Application of A.C. motors in industries Typical application of A.C. motors in industry.


1. A.S. Langsdorf- Theory of Alternating Current Machines.

2. H.Cotton- Electrical Technology.

Branch: Instrumentation EngineeringBranch: Instrumentation EngineeringBranch: Instrumentation EngineeringBranch: Instrumentation Engineering Year: SecondYear: SecondYear: SecondYear: Second Semester: Semester: Semester: Semester:

FourthFourthFourthFourth

Sl

No.

Course No. Subject

Period Evaluation Scheme

Theory L T P Sessional Examination

ESE Subject

Total

Credit

TA CT Total

1. MA 401 Mathematics -IV 3 1 30 20 50 100 150 4

2. HU 402 Sociology and Accountancy 3 1 30 20 50 100 150 4

3. HU 403 Communication Skill 2 15 10 25 50 75 2

4. EE 441 Analog Electronics 3 1 30 20 50 100 150 4

5. EE 444 Data Structure 3 1 30 20 50 100 150 4


Instruments

3 1 30 20 50 100 150 4

7. IE 451 Fundamentals of Instrumentation 3 1 30 20 50 100 150 4

8 IE 452 General Proficiency 25 25 1


8. EE 441 Analog Electronics 3 25 25 50 50 2

9. EE 444 Data Structure 3 25 25 50 50 2


Instruments

3 25 25 50 50 2

TOT

AL 20 6 9 270 205 475 675 1150 33


TA: Teachers’ Assessment CT: Class Test ESE: End Semester

Examination

IE 451: Fundamentals of Instrumentation.

L T P (3 – 1 - 0)

Theory Marks =100 Sessional Marks =100 Time = 3 hours

1. Basic concept of measurement: Measurement system, Block-diagram representation, example. Static and dynamic characteristics, Compensation, dynamic calibration, Generalized instrumentation system block diagram representation, Selection criteria of instryments. 2. Errors & Uncertainties in measurement: Definitions, classification, data quality, equipment errors, interference errors, dynamic response errors, operational errors. 3. Statistical estimates of measurement data: Mean, median, mode, measures of disperson, mean deviation, standard deviation, variance, probable error. Error distribution functions—error tables (Gaussian), and applications, confidence level, significance tests. Chi-squared statistical test, Regression analysis of data, Graphical representation and curve fitting of data, best fit curves. 4. Methods of minimization and elimination of errors due to noise in measured data, input-output configuration,

filtering, averaging and correlation techniques. Recommended texts:- 1. Doeblin, E.O. : “ Measurement System Application and Design”, International Students Edition, McGraw Hill

International Book Co.,1983.

2. Barry E. Jones: “Instrumentation, Measurement & Feedback”, TMH, New Delhi,1983. 3. Cook,N.H.: “Physical Measurement &Analysis”, Addision Wesley, 1965. 4. Doeblin E.O.:”System Dynamics –Modeling & Response”,McGraw Hill,1972. 5. Holman J.P. :” Experimental Methods for Engineers” : McGraw Hill Int. Std. Edn.,1966.

Theory : 6.5 X 100 = 650

Sessional : 6.5 X 50 = 325

Practicals : 3 X 50 = 150

General Proficiency :25

Total :1150

Branch: CSE Year: Second year

Sl.

No.

Course

No. Subject

Periods Evaluation Scheme

L T P Sessional Marks

ESE Total

marks Credit

TA CT Total

1 MA401 Mathematics-IV 3 1 30 20 50 100 150 4

2 ET 464 Electronic Circuits 3 1 30 20 50 100 150 4

3 ET 465 Signals & Systems 3 1 30 20 50 100 150 4

4 CS 476 Computer Architecture &

Organization 3 1 30 20 50 100 150 4

5 CS 477 Data Structure 3 1 30 20 50 100 150 4

6

HU 402

HU 403

Sociology and Accountancy

Comm Skill

3 1 75 150 225 4


7 ET464L Electronic Circuits 3 30 20 50 50 2

8 ET465L Signals & Systems 3 30 20 50 50 2

9 CS 477L Data Structure 3 30 20 50 50 2


Total 18 6 12


TA: teachers assessment CT: Class Test ESE: End Sem Exam

MA 401 Mathematics IV

Theory: 100

Sessional: 50

Time: 3 hours

Unit 1: Series Solutions 25 Marks

Power series solution of initial value problems, Power series solution using recurrence relations, singular points and the method of

Frobenius, solution of Bessel’s equation and Bessel’s functions, solution of Legendre’s equation and Legendre Polynomials, orthogonal

set of functions, Strum-Liouville Problem, eigen values and eigen functions of singular problems, Bessel’s functions as eigen functions

of singular problem, Legendre Polynomials as eigen functions of singular problems, eigen function expansions.

Unit 2: Partial Differential Equations 25 Marks

Basic concepts, formation of partial differential equations, equation solvable by direct integration, linear and non-linear equations of first

order. Homogenous linear equations with constant coefficients, solutions of heat equations, wave equations, transmission line equations

and Laplace equations.

Unit 3: Tensor Analysis 20 Marks

Curvilinear coordinates, unit vectors in curvilinear system, representation of as vector F in terms of unit base vectors, contravariant and

covariant components of F, arc length and volume element in orthogonal curvilinear coordinates. Transformations of coordinates.

Definition of tensors, fundamental operations with tensors, Symmetric and skew-Symmetric tensors, Riemannian space and metric

tensor, Conjugate tensor, Christoffel symbols.

Unit 4: Calculus of Complex Variables 20 Marks

Analytic functions, C-R equations, conjugate functions, Harmonic functions, orthogonal systems.

Formation of analytic functions, conformal mapping, integration of a complex functions, Cauchy’s Integral Theorem, power series

representation of complex functions, Laurent’s Series, singularities, Residue Theorem.

Unit 5: Z-Transform 10 Marks

Definition, properties, Z-transform of some basic sequences, Z-transforms of some basic discrete functions, Shifting theorems.

Text books and References:

1. Advanced Engg. Maths, E. Kreyszig. Wiley Eastern Ltd.

2. Advanced Engg. Maths, Peter V. O. Neil. Thomson Books.

3. A Text Book on Engg. Maths, Bali, Tyenger. Laxmi Publishers.

4. Higher Engg. Maths, B.S. Grewal. Khanna Publishers.

5. Linear Algebra and it’s Applications, Gilbert Strang. Thomson Books.

6. Calculus, James Stewart. Thomson Books.

7. Laplace Transform, Spiegel. Thomson Books.

8. Elements of Partial Differential Equations, I. M. Snedon. S. Chand and Co.

9. Text book of Vector Calculus by Shanti Narayan, S. Chand and Co.

10. Function of Complex Variables by Shanti Narayan, S. Chand and Co.

ET464 Electronic Circuits

Theory: 100

Sessional: 50

Time: 3 hours

Bipolar amplifiers

Basic circuit-common base, common emitter and common collector topology. Biasing of single stage amplifiers- single power

supply and bipolar power supply. Multiple stage amplifiers biasing schemes with emphasis on direct coupling. NPN and PNP

connections. Hand calculation of bias current and voltages. Simulation of such circuits on SPICE.

Hybrid π small signal equivalent circuit

Computation of input resistance, output resistance and gain of amplifiers at low to high frequencies. High frequency response.

Simulation on SPICE. Some idea about time domain response and determining of transient response on SPICE.

Compound Configurations

Study of the differential pair, current sources, voltage sources, the Darlington and Cascode connections. Large signal output stages.

Application of Op-Amps.

Feedback amplifiers

Basic principles-advantages. Frequency response and stability of feedback amplifiers. Frequency

compensation.

Oscillators

Principles. The Hartley, Colpitt, Wien- bridge and phase shift oscillators. Determination of

frequency of oscillation and criteria for oscillations to occur.


4. P.E. Gray and Campbell L.Searle- Electronic Principles. Published by McGraw- Hill Book Company.

5. Paul R. Gray and R.G.Mayer- Analog Integrated Circuits Published by John Wiley and Sons, international edition.

6. Handouts to be supplied by the instructor.

ET 465 Signals and Systems

Theory: 100

Sessional: 50

Time: 3 hours

Introduction

Definitions, continuous and discrete-time signals. Systems and their classifications.

LTI systems

Continuours-time LTI systems - the convolution integral. Discrete time LTI systems – the convolution sum. Properties of LTI systems.

Systems described by differential and difference equations.

Fourier analysis of continuous time case

Response of LTI systerr-ss to complex exponential waveforms. Representations of periodic signals by the Fourier series. Representation

of periodic signals by Fourier transforms. Properties of Fourier transforms. System analysis by Fourier transforms.

Fourier analysis of discrete time case

Response of LTI systems to complex exponential waveforms. Discrete time Fourier series discrete time Fourier transform and their

properties. Analysis of systems.

Sampling

The sampling theorem Effects of undersampling. Spectrum of sampled signal.

Laplace transform

Definition and properties Methods of inversion. Application to LTI system analysis.

Z – transform

Definition. The region of convergence. Properties of z-transform. Inversion of Z- transforms. Application to system analysis.

Random signals and systems

Random variabies. Distribution and density functions. Statisticai averages. Different probabi'ity distribution models. Random processes.

Ensemble averages and correlation. Stationary and ergodic processes. Spectral density and its correlation functions Response of linear

random inputs.

CS 476 Computer Architecture and Organization

Theory: 100 marks

Sessional: 50 marks

Time: 3 hours

Evolution of Computer

Introduction, different generations till the present time. Basic structure of a computer.

Design Methodology

Components and design techniques at gate level, resistor level and processor level. Processing Unit of a Computer.

Processor organization

Number formats. Instruction formats, instruction types. Fixed point arithmetic, addition, subtraction, division and multiplication.

ALU

Organization floating point arithmetic, arithmetic processor.

Control Unit

Instruction sequencing and interpretation. Control unit design.

Memory Organization

Types of memories. Memory device characteristics. RAM organization. Memory hierarchies. Cost and performance Virtual memories.

High speed memories like caches.

Parallel Processing

Introduction and types of parallel processors with performance considerations. Pipe-line processors and multiple processors.

Text Books / references:

1. John P Hayes - Computer Architecture & Organization, Mc Graw Hill Book Company.

2. M. Mano - Computer System Architecture, Prentice-Hall of lndia.

CS477 Data Structure

Theory: 100

Sessional: 50

Time 3 Hours

Time and Space analysis of Algorithms – Order Notations.

Linear Data Structures : Sequential representations – Arrays and Lists, Stacks, Queues, Strings; Link Representations – Linear linked

lists, Circular linked lists, Doubly linked lists; Applications.

Recursion – Design of Recursive Algorithms, Tail Recursion.

Nonlinear Data Structures : Trees – Binary Trees, Traversals and Threads, Binary Search Trees, Insertion and Deletion algorithms,

Height Balanced Trees and Weight Balanced Trees, B-trees, B+ trees, Application of trees; Graphs – Representations, Breadth-first and

Depth-first Search.

Hashing – Hashing Functions, Collision Resolution Techniques.

Sorting and Searching Algorithms : Bubble sort, Selection sort, Insertion sort, Quick sort, Merge sort, Heap sort, Radix sort.

File Structures: Sequential and Direct Access, Relative files, Indexed files, B+ tree aas index, Multi-index files, Hashed files.

Books:

1. Data Structures and Algorithms, A. V. Aho, J. E. Hoppcroft, J. E. Ullman, Addision Wesley.

2. Fundamentals of Data Structures, E. Horowitzz, S. Sahni, Galgotia Publ.

3. Data Structures using C, A. S. Tanenbaum

4. Algorithms, Data Structures, and Problem Solving, Addision Wesley.

5. Data Management and File Structures, Loomis, Marry, PHI

6. M. A. Weiss – Data Structures & Algorithm Analysis in C++

, Addison Wesley.

7. Lipshutz – Theory and Problems of Data Structures, McGraw Hill.

8. Neil Graham – Learning with C++

, McGraw Hill

BRANCH: INDUSTRIAL & PRODUCTION ENGG. (4TH

Semester)

SL.No Course

No


Theory

L

T

P

Sessional/Exam.

TA CT Total

ESE Subject

Total

Credit

1 MA 401 Mathematics – IV 3 1 0 30 20 50 100 150 4

2 HU 402 Sociology and

Accountancy

3 1 0 30 20 50 100 150 4

3 HU 403 Communication Skill 2 0 0 15 10 25 50 75 2

4 ET 436 Applied Electronics 3 1 2 30 20 50 100 150 4

5 IP 434 Manufacturing Process –

II

3 0 0 30 20 50 100 150 4

6 IP 435 Industrial Statistics 3 2 0 30 20 50 100 150 4

7 IP 437 Material Science &

Technology

3 1 0 30 20 50 100 150 4

8 IP 439 General Proficiency 25 25 1

Practical/ Drawing/Design

9 IP 434L Manufacturing Process -

II

0 0 3 30 20 50 50 2

10 IP 437L Material Sc. &

Technology

0 0 2 30 20 50 50 2

11 IP 438L Workshop Practice - III 0 0 3 30 20 50 50 2

Total 20 6 10 1150 33

Total marks : 1150 Total Periods: 36 Total Credits : 33

TA : Teachers Assessment CT: Class test ESE : End Semester examination

IP 434 : MANUFACTURING PROCESS -II [ 3-0-3 ]

Theory-100 marks Sessional-50 marks Lab/Pract50 marks Time 3Hrs

Unit I : Mechanics of Metal Cutting Orthogonal and oblique cutting : chip thickness ratio, velocity relationships. Merchants’s theory

of metal cutting and Force relationship ; stress and strain and power consumption. Heat zones metal cutting. Economics of metal cutting.

Unit II : Lathe Classification, specification and size – lathe parts, work holding devices ; Lathe operations – Taper tuning, Thread

cutting, Speed, feed and depth of cut. Calculation of machining time.

Unit III : Drilling, Boring and Reaming Types of drilling machines , parts and their functions; drill types, twist drill terminology

,drill chucks—special drilling machines; speed, feed, torque and power consumption ; machining time. Deephole drilling and

Trepanning. Boring operation ; boring machine – Jig boring machine. Reaming – Reamer geometry, reaming allowances on a drilled

hole.

Unit IV : Shaping, Planning and Slotting machine Classification, specification and size – principle of Quick return mechanism.

Stroke length and Position adjustment of the ram. Simple operations – tool machining time.

Unit V: Milling Milling machine classification, milling spindle details, milling cutter types, Geometry of plain cutter. Milling operation

– up-milling and down-milling ; End, Gang and Form milling. Indexing – milling threads, gear and splines.

Unit VI: Grinding Types, specification and size of grinding machine. Grinding wheel – abrasive, bond, grift, structure, grain size ;

wheel dressing, truing, balancing and mounting – soft and hard wheels ; selection of wheels. Operation – grinding of flat, cylindrical and

contoured surfaces. Centreless grinding.

Unit VII: Broaching Types of broaching – broach tools – examples of broach work.

Unit VIII: Micro-finishing Processes Different processes – Grinding, Lapping, Honing and super-finishing – Polishing, Buffing,

Tumbling and Burnishing.

IP 435 : INDUSTRIAL STATISTICS [ 3-2-0 ] Theory-100 marks Sessional-50 marks, Time-3 Hrs

Unit I: Basic Statistical Concept Method of collection and presentation of data – variables and attribute. The frequency distribution

and its graphical representation : normal distribution.

Measurement of Central tendency and dispersion.

Unit II:Probability Definition and basic laws of probabilities, conditional probability, random variables, binomial, Poission’s & normal

distribution (only properties and applications ) sampling distributions : statistical hypotheses.

Statistical tests of significance, correlation and regression analysis. Auto-correlation.

Unit III :Statistical Quality Control Control charts for variables -- X & R chart and control charts for attributes -- P and C charts.

Unit IV:Acceptance Sampling Introduction – Methods, The O.C. Curve : Quality indices for acceptance sampling plans -- design

of an acceptance plan.

Unit V:Analysis of variance & Design of Experiments One way & two way classification, Basic Experimental design : Randomised

block, Latin square, Factorial 22 experiment.

Unit VI : Introduction to stochastic problems in engineering.

Reference Books

1) Statistical Methods ---- an introduction by J. Medhi.

2) Fundamentals of Statistics Vol – II by A.M. Goon, M.K. Gupta and B.D. Gupta (Chapters 20, 27)

3) Fundamentals of Applied Statistics by S.C. Gupta and V.K. Kapoor ( Chapter 5 & 6 )

IP 437 : MATERIAL SCIENCES AND TECHNOLOGY [ 3-1-2 ]

Theory-100marks Sessional-50marks Lab./ Practical-50marks Time 3Hrs

Unit I:Crystal Structure Atomic bonding, packing and crystalline structure – unit cell, Miller indices, crystal imperfections.

Determination of grain structure by light microscope, electron microscope and X-ray diffraction.

Nucleation, grain growth from liquid phase, dendritic growth.

Unit II :Deformation in solids Slip and twining, critical resolved shear stress. Fracture – brittle and ductile, Griffith’s theory. Elastic

after effect, Bauchinger effect, Season cracking and preferred orientation.

Work Hardening – concept, theory and stages.

Recovery, recrystallisation and grain growth.

Unit III : Phase diagrams Gibb’s phase rule – simple binary phase diagrams, Lever rule.

Iron – Carbon equilibrium diagram – eutectic. Peritectic and eutectoid reactions – microstructure. T-T-T diagram.

Unit IV : Heat Treatment Objectives and principle – General heat treatment processes – hardenability and Jominy hardness test.

Heat treatment of steel.

Unit V : Steel and cast Iron Classification and types – Effect of alloying elements ; Tool and die steels. Spring steels, heat and Scale

resistance steels. Non-ferrous alloys : babbits : copper-based, aluminium-based and nickel based alloys.

Unit VI:Corrosion Definition, factors influencing corrosion, types of corrosion, basic corrosion mechanisms, specific types. Control

and prevention, Oxidation.

Unit VII : Material Testing Testing for tensile and compressive strength, hardness, impact and bend test – Fatigue and Creep testing.

Non-destructive testing.

EE436: Applied Electronics Theory: 100 Marks

Sessional:

Time: 3Hrs

1. Study of Electronic Devices: Diode. BiT, JFET, MOSFET- device characteristics and principle of operation.

2. Power Supply: Rectifiers, half wave and full wave rectifiers, filters and regulators.

3. Amplifiers: Transistor biasing and amplification using I3JT and FETs for current and voltage signals. Amplifiers with negative feedback.

Sinusoidal Oscillators : RC phase shift oscillator, Wein Bridge oscillator.

4. Operational Amplifiers: Various applications of 0p

amps along with circuit diagram. ADCs, DACs.

5. Power Electronics: SCR, UJT characteristics, working principle and applications.

6. Digital Electronics: Number system, Boolean algebra, Logic gates, combinational logic circuit representation and minimization, Various

combinational logic circuits- binary arithmaric circuit, multiplexer, demultiplexer, decoders, encoders, comparators etc. Sequential logic circuits:

flip Hops, registers, counters, memories, FPGA, PLA, PLC’S.

7. Present trend in digital techniques for measurement and control of industrial process using microprocessors, microcontrol lers. embedded syste

ins.

8. Electronic instruments: Multimeter for voltage and current measurement, CR0 and its various controls, function generators. counters. IC tester

Documents

Branch: Civil Engineering. Year: Second. Semester: Fourth ...bbec.ac.in/wp-content/uploads/2015/08/4th-Sem-all.pdf · MA 411 (CE & Ch.E) ADVANCED MATHEMATICS AND NUMERICAL ANALYSIS