Mbatech Trimester 1 Syllabus

SVKM’s NMIMS University Mukesh Patel School of Technology Management & Engineering

1

MBA (Tech) IT, Telecommunication, Chemical, Manufacturing

Trimester I

Sub: APPLIED PHYSICS-I Code: 501 PHS Lecture* 2.5 Practical 3 Hrs. Periods per week Tutorial -

Hours Marks Theory Examination 1.5 50 scaled down to 25 Evaluation system Term work 25

*Each lecture of 1hr Objective: To develop understanding of the fundamentals of the subject and develop the ability to use it for various Engineering applications. To expose the students to relevant topics in the subject of Physics Prerequisite Knowledge of HSC Level Physics

Detailed syllabus Unit Topics Duration (Hr)

1

Solid State Physics: Crystal Structure: Structure of cubic crystals, special form in cubic crystals, diamond structure, Barium Titanate, Miller indices, planes and direction, legancy and critical radius ratio in ionic crystal. Imperfections: point, line, surface & volume (Introductory); Formation of energy bands and classification of solids, conductors, semiconductors, insulators. Physics of semiconductor junction. Fermi levels in semiconductor, energy gap and its temperature dependence.

10

2

Electricity and Magnetism: Motion of charges in electric field and magnetic field. Application of electric and magnetic field to determine e/m and cyclotron. Electrostatic focusing system, C.R.O. (concept, theory) and uses.

7

3

Thermo-electricity: See back effect, Peltier effect, Thomson effect, thermo-electric power, law of successive temperature, law of intermediate metals, application of thermodynamics on thermocouple. Thermopile

4

4

Sound Waves:Audible, ultrasonic and infrasonic wave propagation, peizo-electric effect, production of ultrasonic waves. Applications of ultrasonic waves, echo sounding, thickness measurement, cavitation and non-destructive testing and flow detection.

4

Total 25


2

Books:

Reference books: Concept of Modern Physics; Arthur Beiser TMH Engineering Physics; R.K. Gaur and S. L. Gupta; S.Chand Co. Engineering Physics; A. S. Vasudeva Nuclear Physics; Cohen.

Internet references: Nil

Term work: Report on experiments performed (at least 5) based on syllabus Assignment consisting of numerical problems (at least 20) Two Written Test during the term.


3

MBA (Tech) IT, Telecommunication, Chemical, Manufacturing Trimester I Code: 502 CHS

Lectures * 2.5 Sub: Applied Chemistry I Periods per Week

Practical 3 Hrs.

Theory Examination Hours Marks

1.5 50 (scaled down to 25)

Evaluation system

Term work - 25 *Each lecture of 1hr Objective: To understand and explain the applications of core chemistry to the materials. To understand the gravity of the air and water pollution and implement the safety measures to overcome the problems due to pollution.

Prerequisite

1. Brief Knowledge of environmental cycles 2. Use of formulae for the calculations. 3. Chemistry of functional groups – hydroxy compounds and

hydrocarbons Detailed syllabus

Unit Topics Duration (Hr)

1 Environmental Chemistry: Natural cycles of the Environment 02

2 Pollution: Air Pollution, Control of Air Pollution, Water, Water pollution. 07

3 Polymers: Polymerisation, Classification of Polymers, Methods of Polymerisation, Commercial polymers, Elastomers, Commercial Elastomers

07

4 Lubricants: Importance, classification of lubricants, Testing of Liquid Lubricants 06

Total 25


4

Books: Reference books: 1. Engineering Chemistry – B.K. Sharma 2. Engineering Chemistry – Jain & Jain (Dhanpat Rai Publishing Company) 3. Applied Science – I - Dr. (Mrs.) J.A. Parikh & Dr. I.S. Sheikh (Nanddu Publishers & Pvt. Ltd) 4. Polymer Science – V.R. Gowarikar, Wiley Eastern Ltd. 5. Fundaamentals of Engineering Chemistry – Theory & Practiceee – S.K. Sigh (New Age Industrial Publishers)

Internet references: www.chemweb.com

Term work: 1. Experiment based on above syllabus. 2. Minimum two class tests. 3. Any assignment given by the Faculty.


5


Trimester I

Sub: BASIC ELECTRICAL ENGINEERING

Code: 505 EES

Lecture* 5 Practical 3 Hrs Periods per week

Tutorial - Hours Marks Evaluation system Theory Examination 3 50 (100 scaled down to 50) Term work 50 *Each lecture of 1hr Objective: At the completion of this course, student becomes familiar to fundamentals of electrical engineering. Machines and transformers form the major component of electrical engineering discipline and understanding their principles and technicality is the prime objective of this course. No enterprises engaged in any activity do away with machines, motors and transformers either as tools. Prerequisite Knowledge of HSC level Physics. Detailed syllabus Unit Topics Duration (Hr)

1 Units of work, power and energy. Effect of temperature on resistance. Series parallel circuits. 4

2 Concept of linear & nonlinear circuit. Kirchoff’s law, Superposition theorem, Thevenin’s theorem & Norton’s theorem. Max Power Transfer theorem

13

3 DC Transients: R-L & R-C transients, time constant, expression for energy stored for inductance & capacitance. 4

4

AC Fundamentals: Alternating quantities, RMS & Avg values, form factor, frequency, crest factor, series combination of R-L, R-C & R, L, C (with resonance) & parallel circuits (with resonance). Three phase circuit. Concept of balanced & unbalanced tools. Expression for total power, KW, KVAR & KVA.

16

5 Single-phase transformer, emf equation, determination of efficiency & regulation by direct loading. 4

6 Basic principles of measurement of electrical quantities voltmeter, ammeter, wattmeter, energy meter. 4


6

7 DC & AC Machines: Working principles, speed control. Three phase induction motor, single-phase motor, working, applications of motors.

5

Total 50

Books:

Reference books:

1. Electrical Engineering Fundamentals; Vincent Del Toro, Prentice Hall Pvt. Ltd.

2. Electrical Technology “Cotton”; Wheeler Pub. 3. Electrical Technology; B. L. Theraja 4. A course in Electrical & Electronics Measurement & Instrumentation;

A. K. Shawney, Dhampat Rai & Sons. 5. Basic Electrical Engineering; V. N. Mittle; Tata McGraw Hill.

Internet references: www.electric circuit.com Term work:

1. The term work shall comprise of at least six laboratory experiments and assignments based on the whole syllabus, duly recorded and graded.

2. Minimum two class tests.


7


Trimester I

Sub: Applied Mathematics - I Code: 503 MAS Lecture* 6 Practical Periods per week

Tutorial - Hours Marks

Evaluation system Theory Examination 3 50 (100 scaled down to 50) Term work - 50 *Each lecture of 1hr Objective: To provide an understanding of the basic concept of Applied Mathematics at post secondary level Prerequisite Knowledge of HSC level mathematics

Detailed syllabus Unit Topics Duration (Hrs)

1

Applications of Derivatives: Curve Sketching; maxima and minima; increasing and decreasing functions; concavity and points of inflection; asymplotes; and symmetry; related rates; mean value theorems; Taylor’s formula; Maclauarin series; l’Hospital’s rule; linear and quadratic approximations; arc-length in Cartesian coordinates.

15

2

Partial Derivatives: Level curves and level surfaces; chain rule; homogeneous functions in 2 or 3 variables; Euler’s theorem; examples linear approximations and bounds on the error; gradient, directional derivative, tangent plane and normal line to a level surface.

15

3 Lagrange Multiplier Method: Maxima and minima in 2 variables; constrained maxima with one or two constraints; least squares method for fitting a straight line or a parabola.

15

4 Vectors: Scalar and vector triple products; equation of a line and a plane; angle between 2 planes; distance of a point from a line or plane; plane determined by 2 lines.

15


8

Total 60

Note: Proofs and theorems are not expected.

Books:

Reference books:Advanced Engineering Mathematics; Erwin Kreyszig, Wiley Eastern Limited. Calculus and Analytic Geometry; G. B. Thomas and R. L. Finney, Narosa Publishing House.

Internet references: Nil

Term work: 1. At least 2 written test shall be given during the trimester. 2. Any assignment given by the Faculty


9


Trimester I

Sub: COMPUTER FUNDAMENTALS Code: 506 CCS Lecture* 5 Practical 3 Hrs. Periods per week


Evaluation system Theory Examination 3 50 (100 scaled down to 50)

Term work 50 *Each lecture of 1hr Objective: To give basic idea of operating environment and the system oriented languages and the in-depth understanding of “C” programming language. This will help in learning the various techniques to be covered in future trimester. Prerequisite Basic knowledge of Computers


1

Computer Basics: Organization of a computer, characteristics of a computer, Central Processing Unit (CPU), input/output devices, computer memory, primary memory and secondary memory, memory organization, backup devices.

08

2 Data Representation: Representation of characters, integers and fractions, binary and hexadecimal representations. 03

3 Computer Languages: Assembly language and characteristics of high-level language. 03

4 Operating System Basics: Multiprogramming and time-sharing operating systems. 04

5 C Fundamentals: Character Set, Identifiers and Keywords, Data types, Constants, Variables and Arrays, Declarations, Operators & Expressions, Library functions, Statements,

04


10

Symbolic Constants, Preprocessor directives.

6 Data Input and Output: getchar( ), putchar( ), scanf( ), printf( ), gets( ), puts( ) functions 02

7 Control Statements: if-else, while, do-while, goto, for statements, nested control structures, switch, break, continue statements, comma operator.

07

8 Functions: Function prototypes, passing arguments to a function by value, recursion, storage classes, automatic, external, static, register variables in single file environment.

07

9 Arrays: Defining – processing array, passing arrays to functions. Introduction to multidimensional arrays, arrays and strings.

04

10 Pointers: Declarations, Referencing and de-referencing, passing pointers as functions, pointer to array. 04

Structures and Unions: Defining and processing a structure. 04 Total 50

Books:

Reference books: V. Rajaraman; Fundamentals of computers; PHI Balaguruswamy; Programming in C; TMH Ram Kumar & R. Aggarwal; Programming in ANSI C; TMH Schaum Outline Series; Programming in C Y. Kanetkar; Let us C; BPB Internet references: As given by the faculty Term work: Each student has to appear for three class test & clear at least two. Programs based on above Syllabus. Any assignment given by the Faculty.


11

MBA (Tech) (Common for all) Trimester I Sub: Basic Engineering Drawing Code: 504 MES

Lecture* 2 Practical 5 Periods per week Tutorial -

Evaluation system Theory Examination Hours Marks 4 50 (100 scaled down to 50)

Term work 50 *Each lecture of 1hr Objective: To develop skill in reading & understanding of drawings used in engineering industries. Students should be conversant with the use of code of practice used in Engineering Drawing. This will develop proficiency in use of drawing as a medium of communication and information document between a designer, manufacturer & end user. Prerequisite Nil

Detailed syllabus Unit Topics Duration

(Hr)


12

1

Introduction to Engineering Drawing. Engineering Curves Projections of lines (only first quadrant) Sections of Solids & development. Multi view orthographic projections of machine parts by first angle and third angle method of projections. Sectional views to be included. Reading and interpretation of orthographic projections (Missing views) Isometric View Free hand sketches Bolts: - Hexagonal, Square and Cylindrical heads. Nuts: - Hexagonal, Square, Wing and Capstan. Set screws.

2 2 3

5

3

3

1

2 Preparation of three views of 2 D drawings using computer 2

Total 20

Books: Reference books:

1. Engineering drawing By N D. Bhatt 2. Engineering drawing By P.J.Shah

References: Engineering drawing By N H. Dubey Internet references: Nil Term work:

1. Single drawing sheet per topic – 10 Drawing sheets 2. 3 Test of which best two will be considered.


13


Trimester II

Sub: Applied Mathematics II Code: 509 MAS Lecture* 6 Practical -

Periods per week

Tutorial - - Hours Marks Evaluation System Theory Examination 3 100(Scaled down to 50) Term work 50 *Each lecture of 1 Hr. Objective: To provide an understanding of the basic concept of Applied Mathematics at post secondary level


14

Prerequisite To provide an understanding of the basic concept of Applied Mathematics at post secondary level

DETAILED SYLLABUS Unit Topics Duration (Hr)

1 Hyperbolic functions: Complex numbers and De Moivre’s theorem, roots of unity, Log z, Sinh Z, Cosh Z; graphs, identities, derivatives and integrals; catenary (hanging cable); inverse hyperbolic functions

08

2 Double and Triple integrals: Set up and change of order; centre of mass and moments of inertia; radius of gyration; polar coordinates using the Jacobian; triple integrals in rectangular and spherical coordinates; application of double and triple integral to area, mass, volume and centroid.

12

3 Beta and Gamma functions: Definitions; relation between beta and gamma functions; duplication formula; evaluation of integrals.

12

4 Differential Equations: First order and first degree exact differential equation and those which can be reduced to exact by use of integrating factor (only four rules of IF and IF by inspection), Linear differential equation and equation reducible to linear equation, Linear differential equation of higher order with constant coefficients. Complementary functions. Particular integrals for the equation of the type f(D)y = X where X = eax , xm , Sin(ax + b), Cos(ax + b), eaxV, x.V where V is a function of x (Derivations of PI are not expected), Cauchy’s linear homogenous equation and Legendre differential equation. Variation of parameter methods and method of undetermined coefficients. LRC circuit equation and its solution

18

5 Standard curves: Straight line, circle, parabola, ellipse, hyperbola, regular hyperbola 10

TOTAL 60

BOOKS:

Reference books: • Advanced Engineering Mathematics: Erwin Kreyszig, Wiley Eastern Schaum

Outline Series: McGraw Hill Book Co.

Internet references: nil


15

Term work: • Minimum two assignments given by the faculty • Two Team tests of which best will be considered


Trimester II

Sub: Applied Chemistry II Code: 508 CHS Lecture* 2.5 Practical 1.5 Hrs

Periods per week

Tutorial -

Hours Marks

Evaluation System Theory Examination 1.5 50 (scaled down to 25)

Term work 50 (scaled down to 25)


16

*Each lecture of 1 Hr. Objective: To understand and explain the applications of core chemistry to the materials. To understand the gravity of the problem of corrosion w. r. t. maintenance of the machines in the industry. Prerequisite: Knowledge of electrochemical reactions. Properties of the metals. Knowledge of conventional fuels.

DETAILED SYLLABUS

Unit Topics Duration (Hr)

1 Fuels: classification of fuels, bomb calorimeter, solid fuels, liquid fuels, cracking, octane no., gaseous fuels. 06

2 Corrosion: types of corrosion, factors influencing corrosion, corrosion control 06

3 Alloys: Principal of alloying, types of alloys 02 4 Protective coating: metallic coating, organic coating 05

5 Electrochemistry: electrochemical cell, EMF, Nernst theory, batteries- primary and secondary. 06

TOTAL 25

Books:

Reference books: Engineering chemistry – B.K.Sharma Applied Science – II - Dr. Mrs. J.A.Parikh (Nandu hi

Publications)

References: Engineering Chemistry – Jain& Jain , Dhanpat Rai & sons Numerical problem in Chemistry - R.N.Sarin Chemistry of Engineering Materials – Robert B. Ligeou

Internet references: www.chemweb.com

Term work: • Experiments based on above syllabus. Minimum 5 experiment based on above syllabus. • Assignment given by Faculty. Minimum 2 assignments given by the faculty • Two class tests of which best will be considered


17


Trimester II

Sub: Applied Physics II Code: 507 PHS Lecture* 2.5 Practical 1.5 Hrs

Periods per week

Tutorial - Hours Marks Evaluation System Theory Examination 1.5 50 (scaled down to 25) Term work 50 (scaled down to 25) *Each lecture of 1 Hr.


18

Objective: To enable students to understand the basic principles of advanced physics theory and practice To prepare students with necessary foundation for further studies in electronics, Applied Physics etc. Prerequisite Knowledge of HSC level Physics


1

Optics: Analytical treatment of interference, intensity distribution of fringe system, coherent and non-coherent sources, interference in thin film in reflected and transmitted system, wedge shaped film, Newton’s rings and applications. Diffraction: Fraunhotter’s diffraction at single slit, double slit, N Parallel slits, (Mathematical deviation not expected), diffraction grating, resolving power of grating, dispersive power of grating.

7

2

X-Ray: X-Rays origin and characteristic of X-Ray, properties of X-Rays, Mosseley’s law, X-Ray diffraction, Bragg’s law, Bragg’s X-Ray Spectrometer and determination of crystal structure.

5

3

LASER: Spontaneous and stimulated emission population inversion, pumping device and active device. Lasing action, Ruby Laser, He-Ne Laser, CO2 Laser, Semiconductor Laser. Applications of laser & application of laser in holography

5

4 Fiber Optics: Total internal reflection, principle and working of optical fibers, different types of optical fibers, modes of propagation in fiber, multimode and monomode fibers.

4

5 Super-conductors: Theoretical Explanation of super conductors: BCS Theory, Meissner effect, Type-I & Type-II Superconductors, properties and uses of superconductors.

4

TOTAL 25

Books:

Reference books: 1) Jenkins and White “Optics” MC Graw Hill 2) A.K. Ghatak “Optic” 3) A.K. Ghatak & Thyagarajan “LASER” Theory and application.. 4) Agrawal, Fiber Optics Communication. 5) Engineering Physics – A.S. Vasudeva.

Internet references: www.orcad.com


19

Term Work: A: Part on experiments performed (at least 5) based on syllabus. (ii) Assignment consisting of numerical problems (at least 20)

B: Two written test during term.


Trimester II

Sub: Basic Electronics Code: 511 EES Lecture* 5 Practical 3 Hrs

Periods per week



20

Evaluation system Theory Examination 3 100 (Scaled down to 50)

Term work 50 *Each lecture of 1 Hr. Objective: Electronics engineering deals with semiconductor devices handling currents, voltages and powers of much smaller magnitudes (Few volts, few hundred milli-amperes and few watts) and today’s major technological break through in telecommunication, computers work with electronic devices.)It is the aim of this course to introduce, the basic electronic devices, their working principles, constructional details and their utilizes in few known electronic systems like amplifiers. Prerequisite Knowledge of HSC level Physics


1 Semiconductor-Energy bands, PN junction diode, type of different diode & their characteristics, users.

4

2 Rectifies circuits, Basic filters, voltage regulators (using zener diode)

10

3 Trnsistors: Static characteristics, constructional details of BJT, FET & UJT etc.

12

4 Photo devices: construction, characteristics & users of photo devices such as phototransistors, LEDs, LCDs etc

6

5 Thyristors-Basic principles of conduction, static Characteristics, DIAC, TRIAC &applications

6

6 Amplifiers: Amplifier concept, Introduction to feedback, different configurations-CE, CB, CC, RC Coupled & Transistors coupled amplifier. Introduction of Power amplifier.

12

TOTAL 50

Books: Reference books: Electronic Devices & Circuits Theory-R.L.Boylestad & L Nashelsly Electronic Devices & Circuits – Allen Motorshed Basic Electronic-Bernad Grob,Tata Mc Graw Hill Company Basic Electronic-B.L.Theraja

Internet references: As given by the Faculty

Term work:


21

• The term work shall comprise of at least six laboratory experiments and minimum two assignments based on the whole syllabus, duly recorded and graded.

• Minimum two class tests of which best will be considered.


22


Trimester II

Sub: Computer Programming Code: 512 CSS Lecture 5 Practical 3 Hrs

Periods per week

Tutorial - Hours Marks Evaluation system Theory Examination 3 100 (Scaled down to 50) Term work 50 *Each lecture of 1 Hr. Objective: This course consists of fundamentals of Object Oriented Programming. The basic idea of Object Oriented Concepts like Abstraction, Encapsulation, Polymorphism, Inheritance and Data Hiding are covered. The objective of the course is to implement the various concepts through the Object Oriented Language ‘C++’ which is the basic need for learning the various techniques to be covered in the further semesters. Prerequisite Knowledge of Trimester I level Computer Fundamentals


1 C++ Fundamentals: Data types, operators, Preprocessor directives, Declarations, Input & Output, Manipulators (endl,setw(), setprecision()), Control structures, functions and arrays.

05

2 Objects and classes: Data hiding and encapsulation, Private and public members, Member functions, Accessing class members, Objects as function parameters, static data & member functions, friend functions & friend classes.

9

3 Object Initialization & Cleanup: Constructors, Parameterised constructors, Destructor, Constructor overloading, Constructors with default arguments, Constructors with dynamic operations.

06

4 Function & Operator Overloading: Function overloading, functions with default arguments, inline functions, unary operator overloading, binary operator overloading, overloading arithmetic, relational & assignment operators

07

5 Inheritance: Derived & base class, protected members, Overriding functions. Private, protected & public inheritance, derived class

06


23

constructors, levels of inheritance & multiple inheritance 6 Pointers:

Void pointers, Pointer to functions & objects, this pointer, Pointers & memory management, new & delete operators, Dynamic memory allocation, creating one & two dimensional arrays with dynamic memory allocation.

05

7 Virtual Functions & Polymorphism: Need for virtual functions, Pointer to derived class object, Pure virtual functions, Abstract classes, Dynamic or late binding.

04

8 File Handling Introduction: Files & streams, Opening & closing a file, Input and output, Classes and files.

04

9 Templates: Function templates & class templates.

04

TOTAL 50

Books:

Reference books: Balaguruswamy, “Programming in C++”, TMH Robert Lafore, “Object Oriented Programming in turbo C++”, Galgotia Herbert Schildt, “Complete Reference”, TMH Y.Kanetkar, “Let us C++”, BPB Internet references: Nil Term work:

• Term work should consist of at least 10 practical experiments and two assignments covering the topics of the syllabus. Two class tests will be conducted during course of which best will be considered.


24


Trimester II

Sub: Material Science Code: 510 MMS Lecture* 5 Practical 3 hrs.

Periods per week

Tutorial - Hours Marks Evaluation system Theory Examination 3 100 (Scaled

down to 50) Term work 50 *Each lecture of 1hr duration Objective: To enable an understanding of engineering materials their structures, properties and performance. To enable an understanding of the criteria for selection of engineering materials for different applications. Prerequisite Higher Secondary level Physics


1

Crystal structure: Classification of crystal structure, unit cell, co-ordination number, atomic packing factor. Single crystal and polycrystals. Deformation in single and polycrystalline materials.

4

2

Crystal Imperfections & Deformation: Point defects : Vacancy, Interstitialty, Impurity atoms, their formation and effects. Dislocation: Edge and Screw dislocations, their significance Surface defects, Grain boundary, sub-angle grain boundary, stacking fault, their significance. Deformation: Elastic & Plastic deformations and their significance

6

3

Metals & Alloys: Formation of solids from liquid of pure metals and alloys. Ingot defects and their remedies. Classification of alloys: Eutectic, Eutectoid & peritectic alloys, conditions of their formation and importance. Solid solutions (conditions and importance of their formation). Effects of alloying elements Minor alloying elements Major alloying elements

8


25

4

Principles of heat and surface treatments: Equilibrium transformations in Iron-Iron carbide systems. Non-equilibrium transformation Mechanisms of pearlite, bainite and martensite transformations Principle of heat treatment of steels from T.T.T. diagram Significance of austenization, homogenization and controlled decomposition of austenite Heat treatment furnaces, salt baths and cooling media. Heat treatment in controlled atmosphere Basics of Hardening- (case & full ) Annealing & Normalizing Basics of Surface Treatments like electroplating, anodizing, Surface Coatings etc.. Joining: Welding, Brazing & Soldering (briefly)

12

5

Polymeric & Composite Materials – Classification, Types, Properties & Applications. Introductions to Additives for Polymers. Introduction to Polymer composites, Blends & Alloys. Simple method of identification of Polymeric materials Introduction to ceramic & composite materials

10

6

Properties, Testing & Selection of Materials: Introduction and Classification of Materials. Basics of Properties of Materials (Physical , Mechanical, Electrical, Chemical, Thermal etc.). Testing of Materials for Mechanical, Physical, Electrical, and Thermal etc. Basics of Non Destructive testing techniques for flaw detection. Important alloys: Alloy steels, tool steels, stainless steels. aluminium copper, nickel, tin and zinc, their specification and application. Selection of Materials for industrial applications

10

TOTAL 50

Reference books: A text Book of Material and Metallurgy – Dr. O. P. Khanna Engineering Physics – A. S. Vasudeva Physical Metallurgy – Y. Lakhtin Introduction to Engineering Materials – NIIT, Phi, Pvt. Ltd., New Delhi Mechanical Metallurgy – George Dieter Physical Metallurgy - Sydney Avner, Tata McGraw Hill Internet references: www. asm international – Website – USA Term work: Practicals based on Syllabus. Minimum two-class test Any assignment given by the Faculty


26

MBA (Tech) IT, Telecommunication, Chemical, Manufacturing Trimester III Sub: COMPUTER APPLICATIONS AND NUMERICAL TECHNIQUES

Code: 517 CSS 518 MAS

Lecture* 5 Practical 3 Hrs. Periods per week Tutorial

Hours Marks

Evaluation system Theory Examination 3 50 (100 Scaled down to 50)

Term work 50 *Each lecture of 1hr duration Objective: This will lay strong foundation for solving calculus problems of numerical methods using computer.

Prerequisite Computer Fundamentals, Computer Programming


1

Introduction to Spreadsheets: Understanding Workbooks and Worksheets, Editing Worksheet Data, Working with cells and ranges, Worksheet Formatting, Understanding Files and Templates, Working with Formulas and Functions, Creating charts and Graphics.

08

2

Introduction to Databases: Reaching the limits of spreadsheets, importing the spreadsheet idea into Access, Obtaining information using Queries, Relational Database Design, Different types of Access Queries, Designing Reports

09

3 Web-Site Design: HTML: Common Tags in HTML, Cascading Style Sheets, Frames, Form elements, DHTML, Introduction to Client Side Scripting.

09

4 Solution: of Algebraic and Transcendental Equations. 05

5

Curve fitting (including relevant engineering Problems): Interpolation – Newton’s divided difference, language interpolating polynomials, Approximation; least square approximation, linear regression, and polynomial egression.

07

6 Numerical differentiation (including relevant engineering application): Methods based on interpolation and finite differences, 05

7 Numerical integration (including relevant engineering Problems): 07


27

Taylor’s method, Picard’s method of successive approximation, Runge-Kutta methods, Euler’s predictor-corrector Milne’s method, Runge-Kutta methods of second and fourth order, boundary value and eigen-value problems.

TOTAL 50

Books: John Walkenbach “ Excel Bible”, Wiley publishing, Inc Bernarn V. Liengme, “A guide to Microsoft Excel 2003 for Scientists and Engineers”, Butterworth Heinemann Alex Homer, “ The Beginners Guide to Access”, Wrox Thomas A.Powell, “HTML: The complete Reference”, TMH S.S.Sastry, “Introductory Methods of Numerical Analysis”, PHI Chapra, Steven C. Canale, Raymond P.”Numerical Methods for Engineers”, TMH Robert S. Schilling, Sandra Hasses “Applied Numerical Methods for Engineers”(Using MATLABS and C), Thompson Learning Publications. Balagurusamy, “Numerical Methods”, TMH. Veer Rajan “Numerical Methods & Solutions.” Internet references: As given by the Faculty

Term work: Term work should consist of at least 10 practical experiments and two assignments covering the topics of the syllabus. The 10 experiments should include 6 experiments on Numerical Techniques using Excel, 4 experiments on HTML. Two class tests


28


Trimester - III

Sub: Applied Mathematics - III Code: 514 MAS Lecture* 5 Practical - Hrs Periods per week

Tutorial 3 Hrs. Hours Marks

Evaluation system Theory Examination 3 50(100 scaled down to 50) Term work 50 *Each lecture of 1hr duration Objective: To provide an understanding of the basic concept of applied mathematics at post secondary level

Prerequisite


1

Matrices: Definition, transpose; addition, subtraction and multiplication of matrices, Types of matrices, adjoint of a matrix, determinant, inverse of a matrix, rank of a matrix, linear dependence and independence of rows and columns of a matrix over real field. Simultaneous equations: Three unknowns, consistency of a set of equations and its solution, Cramer’s rule. Polynomial: Characteristic equation, characteristic roots and characteristic vectors of a square matrix.

16

2

Laplace transform, Definition, Laplace transform of, a constant, t, e-at , sin at, cos at, e-at sin a and, e-at cos at, evaluation of Inverse Laplace using partial fraction expansion (simple cases), Laplace transform of the derivatives of a function, solution of linear constant coefficient inhomogeneous differential equations using Laplace transforms.

12


29

3

Fourier Series: Orthogonality and orthonormal functions, Expression for a function in a series of orthogonal functions, Drichlet’s conditions, with period 2 pi, and 2 l (Derivation of Fourier coefficients a0, an, bn is not expected) Drichlet’s theorem, Even and Odd functions. Half range sine and cosine expansions, Parseval’s identities (without proof).

10

4

Random variables: Discrete and continuous random variables, probability mass function, and density probability distribution for random variables, expected value, variance, moments, and moment generating functions, relation between raw moments and central moments

12

TOTAL 50

Books:

Reference books: Advanced Engineering Mathematics- Erwin Kreyszig, (Wiley Eastern Ltd.) Schaaum’s Outline Series- Mc Graw Hill Book Co.


Term work: 1. Minimum two class tests. 2. Assignments given by the faculty based on above syllabus


30


Trimester - III

Sub: Engineering Mechanics Code: 515 MAS Lecture* 5 Practical 3 Hrs. Periods per week


Evaluation system Theory Examination 3 50(100 scald down to 50)

Term work 50 *Each lecture of 1hr duration Objective: Engineering Mechanics is a physical science, which is concerned with the study of resultant effect of action of forces on bodies, both in a state of rest and in motion. This subject is a basic course in engineering study of advance engineering subjects, like Mechanics of Deformable bodies, Mechanics of fluids, Structural Analysis, Theory of Machines and Robotics.

Prerequisite Knowledge of H.S.C level Physics

Detailed Syllabus Unit Topics Duration (Hr)

STATICS

1

Coplanar Forces: • System of forces, Moment of force, Varignon’s Theorem,

Resultant of – I. Concurrent Forces ii. Parallel Forces, iii. General force system.

• Equilibrium of coplanar forces, Condition of Equilibrium, Free Body diagrams, Types of supports and their reactions,

10


31

Detrmination of support reactions, Lami’s theorem.

2

Frames and Trusses: • Analysis of determinate pin-joined frames. • Analysis of determinate plane trusses by method of joints and

method of sections

6

3

Friction: • Laws of friction, Angle of friction, Angle of repose, cone of

friction. • Applications to problems involving bodies on inclined plane,

wedges, ladders and screw jack.

6

4

Centroid and Moment of Inertia: • Centroid of Centroid composite plane areas, Centroid of bent up

wires. • Moment of Inertia of composite plane areas, Parallel axis

theorem, Perpendicular axis theorem, Radius of gyration.

6

DYNAMICS

5

Kinematics of Particles: • Rectilinear motion, Uniform velocity, Uniform acceleration,

Variable acceleration, Graphical analysis using motion curves. • Curvilinear motion, Rectangular system, Normal and Tangential

components of acceleration, Projectile motion. • Relative motion.

10

6

Kinetics of Rigid Bodies: • Types of rigid body motion, Translation motion, Rotation about

fixed axis, General plane motion. • Instantaneous center method for bodies in General plane motion

4

7

Kinetics of Particles: • Newton’s second law of motion applied to particles in rectilinear

and curvilinear motion, D’ Almebert’s principle. • Work done by force, Work energy principle, Principle of

conservation of energy, Power & efficiency. • Linear momentum, Impulse, Application of Impulse Momentum

Equation, Principle of conservation of momentum, Direct central impact, Oblique central impact.

8


32

TOTAL 50

Books: Reference books:

• Engineering Mechanics – M. D. Dayal • Engineering Mechanics – Beer and Johnston • Engineering Mechanics – J. L. Meriam

Internet references: As given by the Faculty Term work:

• Report on experiments performed (minimum five) based on syllabus • Assignment consisting of numerical problems • Minimum two written class test


Trimester - III

S u b : I n s t r u m e n t a t i o n F u n d a m e n t a l s Code: 516 EES Lecture* 05 Practical 5 Hrs. Periods per week

Tutorial Hours M a r k s Evaluation system T h e o r y E x a m i n a t i o n 3 1 0 0 ( s c a l e d d o w n t o 5 0 ) Term work 50 *Each lecture of 1hr duration Objective: Sensors and measurements form the basis of instrumentation branch of electronics engineering. Instrumentation is the backbone of all industrial development and at the end of this course, student becomes familiar with basics of most frequently used sensors and measurements techniques of physical quantities like temperature, pressure, flow, velocity, torque, humidity etc.

Prerequisite Basic Electrical & Electronic Engineering

Detailed syllabus U n i t Topics Duration (Hr)


33

1 Principles used in Instrumentation: - (a) Basic behaviour of materials: - Linear expansion with stress and temperature, Volumetric changes, Resistance changes with temperature, Thermoelectric effects, effect of pressure, changes in materials because of light (photoelectric), piezo electric effect, Hall effect. (b) Basic principles: - Bernoulli’s principles, Force, torque flow calculation, Heat and heat transfer (c) Measurement Principles: - Displacement, Speed linear & rotational, flow, Pressure level, weight, temperature (d) Electrical Principles: - Galvanometer, Potentiometric Devices, Bridges

7

5 5 2

2 Transducers: - (a) Mechanical: - Bellows, Metallic Diaphragm, Bourdon’ spring, flow nozzles, orifice plate, pitot tube, rotameter, turbine type meters. (b) Electrical: - Strain gauges, RTD’s, Thermocouple, Pirani gauge, LVDT, magnetic flow meter (c) Characteristics: - Speed response and accuracy span and range, repeatability.

5

3

3

3 Measurements using Transducers for a given application: - Pressure, force, torque, velocity, flow, level, Ph, humidity & position

6

4 Signal Conditioning: - Need for signal conditioning, Op-amps as inverting and non-inverting modes, integrators, differentiators, Instrumentation applications.

5

5 Converters & Transmitters: - Current to Voltage, Voltage to Current using o/ps of transducers, 4-20 mA source

5

6 Indicating & Recording Devices: - Introduction to D.C. &A.C. recorders, Data logging-A/D converters, counters.

4

Total 50

Books: Reference books: Fundamentals of Electrical &Electronic -B.L.Theraja Modern Electronic Instrumentation and measurements techniques- Albert D. Helfrick, William D. Cooper


34

Electronic Instrumentation –Curtis Johnson Internet references: As given by the Faculty Term work: The term work shall comprise of at least six laboratory experiments and assignments based on the whole syllabus, duly recorded and graded. Minimum two class tests


Trimester III

S u b : W o r k S h o p P r a c t i c e C o d e : 5 1 3 M E S Lecture* Nil Practical 06 Hrs. Periods per week

Tutorial Hours Marks Evaluation system Theory Examination T e r m w o r k 100 *Each lecture of 1hr Objective: To impart training to help the students develop skill sets for creating entities from primitive engineering materials. This exercise also aims at inculcating respect for physical work and hard labour in addition to some amount of value addition by getting exposed to inter disciplinary engineering domains. Prerequisite

Detailed syllabus U n i t Topics Duration (Hr)


35

1 Fitting (compulsory): Use and setting of fitting tools for chipping, cutting, filing, Marking, centre punching, drilling, tapping.

12

2 Carpentry (compulsory): Use the setting of hand tools likes handsaws, jack planes, chisels and gauges for construction of various joints, wood turning, modern wood turning methods.

12

3

Welding & Sheet Metal Fabrication: Edge preparation for welding jobs. Arc welding for different jobs like; lap welding of two plates, butt-welding of plates with cover plates, welding to join plates at right angles, etc. Spot welding, Brazing and Soldering. Use of hand tools for sheet metal fabrication. Sheet metal fabrication of jobs involving cutting, shearing, bending, edge folding, soldering, brazing etc.

12

4 Machine shop (Conventional &CNC): At least one turning job is to be demonstrated on a conventional lathe as well as on a CNC lathe.

08

5 PCB Laboratory Exercises: Layout drawing, +ve and –ve film making, PCB etching and drilling, tinning and soldering techniques.

08

6 P l u m b i n g : Various fittings/joints used in plumbing work. Use of hand tools in plumbing. Preparation of pipe joint assembly involving various pipefittings.

08

T o t a l 60

Books:

Reference books: As given by the Faculty


Term work: 1. Fitting: One job-involving Fitting to size, one simple male-female

joint. 2. Carpentry: One workshop practice carpentry job involving a joint

and a report on demonstration of a job involving woodturning.

Documents

Mbatech Trimester 1 Syllabus