Curricula, Scheme of Examinations & Syllabi for Semesters V to VIII of B. Tech. Degree Programme in Mechanical Engineering (Production & Management) with effect from Academic Year 2000-2001




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НазваниеCurricula, Scheme of Examinations & Syllabi for Semesters V to VIII of B. Tech. Degree Programme in Mechanical Engineering (Production & Management) with effect from Academic Year 2000-2001
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UNIVERSITY OF CALICUT

Faculty of Engineering

Syllabi for B.Tech Degree Programme with effect from Academic Year 2000-2001



ME : Mechanical Engineering (Production & Management)


PM2K 501 : SOFTWARE ENGINEERING

(common to all programmes)


3 hours lecture and 1 hour tutorial per week


Module I (13 hours)

Introduction - FAQs about software engineering - professional and ethical responsibility - system modeling - system engineering process - the software process - life cycle models - iteration - specification - design and implementation - validation - evolution - automated process support - software requirements - functional and non-functional requirements - user requirements - system requirements - SRS - requirements engineering processes - feasibility studies - elicitation and analysis - validation - management - system models - context models - behavior models - data models - object models - CASE workbenches


Module II (13 hours)

Software prototyping - prototyping in the software process - rapid prototyping techniques - formal specification - formal specification in the software process - interface specification - behavior specification - architectural design - system structuring - control models - modular decomposition - domain-specific architectures - distributed systems architecture - object-oriented design - objects and classes - an object oriented design process case study - design evolution - real-time software design - system design - real time executives - design with reuse - component-based development - application families - design patterns - user interface design - design principles - user interaction - information presentation - user support - interface evaluation


Module III (13 hours)

Dependability - critical systems - availability and reliability - safety - security - critical systems specifications - critical system development - verification and validation - planning - software inspection - automated static analysis - clean room software development - software testing - defect testing - integration testing - object-oriented testing - testing workbenches - critical system validation - software evolution - legacy systems - software change - software maintenance - architectural evolution - software re-engineering - data re-engineering


Module IV (13 hours)

Software project management - project planning - scheduling - risk management - managing people - group working - choosing and keeping people - the people capability maturity model - software cost estimation - productivity estimation techniques - algorithmic cost modeling, project duration and staffing - quality management - quality assurance and standards - quality planning - quality control - software measurement and metrics - process improvement - process and product quality - process analysis and modeling - process measurement - process CMM - configuration management - planning - change management - version and release management - system building - CASE tools for configuration management


Text book

Ian Sommerville, Software Engineering, Pearson Education Asia

Reference books

  1. Pressman R.S., Software Engineering, McGraw Hill

  2. Mall R., Fundamentals of Software Engineering, Prentice Hall of India

  3. Behferooz A. & Hudson F.J., Software Engineering Fundamentals, Oxford University Press

  4. Jalote P., An Integrated Approach to Software Engineering, Narosa


Sessional work assessment

Assignments 2x10 = 20

Tests 2x15 = 30

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions of 15marks each from module I with choice to answer any one

Q III - 2 questions of 15marks each from module II with choice to answer any one

Q IV - 2 questions of 15marks each from module III with choice to answer any one

Q V - 2 questions of 15marks each from module IV with choice to answer any one

PM2K 502 : DYNAMICS OF MACHINERY

(common with ME2K 502)


3 hours lectures and 1 hour tutorial per week


Module I (15 hours)

Kinematics and kinetics of rigid bodies - aspects of motion of rigid body referred to local and global reference frames - energy and impulse - momentum methods for rigid bodies - energy methods - impulse -momentum methods - impulse - momentum equations - dynamics of general rigid body motion - Euler's equation of motion - applications - equations of motion using Euler angles - gyroscope - torque - free motion


Module II (13 hours)

Introduction to lagrangian dynamics - work and energy - the principle of virtual work - D'Alembert's principle - generalized coordinates - Lagrange's equation of motion - introduction to calculus of variations - Hamilton's principle


Module III (13 hours)

Force analysis of machinery - static and dynamic force analysis of plane motion mechanisms - graphical method - principle of superposition - matrix methods - method of virtual work - complex number method - bevel - helical and worm gearing


Module IV (11 hours)

Flywheel analysis - balancing - static and dynamic balancing - balancing of masses rotating in several planes - balancing of reciprocating masses - balancing of multicylinder engines - balancing machines


Text books

  1. Shames I.H., Engineering Mechanics, Prentice Hall of India, Module I

  2. Meirovitch L., Elements of Vibration Analysis, McGraw Hill, Module II

  3. Greenwood D.T., Classical Dynamics, Prentice Hall of India, Module II

  4. Hollowenko, Dynamics of Machinery, McGraw Hill, Modules III & IV

  5. Hamilton H., Mabie & Charles F. Reinholtz, Mechanisms and Dynamics of Machinery, John Wiley Modules III & IV

Reference books

  1. Beer F.P. & Johnston E.R. Jr., Vector Mechanics for Engineers-Dynamics, McGraw Hill, Module I

  2. Meirovitch L., Methods of Analytical Dynamics, McGraw Hill, Module II

  3. Shigley J.E. & Uicker J.J. Jr., Theory of Machines and Mechanisms, McGraw Hill, Modules III & IV

  4. Moon F.C., Applied Dynamics, John Wiley

  5. Forray M.J., Variational Calculus In Science and Engineering, McGraw Hill, Module II


Sessional work assessment

3 Tests 2x15 = 30

4 Assignments = 20

Total marks = 50

Note: Computer based assignments are to be included


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 503 : METAL CUTTING


3 hours lecture and 1 hour tutorial per week


Module I (13 hours)

Tool materials - carbon steel - HSS - cemented carbide - ceramics etc - properties of tool materials - heat treatment - tool geometry - ASA and ORS system of tool signature - geometry of drills - milling cutters and broaches -grinding - wheel specification and selection - mounting of wheels - grinding process parameters - MRR and wheel wear - tool and cutter grinder - lapping, honing and super finishing


Module II (13 hours)

Kinematic elements in metal cutting - tool in hand nomenclature - mechanics of chip formation - orthogonal and oblique cutting - shear angle - velocity relationship - merchant's analysis of cutting forces - cutting power estimation - tool dynamometers - turning, milling, drilling and grinding dynamometers - thermal aspects of machining - measurement of cutting temperature - cutting fluids & their selection


Module III (13 hours)

Failure of cutting tools - tools wear - flank and crater wear - mechanisms of wear Taylor's tool life equation - tool life testing - economics of machining - selection of optimal machining conditions and productivity -machinability - criteria and factors affecting machinability


Module IV (13 hours)

Non - traditional machining processes - principles, process characteristics and application of ECM, EDM, AJM, USM, EBM & LBM - capability analysis


Text & Reference books

  1. Bhattacharyya A., Metal Cutting: Theory & Practice, Central book publishers

  2. HMT, Production Technology, Tata McGraw Hill

  3. Ghosh & Mallik, Manufacturing Science, Affiliated East West Press

  4. Juneja & Skekhon, Fundamentals of Metal Cutting and Machine Tools, Wiley Eastern

  5. Boothroyd, Fundamentals of Metal Machining & Machine Tools, McGraw Hill Book company

  6. ASTME, Fundamentals of Tool Design, Prentice Hall of India

  7. Kronenberg M., Machining Science & Application, Pergamon Press

  8. Shaw M.C., Metal Cutting Principles, Oxford & IBH

  9. Sharma P.C., A Text Book of Production Engineering, S. Chand & Company

  10. Pandey & Shaw, Modern Machining Processes, Tata McGraw Hill


Sessional work assessment

Two Tests = 30

Two Assignments = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 504 : HEAT & MASS TRANSFER

(common with ME2K 504)


3 hours lecture & 1 hour tutorial per week


Module I (13 hours)

Introduction to heat transfer - basic modes of heat transfer - conduction heat transfer - energy balance - intergral and differential approaches - general heat conduction equation in Cartesian - cylindrical and spherical coordinates - initial and boundry conditions one-dimensional steady state conduction with heat generation - conduction shape factor - temperature dependance of thermal conductivity - applications like extended surface heat transfer and critical insulation thickness - two dimensional steady state heat conduction - examples - unsteady state heat conduction in one dimension - lumbed heat capacity system - semi infinite solids with sudden and periodic change in surface temperature - numerical methods in conduction problem


Module II (13 hours)

Convective heat transfer - Newton's law of cooling - thermal boundary layer - prantl number hydrodynamic and thermal boundary layer equations - laminar forced convection heat transfer from flat plates - similarity and integral solutions - internal flow and heat transfer - fully developed laminar flow in pipes - turbulant forced convection - reynolds analogy - emperical relations in free convection - natural convection - similarity and integral formulation of natural convection heat transfer from vertical plates - emperical relations in free convection - condensation and boiling - film and dropwise condensation - film boiling and pool boiling empirical relations for heat transfer with phase change - introduction to multiphase flow and heat transfer


Module III (13 hours)

Radiative transfer - electromagnetic radiation spectrum - thermal radiation - black body - grey body and coloured body - monochromatic and total emissive power - Planck's law - Stefan-Boltzman law - Wien's displacement law - absorptivity - reflectivity - transmissivity - emissivity - Kichhoff's identity - radiation exchange between surfaces - shape factor - shape factors for simple configurations - heat transfer in the presence of re-radiating surfaces - radiation shields - surface and shape resistances - electrical network analogy


Module IV (13 hours)

Mass transfer - definition of terms like concentration, mass velocity and mass flux - Fick's law of diffusion - temperature and pressure dependence of mass diffusivity - diffusion in gases at low density - diffusion in liquids - multi-component systems and their governing equations - concentration distribution in solids and in laminar flow - example problems


Text book

Holman J.P., "Heat Transfer," McGraw Hill International Students Edition

Reference books

  1. Incorpera F.P. & De Witt D.P., "Fundamentals of Heat and Mass Transfer”, John Wiley

  2. Kreith F., "Heat Transfer", International Text Book Company

  3. Gebhart B., "Heat Transfer", McGraw Hill


Sessional work assessment

Two Tests = 30

Two Assignments = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 505 : LINEAR SYSTEMS ANALYSIS

(common with ME2K 505, PE2K 506F))


3 hours lecture and 1 hour tutorial per week


Module I: System concepts and modelling of systems (11 hours)

Systems - subsystems - elements - systems approach - classification of systems - static and dynamic systems - linear and nonlinear systems - distributed and lumped systems - time invariant and time varying systems - stochastic and deterministic systems - system modeling and approximations - superposition principle - homogeneity and additivity - modelling of electrical systems - active and passive elements - resistance inductance and capacitance - dynamic equations using Kirchhoff's current and voltage laws - RL, RC and RLC circuits and their dynamic equations - block diagrams and signal flow graphs - masons gain formula


Module II: Modelling of non-electrical systems (11 hours)

Modelling of translational and rotational mechanical systems - differential equations for mass spring dashpot elements, D'Alembert's principle - rotational inertia - stiffness and bearing friction - gear trains - equivalent inertia and friction referred to primary and secondary shafts - dynamic equations for typical mechanical systems - electromechanical analogues - force-current and force-voltage analogue - capacitance and resistance of thermal, hydraulic pneumatic systems - dynamic equations for simple systems - comparison of electrical, electromechanical, hydraulic and pneumatic systems


Module III: Transfer function and time domain analysis (15 hours)

Use of laplace transforms - concept of transfer function - impulse response - convolution integral - response to arbitrary inputs - transfer function of typical systems discussed in Module I - time domain analysis - test inputs - step - velocity and ramp inputs - transient and steady state response - first and second order - under damped and over damped responses - maximum overshoot - settling time - rise time and time constant - higher order systems - steady state error - error constants and error different types of inputs - Fourier series expansion of periodic functions - symmetry conditions - exponential form of Fourier series - Fourier integrals and Fourier transform - spectral properties of signals - analysis by Fourier methods


Module IV: State space analysis and stability of systems (15 hours)

Concept of state - state space and state variables - advantage over transfer function approach - state equations for typical electrical and mechanical and electromechanical systems - representation for linear time varying and time invariant systems - solution of state equation for typical test inputs - zero state and zero input response - concept of stability - bounded input bounded output stability - Lyapunov’s definition of stability - a symptitic stability - stability in the sense of Lyapunov-Routh Hurwitz criterion of stability for single input single output linear systems described by transfer function model

Reference books

  1. Cheng D.K. Addison Wesley, Linear Systems Analysis, Addison Wesley

  2. Tripati J.N., Linear Systems Analysis, New Age International


Sessional work assessment

Assignments 2x10 = 20

2 tests 2x15 = 30

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 506A : NUMERICAL ANALYSIS

(common for AI2K/CE2K/CH2K/EC2K/EE2K/IC2K/ME2K 506A)


3 hours lecture and 1 hour tutorial per week


Module I: Errors in numerical calculations (13 hours)

Sources of errors, significant digits and numerical instability - numerical solution of polynomial and transcendental equations - bisection method - method of false position - Newton-Raphson method - fixed-point iteration - rate of convergence of these methods - iteration based on second degree equation - the Muller’s method - Chebyshev method - Graeffe’s root squaring method for polynomial equations - Bairstow’s method for quadratic factors in the case of polynomial equations


Module II: Solutions of system of linear algebraic equations (13 hours)

Direct methods - gauss and gauss - Jordan methods - Crout’s reduction method - error analysis - iterative methods - Jacobi’s iteration - Gauss-seidel iteration - the relaxation method - convergence analysis - solution of system of nonlinear equations by Newton-Raphson method - power method for the determination of Eigen values - convergence of power method


Module III: Polynomial interpolation (13 hours)

Lagrange’s interpolation polynomial - divided differences Newton’s divided difference interpolation polynomial - error of interpolation - finite difference operators - Gregory-Newton forward and backward interpolations - Stirling’s interpolation formula - interpolation with a cubic spline - numerical differentiation - differential formulas in the case of equally spaced points - numerical integration - trapezoidal and Simpson’s rules - Gaussian integration - errors of integration formulas


Module IV: Numerical solution of ordinary differential equations (13 hours)

The Taylor series method - Euler and modified Euler methods - Runge-Kutta methods (2nd order and 4th order only) - multistep methods - Milne’s predictor - corrector formulas - Adam-Bashforth & Adam-Moulton formulas - solution of boundary value problems in ordinary differential equations - finite difference methods for solving two dimensional Laplace’s equation for a rectangular region - finite difference method of solving heat equation and wave equation with given initial and boundary conditions


Reference books

  1. Froberg C.E., Introduction to Numerical Analysis, Addison Wesley

  2. Gerald C.F., Applied Numerical Analysis, Addison Wesley

  3. Hildebrand F.B., Introduction to Numerical Analysis, T.M.H.

  4. James M.L., Smith C.M. & Wolford J.C., Applied Numerical Methods for Digital Computation, Harper & Row

  5. Mathew J.H., Numerical Methods for Mathematics, Science and Engineering, P.H.I


Sessional work assessment

Assignments 2x10=20

2 tests 2x15=30

Total marks =50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 506B : COMPOSITE MATERIALS

(common with ME2K/PE2K 506B)


3 hours lecture and 1 hour tutorial per week


Module I (11 hours)

Introduction - classification and characteristics of polymer matrix and metal matrix composites - mechanical beheaviour of UD composites - longitudinal strength and stiffness - transverse strength and stiffness - failure modes - short fiber composites


Module II (15 hours)

Manufacturing and testing methods - production of various fibers - matrix materials and surface treatments - fabrication of composites - fabrication of thermosetting resin matrix composites - fabrication of thermoplastic - resin matrix composites/short fiber composites - fabrication of metal matrix composites - fabrication of ceramic matrix composites - carbon-carbon composites - machining aspects of composites - experimental characterization of composites - uniaxial tension - compression and shear tests - determination of interlaminar and fracture toughness - damage identification through non-destructive evaluation techniques - ultrasonic - acoustic emission and X-radiography


Module III (13 hours)

Analysis of orthotropic lamina - Hook’s law for orthotropic materials - stress-strain relations and engineering constants - specially orthotropic lamina - relation between engineering constants and elements of stiffness and compliance matrices - restrictions on elastic constants - stress-strain relationships for generally orthotropic lamina - transformation of engineering constants - strengths of orthotropic lamina - typical design application examples


Module IV (13 hours)

Analysis of laminated composites - strain and stress variation in a laminate - synthesis of stiffness matrix construction and properties of special laminates - symmetric laminates - unidirectional, cross-ply and angle-ply laminates - quasi-isotropic laminates - determination of laminae stresses and strains - laminate analysis through computers - typical design application examples


Reference books

  1. Agarwal B.D. & Broutman L.J., Analysis and Performance of Fiber Composites, John Wiley

  2. Gibson R.F., Principle of Composite Material Mechanics, McGraw Hill

  3. Schwartz M.M., Composite Materials Handbook, McGraw Hill, Inc.

  4. Jones R.M., Mechanics of Composite Materials, McGraw Hill, Inc.

  5. Tsai S.W., Introduction to Composite Materials, Technomic Publishing Company

  6. Chawla K.K., Ceramic Matrix Composites, Chapman & Hall


Sessional work assessment

Two Tests = 30

Two Assignments = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 506C : MULTI-PHASE FLOW

(common with ME2K/PE2K 506C)


3 hors lecture & 1 hour tutorial per week


Module I (13 hours)

Basic equations and empirical correlation's for multi-phase flow - flow patterns - identification and classification - flow pattern maps and transition - momentum and energy balance - homogeneous and separated flow models - correlation's for use with homogeneous and separated flow models - two phase flow through inclined pipes and singularities - void fraction and slip ratio correlation's - influence of pressure gradient - empirical treatment of two phase flow - drift flux model - correlation's for bubble - slug and annular flows - pressure losses through enlargements - contractions - orifices - bends and values


Module II (13 hours)

Boiling and multiphase heat transfer - vapour-liquid equilibrium - mechanisms - pool boiling convective boiling - heat transfer in partial and fully developed sub cooled boiling - void fraction and pressure drop in sub cooled boiling - saturated boiling heat transfer - two phase forced convection laminar and turbulent flow solutions for film heat transfer - empirical equations for film boiling and transition boiling - burnout mechanism and correlation's - critical coefficient in nucleate and convective boiling


Module III (13 hours)

Condensation - basic processes of condensation - mechanism of evaporation and condensation - film condensation on a planar surface - dropwise condensation - pressure gradient in condensing systems - methods of improving heat transfer coefficient in condensation


Module IV (13 hours)

Critical multiphase flows - mathematical models - critical flow criterion - compatibility conditions and their physical interpretation - experimental observations - propagation of small disturbances - pressure drop limitation effect - graphical representation of critical flow conditions


Text books

Collier J.G., Convective Boiling and Condensation, McGraw Hill

Reference books

  1. Hsu Y.Y. & Graham R.W., Transport Processes in Boiling and Two Phase Systems, Hemisphere

  2. Ginoux J.J., Two Phase Flows and Heat Transfer, Hemisphere, McGraw Hill

  3. Tong L.S., Boiling Heat Transfer and Two Phase Flow, Wiley

  4. Hewitt G., Delhaye J.M. & Zuber N., Multiphase Science and Technology, Vol. I., McGraw Hill


Sessional work assessment

Two Tests = 30

Two Assignments = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one
PM2K 506D : FINITE ELEMENT METHODS

(common with ME2K/PE2K 506D)


3 hours lecture and 1 hour practical per week


Module I (13 hours)

Linear vector spaces - linear transformations and functionals - linear, bilinear and quadratic forms - theory of normed spaces - theory of inner product spaces - concepts from variational calculas - variational methods of approximation - Ritz method - weighted residual method - Galerkin method - subdomain method - collocation method


Module II (11 hours)

Finite element analysis of one dimensional problems - procedure - one dimensional elements and interpolation functions - analysis of one dimensional second and fourth order equations - approximation errors in the finite element method - computer implementation


Module III (15 hours)

Finite element analysis of two dimensional problems - two dimensional elements and interpolation functions - second order equations involving a scaler valued function - comments on mesh generation and composition of boundary conditions - analysis of plane elasticity and incompressible fluid flow problems - time dependent problems (transient heat transfer) - isoparametric elements and numerical integration


Module IV (13 hours)

Alternative formulations - the least square formulation - the mixed formulation - Eigen value problems - non linear problems - three dimensional elements and interpolation functions - formulation of three dimensional problems (two and three dimensional Navier Stoke's equations - three dimensional heat transfer equations)


Text books

  1. Reddy J.N., An Introduction to the Finite Element Method, McGraw Hill, International Edition

  2. Reddy J.N., Applied Functional Analysis and Variational Methods in Engineering, McGraw Hill, International Edition

Reference books

  1. Huebner K.H., The Finite Element Method for Engineers, John Wiley

  2. Zenkiewicz O., The Finite Element Method, McGraw Hill International Edition


Sessional work assessment

3 Tests 2 x 15 = 30

2 Assignments 2 x 10 = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 506E : OBJECT ORIENTED PROGRAMMING

(common for all programmes)


3 hours lecture and 1 hour tutorial per week


Module I (12 hours)

OOPS and Java basics - Java virtual machine - Java platform API - extended security model - applet classes - exceptions and abstract classes - Java applet writing basics - GUI building with canvas - applet security - creating window applications - writing console applications - utility and math packages


Module II (10 hours)

Swing programming - working with swing components - using the clipboard - input/output streams - printing - working with 2D and 3D Graphics - using audio and video - creating animations


Module III (10 hours)

Java beans development kit - developing beans - notable beans - network programming - client and server Programs - naming and directory services - working with Java management APIS


Module IV (20 hours)

Distributed application architecture - CORBA - RMI and distributed applications - working with remote objects - object serialization and Javaspaces - Java IDL and ORBs, connecting to database - using JDBC - integrating database - support into web applications - Java servlets - JSDK - JAR files - Java native interface


Text books

  1. Campione, Walrath & Huml Tutorial team, “The Java Tutorial Continued: The Rest of the JDK”, Addison Wesley

  2. Jamie Jaworski, “Java 2 Platform Unleashed: The Comprehensive Solution”, SAMS Teachmedia

References books

  1. Holzner S., Java 2, Swings, Servlets, JDBC & Java Beans Programming, IDG Books

  2. Campione M. & Walrath K. “ The Java Tutorial: Object-Oriented Programming for the Internet”, Addison Wesley

  3. Naughton Patrick & Herbert Schildt, “Java 2: The Complete Reference”, Tata McGraw Hill


Sessional work assessment

Assignments 2x10 = 20

Tests 2x15 = 30

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions of 15marks each from module I with choice to answer any one

Q III - 2 questions of 15marks each from module II with choice to answer any one

Q IV - 2 questions of 15marks each from module III with choice to answer any one

Q V - 2 questions of 15marks each from module IV with choice to answer any one

PM2K 506F : MARKETING MANAGEMENT

(common with ME2K 506F)


3 hours lecture & 1 hour tutorial per week


Module I (14 hours)

Introduction to marketing - concept of market and marketing - marketing environment - controllable factors - factors directed by top management - factors directed by marketing - uncontrollable factors - demography, economic conditions, competition, social and cultural forces, political and legal forces, and technology


Module II (14 hours)

Marketing planning - marketing planning process - Boston consultancy group model - marketing mix - marketing mix variables - market segmentation and market targeting - introduction to segmentation - targeting and product positioning


Module III (12 hours)

Marketing research - need and scope - marketing research process - research objectives, developing research plan, collecting information, analysis, and findings - consumer behaviour - factors influencing consumer behaviour - perceived risks - product life cycle - marketing strategies for different stages of product life cycle


Module IV (12 hours)

Marketing communication - marketing mix variables - steps in developing effective communication - identification of target audience - determination of communication objectives - designing the message - selecting the communication channels - promotion mix evaluation - advertising and sales promotion - factors in advertising - sales promotion tools


Text books

  1. Kotler P., Marketing Management: Analysis, Planning, Implementation and Control, Prentice Hall of India Private Limited

  2. Ramaswamy V.S. & Namkumari S., Marketing Management: Planning, Implementation and Control, Macmillan India Limited

Reference books

  1. Stanton W.J., Etzel M.J. & Walker B.J., Fundamentals of Marketing, McGraw Hill International Edition

  2. Majumdar R., Marketing Research, Text, Applications and Case Studies, New Age International (P) Limited Publishers

  3. Robert, Marketing Research, Prentice Hall of India


Sessional work assessment

Two Tests = 30

Two Assignments = 20

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions A and B of 15marks each from module I with choice to answer any one

Q III - 2 questions A and B of 15marks each from module II with choice to answer any one

Q IV - 2 questions A and B of 15marks each from module III with choice to answer any one

Q V - 2 questions A and B of 15marks each from module IV with choice to answer any one

PM2K 506G : ENGLISH LANGUAGE & LITERATURE

(common with ME2K 506G)


3 hours lecture and 1 hour tutorial per week


Module I (8 hours)

History of England - cultural, social and political - origin of the English language - vocabulary - grammar - syntax - English language vis - a - vis other European and Asian languages - Indo European languages - Language families of the world - Language, literature, history and culture of a nation - English as a global language


Module II (14 hours)

Introduction to English usage and composition - essentials of English grammar - style and technique of effective English communication - techniques of persuasive speech and writing - Rhetoric- Common errors in English usage (spoken and written) - Different varieties of English (British, American and Indian)

Basics of English pronunciation- Phonetics - Stress, Accent, Rhythm (Appreciation of English speech patterns, conversations, great orators etc. through audio cassettes and CDs) - Practical Speaking Listening sessions in the Language Laboratory - Different forms of communication in English - Business English, English for professionals and literary English


Module III (15 hours)

English literature - Survey, Scope and History

English prose - Great essayists - Addison, Steele, Lamb, Russell, Chesterton, Bacon

English Poetry - Ancient (Chaucer, Milton, Spencer)

Medieval and Modern English poetry - Shakespeare, Wordsworth, Keats, Shelley, Byron, Browning, Tennyson, T.S. Eliot (Core reading)

Novels: Classics of English fiction - critical appreciation with a view for improving style and expressions (Charls Dickens, Aldous Huxley, Jane Austen, George Eliot, Jonathan Swift)

The great short story writers - O. Henry, Saki, James Joyce (Dubliners)


Module IV (15 hours)

English Drama and theatre - Shakespeare - The Great Tragedies - Othello, Hamlet, Macbeth, King Lear

Comedies - As you like it (Others in Recommended Reading) - George Bernard Shaw - Man and Superman, Pygmalion

Modern Drama - Harold Pinter, Edward Bond

Literary appreciation theories - English texts - William Wordsworth - Samuel Taylor Coleridge - Mathew Arnold, T.S. Eliot, David Lodge

Others - Plato, Longinus, Rasa theory and Indian poetics (In this module students will be expected to have read the primary works and develop a critical appreciation of them)


Text books

  1. Barber C.L., History of the English Language

  2. Trevelyan G.M., Social History of England, Longmans

  3. Winston Churchill, A History of England

  4. Wren & Martin, High School English Grammar, K&J Copper

  5. Krishna Mohan & Meera Banerji, Developing Communication Skills

  6. Krishna Mohan & Meera Banerji, Effective English Communication

  7. The Harp &the Lyre - An Anthology of English Poems

  8. Elements of Style Strunk


Sessional work assessment

Assignments 2x10 = 20

Tests 2x15 = 30

Total marks = 50


University examination pattern

Q I - 8 short type questions of 5 marks each, 2 from each module

Q II - 2 questions of 15marks each from module I with choice to answer any one

Q III - 2 questions of 15marks each from module II with choice to answer any one

Q IV - 2 questions of 15marks each from module III with choice to answer any one

Q V - 2 questions of 15marks each from module IV with choice to answer any one
1   2   3   4   5   6   7   8

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