NATIONAL INSTITUTE OF TECHNOLOGY

WARANGAL

COURSE STRUCTURE AND SYLLABUS

for
M. Tech
AUTOMOBILE ENGINEERING
Effective from 2016-17

DEPARTMENT OF MECHANICAL ENGINEERING

NATIONAL INSTITUTE OF TECHNOLOGY
WARANGAL - 506 004 (T.S), INDIA
 M.Tech. Automobile Engineering
Scheme of instructions and Evaluation
I Year (M.TechAutomobile Engineering), Semester – I

Course Course Title L T P Credits

Code
ME5501 Automotive Engineering 4 0 0 4
ME5102 Computational Methods in Thermal Engg. 4 0 0 4
ME5403 Mechanical Vibrations 4 0 0 4
ME5104 Advanced Internal Combustion Engines 4 0 0 4
Elective-1 3 0 0 3
Elective-2 3 0 0 3
ME5541 Automotive Engineering laboratory 0 0 3 2
ME5542 Computational Laboratory 0 0 3 2
ME5543 Seminar-I 0 0 3 1
Total 22 0 9 27

I Year (M.TechAutomobile Engineering), Semester – II

Course Code Course Title L T P Credits

ME5551 Vehicle Body Engineering 4 0 0 4
ME5456 Vehicle Dynamics 4 0 0 4
Elective-3 3 0 0 3
Elective-4 3 0 0 3
Elective-5 3 0 0 3
Elective-6 3 0 0 3
ME5591 Automotive Systems laboratory 0 0 3 2
ME5592 Modeling and Analysis laboratory 0 0 3 2
ME5593 Seminar-II 0 0 3 1
Total 20 0 9 25

II Year (M.Tech. Automobile Engineering), Semester – I

S. No. Course No. Course Title Credits

1 ME5548 Comprehensive Viva – Voce 2
2 ME5549 Dissertation - Part A 6
Total 8

II Year (M.Tech. Automobile Engineering), Semester – II

S. No. Course No. Course Title Credits

1 ME5599 Dissertation - Part B 12
Total 12
 List of Elective Courses(M. TechAutomobile Engineering)

Semester – I (3-0-0) 3 Semester – II (3-0-0) 3

Course Course
Course Title Course Title
Code Code
ME5511 Automotive Electronics ME5561 Noise, Vibrations & harshness

ME5521 Alternate Fuels & Emissions ME5562 Vehicle Testing & Instrumentation

ME5522 Combustion and Emission control ME5563 Engine Management Systems

ME5321 Enterprise Resource Planning ME5564 Automotive Safety & Maintenance

ME5331 Manufacturing Management ME5171 Design of Heat Transfer Equipment

ME5336 Soft Computing Techniques ME5172 New Venture Creation

Analysis and Synthesis of

ME5421 ME5186 Energy Systems and Management
Mechanisms

ME5422 Mathematical Methods in

ME5168 Renewable Sources of Energy
Engineering

ME5621 Advanced Metal Forming ME5271 Mechatronics and Robotics

ME5274 Fluid Power Systems

ME5281 Precision Manufacturing

ME5386 Design and Analysis of Experiments

ME5387 Project Management

ME5471 Tribological Systems Design

ME5472 Condition Monitoring

ME5473 Design of Transmission Systems

ME5483 Computer Aided Design

ME5377 Reliability Engineering

ME5771 Re-Engineering

ME5479 Optimization for Engineering Design

ME5482 Finite Element Method

ME5686 Non Destructive Testing

Assessment of Academic Performance for Theory Courses:

Continuous Evaluation : 20 marks

Mid-semester Examination : 30 marks (as per academic calendar)
End-semester Examination : 50 marks (as per academic calendar)
Total : 100 marks

Assessment of Academic Performance for Laboratory Courses:

Continuous Evaluation : 25 Marks
(Lab report, viva,Quiz, etc.)
Skill test : 25 Marks
End Semester Examination : 50 Marks
Total : 100 Marks
Program Educational Objectives

PEO1 Apply concepts of engineering to analyze automotive systems.

PEO2 Develop innovative automotive technologies to address specific needs of
performance, comfort, safety and eco-friendliness.
PEO3 Apply computational tools for comprehensive understanding of the complex systems
in automotive engineering.
PEO4 Communicate effectively and support constructively towards team work
PEO5 Engage in lifelong learning for career and professional growth with ethical concern
for society and the environment

Program Outcomes

PO1 Identify and analyze automotive systems and subsystems

PO2 Explore and evaluate alternate power sources in modern automobiles

PO3 Develop and evaluate emission control strategies to comply with National/
International norms
PO4 Model and Analyze stability and performance of the vehicle

PO5 Design and conduct experiments to evaluate vehicle performance as per driving
cycles and emission norms.
PO6 Identify sensors and actuators, and integrate for optimal control and performance of
automobile
PO7 Develop methodologies for design of automobiles using state of art tools and
techniques, and innovative methodologies.
PO8 Develop methodologies for design of automobile systems adhering to professional,
ethical, legal, safety, environmental and societal aspects
PO9 Communicate effectively with diverse groups while leading and executing
interdisciplinary projects.
PO10 Engage in lifelong learning for career and professional growth with ethical concern
for society and environment.
 DETAILED SYLLABUS

ME5501 AUTOMOTIVE ENGINEERING 4-0-0 4 Credits

Prerequisites: Internal Combustion Engines

Course Outcomes:

CO1 Identify the systems and sub-systems of a typical automobile

CO2 Classify engines based on their configuration
CO3 Outline the functions of power transmission system, cooling and lubrication
system and its components
CO4 Explain the essential requirements of center point steering, suspension and braking
CO5 Adopt recent innovations in automobile sector.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 1 1 2 2 1 1 2
CO2 3 3 2 2 3 2 2 1 1 2
CO3 3 2 1 3 3 3 3 1 1 2
CO4 3 2 3 2 3 3 1 1 2
CO5 3 2 2 2 2 3 3 1 1 2

Introduction: Overview of the course, Examination and Evaluation patterns, History of

Automobiles, Classification of Automobiles.

Power Plant: Classification, Engine Terminology, Types of Cycles, working principle of an

IC engine, advanced classification of Engines- Multi cylinder engines, Engine balance, firing
order.

Fuel System and Ignition System and Electrical system: spark Ignition engines-Fuel tank,
fuel filter, fuel pump, air cleaner/filter, carburettor, direct injection of petrol engines.
Compression Ignition engines, Fuel Injection System- air & solid injection system, Pressure
charging of engines, super charging and turbo charging, Components of Ignition systems,
battery ignition system, magneto ignition system, electronic ignition and ignition timing.
Main electrical circuits, generating & stating circuit, lighting system, indicating devices,
warning lights, speedometer.

Lubricating system and cooling systems: Functions & properties of lubricants, methods of
lubrication-splash type, pressure type, dry sump, and wet sump & mist lubrication. Oil filters,
oil pumps, oil coolers. Characteristics of an effective cooling system, types of cooling
system, radiator, thermostat, air cooling & water cooling.

Transmission, axles, clutches, propeller shafts and differential: Types of gear boxes,
functions and types of front and rear axles, types and functions, components of the clutches,
fluid couplings, design considerations of Hotchkiss drive torque tube drive, function and parts
of differential and traction control.
Steering system: functions of steering mechanism, steering gear box types, wheel geometry.

Braking and suspension system: functions and types of brakes, operation and principle of
brakes, constructional and operational classification and parking brake. Types of springs
shock observers, objectivesand types of suspension system, rear axles suspension, electronic
control and proactive suspension system.

Wheels and tyres: Wheel quality, assembly, types of wheels, wheel rims. Construction of
tyres and tyre specifications.

Automation in automobiles: Sensors and actuators, electronic fuel injection system,

electronic management system, automatic transmission, electronic transmission control,
Antilock Braking System (ABS)

Reading:

1. Joseph Heitner, Automotive Mechanics, CBS publications

2. Srinivasan.S, Automotive Mechanics, 2nd Edition, Tata McGraw-Hill, 2003
3. Crouse and Anglin, Automotive Mechanism, 9th Edition. Tata McGraw-Hill, 2003.
4. Jack Erjavec, A Systems Approach to Automotive Technology, Cengage Learning Pub.,
009
 ME5102 COMPUTATIONAL METHODS IN 4-0-0 4 Credits
THERMAL ENGINEERING
Pre-requisites:
Fluid Mechanics, Heat Transfer, Numerical Methods, Computer Programming

Course Outcomes:

CO1 Derive the governing equations and understand the behaviour of the equations.
CO2 Understand the stepwise procedure to completely solve a fluid dynamics problem
using computational methods.
CO3 Analyse the consistency, stability and convergence of discretization schemes for
parabolic, elliptic and hyperbolic partial differential equations.
CO4 Analyse variations of SIMPLE schemes for incompressible flows and variations of
Flux Splitting algorithms for compressible flows.
CO5 Evaluatemethods of grid generation techniques and application of finite difference and
finite volume methods to thermal problems.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 P10
CO1 1 1 3 2 3 1 1 2
CO2 1 2 3 2 3 1 1 2
CO3 3 3 3 2 1 3 1 1 2
CO4 3 3 3 2 1 3 1 1 2
CO5 3 3 3 2 1 3 1 1 2

Introduction:History and Philosophy of computational fluid dynamics, CFD as a design and

research tool, Applications of CFD in engineering, Programming fundamentals, MATLAB
programming, Numerical Methods

Governing equations of fluid dynamics:Models of the flow, The substantial derivative,

Physical meaning of the divergence of velocity, The continuity equation, The momentum
equation, The energy equation, Navier-Stokes equations for viscous flow, Euler equations for
inviscid flow, Physical boundary conditions, Forms of the governing equations suited for
CFD, Conservation form of the equations, shock fitting and shock capturing, Time marching
and space marching.

Mathematical behavior of partial differential equations:Classification of quasi-linear

partial differential equations, Methods of determining the classification, General behavior of
Hyperbolic, Parabolic and Elliptic equations.

Basic aspects of discretization:Introduction to finite differences, Finite difference equations

using Taylor series expansion and polynomials, Explicit and implicit approaches, Uniform
and unequally spaced grid points.

Grids with appropriate transformation:General transformation of the equations, Metrics

and Jacobians, the transformed governing equations of the CFD, Boundary fitted coordinate
systems, Algebraic and elliptic grid generation techniques, Adaptive grids.
Parabolic partial differential equations:Finite difference formulations, Explicit methods –
FTCS, Richardson and DuFort-Frankel methods, Implicit methods – Laasonen, Crank-
Nicolson and Beta formulation methods, Approximate factorization, Fractional step methods,
Consistency analysis, Linearization.

Stability analysis:Discrete Perturbation Stability analysis, von Neumann Stability analysis,

Error analysis, Modified equations, Artificial dissipation and dispersion.

Elliptic equations:Finite difference formulation, solution algorithms: Jacobi-iteration

method, Gauss-Siedel iteration method, point- and line-successive over-relaxation methods,
alternative direction implicit methods.

Hyperbolic equations:Explicit and implicit finite difference formulations, splitting methods,

multi-step methods, applications to linear and nonlinear problems, linear damping, flux
corrected transport, monotone and total variation diminishing schemes, tvd formulations,
entropy condition, first-order and second-order tvd schemes.

Scalar representation of Navier-stokes equations:Equations of fluid motion, numerical

algorithms: ftcs explicit, ftbcs explicit, Dufort-Frankel explicit, Maccormack explicit and
implicit, btcs and btbcs implicit algorithms, applications.
GRID GENERATION: Algebraic Grid Generation, Elliptic Grid Generation, Hyperbolic
Grid Generation, Parabolic Grid Generation

Finite volume method for unstructured grids:Advantages, Cell Centered and Nodal point
Approaches, Solution of Generic Equation with tetra hedral Elements, 2-D Heat conduction
with Triangular Elements

Numerical solution of quasi one-dimensional nozzle flow:Subsonic-Supersonic isentropic

flow, Governing equations for Quasi 1-D flow, Non-dimensionalizing the equations,
MacCormack technique of discretization, Stability condition, Boundary conditions, Solution
for shock flows.

Reading:

1. Anderson, J.D.(Jr), Computational Fluid Dynamics, McGraw-Hill Book Company, 1995.

2. Hoffman, K.A., and Chiang, S.T., Computational Fluid Dynamics, Vol. I, II and III,
Engineering Education System, Kansas, USA, 2000.
3. Chung, T.J., Computational Fluid Dynamics, Cambridge University Press, 2003.
4. Anderson, D.A., Tannehill, J.C., and Pletcher, R.H., Computational Fluid Mechanics and
Heat Transfer, McGraw Hill Book Company, 2002.
5. Versteeg, H.K. and Malalasekara, W.,AnIntroduction to Computational Fluid Dynamics,
Pearson Education, 2010.
ME5403 MECHANICAL VIBRATIONS 4-0-0 4 Credits
Pre-requisites: Nil

Course Outcomes:

CO1 Analyze the causes and effects of vibrations in mechanical systems and identify
discrete and continuous systems.
CO2 Model the physical systems into schematic models and formulate the governing
equations of motion.
CO3 Compute the free and forced vibration responses of multi degree of freedom
systems through model analysis and interpret the results.
CO4 Analyse and design the systems involving unbalances, transmissibility, vibration
isolation and absorption.
CO5 Analyse and design to controlandreduce vibration effects in machinery.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 3 1 2 2 1 1 2
CO2 3 3 1 2 2 1 1 2
CO3 3 3 1 2 2 1 1 2
CO4 3 3 1 2 2 1 1 2
CO5 3 3 1 2 2 1 1 2

Introduction: Causes and effects of vibration, Classification of vibrating system, Discrete

and continuous systems, degrees of freedom, Identification of variables and Parameters,
Linear and nonlinear systems, linearization of nonlinear systems, Physical models, Schematic
models and Mathematical models.

SDF systems:Formulation of equation of motion: Newton –Euler method, De Alembert’s

method, Energy method,

Free Vibration:Undamped Free vibration response, Damped Free vibration response, Case
studies on formulation and response calculation. Forced vibration response of SDF systems:
Response to harmonic excitations, solution of differential equation of motion, Vector
approach, Complex frequency response, Magnification factor Resonance,
Rotating/reciprocating unbalances.

Dynamics of Rotors:Whirling of rotors, Computation of critical speeds, influence of

bearings, Critical speeds of Multi rotor systems.

Design case studies: design case studies dealing with Transmissibility of forces and motion
Trans, Vehicular suspension, Analysis of Vehicles as single degree of freedom systems -
vibration transmitted due to unevenness of the roads, preliminary design of automobile
suspension. Design of machine foundations and isolators.

Two degree of freedom systems:Introduction, Formulation of equation of motion:

Equilibrium method, Lagrangian method, Case studies on formulation of equations of
motion, Free vibration response, Eigen values and Eigen vectors, Normal modes and mode
superposition, Coordinate coupling, decoupling of equations of motion, Natural coordinates,
Response to initial conditions, coupled pendulum, free vibration response case studies,
Forced vibration response, Automobile as a two degree of freedom system –bouncing and
pitching modes undamped vibration absorbers, Case studies on identification of system
parameters and design of undamped vibration absorbers.Analysis and design of damped
vibration absorbers.

Multi degree of freedom systems:Introduction, Formulation of equations of motion, Free

vibration response, Natural modes and mode shapes, orthogonally of model vectors,
normalization of model vectors, Decoupling of modes, model analysis, mode superposition
technique, Free vibration response through model analysis, forced vibration analysis through
model analysis, Model damping, Rayleigh’s damping, Introduction to experimental model
analysis.

Continuous systems:
Introduction to continuous systems,discretevs continuous systems. Exact and approximate
solutions, free vibrations of bars and shafts, Free vibrations of beams, Forced vibrations of
continuous systems Case studies, Approximate methods for continuous systems and
introduction to Finite element method.

Vibration Control in structures: Introduction, , State space representation of equations of

motion, Passive control, active control and semi active control o, Free layer and constrained
damping layers, Piezo electric sensors and actuators for active control, semi active control of
automotive suspension systems.

Reading:
1. L. Meirovich, Elements of Vibration analysis, 2nd Ed. Tata Mc-Graw hill 2007

Reference Books:

1. Singiresu S Rao, Mechanical Vibrations. 4th Ed., Pearson education 2011

2. W.T., Thompson, Theory of Vibration, CBS Publishers
3. Clarence W. de Silva , Vibration: Fundamentals and Practice, CRC Press LLC, 2000
 ME5104 ADVANCED INTERNAL 4-0-0 4 Credits
COMBUSTION ENGINES
Prerequisites: Internal Combustion Engines

Course Outcomes:

CO1 Understand the importance of IC engine as a prime mover and compare its
performance on the basis of thermodynamic cycles and combustion process.
CO2 Identify harmful IC engine emissions and use viable alternate fuels in engines.
CO3 Analyze and evaluateengine performance and adopt improvement devices and new
combustion concepts.
CO4 Classify and analyzealternate power sources for automobiles.

CO – PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 3 3 2 2 2 1 1 1 2
CO2 3 3 3 2 3 2 1 1 1 2
CO3 3 3 3 3 3 3 1 1 1 2
CO4 3 3 3 2 2 2 1 1 1 2

Introduction to IC engines:Overview of the course, Examination and Evaluation Patterns-

Classification of Prime Movers; IC Engines as Prime Movers; Historical Perspective-
Contribution of IC Engines for Global Warming. Concept of charge, Differences between EC
Engines and IC Engines-Classification, Mechanical cycle and Thermodynamic cycle, Air
standard cycles-Diesel, Otto, Dual and Miller cycles.Classification of 2-s cycle engines based
on scavenging, Differences between 2-s and 4-s cycle engines, Differences between SI and
CI engines.

Spark Ignition Engines: Flame Propagation- Combustion phenomena (Normal and

Abnormal), Factors affecting, Detonation, Ignition quality, HUCR-Carburetion and fuel
injection systems for SI Engines

Compression Ignition Engines: Advantages of CI engines-Importance of air motion and

Compression Ratio, Mixture Preparation inside the CC. Normal and abnormal combustion -
Ignition Quality-Cetane number-Characteristics of a Good Combustion Chamber-
Classification of Combustion Chambers (DI and IDI). Description of Fuel injection Systems -
Individual, Unit and Common Rail (CRDI), Fuel Injectors-Nozzle types, Electronic Control
Unit (ECU)-Numerical problems on fuel injection

Supercharging of IC Engines: Need of Supercharging and advantages, Configurations of

Supercharging-Numerical problems on turbocharging.

Pollutant emissions from IC Engines:Introduction to clean air, Pollutants from SI and CI

Engines: Carbon monoxide, UBHCs, Oxides of nitrogen (NO-NO X) and Particulate
Matter.Mechanism of formation of pollutants, Factors affecting pollutant
formation.Measurement of engine emissions-instrumentation, Pollution Control Strategies,
Emission norms-EURO and Bharat stage norms.
Performance of IC Engines: Classification of engine performance parameters-Measurement
of brake power, indicated power and friction power.Factors affecting performance, Heat loss,
Air-fuel ratio, Pumping loss, Energy Balance: Pi and Sankey diagrams Numerical problems.

Alternate Fuels: Need for Alternate fuels, Desirable Characteristics of good Alternate Fuel-
Liquid and Gaseous fuels for SI and CI Engines, Kerosene, LPG, Alcohols, Bio-fuels,
Natural gas, Hydrogen and use of these fuels in engines.

Batteries: Battery: lead-acid battery, cell discharge and charge operation, construction,
advantages of lead- acid battery- Battery parameters: battery capacity, discharge rate, state of
charge, state of discharge, depth of discharge, Technical characteristics-Ragone plots.

Electric vehicles: Introduction: Limitations of IC Engines as prime mover, History of EVs,

EV system, components of EV-DC and AC electric machines: Introduction and basic
structure-Electric vehicle drive train-advantages and limitations, Permanent magnet and
switched reluctance motors-EV motor sizing: Initial acceleration, rated vehicle velocity,
Maximum velocity and maximum gradeability

Hybrid vehicle: Configurations of hybrids, advantages and limitations-Hybrid drive trains,

sizing of components Initial acceleration, rated vehicle velocity, Maximum velocity and
maximum gradeability-Hydrogen: Production-Hydrogen storage systems-reformers

Fuel Cell vehicles: Fuel cells: Introduction-Fuel cell characteristics, Thermodynamics of fuel
cells-Fuel cell types: emphasis on PEM fuel cell

Reading books:

1. J.B. Heywood Internal Combustion Engine Fundamentals, McGraw Hill Co.1988

2. W.W.PulkrabekEngineering Fundamentals of IC Engine, PHI PvtLtd 2002
3. SethLeitman and Bob Brant Build your own electric vehicle McGraw Hill Co.2009.
4. F. BarbirPEM Fuel Cells-Theory and Practice Elsevier Academic Press-2005.
 ME5541 AUTOMOTIVE ENGINES LABORATORY 0-0-3 (2 Cr)
Prerequisites: Nil

Course Outcomes:

CO1 Identify the components of IC engines and assemble and dissemble the parts
CO2 Determine properties of a given fuel/oil sampleand identify fuel/oil for specific use
CO3 Conduct performance and emission tests on SI and CI Enginesand analyze the results
CO4 Identify viable alternate fuels for SI and CI engines by analyzing the in-cylinder
parameters

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 3 2 3 2 2 2 3 2
CO2 3 2 3 2 3 2 2 2 3 2
CO3 3 2 3 3 3 2 2 2 3 2
CO4 3 3 3 2 3 2 2 2 3 2

Week Exercise
1 Performance test on reciprocating air compressor.
2 Performance Test on a Single Cylinder Diesel Engine with DC shunt
Dynamometer
4 Performance Test on Dual Fuel Engine with Electrical heater plugs
5 Performance Test on Single Cylinder petrol Engine with Electrical Dynamometer
6 Retardation test on a Single Cylinder Diesel Engine with DC shunt Dynamometer
7 Morse test on a Multi Cylinder Petrol Engine
8 Heat Balance Test on a Single Cylinder Diesel Engine with Water brake
Dynamometer
9 Heat transfer experiments: Free convection, Forced convection, Extended surfaces
10 Nozzle Test and Performance test on Prototype steam turbine
11 Determination of Fuel properties with the apparatus available in the Laboratory
12 Conduct of experiment on Computerized single cylinder diesel engine to determine
performance, Heat balance, Exhaust emissions and temperatures
 ME5542 COMPUTATIONAL LABORATORY 0-0-3 (2 Cr)

Course Outcomes:

CO1 Develop codes for solution of algebraic and differential equations

CO2 Build up the skills in the actual implementation of CFD methods (e.g. boundary
conditions, turbulence modelling etc.) with their own codes
CO3 Gain experience in the application of CFD analysis to real engineering designs.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 2 3 2 3 2
CO2 1 3 2 3 2 3 2
CO3 1 3 2 3 2 3 2

Syllabus:
Writing programs using C++ and MATLAB for Solution of transcendental equations,
solution of simultaneous algebraic equations, numerical differentiation and integration,
solution of ordinary differential equations, Explicit and implicit methods of solving the fluid
flow problems under various types of boundary conditions, methods of solving partial
differential equations of elliptic, parabolic and hyperbolic types.

1. Solution of Quadratic Equations

2. Matrix Operations
3. Solution of Simultaneous Algebraic Linear Equations (Gauss-Siedel Method)
4. Solution of 1-D parabolic equations
(a) Explicit (FTCS, DuFort-Frankel)
(b) Implicit (Laasonen)
Examples: (i) Fin problem with insulated and Convective end [k A Txx = h P (T-Ta)]
(ii) Couette Problem with and without pressure Gradient [u t = - px /ρ + ν
uxx]
5. Solution of Elliptic Equations (Tt = α Txx ]
(a) With Point Gauss Siedel method
(b) With Point Successive Over Relaxation Method
Examples: (i) Temperature Distribution over a rectangular plate with different
Boundary conditions on the sides.
6. Solution of Linear Hyperbolic Equations. [ ut = -a ux ]
(a) Using upwind and Lax explicit methods
(b) Using BTCS and Crank-Nicolson implicit methods
Examples: Wave propagation at a high altitude
7. Solution of Non-Linear Hyperbolic Equations. [ ut = -u ux ]
(a) Lax Method
(b) MacCormack Method
Examples: Shock Tube Problem
8. Solution of Incompressible NSEs
(a) Vorticity-Stream function formulation
(b) Primitive Variable Formulation
 Examples: (i) Lid Driven Cavity Problem
(ii) Mass entering and leaving a square chamber

Readings:

1. Versteeg, H. K. and Malalasekera, W., An Introduction to Computational Fluid Dynamics:

The Finite Volume Method, 2nd Edition, Pearson, 2010.
2. Tannehill, J. C., Anderson, D. A. and Pletcher, R. H., Computational Fluid Mechanics and
Heat Transfer, McGraw Hill, 2002.
3. Blazek, J., Computational Fluid Dynamics: Principles and Applications, 2nd Edition,
Elsevier Science & Technology, 2006.
4. Chung, T. J., Computational Fluid Dynamics, Cambridge University Press, 2003.
 ME5543 SEMINAR-I 0-0-3 (1 Cr)

Course Outcomes:

CO1 Identify and compare technical and practical issues related to Automobile Engineering
CO2 Outline annotated bibliography of research demonstrating scholarly skills.
Prepare a well-organized report employing elements of critical thinkingand technical
CO3
writing
Demonstrate the ability to describe, interpret and analyze technical issues and develop
CO4
competence in presenting.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 2 1 2 2 1 1 3 3 3
CO2 1 2 1 2 1 1 2 3 3 3
CO3 1 1 1 1 1 1 1 3 3 3
CO4 1 2 1 2 2 1 2 3 3 3
 I- Year. I- Semester Elective Courses

ME5511 AUTOMOTIVE ELECTRONICS 3 - 0 - 0 (3 Cr)

Prerequisites: Nil

Course Outcomes:

CO1 Understand the need of safety and use of electronics in automobiles

CO2 Understand the electronic circuit fundamentals and basic test equipment.
CO3 Analyze vehicle electronic circuits.
CO4 Outline the working of batteries, starting systems, charging systems, ignition
systems and auxiliaries.
CO5 Understand the working of sensors and ECU.

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 1 2 3 3 1 1 2
CO2 2 1 2 3 2 1 1 2
CO3 2 1 2 3 2 1 1 2
CO4 2 1 2 3 3 1 1 2
CO5 2 1 2 3 3 1 1 2

Introduction: Overview of the course, Examination and Evaluation patterns, History of

Automotive electronics.

Safety and Communication: Safe working practices-work cloths, eye protection, fire
protection, battery safety. Working as an electricity / electronics technician-your toolbox,
access to wiring diagrams and repairs information, communicating with the customer,
working around air bags

Circuit fundamentals and basic test equipment:voltage, current, resistance, circuits

components, series and parallel circuits, purpose of voltmeters, measuring voltage drop,
connecting the voltmeter, types of ammeters, current probes, reading and interpreting
ohmmeter readings, continuity testing.

Vehicle circuits: circuit components, analyzing series and parallel circuits, control circuits,
diagnosing open and short circuits.

Digital Storage Oscilloscope: voltage and time setting, DSO trigger and slope, using a
current probe with DSO, using the DSO’s multiple-trace capability.

Electronic fundamentals: solid state devices, electronic control input devices, diagnosing
and servicing electronic control input devices, integrated circuits as input devices, diagnosing
and servicing ICs, oxygen sensors, diagnosing and servicing oxygen sensors.

Wiring diagrams and Batteries: wiring diagram symbols, using the wiring diagram as
aservice tool, automotive batteries, diagnosing batteries, servicing batteries.
Starting and charging systems: starting circuits, solenoid shift starters, diagnosing and
servicing solenoid shift starters systems, positive engagement starters, diagnosing and
servicing positive engagement starting system, gear-reduction starters, diagnosing gear-
reduction starters, charging system overview, field circuits, diagnosing and servicing the
charging system.

Ignition systems and accessories: secondary ignition systems, servicing the secondary
ignition system, primary ignition system, diagnosing and servicing distributed primary
ignition systems, distributorless ignition secondary circuits, diagnosing and servicing the
secondary ignition system on a distributorless vehicles, distributorless ignition primary
circuits, diagnosing and servicing the primary circuit on a distributorless ignition system.
Lighting circuits, diagnosing lighting circuits, defogger, horn, and windshield wiper circuits,
diagnosing defogger, horn, and windshield wiper circuits, motor driven accessories,
diagnosing motor driven accessories.

Electronic control units and sensors: Vehicle sensors-speed, temperature, fuel level, battery
condition, emissions, feedback circuits.

Reading:

1. Al Santini, Automotive Technology, Electricity and Electronics, Cengage Publishers,

2011.
2. William Ribbens, Understanding Automotive Electronics, 6th Edition, Elsevier, 2011.
 ME5521 ALTERNATE FUELS AND EMISSIONS 3 - 0 - 0 (3 Cr)
Pre - Requisites:IC Engines, Thermodynamics

Course Outcomes: At the end of the course, the student shall be able to:

CO1 Categorize, interpret and understand the essential properties of fuels for IC engines
CO2 Identify the need for alternate fuels and characterize prospective alternate fuels
CO3 evaluate the storage and dispensing facility requirements
Analyze the implement limitations with regard to performance, emission and materials
CO4
compatibility
CO5 Develop strategies for control of emissions as per the legislation standards

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 2 1 2 1 2 1 1 2
CO2 1 3 2 1 2 1 2 1 1 2
CO3 2 3 1 1 2 1 2 1 1 2
CO4 2 3 3 2 3 2 2 1 1 2
CO5 2 3 3 2 3 2 2 1 1 2

1. Introduction: Estimation of petroleum reserve – Need for alternate fuels – Availability

and properties of alternate fuels, ASTM standards
2. Alcohols: General Use of Alcohols – Properties as Engine fuel – Gasolene and alcohol
blends – Performance in SI Engine – Methanol and Gasolene blend – Combustion
Characteristics in engine – emission characteristics
3. Vegetable oils: Soybean Oil, Jatropha, Pongamia, Rice bran, Mahua, etc. as alternate fuel
and their properties, Esterification of oils
4. Natural Gas, LPG: Availability of CNG, properties, modification required to use in
engines – performance and emission characteristics of CNG using LPG in SI & CI
engines.
5. Hydrogen:Hydrogen production, Hydrogen as an alternative fuel, fuel cell
6. Automobile emissions & its control: need for emission control -Classification/
categories of emissions -Major pollutants - control of emissions – Evaluating vehicle
emissions – EURO I,II,III,IV standards – Indian standards

Readings:

1. Alternate Fuels Guide Book

Authors:Richard L. Bechhold P.E.
Publisher: Society of Automotive Engineers, 1997
2. Hydrogen fuel for surface transportation
Authors: Norbeck, Joseph M.
Publisher: Society of Automotive Engineers, 1996
3. History of the Electric Automobiles: Hybrid Electric Vehicles
Authors: Wakefield, Earnest Henry
4. Engine Emissions: Pollutant formation and advances in control Technology
Authors: NorbePundir B.R.
Publisher: Narosa Publishing House
 ME5522 COMBUSTION AND EMISSION CONTROL 3 - 0 - 0 (3 Cr)
Pre - Requisites: Nil

Course Outcomes:

CO1 Understand the concepts of combustion phenomena in energy conversion devices.

Apply the knowledge of adiabatic flame temperature in the design of combustion
CO2
devices.
CO3 Identify the phenomenon of flame stabilization in laminar and turbulent flames.
Analyze the implementation limits with regard to performance, emission and materials
CO4
compatibility
CO5 Identify and understand possible harmful emissions and the legislation standards

CO-PO Mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 1 2
CO2 2 3 2 1 2
CO3 2 3 2 3 1 2
CO4 2 3 3 3 1 2
CO5 2 3 3 1 2

Combustion Principles
Combustion – Combustion equations, heat of combustion - Theoretical flame temperature –
chemical equilibrium and Dissociation -Theories of Combustion - Flammability Limits -
Reaction rates – Laminar and Turbulent Flame Propagation in Engines. Introduction to spray
formation and characterization.

Combustion in S.I. Engines

Stages of combustion, normal and abnormal combustion, knocking, Variables affecting
Knock, Features and design consideration of combustion chambers. Flame structure and
speed, Cyclicvariations, Lean burn combustion, Stratified charge combustion systems. Heat
release correlations.

Combustion in C.I. Engines

Stages of combustion, vaporization of fuel droplets and spray formation, air motion, swirl
measurement, knock and engine variables, Features and design considerations of combustion
chambers, delay period correlations, heat release correlations, Influence of the injection
system on combustion, Direct and indirect injection systems.

Combustion In Gas Turbines

Flame stability, Re-circulation zone and requirements - Combustion chamber configurations,
Cooling, Materials.

Pollutant Emissions from IC Engines

Introduction to clean air, Pollutants from SI and CI Engines: Carbon monoxide, UBHCs,
Oxides of nitrogen (NO-NOX) and Particulate Matter.Mechanism of formation of pollutants,
Factors affecting pollutant formation.Measurement of engine emissions-instrumentation,
Pollution Control Strategies, Emission norms-EURO and Bharat stage norms. Emission
control measures for SI and CI engines. Effect of emissions on environment and human
beings.

Control Techniques for Reduction Of Emission

Design modifications – Optimization of operating factors – Fuel modification – Evaporative
emission control - Exhaust gas recirculation – SCR – Fumigation – Secondary Air injection –
PCV system – Particulate Trap – CCS – Exhaust treatment in SI engines –Thermal reactors –
Catalytic converters – Catalysts – Use of unleaded petrol.

Test Procedure, Instrumentation & Emission Measurement

Test Procedures CVS1, CVS3 – Test cycles – IDC – ECE Test cycle – FTP Test cycle –
NDIRanalyzer – Flame ionization detectors – Chemiluminescent analyzer – Dilution tunnel –
Gas chromatograph – Smoke meters –SHED test.

Readings:

1. Ramalingam, K.K., Internal Combustion Engines, SciTech Publications (India) Pvt. Ltd.,
2004.
2. Ganesan, V, Internal Combustion Engines, Tata McGraw Hill Book Co., 2003.
3. John B. Heywood, Internal Combustion Engine Fundamentals, McGraw Hill Book, 1998.
4. B.P. Pundir I.C. Engines Combustion and Emission, 2010, Narosa Publishing House.
5. B.P. Pundir Engine Combustion and Emission, 2011, Narosa Publishing House.
6. Mathur, M.L., and Sharma, R.P., A Course in Internal Combustion Engines, DhanpatRai
Publications Pvt.New Delhi-2, 1993.
7. Obert, E.F., Internal Combustion Engine and Air Pollution, International Text Book
Publishers, 1983.
8. Cohen, H, Rogers, G, E.C, and Saravanamuttoo, H.I.H., Gas Turbine Theory, Longman
Group Ltd., 1980.
9. Domkundwar V, A course in Internal Combustion Engines, DhanpatRai& Co. (P) Ltd,
2002.
10. Rajput R.K. Internal Combustion Engines, Laxmi Publications (P) Ltd, 2006.
11. Willard W. Pulkrabek, Engineering Fundamentals of the Internal Combustion Engines,
2007, Second Edition, Pearson Prentice Hall
12. Stephen, R. Turns., Combustion, McGraw Hill, 2005.
13. Mishra, D.P., Introduction to Combustion, Prentice Hall,2009
14. Sharma, S. P., Fuels and Combustion, Tata McGraw Hill, New Delhi, 2001.
15. Heywood Internal Combustion Engine Fundamentals, McGraw Hill Co.1988
ME5321 ENTERPRISE RESOURCE PLANNING 3 - 0 - 0 (3 Cr)
Pre-Requisites: NIL

Course Outcomes:

CO1 Understand the concepts of ERP and managing risks.

CO2 Choose the technologies needed for ERP implementation.
CO3 Develop the implementation process.
CO4 Analyze the role of Consultants, Vendors and Employees.
CO5 Evaluate the role of PLM, SCM and CRM in ERP.

CO-PO Mapping:
PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 2
CO2 3 1 2
CO3 3 1 2
CO4 3 1 2
CO5 3 1 2

DETAILED SYLLABUS:

Introduction to ERP: Enterprise – an overview, brief history of ERP, common ERP

myths, Role of CIO, Basic concepts of ERP, Risk factors of ERP implementation,
Operation and Maintenance issues, Managing risk on ERP projects.

ERP and Related Technologies: BPR, Data Warehousing, Data Mining, OLAP, PLM,
SCM, CRM, GIS, Intranets, Extranets, Middleware, Computer Security, Functional
Modules of ERP Software, Integration of ERP, SCM and CRM applications.

ERP Implementation: Why ERP, ERP Implementation Life Cycle, ERP Package
Selection, ERP Transition Strategies, ERP Implementation Process, ERP Project Teams.

ERP Operation and Maintenance: Role of Consultants, Vendors and Employees,

Successes and Failure factors of ERP implementation, Maximizing the ERP system, ERP
and e-Business, Future Directions and Trends.

Reading:

1. Alexis Leon, Enterprise Resource Planning, Tata McGraw Hill, Second Edition,
2008.
2. Jagan Nathan Vaman, ERP in Practice, Tata McGraw Hill, 2007.
3. Carol A Ptak, ERP: Tools, Techniques, and Applications for Integrating the Supply
Chain, 2nd Edition, CRC Press, 2003.
 ME5331 MANUFACTURING MANAGEMENT 3 - 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:
CO1 Design of production planning and control systems encompassing competitive
priorities and strategies.
CO2 Evaluate and interpret Demand Forecast for production planning.
CO3 Design an optimal facility layout and select appropriate product design approach.
CO4 Apply ROP, MRP and JIT systems for inventory control in production systems.

CO-PO Mapping:
PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 2 1 2
CO2 1 3 2 1 2
CO3 1 3 2 1 2
CO4 1 3 2 1 2

Competitive priorities and manufacturing strategy: Introduction, Historical perspective of

manufacturing management, Competitive priorities and operational strategy, Functional area
strategy and Capability, Case Study.

Demand Forecasting: Introduction, Quantitative Methods introduction, Time series and

moving averages method, Exponential Smoothing method, Regression Analysis Method,
Qualitative Methods.

Facility Design: Introduction and History, Product design and process selection, Capacity
planning, Plant location and Plant layout.

Inventory control: From EOQ to ROP, Independent Demand Inventory control & Economic
Order Quantity (EOQ), Dynamic lot sizing, Statistical inventory control models.

The MRP crusade: History, Need, Evolution, Dependent Demand & Material Requirement
Planning (MRP), Structure of MRP system, MRP Calculations.

The JIT revolution: Just-in-Time System: origin & goals, Characteristics of JIT Systems,
Continuous Improvement, The Kanban System, Strategic Implications of JIT System.

Production Planning and Control: Shop floor control, Production scheduling, Aggregate
planning, Aggregate and workforce planning.

Reading:

1. Krajewski U and Ritzman LP, Operations Management: Strategy and Analysis, Pearson
Education Pvt Ltd., Singapore, 2002.
2. Gaither N and Frazier G, Operations Management, Thomson Asia Pvt. Ltd., Singapore,
2002.
3. Chase RB, Aquilano NJ and Jacobs RF, Operations Management for Competitive
Advantage, McGraw-Hill Book Company, NY, 2001.
 ME5336 SOFT COMPUTING TECHNIQUES 3 - 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:
CO1 Classify and differentiate problem solving methods and tools.
CO2 Apply A*, AO*, Branch and Bound search techniques for problem solving.
CO3 Formulate an optimization problem to solve using evolutionary computing methods.
Design and implement GA, PSO and ACO algorithms for optimization problems
CO4
in Mechanical Engineering.
Apply soft computing techniques for design, control and optimization of
CO5
Manufacturing systems.

CO-PO Mapping:
PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 2
CO2 3 1 2
CO3 3 1 2
CO4 3 1 2
CO5 3 1 2

Problem Solving Methods and Tools: Problem Space, Problem solving, State space,
Algorithm’s performance and complexity, Search Algorithms, Depth first search method,
Breadth first search methods their comparison, A*, AO*, Branch and Bound search
techniques, p type, Np complete and Np Hard problems.

Evolutionary Computing Methods: Principles of Evolutionary Processes and genetics, A

history of Evolutionary computation and introduction to evolutionary algorithms, Genetic
algorithms, Evolutionary strategy, Evolutionary programming, Genetic programming.

Genetic Algorithm and Genetic Programming: Basic concepts, working principle,

procedures of GA, flow chart of GA, Genetic representations, (encoding) Initialization and
selection, Genetic operators, Mutation, Generational Cycle, applications.

Swarm Optimization: Introduction to Swarm intelligence, Ant colony optimization

(ACO), Particle swarm optimization (PSO), Artificial Bee colony algorithm (ABC), Other
variants of swarm intelligence algorithms.

Advances in Soft Computing Tools: Fuzzy Logic, Theory and applications, Fuzzy Neural
networks, Pattern Recognition, Differential Evolution, Data Mining Concepts,
Applications of above algorithms in manufacturing engineering problems.

Artificial Neural Networks: Neuron, Nerve structure and synapse, Artificial Neuron and
its model, activation functions, Neural network architecture: single layer and multilayer
feed forward networks, recurrent networks. Back propagation algorithm, factors affecting
back propagation training, applications.
Application of Soft Computing to Mechanical Engineering/Production Engineering
Problems: Application to Inventory control, Scheduling problems, Production,
Distribution, Routing, Transportation, Assignment problems.

Reading:

1. Tettamanzi Andrea, Tomassini and Marco, Soft Computing Integrating Evolutionary,

Neural and Fuzzy Systems, Springer, 2001.
2. Elaine Rich, Artificial Intelligence, McGraw Hill, 2/e, 1990.
3. Kalyanmoy Deb, Multi-objective Optimization using Evolutionary Algorithms, John Wiley
and Sons, 2001.
 ME5421 ANALYSIS AND SYNTHESIS OF MECHANISMS 3 - 0 - 0 (3 Cr)
Pre-Requisites: Theory of Machines

Course Outcomes:

Understand basic mechanisms and machines and formulate the design problem.
CO1
Develop analytical equations for relative position, velocity and acceleration of all
CO2
moving links.
CO3 Analyze Simple and Complex mechanisms.
Apply the knowledge of Kinematic theories to practical problems of mechanism
CO4
design and synthesis.
CO5 Design higher pair kinematic linkages for a given application.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 2 1 2
CO2 2 3 2 1 2
CO3 2 3 2 1 2
CO4 2 3 2 1 2
CO5 2 3 2 1 2

Introduction: Mechanisms and machines, Planer and Spatial Mechanisms, Mobility, type of
motion, links, joints and kinematic chains, of mechanisms, four bar chain, isomers, Linkage
transformation, Inversion, four link planar mechanisms, Groshof condition, spring as a link,
complaint mechanisms, Practical considerations – pin joints versus sliders.

Position Analysis: Position and systems, co-ordinate transformation, rotation, translation and
combined motion, Algebraic position analysis, position any point on a linkage, transmission
angles, toggle positions.

Kinematics of Rigid Bodies: Plane Motion of a rigid body, graphical velocity and
acceleration analysis, Instantaneous centers of velocity, Centrodes, velocity of rub, Analytical
solutions for velocity Analysis – velocity of any point on a linkage, Acceleration of any point
on a linkage, Coriolis acceleration. Analytical solutions for velocity and acceleration analysis
- loop closure equations, Case studies – four-bar pin joined linkage, four link slider-crank.

Analytical Linkage Synthesis:Types of kinematic synthesis – Motion and Path generation,

Number synthesis, Dimensional synthesis, Two position synthesis for rocker output,
Precision Points, Comparison of analytical and graphical two position synthesis, three
position synthesis.

Graphical Linkage Synthesis:Two position synthesis for rocker output, Three position
synthesis, Position synthesis for more than three positions (four and six bar quick return),
Coupler curves, Exact and approximate straight line mechanisms.
Cam:Terminology, types of follower, follower motions, cams, SVAJ diagrams, law of cam
design, Single and Double dwell cam design using SHM, cycloidal displacement, combined
functions. Critical path motion, practical design considerations.

Gears and Gear Trains:Law of gearing, involute tooth form, pressure angle, backlash,
contact ratio, Interference and method to avoid interference, Gear Train and its analysis.

Reading:

1. Kinematics and Dynamics of machnery, R L. Norton, Pearson, 2009

2. Kinematics Analysis and Synthesis of Mechanisms - A K Mallik, Amitabha Ghosh and
Guntur, D. CRC Press, 2011.
3. Mechanical Engineering Design - Shigley et al., Tat McGraw Hill, 2011.
 ME5422 MATHEMATICAL METHODS IN ENGINEERING 3 - 0 - 0 (3 CR)
Pre-Requisites: Nil

Course Outcomes:

CO1 Apply methods of Applied Linear Algebra in engineering design.

CO2 Solve problems involving Nonlinear Optimization in engineering.
CO3 Simulate engineering systems using Numerical Methods.
CO4 Model the physical systems using Differential Equations.

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 2
CO2 3 1 2

CO3 3 1 2
CO4 3 1 2

Mathematical Modeling: Modeling of systems related to mechanical engineering,

assumptions, appropriate methods and fundamental of a computer implementation

Solution of Systems of Linear Equations: Introduction, Basic Ideas of Applied Linear

Algebra, Systems of Linear Equations, Square, Non-Singular Systems, Ill-Conditioned and
Ill-Posed Systems. Applications in engineering analysis using Finite Element.Computer
implementation of the methods.

The Algebraic Eigenvalue Problem: The Algebraic Eigenvalue Problem, Canonical Forms,
Symmetric Matrices, Methods of Plane Rotations, Householder Method, Tridiagonal
Matrices, QR Decomposition, General Matrices. Case studies related to mechanical
vibrations. Computer implementation of the methods.

Selected Topics in Linear Algebra and Calculus: Singular Value Decomposition, Vector
Space: Concepts, Multivariate Calculus, Vector Calculus in Geometry, Vector Calculus in
Physics.

An Introductory Outline of Optimization Techniques: Solution of Equations, Introdcution

to Optimization, Multivariate Optimization, Constrained Optimization: Optimality Criteria,
Constrained Optimization: Further Issues. Applications in design optimization,
manufacturing and thermal process optimization.Computer implementation of the methods.

Selected Topics in Numerical Analysis: Interpolation, Regression, Numerical Integration,

Numerical Solution of ODE's as IVP Boundary Value Problems, Question of Stability in IVP
Solution, Stiff Differential Equations, Existence and Uniqueness Theory.Application to CAD,
Experimental research in mechanical engineering.Computer implementation of the methods
.
Ordinary Differential Equations: Theory of First Order ODE's, Linear Second Order
ODE's, Methods of Linear ODE's, ODE Systems, Stability of Dynamic Systems. Case studies
of Modal analysis.

Application of ODE's in Approximation Theory: Series Solutions and Special Functions ,

Sturm-Liouville Theory, Approximation Theory and Fourier Series, Fourier Integral to
Fourier Transform, MinimaxApproximation.Computer implementation of the methods.

Overviews: PDE's, Complex Analysis and Variational Calculus: Separation of Variables

in PDE's, Hyperbolic Equations, Parabolic and Elliptic Equations, Membrane Equation,
Analytic Functions , Integration of Complex Functions, Singularities and Residues, Calculus
of Variations. Applications in FEM, Thermal engineering.Computer implementation of the
methods.

Reading:

1. B. Dasgupta , Applied Mathematical Methods, Pearson Education, 2006.

2. E. Kreyszig , Advanced Engineering Mathematics, Wiley, 2010.
3. M. T. Heath, Scientific Computing, McGraw-Hill Education, 2001.
4. Steven Chapra, Applied Numerical Methods with Matlab, McGraw-Hill Education, 2011.
 ME5621 ADVANCED METAL FORMING 3 - 0 - 0 (3 Cr)

PRE-REQUISITES: Nil
COURSE OUTCOMES:

CO1 Solve for strain rates, temperatures and metallurgical states in forming problems.

CO2 Develop process maps for metal forming processes using plasticity principles.
CO3 Estimate formability limits for sheets and bulk metals.
CO4 Evaluate workability of different ductile materials
CO5 Apply FE principles to simulate metal forming processes

CO-PO MAPPING:

PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 2 3 1 2
CO2 2 2 3 1 2
CO3 2 2 3 1 2
CO4 2 2 3 1 2
CO5 2 2 3 1 2

Introduction Metal forming as a manufacturing process and its relation with other processes
– Classification based on type of stresses - Examples.

Theoretical analysis (theory of plasticity), Stress-strain relationship, Strain hardening,

Material incompressibility, Work of plastic deformation, Work hardening, Yield criteria,
Flow rule, Yield criterion and flow rule for Anisotropic material, Initiation and extent of
plastic flow- Problems.

Overview of various metal forming operations: Mechanics of Various Plastic Flow

Problems Introduction to; (i). Theory of slip lines, Upper bound theorem, Lower bound
theorem.

Forging processes: Metal flow in forging, Analysis of plane strain compression, Analysis of
compression of circular disc with slab method.

Extrusion Processes: Calculation of extrusion load using slab method, slip line method and
upper bound method. Defects in extrusion. Direct & indirect extrusion.

Wire Drawing Processes: Introduction,wire drawing load calculation using slab method.

Rolling Processes:Analysis of longitudinal strip or sheet rolling process (calculation of roll

separating force, torque & power, angle of bite, maximum reduction in rolling), rolling
defects.
Sheet forming: Mechanics – Flow Rules – Anisotropy - Formability of sheet, Formability
tests, forming limit diagrams, Case studies.

Pressing and Sintering: Workability Studies – Densification - Problems & Case Studies

Incremental Forming: Statics and Kinematics of Incremental Stresses and Strains - The
Kinematics of Two-Dimensional Strain, The Kinematics of Three-Dimensional Strain,
Incremental Stresses in Two Dimensions, Incremental Stresses in Three Dimensions,
Equilibrium Equations for the Stress Field in Two Dimensions, Equilibrium Equations for
the Stress Field in Three Dimensions,

Modeling and Simulation in Metal Forming: Plasticity and Viscoelasticity – Constitutive

relations - The Plane Strain Compression Test, FEM Model and Input Data to the Model -
Deformations in the Compression Gap - Effective Strain and Strain-Rate Distributions in
Deformed Zones - Damage Parameter and Edge Cracking.

Reading:

1. Surender Kumar, Technology of Metal Forming Processes, Prentice - Hall, Inc., 2008.
2. Henry S. Valberg, Applied Metal Forming - Including FEM Analysis, Cambridge
University Press, 2010.
3. Metal Forming: Mechanics and Metallurgy by William F. Hosford and Robert M.
Caddell, Prentice-Hall (USA) – 2012
4. Slater.RA.C.Engineering Plasticity-Theory & Applications to Metal Forming, John
Wiley and Sons, 1987.
5. Shiro Kobayashi,Altan.T, Metal Forming and Finite Element Method, Oxford University
Press, 1989
6. Maurice A. Biot, Mechanics of Incremental Deformations, John Wiley & Sons,2008
 I-Year, II Semester, Core Courses

ME5551 VEHICLE BODY ENGINEERING 4 - 0 - 0 (4 Cr)

Prerequisites: Nil

Course outcomes:

CO1 Classify vehicle body according to body shape and frame structures.
CO2 Enumerate the aerodynamic forces acting on the vehicle body and examine the
methods to reduce them.
CO3 Apply the principles of simple structural surface method to strengthen vehicle body
panels.
CO4 Examine the vehicle crash testing methods
CO5 Identify sources of noise and methods to minimize it.

CO-PO mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 2 1 1 2
CO2 2 3 3 2 2 1 1 2
CO3 2 3 2 2 1 1 2
CO4 2 3 3 2 2 1 1 2
CO5 2 2 3 2 2 1 1 2

Frame: Introduction, Loads on the Frames, Construction and Cross sections of the frame,
Types of Frames

Automotive Body: Vehicle body styles, Aerodynamic considerations in body profiling:

Drag reduction, Drag force calculation.

Vehicle Structure: Basic requirement of stiffness and strengthVehicle structure types

Demonstration of Simple Structural Surfaces (SSS).

Body Components:Bumpers, Grilles, Sill covers and side airdams, outer moldingsWeather
strips, Glass and Mirrors.

Body Interiors: Seat Belt Restraint system-Air-Bag, components of Air- Bag, Dash Board

Vehicle Safety: Introduction, Crash testing, protection of occupantsTesting for occupants

safety, safety controls.

Noise: Interior noise-Engine noise, Road noise, wind noise, brake noise, Interior noise:
Assessment and control

Text Books:

1. Powloski J, Vehicle Body Engineering, Business Books Ltd, 2000.

2. Lorenzo Morello, Automotive Body, Volume-I (component design), Springer, 2011
3. David A Crolla, Automotive Engineering (Power Train, Chassis system and Vehicle
Body), Elsevier collection, 2009.
Reference books:

1. Giles G.J. Body Construction & Design Illiffe Books Butter worth & co., 2000.
2. John Fenton Vehicle Body Layout and Analysis, Mechanical Engineering Publication
Ltd., London, 2001.
 ME5456 VEHICLE DYNAMICS 4 - 0 - 0 (4 Cr)
Prerequisites: Nil

Course Outcomes:

CO1 Understandthe principles underlying the development and design of road vehicles
under the influence of dynamic loads.
CO2 Analyze the performance and establish the design specifications for the acceleration
and braking conditions.
CO3 Model, simulate and analyze the conventional road vehicles for better ride comfort.
CO4 Analyze the cornering forces and effects of tractive forces on cornering
CO5 Design suspension systems for better damping and comfort

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 3 2 2 1 1 1 2
CO2 2 3 3 2 2 1 1 2
CO3 3 3 3 2 3 1 1 2
CO4 3 3 2 2 2 1 1 2
CO5 3 3 3 2 3 1 1 2

Introduction: Hypothetical vehicle control loop, Fundamental Approach, Vehicle co-

ordinates, motion variables. Forces – Dynamic axle loads, Static loads on level ground,
aerodynamic forces on body, hitch forces – problems

Acceleration & Braking Performance – Power limited acceleration, Static loads on level
ground, aerodynamic forces on body, Fundamental Expressions, Constant retardation, Wind
Resistance, Power, Braking forces, Brakes: disc and drum, front, rear and four wheel braking,
Road friction rolling resistance, problems.

Road Loads: Aerodynamic, Mechanics of pressure distribution – Aerodynamic forces: lift &
drag, Spoilers, Lift force, side force and roll, pitch and yaw moments, Crosswind sensitivity.
Rolling Resistance, Factors affecting pressure, velocity, slip temperature, etc – Total road
loads – Fuel Economy Effects.

Ride: Excitation sources – road roughness, wheel assembly, driveline excitation, engine
transmission. Vehicle response properties: Suspension isolation, suspension stiffness &
damping Wheel Hop Resonance. Road-tyre friction – dynamic response of tires – Rigid body
bounce, pitch motion.Perception of ride and other vibration forms, Problems.

Steady – State Cornering: Introduction, Low and high speed turning –Tire cornering forces,
governing expressions, understeer gradient, oversteer and nutral conditions. Characteristic
speed, critical speed, yaw velocity gain, sideslip angle, static margin. Suspension effects on
cornering: roll moment distribution – effect of tractive forces on cornering – Problems

Suspension – Solid axes – Independent suspension, Trail arm, Front – Multi link – Trailing
rear suspension – Anti-squat and anti- pitch suspension - Active suspension – Performance.
Reading:
1. Hans B Pacejka, Tire and Vehicle Dynamics,3rd Edition, Elsevier Ltd., 2012.
2. Amitosh D, Vehicle Dynamics, Galgotia Book Ltd., 2010.
3. Rao V Dukkipati, Road Vehicle Dynamics,Springer 2008
4. Werner and Karl, Ground Vehicle Dynamics,Springer Berlin Heidelberg, 2008.
5. Wong H, Theory of Ground Vehicles, McGraw Hill, Second edition, 2006.
 ME5591 AUTOMOTIVE SYSTEMS LABORATORY 0- 0 - 3 (2 Cr)
Prerequisites: I C Engines Lab.

Course Outcomes:

CO1 Analysethe power transmission system

CO2 Understand power steering and braking systems
CO3 Perform tests on chassis dynamometer
CO4 Perform tests on wheel alignment and onboard diagnostic
CO5 Evaluate the performance characteristics of solar and fuel cell systems

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 1 2 3 2 2 2 3 2
CO2 3 1 2 3 3 3 2 2 3 2
CO3 3 3 3 3 3 3 3 2 3 2
CO4 3 2 1 2 2 3 1 2 3 2

Week Exercise
1 Assemble and Dismantle the Old vehicle to study the parts.
2 Study of Power steering system, Braking System, Gear Box and Clutch assembly
3 Draw the Valve Timing Diagram of a given Engine
4 Wheel alignment test
5 Onboard diagnostic test
6 Vehicle performance test using chassis dynamometer
7 Wind resistance test
8 Fuel consumption test
9 Vehicle emission measurement using chassis dynamometer as per Indian Driving
Cycle (IDC)
10 Study of vehicle lighting system and Bendix drive
11 V-I characteristics of solar simulator in different configurations
12 Performance test on PEM fuel cell
 ME5592 MODELING AND ANALYSIS LABORATORY 0- 0 - 3 (2 Cr)
Prerequisites: Nil

Course Outcomes:

CO1 Develop programs in MATLAB to solve typical analysis problems.

CO2 Solve problems involving Trusses, Beams and Frames using the developed code.
CO3 Solve problems involving Triangular element and higher order elements using the
developed code.
CO4 Solve structural problems using Ansys.
CO5 Execute a medium size project.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 3 3 2 3 2
CO2 2 3 3 3 2 3 2
CO3 2 3 3 3 2 3 2
CO4 2 3 3 3 2 3 2
CO5 2 3 3 3 2 3 2

Week Exercise
1 Introduction to developing code for finite element analysis in MATLAB
2 Practice session on handling assembly, boundary conditions etc
3 Solving problems of Trusses
4 Solving problems of Beams and Frames
5 Solving problems involving triangular element etc
6 More practice with case studies
7 Introduction to commercial software, Ansys
8 Solving problems of Trusses using Ansys
9 Solving problems of Beams and Frames using Ansys
10 Solving problems involving triangular element etc using Ansys
11 Crash analysis using LS Dyna
12 Case studies and working on projects
13 Case studies and working on projects.
14 Case studies and working on projects
 ME5593 SEMINAR-II 0- 0 - 3 (1 Cr)
Prerequisites: Nil

CO1 Identify and compare technical and practical issues related to Automobile Engineering
CO2 Outline annotated bibliography of research demonstrating scholarly skills.
Prepare a well organized report employing elements of technical writing and critical
CO3
thinking
Demonstrate the ability to describe, interpret and analyze technical issues and develop
CO4
competence in presenting.

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 2 1 2 2 1 1 3 3 3
CO2 1 2 1 2 1 1 2 3 3 3
CO3 1 1 1 1 1 1 1 3 3 3
CO4 1 2 1 2 2 1 2 3 3 3
 I-Year II-semester Elective Courses)
ME5561 NOISE, VIBRATIONS & HARSHNESS 3- 0 - 0 (3 Cr)

Course Outcomes:

CO1 Identify sources of noise and vibration

CO2 Measure sound intensity and human sensitivity
CO3 Model statistical energy analysis and simulators
CO4 Evaluate active control techniques
CO5 Identify and evaluate the signal processing techniques.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 1 2 1 3 2 1 2
CO2 2 1 2 1 3 2 1 2
CO3 2 1 2 1 3 2 1 2
CO4 2 1 2 1 3 2 1 2
CO5 2 1 2 1 3 2 1 2

NVH in the Automotive Industry

Sources of noise and vibration. Design features. Common problems. Marque values. Noise
quality. Pass-by noise requirements. Target vehicles and objective targets. Development
stages in a new vehicle programme and the altering role of NVH engineers.

Sound and Vibration Theory

Sound measurement. Human sensitivity and weighting factors. Combining sound sources.
Acoustical resonances. Properties of acoustic materials. Transient and steady state response
of one degree of freedom system applied to vehicle systems. Transmissibility. Modes of
vibration.

Test Facilities and Instrumentation

Laboratory simulation: rolling roads (dynamometers), road simulators, semi-anechoic rooms,
wind tunnels, etc. Transducers, signal conditioning and recording systems. Binaural head
recordings., Sound Intensity technique, Acoustic Holography, Statistical Energy Analysis.

Signal Processing
Sampling, aliasing and resolution. Statistical analysis. Frequency analysis. Campbell's plots,
cascade diagrams, coherence and correlation functions.

NVH Control Strategies & Comfort

Source ranking. Noise path analysis. Modal analysis. Design of Experiments, Optimization of
dynamic characteristics. Vibration absorbers and Helmholtz resonators. Active control
techniques.

Reading:

1. Norton M P, Fundamental of Noise and Vibration, Cambridge University Press,2001

2. Munjal M.L., Acoustic Ducts and Mufflers, John Wiley, 2002

Reference Books:

1. Baxa, Noise Control of Internal Combustion Engine, John Wiley, 2000.

2. Ewins D. J., Model Testing : Theory and Practice, John Wiley,1995.
3. Boris and Kornev, Dynamic Vibration Absorbers, John Wiley, 1993.
4. McConnell K, “Vibration Testing Theory and Practice”, John Wiley, 1995.
 ME5562 VEHICLE TESTING AND INSTRUMENTATION 3- 0 - 0 (3 Cr)
Prerequisites: Nil

Course Outcomes:

CO1 Understand the importance of testing of vehicle components and systems as per
standards.
CO2 Apply the knowledge of error and uncertainty with regards to instruments and
equipment used in engine and vehicle testing.
CO3 Classify the dynamometers for testing the engines and vehicles.
CO4 Identify the harmful pollutants and analyze the instruments used for measuring
vehicle emissions.
CO5 Develop methods for quantifying and reduction of aerodynamic drag of vehicles.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 1 2 3 3 1 1 1 2
CO2 3 1 3 3 3 3 2 1 1 2
CO3 3 2 3 2 3 2 1 1 1 2
CO4 3 2 3 1 3 2 3 1 1 2
CO5 3 2 3 3 3 2 1 1 2

Introduction: Overview of the course-Need of vehicle testing (engine testing both for
performance and emissions in specific)-Requirement of standard instrumentation and
equipment, certification and national and international standards, Importance of expertise in
testing, certification.

Measurement fundamentals: Definitions associated with measurements-Least count,

resolution, Precision, Accuracy, Error / Uncertainty analysis- Data collection and handling-
Simple numerical problems.

Engine Testing: Definition and importance of engine in a vehicle- Road load equation-
Testing under constant speed and variable speed condition. Classification of engine
dynamometers- Characteristic curves of various types of dynamometers-Advantage and
limitations of different types engine dynamometers-Discussion on typical engine
performance characteristics.

Combustion analysis: Definition of Combustion, Combustion stoichiometry, SI engine

combustion and CI engine combustion-Measurement of in-cylinder pressure, temperatures-
instrumentation

Fuel injection systems: Fuel injection for SI and CI engines, Types of different systems-
Electronic injection systems and Electronic Control Units-Testing of injection systems.

Vehicle Emissions: Types of emissions and pollutant formation mechanisms-Vehicle

Driving Cycles, Emission measurement on engine and chassis dynamometer-Measurement of
regulated and non-regulated pollutants-Description of emission measuring instrumentation-
NDIR, FID, Chemiluminescence Analyzer, Chromatograph, Smoke meters -Emission
regulations and legislation- EURO and Bharat Stage norms

Vehicle performance and testing techniques: Schematic layout of typical vehicle-Types of

testing for both engine in specific, and whole vehicle body. Description of important
components of Vehicle and Engine that require testing. Different types of engines for
Vehicles- fossil fuel run engines, hybrid and electric vehicles -Testing procedure for electric
vehicles- -Chassis and Rolling road dynamometers-Brief introduction to testing of tires,
steering, brakes, wheel alignment-Introduction to on-board diagnostics.

Vehicle Drag & Aerodynamics of Vehicle: Introduction to drag and aerodynamics,

Description drag-terms associated; streamlined and bluff bodies-Definition of Ahmed car-
adverse effects of drag-Drag measuring techniques-drag reduction strategies

Vehicle certification: Need for Vehicle certification and facilities required, Importance
driving cycles-Indian Driving Cycle, MIDC-procedures, Introduction to other country driving
cycle-Japan, EUDC

Reading Books:

1. Heinz Heisler, Advance Vehicle Technology, Butterworth-Heinemann, 2002

2. Tom Denton, Advanced Automotive Fault Diagnosis, Elsevier Butterworth-
Heinemann,2006
3. Martyr and Plint, Engine testing-theory and Practice, Butterworth-Heinemann, 2002.
4. J.P. Holman, Experimental Methods for Engineers, Tata McGraw Hill Co. 2007.
 ME5563 ENGINE MANAGEMENT SYSTEMS 3- 0 - 0 (3 Cr)
Prerequisites: I C Engines

Course Outcomes:

CO1 Identify modern automobile accessories and engine management systems.

CO2 Understand the computerized engine testing and diagnosis procedures of engine
control systems.
CO3 Understand the concept of various sensors and actuators
CO4 Develop SI and CI engine management systems
CO5 Analyse electronic fuel andignition management systems in the modern automobile.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 3 2 3 1 2
CO2 3 2 2 3 1 1 2
CO3 3 2 3 1 3 2 3 1 1 2
CO4 2 3 3 2 1 2
CO5 3 2 3 1 2 2 1 2

Computerized Electronic Fuel Injection:Engine Input Sensors-

Coolant & Intake Temperature, Crankshaft Position, Camshaft Position, Manifold Absolute
Pressure, Throttle Position, Oxygen, Air/Fuel Ratio, Knock Speed& Distance, Battery &
Switches
Output Devices -Relays, Injector Sequencing & Management, Ignition Operation, Idle Air
Control, EGR, EVAP, Wastegate Solenoids, Torque Converter & Speed Control,
Malfunction Indicator Light

Speed Density/Mass Air Flow Fuel Management Strategies:

Key ON Mode, Crank Mode, Open & Closed Loop, Wide-Open Throttle, Adaptive Memory
Cells, Cruise &Deceleration, Wide-Open Throttle, Key OFF Mode

Fuel Injection Systems -Electronic Fuel Systems, Computer Self-Diagnostic Circuits,

Electronic Throttle Actuator Control Systems, Fuel Control, Fuel Supply System Control,
Injection System Inspection and Maintenance.

Engine Diagnostic Procedures

Fuel System testing, On Board Diagnostics, Monitored &Non Monitored Circuits, Diagnostic
Trouble Codes

Digital Engine Control System:

Open loop and close loop control system, engine cooling and warm up control, idle speed
control, acceleration and full load enrichment, deceleration fuel cutoff. Fuel control maps,
open loop control of fuel injection and closed loop lambda control exhaust emission control,
on-board diagnostics, diagnostics, future automotive electronic systems, Electronic dash
board instruments – Onboard diagnosis system.
SI Engine Management:Feedback carburetor system, throttle body injection and multi point
fuel injection system, injection system controls, advantage of electronic ignition systems,
three-way catalytic converter, conversion efficiency versus lambda. Layout and working of
SI engine management systems like Bosch Monojetronic, L-Jetronic and LH-Jetronic. Group
and sequential injection techniques. Working of the fuel system components.Advantages of
electronic ignition systems.Types of solid state ignition systems and their principle of
operation, Contactless electronic ignition system, Electronic spark timing control.

CI Engine Management:Fuel injection system, parameters affecting combustion, noise and

emissions in CI engines. Pilot, main, advanced, post injection and retarded post injection.
Electronically controlled Unit Injection system.Layout of the common rail fuel injection
system. Working of components like fuel injector, fuel pump, rail pressure limiter, flow
limiter, EGR valve control in electronically controlled systems.

Reading Books:

1. Halderman, J. & Linder, J. (2012). Automotive Fuel and Emissions Control Systems (3rd
Edition)Upper Saddle River, NJ: Pearson Education.

2. Halderman, J. D. (2011). Diagnosis &Troubleshooting of Automotive Electrical,

Electronic, &Computer Systems (6th Edition) Upper Saddle River, NJ: Pearson
Education.
3. Diesel Engine Management by Robert Bosch, SAE Publications, 3rd Edition, 2004
4. Gasoline Engine Management by Robert Bosch, SAE Publications, 2nd Edition, 2004
5. Understanding Automotive Electronics – Bechfold SAE 1998
6. Automobile Electronics by Eric Chowanietz SAE.
7. Fundamentals of Automotive Electronics - V.A.W.Hilliers - Hatchin, London

Reference:

1.Automobile Electrical & Electronic Equipments (2000) Young, Griffitns - Butterworths,

London.
2.Understanding Automotive Electronics, Wiliam B. Ribbens, 5th Edition, Newnes,
Butterworth–Heinemann, 2001.
3. Automotive Computers & Digital Instrumentation – Robert N. Brandy, Prentice Hall, 2004
4. The Fundamentals of Electrical Systems - John Hartly - Longman Scientific & Technical,
2002.
 ME5564 AUTOMOTIVE SAFETY AND MAINTENANCE 3- 0 - 0 (3 Cr)
Prerequisites:Nil

Course Outcomes:

CO1 Identify safety systems necessary for automobiles

CO2 Understand active and passive safety systems
CO3 Design and develop automobile safety systems and, comfort and convenience
systems.
CO4 Understand and diagnose engine maintenance and its trouble shooting.
CO5 Understand and diagnose the transmission, steering, braking, air conditioning and
electrical systems.

Mapping Matrix:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 3 1 3 3 1 1 2
CO2 2 3 3 2 2 2 1 1 2
CO3 2 3 3 1 2 3 1 1 2
CO4 1 2 2 2 2 2 2 1 1 2
CO5 3 3 2 2 2 2 2 1 1 2

Introduction
Design of the body for safety, energy equation, engine location, deceleration of vehicle inside
passenger compartment, deceleration on impact with stationary and movable obstacle,
concept of crumble zone, safety sandwich construction.

safety concepts
Active safety: driving safety, conditional safety, perceptibility safety, operating safety,
passive safety: exterior safety, interior safety, deformation behaviour of vehicle body, speed
and acceleration characteristics of passenger compartment on impact.

Safety equipments
Seat belt, regulations, automatic seat belt tightener system, collapsible steering column,
tiltable steering wheel, air bags, electronic system for activating air bags, bumper design for
safety.

Collision warning and avoidance

Collision warning system, causes of rear end collision, frontal object detection, rear vehicle
object detection system, object detection system with braking system interactions.

Comfort and convenience system

Steering and mirror adjustment, central locking system, Garage door opening system, tyre
pressure control system, rain sensor system, environment information system.

Engine and engine subsystem maintenance

General Engine service- Dismantling of Engine components- Engine repair- working on the
underside,front, top, ancillaries- Service of basic engine parts, cooling and lubricating system,
fuel system,Intake and Exhaust system, electrical system - Electronic fuel injection and
engine managementservice - fault diagnosis- servicing emission controls

Transmission and driveline maintenance

Clutch- general checks, adjustment and service- Dismantling, identifying, checking and
reassemblingtransmission, transaxle- road testing- Removing and replacing propeller shaft,
servicing of cross andyoke joint and constant velocity joints- Rear axle service points-
removing axle shaft and bearings- servicing differential assemblies- fault diagnosis.

Steering, brake, suspension, wheel maintenance

Inspection, Maintenance and Service of Hydraulic brake, Drum brake, Disc brake,
Parkingbrake.Bleeding of brakes. Inspection, Maintenance and Service of Mc person strut,
coil spring, leaf spring,shock absorbers. Dismantling and assembly procedures.Wheel
alignment and balance, removingand fitting of tyres, tyre wear and tyre rotation. Inspection,
Maintenance and Service of steeringlinkage, steering column, Rack and pinion steering,
Recirculating ball steering service- Worm typesteering, power steering system

Auto electrical and air conditioning maintenance

Maintenance of batteries, starting system, charging system and body electrical -Fault
diagnosis usingScan tools. Maintenance of air conditioning parts like compressor, condenser,
expansion valve,evaporator - Replacement of hoses- Leak detection- AC Charging- Fault
diagnosisVehicle body repair like panel beating, tinkering, soldering, polishing, painting.

Reading Books:

1. Bosch, “Automotive Handbook”, 8 th Edition, SAE publication, 2011.

2. Ed May, "Automotive Mechanics Volume One" , McGraw Hill Publications, 2003
3. Ed May, "Automotive Mechanics Volume Two" , McGraw Hill Publications, 2003
4. Vehicle Service Manuals of reputed manufacturers
5. JullianHappian-Smith ‘An Introduction to Modern Vehicle Design’ SAE, 2002
6. Johnson, W., and Mamalis, A.G., "Crashworthiness of Vehicles, MEP, London, 1995
7. Rollover Prevention, Crash Avoidance, Crashworthiness, Ergonomics and Human
Factors”, SAE Special Publication, November 2003
 ME5171 DESIGN OF HEAT TRANSFER EQUIPMENT 3 - 0 - 0 (3 Cr)
Pre - Requisites: Nil

Course Outcomes:

CO1 Understand the physics and the mathematical treatment of typical heat exchangers
CO2 Apply LMTD and Effectiveness - NTU methods in the design of heat exchangers
CO3 Design and analyze the shell and tube heat exchanger.
Apply the principles of boiling and condensation in the design of boilers and
CO4
condensers
CO5 Design cooling towers from the principles of psychrometry

CO-PO Mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 2 2 2 1 1 2
CO2 1 2 3 3 1 1 2
CO3 3 2 2 3 1 1 2
CO4 2 2 2 3 1 1 2
CO5 2 2 2 3 1 1 2

Introduction to Heat Exchangers: Definition, Applications, Various methods of

classification of heat exchangers with examples.

Governing Equation for heat exchangers: Derivation from steady-state steady-flow

considerations.

Mathematical treatment of Heat Exchangers: Concept of Overall Heat Transfer

Coefficient, Derivation of the concerned equations, Fouling, Fouling Factor, Factors
contributing to fouling of a heat exchanger, Ill-Effects of fouling, Numerical Problems.

Concept of Logarithmic Mean Temperature Difference:Expression for single-pass

parallel-flow and single-pass counter flow heat exchangers – Derivation from first principles,
Special Cases, LMTD for a single-pass cross-flow heat exchanger – Nusselt’s approach,
Chart solutions of Bowman et al. pertaining to LMTD analysis for various kinds of heat
exchangers, Numerical Problems, Arithmetic Mean Temperature Difference [AMTD],
Relation between AMTD and LMTD, Logical Contrast between AMTD and LMTD, LMTD
of a single-pass heat exchanger with linearly varying overall heat transfer coefficient [U]
along the length of the heat exchanger.

Concept of Effectiveness:Effectiveness-Number of Transfer Units Approach, Effectiveness

of single-pass parallel-flow and counter-flow heat exchangers, Physical significance of NTU,
Heat capacity ratio, Different special cases of the above approach, Chart solutions of Kays
and London pertaining to Effectiveness-NTU approach, Numerical Problems.

Hair-Pin Heat Exchangers: Introduction to Counter-flow Double-pipe or Hair-Pin heat

exchangers, Industrial versions of the same, Film coefficients in tubes and annuli, Pressure
drop, Augmentation of performance of hair-pin heat exchangers, Series and Series-Parallel
arrangements of hair-pin heat exchangers, Comprehensive Design Algorithm for hair-pin heat
exchangers, Numerical Problems.

Shell and Tube Heat Exchangers: Single-Pass, One shell-Two tube [1S-2T] and other heat
exchangers, Industrial versions of the same, Classification and Nomenclature, Baffle
arrangement, Types of Baffles, Tube arrangement, Types of tube pitch lay-outs, Shell and
Tube side film coefficients, Pressure drop calculations, Numerical Problems.

Principles of Boilers and Condensers: Boiling, Fundamentals and Types of boiling – Pool
boiling curve, Various empirical relations pertaining to boiling, Numerical problems on the
above, Condensation – Classification and Contrast, Types of condensers, Nusselt’s theory on
laminar film-wise condensation, Empirical Refinements, Several empirical formulae,
Numerical problems.

Cooling Towers: Cooling towers – basic principle of evaporative cooling, Psychrometry,

fundamentals, Psychrometric chart, Psychrometric Processes, Classification of cooling
towers, Numerical problems.

Readings:

1. Kays, W. M. and London, A. L., Compact Heat Exchangers, 2nd Edition, McGraw – Hill,
New York.
2. Donald Q. Kern: Process Heat Transfer, McGraw – Hill, New York.
3. Incropera, F. P. and De Witt, D. P., Fundamentals of Heat and Mass Transfer, 4th
Edition, John Wiley and Sons, New York.
 ME5172 NEW VENTURE CREATION 3 - 0 - 0 (3 Cr)

Pre - Requisites: Nil

Course Outcomes:

Understand entrepreneurship and entrepreneurial process and its significance in

CO1
economic development.
Develop an idea of the support structure and promotional agencies assisting ethical
CO2
entrepreneurship.
Identify entrepreneurial opportunities, support and resource requirements to launch a
CO3
new venture within legal and formal frame work.
CO4 Develop a framework for technical, economic and financial feasibility.
Evaluate an opportunity and prepare a written business plan to communicate business
CO5
ideas effectively.
Understand the stages of establishment, growth, barriers, and causes of sickness in
CO6
industry to initiate appropriate strategies for operation, stabilization and growth.

CO-PO Mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 2 2
CO2 1 3 2 2
CO3 1 3 2 2
CO4 1 3 2 2
CO5 1 3 2 2
CO6 1 3 2 2

Entrepreneur and Entrepreneurship: Introduction; Entrepreneur and Entrepreneurship;

Role of entrepreneurship in economic development; Entrepreneurial competencies and
motivation; Institutional Interface for Small Scale Industry/Enterprises.

Planning a New Enterprise: Opportunity Scanning and Identification; Creativity and

product development process; The technology challenge - Innovation in a knowledge based
economy, Sources of Innovation Impulses – Internal and External; Drucker’s 7 Sources of
Innovation Impulses, General Innovation Tools, Role of Innovation during venture growth;
Market survey and assessment; choice of technology and selection of site.

Establishing a New Enterprises: Forms of business organization/ownership; Financing new

enterprises -Sources of capital for early-stage technology companies; Techno Economic
Feasibility Assessment; Engineering Business Plan for grants, loans and venture capital.
Operational Issues in SSE: Develop a strategy for protecting intellectual property of the
business with patent, trade secret, trademark and copyright law; Financial management
issues; Operational/project management issues in SSE; Marketing management issues in
SSE; Relevant business and industrial Laws.

Performance appraisal and growth strategies: Strategies to anticipate and avoid the
pitfalls associated with launching and leading a technology venture; Management
performance assessment and control; Causes of Sickness in SSI, Strategies for Stabilization
and Growth.
Readings:

1. Byers, Dorf, and Nelson. ‘Technology Ventures: From Ideas to Enterprise’. McGraw Hill.
ISBN-13: 978-0073380186., 2010.
2. Bruce R Barringer and R Duane Ireland, ‘Entrepreneurship: Successfully Launching New
Ventures’, 3rd ed., Pearson Edu., 2013.
3. D.F. Kuratko and T.V. Rao, ‘Entrepreneurship: A South-Asian Perspective’, Cengage
Learning, 2013
4. Dr. S.S. Khanka, ‘Entrepreneurial Development’ (4th ed.), S Chand & Company Ltd.,
2012.
5. Dr. Vasant Desai, ‘Management of Small Scale Enterprises’, Himalaya Publishing House,
2004.
 ME5186 ENERGY SYSTEMS AND MANAGEMENT 3 - 0 - 0 (3 Cr)
Prerequisites: Nil
Course Outcomes:

CO1 Understand the fundamentals of energy management

CO2 Select methods of energy production for improved utilization.
Apply the principles of thermal engineering and energy management to improve the
CO3
performance of thermal systems.
Analyze the methods of energy conservation and energy efficiency for buildings, air
CO4
conditioning, heat recovery and thermal energy storage systems.
CO5 Evaluate energy projects on the basis of economic and financial criteria.

CO-PO Mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 2 2 1 2
CO2 2 3 2 2 1 2
CO3 2 3 2 2 1 2
CO4 2 3 2 2 1 2
CO5 2 3 2 2 1 2

Introduction: Review of the concepts of Thermodynamics, Fluid Mechanics and Heat

Transfer, Properties of Heat transfer media –Pure substances, Thermal fluids, Air-water
vapour mixtures; Heat transfer equipment- Heat exchangers, Steam plant.

Energy storage Methods and systems: Thermal, Electrical and Mechanical energy storage
methods and systems, Energy saving.

Energy conversion systems: Thermo-mechanical energy conversion systems – IC Engines,

Gas Turbines and Steam turbines.

Heat recovery systems: Incinerators, regenerators and boilers.

Energy Conservation:Methods of energy conservation and energy efficiency for buildings,

air conditioning, heat recovery and thermal energy storage systems.

Energy Management: Principles of Energy Management,Energy demand estimation,

Organizing and Managing Energy Management Programs, Energy pricing.

Energy Audit: Purpose, Methodology with respect to process Industries, Characteristic

method employed in Certain Energy Intensive Industries.

Economic Analysis: Scope, Characterization of an Investment Project.

Case studies

Readings:
1. Turner, W. C., Doty, S. and Truner, W. C., Energy Management Hand book, 7th edition,
Fairmont Press, 2009.
2. De, B. K., Energy Management audit & Conservation, 2nd Edition, Vrinda Publication,
2010.
3. Murphy, W. R., Energy Management, Elsevier, 2007.
4. Smith, C. B., Energy Management Principles, Pergamon Press, 2007.
 ME5168 RENEWABLE SOURCES OF ENERGY 3 - 0 - 0 (3 Cr)
Pre - Requisites: Nil

Course Outcomes:

CO1 Identify the renewable energy sources and their utilization

Understand the basic concepts of the solar radiation and analyze the solar thermal systems
CO2
for their utilization
Understand the principle of working of solar cells and their modern manufacturing
CO3
techniques
CO4 Understand the concepts of the wind energy conversion systems and their applications
Outline the methods of energy storage and identify the appropriate methods of energy
CO5
storage for specific applications
Understand the energy conversion from ocean thermal energy, geothermal energy,
CO6
biomass and magneto hydrodynamic power generation

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 2 1 1 2
CO2 1 3 3 1 1 2
CO3 1 3 2 1 1 2
CO4 1 2 1 1 2
CO5 1 3 1 3 1 1 2
CO6 1 1 1 2 1 1 2

Introduction: Overview of the course, Examination and Evaluation patterns. Classification

of energy resources, energy scenario in the world and India.

Basic sun-earth relationships: Definitions. Celestial sphere, altitude-azimuth, declination-

hour angle and declination-right ascension coordinate systems for finding the position of the
sun, celestial triangle and coordinates of the sun. Greenwich Mean Time, Indian Standard
Time, Local Solar Time, sun rise and sun set times & day length.

Solar radiation: Nature of solar radiation, solar radiation spectrum, solar constant, extra-
terrestrial radiation on a horizontal surface, attenuation of solar radiation, beam, diffuse and
global radiation. Measurement of global, diffuse and beam radiation. Prediction of solar
radiation; Angstrom model, Page model, Hottel’s model, Liu and Jordan model etc.
Insolation on an inclined surface, angle of incidence.

Solar thermal systems: Principle of working of solar water heating systems, solar cookers,
solar desalination systems, solar ponds, solar chimney power plant, central power tower
power plants etc. Classification of solar concentrators, Basic definitions such as concentration
ratio, angle of acceptance etc., Tracking of the sun; description of different tracking modes of
a solar collectors and the determination of angle of incidence of insolation in different
tracking modes.

Photovoltaic energy conversion: Introduction. Single crystal silicon solar cell, i-v
characteristics, effect of insolation and temperature on the performance of silicon cells.
Different types of solar cells. Modern technological methods of producing these cells. Indian
and world photovoltaic energy scenario.

Energy storage: Necessity for energy storage. Classification of methods of energy storage.
Thermal energy storage; sensible heat storage, latent heat storage. Reversible chemical
reaction storage. Electromagnetic energy storage. Hydrogen energy storage. Chemical battery
storage. Pumped hydel energy storage etc.

Wind energy:Origin of winds, nature of winds, wind data measurement, wind turbine types
and their construction, wind-diesel hybrid system, environmental aspects, wind energy
programme in India and the world.

Fuel cells: Introduction, applications, classification, different types of fuel cells such as
phosphoric acid fuel cell, alkaline fuel cell, PEM fuel cell, MC fuel cell. Development and
performance fuel cells.

Ocean energy: Ocean thermal energy; open cycle & closed cycle OTEC plants,
environmental impacts, challenges, present status of OTEC systems. Ocean tidal energy;
single basin and double basin plants, their relative merits. Ocean wave energy; basics of
ocean waves, different wave energy conversion devices, relative merits.

Biomass: Introduction, photosynthesis, biofuels, biomass resources, biomass conversion

technologies, urban waste to energy conversion, biomass to ethanol conversion, biomass
energy scenario in India, biogas production, constant pressure and constant volume biogas
plants, operational parameters of the biogas plant

Geothermal energy: Origin, applications, types of geothermal resources, relative merits

Magneto hydrodynamic Power Generation applications; Origin and their types; Working
principles.

Magneto hydrodynamic Power Generation:Magneto hydrodynamic Power Generation

applications; Origin and their types; Working principles.

Readings:

1. B.H.Khan, Non-conventional Energy Resources, Tata McGraw Hill, New Delhi, 2012
2. S.Rao and B.B.Parulekar, Energy Technology: Non-Conventional, Renewable and
Conventional, Khanna Publishers, 2010
3. S.P.Sukhatme and J.K.Nayak, Solar Energy-Principles of Thermal Collection and Storage,
TMH, 2008
4. J.A.Duffie and W.A.Beckman, Solar Energy Thermal Processes, John Wiley, 2010
 ME5271 MECHATRONICS AND ROBOTICS 3- 0 - 0 (3 Cr)
Pre-Requisites: Basic Electrical & Electronics, Mathematics and Design of machine
Elements.

Course outcomes:

CO1. Model, analyze and control engineering systems.

CO2. Select appropriate sensors, transducers and actuators to monitor and control the
behavior of a process or product.
CO3. Develop PLC programs for a given task.
CO4. Evaluate the performance of mechatronic systems.
CO5. Understand the evolution, classification, structures and drives for robots.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 3 1 2
CO2 3 3 1 2
CO3 3 3 1 2
CO4 3 3 1 2
CO5 3 3 1 2

Introduction: Overview of the course, Examination and Evaluation patterns, History of

Mechatronics, Scope and Significance of Mechatronics systems, elements of mechatronic
systems, needs and benefits of mechatronics in manufacturing.

Sensors: Classification of sensors basic working principles, Displacement Sensor - Linear and
rotary potentiometers, LVDT and RVDT, incremental and absolute encoders. Strain gauges.
Force/Torque – Load cells. Temperature – Thermocouple, Bimetallic Strips, Thermistor, RTD
Accelerometers, Velocity sensors – Tachometers, Proximity and Range sensors – Eddy current
sensor, ultrasonic sensor, laser interferometer transducer, Hall Effect sensor, inductive
proximity switch. Light sensors – Photodiodes, phototransistors, Flow sensors – Ultrasonic
sensor, laser Doppler anemometer tactile sensors – PVDF tactile sensor, micro-switch and reed
switch Piezoelectric sensors, vision sensor.

Actuators: Electrical Actuators : Solenoids, relays, diodes, thyristors, triacs, BJT, FET, DC
motor, Servo motor, BLDC Motor, AC Motor, stepper motors. Hydraulic & Pneumatic devices
– Power supplies, valves, cylinder sequencing. Design of Hydraulic & Pneumatic circuits.
Piezoelectric actuators, Shape memory alloys.

Basic System Models & Analysis: Modelling of one and two degrees of freedom Mechanical,
Electrical, Fluid and thermal systems, Block diagram representations for these systems.
Dynamic Responses of System: Transfer function, Modelling Dynamic systems, first order
systems, second order systems.

Digital Electronics: Number systems, BCD codes and arithmetic, Gray codes, self-
complimenting codes, Error detection and correction principles. Boolean functions using
Karnaugh map, Design of combinational circuits, Design of arithmetic circuits. Design of Code
converters, Encoders and decoders.

Signal Conditioning: Operational amplifiers, inverting amplifier, differential amplifier,

Protection, comparator, filters, Multiplexer, Pulse width Modulation Counters, decoders. Data
acquisition – Quantizing theory, Analog to digital conversion, digital to analog conversion.

Controllers: Classification of control systems, Feedback, closed loop and open loop systems,
Continuous and discrete processes, control modes, Two step Proportional, Derivative, Integral,
PID controllers.

PLC Programming: PLC Principles of operation PLC sizes PLC hardware components I/O
section Analog I/O section Analog I/O modules, digital I/O modules CPU Processor memory
module Programming. Ladder Programming, ladder diagrams, timers, internal relays and
counters, data handling, analogue input and output. Application on real time industrial
automation systems.

Case studies of Mechatronics systems: Pick and place robot, Bar code, Engine Management
system, Washing machine etc.

Robotics: Introduction to Robotics, Robot anatomy physical configurations, Manipulator,

Kinematics, Technical features. Programming of Mobile robot, robot programming language,
end effecters.

Reading:

1. W. Bolton, “Mechatronics‟, 5 th edition, Addison Wesley Longman Ltd, 2010

2. DevdasShetty& Richard Kolk “Mechatronics System Design”, 3rd edition. PWS Publishing,
2009.
3. Alciatore David G &Histand Michael B, “Introduction to Mechatronics and Measurement
systems”, 4th edition, Tata McGraw Hill, 2006.
4. Saeed B Niku, “Introduction to Robotics: Analysis, Systems, Applications “, 2nd edition,
Pearson Education India, PHI, 2003.

Video References:

1. http://video_demos.colostate.edu/mechatronics
2. http:// mechatronics.me.wisc.edu
 ME5274 FLUID POWER SYSTEMS 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Understand common hydraulic components, their use, symbols, and mathematical
models
CO2 Design, analyze and implement control systems for real and physical systems.
CO3 Design and analyze FPS circuits with servo systems, fluidic and tracer control.
CO4 Analyze the operational problems in FPS and suggest remedies.

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 1 1 2
CO2 3 1 1 2
CO3 3 1 1 2
CO4 3 1 1 2

Basic components: Introduction, Basic symbols, Merits, Demerits and applications, Pumps,
actuators, Valves.

Hydraulic Circuits: Regenerative sequence, Semiautomatic, automatic Speed controls.

Power amplifiers and tracer control systems: Introduction and type of copying systems,
Single coordinate parallel tracer control systems, tracer control systems with input pressure,
tracer control systems with four edge tracer valve, Static and dynamic copying system, Types of
tracer valve.

Design of Hydraulic circuits: Design of hydraulic circuits for various machine tools.
Servo system: Introduction and types, Hydro mechanical servo valve system, Electro hydraulic
servo valve system, Introduction and evolution.

Fluidics: Introduction and evolution, Type of gates and their features, Applications of Fluidics.

Simulation: FPS implementation and analysis.

Reading:

1. Esposito, Fluid power with applications, Pearson, 2011

2. M.Galalrabie, Rabie M “Fluid power Engg.” Professional Publishing, 2009
3. John J Pippenger and W.Hicks, “Industrial hydraulics” Tata McGraw Hill, 1980.
 ME5281 PRECISION MANUFACTURING 3 - 0 - 0 (3 Cr)
Pre - Requisites: Nil

Course Outcomes:

CO1 Understand the concept of accuracy and precision

CO2 Apply fits and tolerances for parts and assemblies as per ISO standards.
CO3 Evaluate the machine tool and part accuracies.
CO4 Estimate the surface quality of machined components

CO-PO Mapping:
CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 2
CO2 3 2 1 2
CO3 3 2 1 2
CO4 3 2 1 2

Accuracy and Precision: Introduction - Accuracy and precision – Need – application of

precision machining- alignment testing of machine tools, accuracy of numerical control system,
specification of accuracy of parts and assemblies.

Tolerance and fits: Tolerance and fits, hole and shaft basis system, types of fits- Types of
assemblies-probability of clearance and interference fits in transitional fits.

Concept of part and machine tool accuracy: Specification of accuracy of parts and
assemblies, accuracy of machine tools, alignment testing of machine tools.

Errors during machining: Errors due to compliance of machine-fixture-tool-work piece

(MFTW) System, theory of location, location errors, errors due to geometric inaccuracy of
machine tool, errors due to tool wear, errors due to thermal effects, errors due to clamping.
Statistical methods of accuracy analysis.

Surface roughness: Definition and measurement, surface roughness indicators (CLA, RMS,
etc,.) and their comparison, influence of machining conditions, methods of obtaining high
quality surfaces, Lapping, Honing, Super finishing and Burnishing processes.

Readings:

1. R.L.Murty, ”Precision Engineering in Manufacturing”, New Age International Publishers,

1996.
2. V.Kovan, "Fundamentals of Process Engineering", Foreign Languages Publishing House,
Moscow, 1975
3. Eary and Johnson, "Process Engineering for Manufacture"
4. J.L.Gadjala, "Dimensional control in Precision Manufacturing", McGraw Hill Publishers.
 ME5386 DESIGN AND ANALYSIS OF EXPERIMENTS 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Formulate objective(s) and identify key factors in designing experiments for a
given problem.
CO2 Develop appropriate experimental design to conduct experiments for a given
problem.
CO3 Analyze experimental data to derive valid conclusions.
CO4 Optimize process conditions by developing empirical models using experimental
data.
CO5 Design robust products and processes using parameter design approach.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 3 1 2
CO2 3 3 1 2
CO3 3 3 1 2
CO4 3 3 1 2
CO5 3 3 1 2

Fundamentals of Experimentation: Role of experimentation in rapid scientific progress,

Historical perspective of experimental approaches, Steps in experimentation, Principles of
experimentation;

Simple Comparative Experiments: Basic concepts of probability and statistics, Comparison

of two means and two variances, Comparison of multiple (more than two) means & ANOVA;

Experimental Designs: Factorial designs, fractional factorial designs, orthogonal arrays,

standard orthogonal arrays & interaction tables, modifying the orthogonal arrays, selection of
suitable orthogonal array design, analysis of experimental data;

Response Surface Methodology: Concept, linear model, steepest ascent, second order
model, regression;

Taguchi’s Parameter Design: Concept of robustness, noise factors, objective function &
S/N ratios, inner-array and outer-array design, data analysis

Reading:
1. Montgomery DC, Design and Analysis of Experiments, 7th Edition, John Wiley & Sons,
NY, 2008.
2. Ross PJ, Taguchi Techniques for Quality Engineering, McGraw-Hill Book Company, NY,
2008.
 ME5387 PROJECT MANAGEMENT 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Understand the importance of projects and its phases.

CO2 Analyze projects from marketing, operational and financial perspectives.
CO3 Evaluate projects based on discount and non-discount methods.
CO4 Develop network diagrams for planning and execution of a given project.
CO5 Apply crashing procedures for time and cost optimization.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 2
CO2 2 3 2
CO3 2 3 2
CO4 2 3 2
CO5 2 3 2

Introduction: Introduction to Project Management, History of Project Management,

Project Life Cycle.

Project Analysis: Facets of Project Analysis, Strategy and Resource Allocation, Market
and Demand Analysis, Technical Analysis, Economic and Ecological Analysis.

Financial Analysis: Financial Estimates and Projections, Investment Criteria, Financing

of Projects.

Network Methods in PM: Origin of Network Techniques, AON and AOA

differentiation, CPM network, PERT network, other network models.

Optimizationin PM: Time and Cost trade-off in CPM, Crashing procedure, Scheduling
when resources are limited.

Project Risk Management: Scope Management, Work Breakdown Structure, Earned

Value Management, Project Risk Management.

Reading:

1. Prasanna Chandra, Project: A Planning Analysis, Tata McGraw Hill Book Company,
New Delhi, 4th Edition,2009.
2. Cleland, Gray and Laudon, Project Management, Tata McGraw Hill Book Company,
New Delhi, 3rd Edition, 2007.
3. Clifford F. Gray, Gautam V. Desai, Erik W. Larson Project Management ,Tata
McGraw-Hill Education, 2010
 ME5471 TRIBOLOGICAL SYSTEMS DESIGN 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Analyze properties of lubricant and select proper lubricant for a given application.
CO2 Determine tribological performance parameters of sliding contact in different
lubrication regimes.
CO3 Design and select appropriate bearings for a given application
CO4 Predict the type of wear and volume of wear in metallic and polymer surfaces.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 3
CO2 3 2 1 3
CO3 3 2 1 3
CO4 3 2 1 3

Introduction: Overview of the course, history and basic concept of friction, wear and
lubrication.
Lubricants: Types of lubricants, Objectives of lubricant, Physical properties of lubricants,
Selection of lubricant.
Lubrication modes and Theories of hydrodynamic lubrication: Modes of lubrication -
hydrodynamic, hydrostatic, Elasto-hydrodynamic, mixed and boundary lubrication,
Reynolds’ equation, Applications of hydrodynamic lubrication theory - Journal bearing and
Inclined thrust pad bearing, Hydrodynamic lubrication of roughened surfaces, Theories of
Externally pressurized lubrication, Squeeze-film lubrication, Elasto-hydrodynamic
lubrication and air lubricated bearing.
Lubrication regimes and bearings design: Rheological lubrication regime, Functional
lubrication regime, Bearing types and its selection. Bearings design.
Friction and Wear: Origin of sliding friction, Contact between two bodies in relative
motion, Types of wear and their mechanisms - Adhesive wear, Abrasive wear, Wear due to
surface fatigue and wear due to chemical reactions, wear of metallic materials, Tribology of
polymers.

Reading:

1. Stachowaik, G.W., Batchelor, A.W., Engineering Tribology, 3rd Ed., Elsevier, 2010.
2. Majumdar B.C, Introduction to bearings, S. Chand & Co., Wheeler publishing, 1999.
3. Andras Z. Szeri, Fluid film lubrication theory and design, Cambridge University press,
1998.
 ME5472 CONDITION MONITORING 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes: At the end of the course, the student shall be able to:

CO1 Understand effective maintenance schemes in industries.

CO2 Apply vibration monitoring techniques for system diagnoses.
CO3 Apply oil analysis technique to diagnose the wear debris.
CO4 Identify nonconventional methods for machine diagnoses.
CO5 Develop modern technologies for effective plant maintenance.

CO-PO Mapping:

CO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 2
CO2 3 2 1 2
CO3 3 2 1 2
CO4 3 2 1 2
CO5 3 2 1 2

Predictive maintenance: Introduction, Principles of predictive maintenance,Predictive

maintenance techniques, Vibration basics,Spring-mass system: mass, stiffness, damping,
System response,Nature of vibration, Harmonics, Limits and standards of vibration.

Data acquisition and Signal processing: Introduction, Collection of vibration signal,

vibration transducers,characteristics and mountings, Conversion of vibrations to electrical
signal, Fast Fourier transform (FFT) analysis, Time waveform analysis, Phase signal analysis.

Machinery fault diagnosis and Correcting faults: Commonly witnessed machinery faults
diagnosed, Balancing, Alignment, Resonance vibration control with dynamic absorbers.

Oil and particle analysis: Oil fundamentals, Condition-based maintenance and oil analysis,
sampling methods, lubricant properties, contaminants in lubricants, wear debris, Particle
analysis techniques, temperature analysis.

Other predictive maintenance techniques: Non-destructive techniques, Ultrasound,

Infrared thermography, Introduction to structural health monitoring.

Reading:

1. Isermann R., Fault Diagnosis Applications, Springer-Verlag, Berlin, 2011.

2. Rao, J S., Vibration Condition Monitoring, Narosa Publishing House, 2nd Edition, 2000.
3. Allan Davies, Handbook of Condition Monitoring, Chapman and Hall, 2000.
 ME5473 DESIGN OF TRANSMISSION SYSTEMS 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Understand the principles of design of mechanical components under static and
dynamic loading conditions.
CO2 Understand the need of transmission systems, tractive force and resistance to
motion.
CO3 To gain the knowledge on the principles and procedure for designing the
transmission components.
CO4 To impart the knowledge that will enable the student to understand the latest
development in the power transmission systems.
CO5 Able to design transmission components used in machines and engines.

CO-PO Mapping:

CO\PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 3 1 2
CO2 3 2 3 1 2
CO3 3 2 3 1 2
CO4 3 2 3 1 2
CO5 3 2 3 1 2

Introduction: Introduction to transmission system, classification of transmission systems,

Manual, Automatic, transmission used in vehicles, tractive effort.

Manual Transmission: Design of Sliding mesh gear box, constant mesh gear box,
synchronous mesh gear box. Gear shift lever mechanism.
Automatic Transmission: Torque convertors, fluid coupling, five speeds and six speed gear
box.

Clutch: Principle of operation, frictionlining materials, calculation of torque capacity and

axial force. Different types of clutches - Dry andWet type, Design of plate clutches - axial,
cone clutches, centrifugal clutch, Design of Axles.

Differential:Straight bevel gear: Tooth terminology, Estimating the dimensions of pair of

straight bevel gears.

Worm Gear: Merits and demerits- terminology. Thermal capacity, materials-forces and
stresses, efficiency.

Flexible Drives: Design of Flat belts and pulleys, selection of V belts, wire ropes and
pulleys, stepped pulleys – Design of Transmission chains and Sprockets.

Reading:

1. Norton R.L., Machine Design: An Integrated Approach, 4th Ed. Prentice Hall, 2010.
2. Joseph Shigley, Charles Mischke, Richard Budynas and Keith Nisbett “Mechanical
Engineering Design”, 8th Edition, Tata McGraw-Hill, 2008.
3. U.C.Jindal : Machine Design, “Design of Transmission System”, Dorling Kindersley,
2010.
4. Prabhu. T.J., “Design of Transmission Elements”, Mani Offset, Chennai, 2000.
 ME5483 COMPUTER AIDED DESIGN 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO 1 Apply geometric transformations and projection methods in CAD.

CO 2 Develop geometric models to represent curves.
CO 3 Design surface models for engineering design.
CO 4 Model engineering components using solid modelling techniques for design.

CO-PO Mapping:

CO/PO PO 1 PO 2 PO 3 PO 4 PO 5 PO 6 PO 7 PO 8 PO 9 PO10
CO 1 3 3 1 1 2
CO 2 3 3 1 1 2
CO 3 2 3 3 1 1 2
CO 4 2 3 3 1 1 2

Introduction: Introduction to CAE, CAD. Role of CAD in Mechanical Engineering, Design

process, software tools for CAD, geometric modelling.

Transformations in Geometric Modeling: Introduction,Translation, Scaling, Reflection,

Rotation in 2D and 3D. Homogeneous representation of transformation, Concatenation of
transformations. Computer-Aided assembly of rigid bodies, applications of transformations in
design and analysis of mechanisms, etc. Implementation of the transformations using
computer codes.

Projections: Projective geometry, transformation matrices for Perspective, Axonometric

projections, Orthographic and Oblique projections. Implementation of the projection
formulations using computer codes.

Introduction to Geometric Modeling for Design: Introduction to CAGD, CAD input

devices, CAD output devices, CAD Software, Display Visualization Aids, and Requirements
of Modelling.

Curves in Geometric Modeling for Design: Differential geometry of curves, Analytic

Curves, PC curve, Ferguson’s Cubic Curve, Composite Ferguson, Curve Trimming and
Blending. Bezier segments Bernstein polynomials, Composite Bezier. B-spline basis
functions, Properties of basic functions, NURBS. Conversion of one form of curve to other.
Implementation of the all the curve models using computer codes in an interactive manner.

Surfaces in Geometric Modeling for Design: Surfaces entities (planar, surface of

revolution, lofted etc). Free-form surface models (Hermite, Bezier, B-spline surface).
Boundary interpolating surfaces (Coon’s). Implementation of the all the surface models using
computer codes.

Solids in Geometric Modeling for Design: Solid entities, Boolean operations, Topological
aspects, Invariants. Write-frame modeling, B-rep of Solid Modelling, CSG approach of solid
modelling. Popular modeling methods in CAD software. Data Exchange Formats and CAD
Applications:

Reading:

1. Michael E. Mortenson, Geometric Modeling, Tata McGraw Hill, 2013.

2. A. Saxena and B. Sahay, Computer-Aided Engineering Design, Anamaya Publishers, New
Delhi, 2005.
3. Rogers, David F., An introduction to NURBS: with historical perspective, Morgan
Kaufmann Publishers, USA, 2001.
4. David F. Rogers, J. A. Adams, Mathematical Elements for Computer Graphics, TMH,
2008.
 ME5377 RELIABILITY ENGINEERING 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

COURSE OUTCOMES: At the end of the course, the student shall be able to:

CO1 Understand the concepts of Reliability, Availability and Maintainability.

CO2 Develop hazard-rate models to know the behavior of components.
CO3 Build system reliability models for different configurations.
CO4 Assess reliability of components & systems using field & test data.
CO5 Implement strategies for improving reliability of repairable and non-repairable
systems

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 2
CO2 3 2 1 2
CO3 3 2 1 2
CO4 3 2 1 2
CO5 3 2 1 2

Introduction: Probabilistic reliability, failures and failure modes, repairable and non-
repairable items, pattern of failures with time, reliability economics

Component Reliability Models: Basics of probability & statistics, hazard rate & failure rate,
constant hazard rate model, increasing hazard rate models, decreasing hazard rate model,
time-dependent & stress-dependent hazard models, bath-tub curve

System Reliability Models: Systems with components in series, systems with parallel
components, combined series-parallel systems, k-out-of-m systems, standby models, load-
sharing models, stress-strength models, reliability block diagram

Life Testing & Reliability Assessment: Censored and uncensored field data, burn-in testing,
acceptance testing, accelerated testing, identifying failure distributions & estimation of
parameters, reliability assessment of components and systems

Reliability Analysis & Allocation: Reliability specification and allocation, failure modes
and effects and criticality analysis (FMECA), fault tree analysis, cut sets & tie sets
approaches

Maintainability Analysis: Repair time distribution, MTBF, MTTR, availability,

maintainability, preventive maintenance.

Reading:

1. Ebeling CE, An Introduction to Reliability and Maintainability Engineering, TMH, New

Delhi, 2004.
2. O’Connor P and Kleymer A, Practical Reliability Engineering, Wiley, 2012.
 ME5771 RE- ENGINEERING 3- 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Identify the steps involved in re-engineering of a given component.

CO2 Design and fabricate an existing component with suitable modifications as per
customer’s requirements.
CO3 Select and configure a suitable re-engineering system for inspection and
manufacturing.

CO4 Apply the re-engineering techniques in aerospace, automobile and medical sectors.

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 3 2 1 2
CO2 3 2 1 2
CO3 3 2 1 2
CO4 3 2 1 2

Introduction to reverse engineering, Re-Engineering–The Generic Process

Geometric Modelling using Point Cloud Data: Point Cloud acquisition, Surface Modelling
from a point clouds, Meshed or Faceted Models, Planar Contour Models, Points to Contour
Models, Surface Models, Segmentation and Surface Fitting for Prismatic objects and Free
Form Shapes.

Methodologies and Techniques for Re-Engineering: The Potential for Automation with 3-
D Laser Scanners, What Is Not Re-Engineering, What is Computer-aided (Forward)
Engineering, What Is Computer-aided Reverse Engineering, Computer Vision and Re-
Engineering.

Re-Engineering–Hardware and Software: Contact Methods Noncontact Methods,

Destructive Method.

Selecting a Re-Engineering System: The Selection Process, Some Additional Complexities,

Point Capture Devices, Triangulation Approaches, “Time-of-flight” or Ranging Systems,
Structured-light and Stereoscopic Imaging Systems, issues with Light-based Approaches,
Tracking Systems, Internal Measurement Systems, X-ray Tomography, Destructive Systems,
Some Comments on Accuracy, Positioning the Probe, Post processing the Captured Data,
Handling Data Points, Curve and Surface Creation, Inspection Applications, Manufacturing
Approaches.

Integration Between Re-Engineering and Additive Manufacturing: Modeling Cloud Data

in Re-Engineering, Data Processing for Rapid Prototyping, Integration of RE and RP for
Layer-based Model Generation, Adaptive Slicing Approach for Cloud Data Modeling, Planar
Polygon Curve Construction for a Layer, Determination of Adaptive Layer Thickness.

Re-Engineering in Automotive, Aerospace, Medical sectors: Legal Aspects of Re-

Engineering: Copyright Law, Re-Engineering, Recent Case Law, Barriers to Adopting Re-
Engineering. A discussion on a few benchmark case studies.

Reading:

1. K. Otto and K. Wood, Product Design: Techniques in Reverse Engineering and New
Product Development, Prentice Hall, 2001.
2. Reverse Engineering: An Industrial Perspective by Raja and Fernandes, Springer-Verlag
2008.
3. AnupamSaxena, Birendra Sahay, “Computer Aided Engineering Design”, Springer, 2005.
4. Ali K. Kamrani and Emad Abouel Nasr, “Engineering Design and Rapid Prototyping”,
Springer, 2010.
 ME5479 OPTIMIZATION METHODS FOR ENGINEERING 3 - 0 - 0 (3 Cr)
DESIGN
Prerequisites:Nil

Course Outcomes:

CO1 Formulate a design task as an optimization problem

Identify constrained and unconstrained optimization problems and solve using
CO2
corresponding methods
CO3 Solve discontinuous optimization problems using special methods
CO4 Solve the nonlinear optimization problems with evolutionary methods

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 3 3 1 2
CO2 2 3 3 1 2
CO3 2 3 3 1 2
CO4 2 3 3 1 2

Introduction to Optimization in Design: Problem formulation, Optimization problems in

Mechanical Engineering, Classification of methods for optimization.

Single-variable Optimization: Optimal criteria, Derivative-free methods (bracketing, region

elimination), Derivative based methods, root-finding methods.

Multiple-variable Optimization: Optimal criteria, Direct search methods (Box’s, Simplex,

Hooke-Jeeves, Conjugate methods), Gradient-based methods (Steepest Descent, Newton’s,
Marquardt’s, DFP method). Formulation and Case studies.
Constrained Optimization: KKT conditions, Penalty method, Sensitivity analysis, Direct
search methods for constrained optimization, quadratic programming, GRG method,
Formulation and Case studies.

Specialized algorithms: Integer programming (Penalty function and branch-and-bound

method), Geometric programming.

Evolutionary Optimization algorithms: Genetic algorithms, simulated annealing, Ant

colony optimization, Particle swarm optimization.

Multi-objective Optimization: Terminology and concepts, the concepts of Pareto optimality

and Pareto optimal set, formulation of multi-objective optimization problem, NSGA.

Case studies and Computer Implementation: Representative case studies for important
methods and development of computer code for the same to solve problems.

Readings:

1. Jasbir Arora, Introduction to Optimum Design, Academic Press, 2004

2. KALYANMOY DEB, OPTIMIZATION FOR ENGINEERING DESIGN: Algorithms and
Examples, PHI, 2004.
3. Kalyanmoy Deb, Multi-Objective Optimization using Evolutionary Algorithms, Wiley,
2001.
 ME5482 FINITE ELEMENT METHOD 3 - 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Solve the problems involving bar, truss, beam and frame elements under different
boundary conditions.
CO2 Understand and apply Finite Element Formulation for structural Problems
CO3 Analyze plane stress, plane strain and axi-symmetric problems.
CO4 Formulate and solve simple heat transfer and fluid mechanics problems

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 3 1 1 2
CO2 2 3 3 1 1 2
CO3 2 3 3 1 1 2
CO4 2 3 3 1 1 2

Introduction: Historical Perspective of FEM and applicability to mechanical engineering

problems.

Mathematical Models and Approximations: Review of elasticity, mathematical models for

structural problems, Equilibrium of continuum-Differential formulation, Energy Approach-
Integral formulation, Principle of Virtual work - Variational formulation. Overview of
approximate methods for the solution of the mathematical models; Ritz, Rayleigh-Ritz and
Gelarkin’s methods, Philosophy and general process of Finite Element method.

Finite Element Formulation: Concept of discretization, Interpolation, Formulation of Finite

element characteristic matrices and vectors, Compatibility, Assembly and boundary
considerations.

Finite Element Method in One Dimensional Problems: Structural problems with one
dimensional geometry. Formulation of stiffness matrix, consistent and lumped load vectors.
Boundary conditions and their incorporation: Elimination method, Penalty Method,
Introduction to higher order elements and their advantages and disadvantages. Formulation
for Truss elements, Case studies with emphasis on boundary conditions and introduction to
contact problems.

Beams and Frames: Review of bending of beams, higher order continuity, interpolation for
beam elements and formulation of FE characteristics, Plane and space frames and examples
problems involving hand calculations.

Two Dimensional Problems: Interpolation in two dimensions, natural coordinates,

Isoparametric representation, Concept of Jacobian. Finite element formulation for plane
stress plane strain and axi-symmetric problems; Triangular and Quadrilateral elements,
higher order elements, sub parametric, Isoparametric and superparametric elements. General
considerations in finite element analysis of two dimension problems, Introduction plate
bending elements and shell elements.
Algorithmic Approach for problem solving:Algorithmic approach for Finite element
formulation of element characteristics, Assembly and incorporation of boundary conditions,
Guidelines for code development, Introduction to commercial FE packages.

Reading:

1. Seshu P, Textbook of Finite Element Analysis, PHI. 2004

2. Reddy, J.N., Finite Element Method in Engineering, Tata McGraw Hill, 2007.
3. SingiresuS.Rao, Finite element Method in Engineering, 5ed, Elsevier, 2012
4. Zeincowicz, The Finite Element Method for Solid and Structural Mechanics, 4th Edition,
Elsevier 2007.
 ME5686 NON-DESTRUCTIVE TESTING 3 - 0 - 0 (3 Cr)
Pre-Requisites: Nil

Course Outcomes:

CO1 Understand the principles of NDT methods

CO2 Identify appropriate nondestructive testing methods for failure identification

CO3 Utilize radiography to identify underlying failure sites
CO4 Analyze flaws using advanced eddy current methods
CO5 Utilize acoustic emission to identify leaks

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 1 2
CO2 1 3 1 2
CO3 1 3 1 2
CO4 1 3 1 2
CO5 1 3 1 2

Introduction to NDT, Liquid penetrant test: Physical Principles, Procedure for

penetrant testing, penetrant testing materials, Penetrant testing methods, sensitivity,
Applications and limitations, typical examples.

Ultrasonic testing: Basic properties of sound beam, Ultrasonic transducers, Inspection

methods, Techniques for normal beam inspection, Techniques for angle beam inspection,
Flaw characterization techniques, Applications of ultrasonic testing, Advantages and
limitations.

Thermography: Basic principles, Detectors and equipment, techniques, applications.

Radiography: Basic principle, Electromagnetic radiation sources, radiographic imaging,

Inspection techniques, applications, limitations, typical examples.

Eddy current test: Principles, instrumentation for ECT, techniques, sensitivity, advanced
eddy Current test methods, applications, limitations.

Acoustic emission: Principle of AET, Technique, instrumentation, sensitivity,

applications, Acoustic emission technique for leak detection.

Magnetic particle inspection: Principle of MPT, Procedure used for testing a

component, sensitivity, limitations.
 Reading:

1. Peter J. Shull, Nondestructive Evaluation: Theory, Techniques and Applications,

Marcel Dekkar, 2002.
2. P. Mclntire (Ed.), Non-Destructive Testing Hand Book, Vol. 4, American Society for
Non-Destructive Society, 2010
3. ASM Metals Hand Book, Non-Destructive Testing and Quality Control, Vol. 17,
ASM, 1989.
 II-YEARI-SEMESTER
ME5548 COMPREHENSIVE VIVA – VOCE 2 Cr
Pre-Requisites: Nil

Course Outcomes:

CO1 Comprehend the knowledge gained in the course work

CO2 Identify principles of working of automotive systems and controls
CO3 Demonstrate the ability in problem solving and to communicate effectively

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 2 2 2 2 2 2 2 2 2 1
CO2 1 2 2 2 2 3 2 2 2 1
CO3 3 3 3 3 3 3 2 2 3 1
 ME5549 Dissertation: Part-A (8 Cr)

Course Outcomes:

CO1 Identify a topic in advanced areas of Automobile Engineering

CO2 Review literature to identify gaps and define objectives & scope of the work
CO3 Employ the ideas from literature and develop research methodology
CO4 Develop a model, experimental set-up and / or computational techniques necessary to
meet the objectives.

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 1 1 1 1 2 1 2 3
CO2 1 2 2 2 1 1 1 1 3 3
CO3 2 1 1 2 1 2 2 2 3 3
CO4 2 1 1 2 2 2 1 3 1 3
 II-YEAR II-SEMESTER
ME5599 DISSERTATION PART – B 12 CR

Course Outcomes:

CO1 Identify the materials and methods for carrying out experiments/develop a code
CO2 Execute the research methodology with a concern for society, environment and ethics
CO3 Analyse, discuss and justify the results/trends and draw valid conclusions
CO4 Prepare the report as per recommended format and present the work orally adhering to
stipulated time
CO5 Explore the possibility to publish/present a paper in peer reviewed journals/conference
without plagiarism

CO-PO Mapping:

CO/PO PO1 PO2 PO3 PO4 PO5 PO6 PO7 PO8 PO9 PO10
CO1 1 3 1 1 2 1 2 2 2 3
CO2 3 1 2 3 3 3 1 3 1 3
CO3 3 2 2 3 3 2 1 2 3 3
CO4 1 1 1 1 1 1 1 2 3 3
CO5 1 1 1 2 1 2 1 1 3 3