MA9211 MATHEMATICS III L T P C
(Common to all branches of BE / B.Tech) 3 0 0 3
AIM:
To facilitate the understanding of the principles and to cultivate the art of formulation
physical problems in the language of mathematics
OBJECTIVES:
1. To introduce Fourier series analysis which is central to many applications in
engineering apart from its use in solving boundary value problems
2.To acquaint the student with Fourier transform techniques used in wide variety of
situations in which the functions used are not periodic
3. To introduce the effective mathematical tools for the solutions of partial differential
equations that model physical processes
4. To develop Z- transform techniques which will perform the same task for discrete
time systems as Laplace Transform, a valuable aid in analysis of continuous time
systems
UNIT I FOURIER SERIES 9+3
Dirichlet’s conditions – General Fourier series – Odd and even functions – Half-range
Sine and Cosine series – Complex form of Fourier Series – Parseval’s identity –
Harmonic Analysis.
UNIT II FOURIER TRANSFORM 9+3
Fourier integral theorem – Fourier transform pair-Sine and Consine transforms –
Properties – Transform of simple function – Convolution theorem - Parseval’s
identity.
UNIT III PARTIAL DIFFERENTIAL EQUATIONS 9+3
Formation – Solutions of first order equations – Standard types and Equations
reducible to standard types – Singular solutions - Lagrange’s Linear equation –
Integral surface passing through a given curve – Solution of linear equations of
higher order with constant coefficients.
UNIT IV APPLICATIONS OF PARTIAL DIFFERENTIAL
EQUATIONS 9+3
Method of separation of Variables – Solutions of one dimensional wave equation and
One-dimensional heat equation – Steady state solution of two-dimensional heat
equation – Fourier series solutions in Cartesian coordinates.
UNIT V Z – TRANSFORM AND DIFFERENCE EQUATION 9+3
Z-transform-Elementary properties-Inverse z transform – Convolution theorem-Initial
and Final value theorems - Formation of difference equation-Solution of difference
equation using z transform.
TOTAL: 45+15=60 PERIODS
TEXT BOOK
1. B.S.Grewal, “Higher Engineering Mathematics”, Khanna Publications (2007)
REFERENCES
1) Glyn James, “Advanced Modern Engineering Mathematics, Pearson
Education (2007)
2) B.V.Ramana, “Higher Engineering Mathematics” Tata McGraw Hill 2007.
3) N.P.Bali, and Manish Goyal, “A Text Book of Engineering 7 thEdition (2007) Lakshmi Publications (P) Limited, New Delhi.
AE9201 ENGINEERING FLUID MECHANICS L T P C
3 1 0 4
AIM:
To introduce the concepts of Fluid Mechanics. Pre-requisite: Basics of Physics
OBJECTIVE:
To introduce the concepts of fluid statics viscosity and buoyancy. To make the
student understand the basic laws namely, mass momentum and energy. To give an
introduction on fluid machinery.
UNIT I BASIC CONCEPTS 15
Introduction – Fluid properties – Newton’s viscosity law – Classification of fluids and
fluid motion – Fluid statics – Hydrostatic force on submerged surfaces – stability of
floating bodies – Dimensional analysis – The Buckingham-Pi theorem – Significant
dimensionless groups – Flow similarity and model studies
UNIT II BASIC EQUATIONS OF FLUID FLOW ANALYSIS 15
Basic laws for a system in integral form – Conservation of mass – Newton’s 2nd law – Laws of thermodynamics – Application of the basic laws for a control volume – Kinematics – Motion of a fluid particle – Fluid deformation – Differential analysis of fluid motion – Continuity equation – Differential momentum equation – The Navier Stokes equations
UNIT III INCOMPRESSIBLE INVISCID FLOW 8
Euler’s equations of motion – Bernoulli’s equations – Applications – Methods of
pressure measurement – Flow measurement – Orifice plate – Venturi meter –
Irrotational flow – Stream function and velocity potential – Laplace equation –
Elementary plane flows
UNIT IV INCOMPRESSIBLE VISCOUS FLOW 8
Fully developed laminar flow between infinite parallel plates – Laminar and turbulent
flow through pipes – Velocity profiles – Energy considerations in pipe flow –
Calculation of head loss Pipe flow problems – Hydraulic and energy grade lines –
Moody’s diagram
UNIT V FLUID MACHINERY 14
Introduction and classification of fluid machines – Turbo machinery analysis – The
angular momentum principle – Euler turbo machine equation – Velocity triangles –
Application to fluid systems – Working principle of turbines, fans, blowers, pumps and
compressors.
L = 45, T = 15, TOTAL = 60 PERIODS
TEXT BOOKS
1. Shames I H, ‘Mechanics of Fluids’, Kogakusha, Tokyo, 1998
2. Robert W Fox & Alan T Mc.Donald, ‘Introduction to fluid Mechanics’, John Wiley
and Sons, 1995
REFERENCE BOOKS
1. Yuan S W, ‘Foundations of fluid Mechanics’, Prentice-Hall, 1987
2. Milne Thompson L M, ‘Theoretical Hydrodynamics’, MacMillan, 1985
3. Rathakrishnan, E, ‘Fundamentals of Fluid Mechanics’, Prentice-Hall, 2007
AU9201 THERMODYNAMICS AND THERMAL ENGINEERING L T P C
3 1 0 4
OBJECTIVE
To introduce fundamental concepts in thermodynamics, heat tramsfer, propulsion
and refrigeration and air conditioning.
UNIT I BASIC THERMODYNAMICS 16
Systems, Zeroth low, First law. Steady flow energy equation. Heat and work transfer
in flow and non-flow processes. Second law, Kelvin-Planck statement - Clausius
statement - Concept of Entropy, Clausius inequality, Entropy change in non-flow
processes. Properties of gases and vapours.
UNIT II AIR CYCLE AND COMPRESSORS 12
Camot, Otto, Diesel, Dual combustion and Brayton cycles. Air standard efficiency .
Mean effective pressure, Reciprocating compressors.
UNIT III STEAM AND JET PROPULSION 12
Properties of steam – Rankine cycle – Steam Nozzles – Simple jet propulsion system
– Thrust rocket motor – Specific impulse.
UNIT IV REFRIGERATION AND AIR-CONDITIONING 10
Principles of Psychrometry and refrigeration - Vapour compression - Vapour
absorption types - Co-efficient of performance, Properties of refrigerants – Basic
Principle and types Air conditioning.
UNIT V HEAT TRANSFER 10
Conduction in parallel, radial and composite wall – Basics of Convective heat transfer
- Fundamentals of Radiative heat transfer – Flow through heat exchangers.
L = 45, T = 15, TOTAL : 60 PERIODS
(Use of standard thermodynamic tables, Mollier diagram and Refrigerant property
tables are permitted)
TEXT BOOKS
1. Nag.P.K., “Engineering Thermodynamics”, Tata McGraw-Hill, New Delhi, 2007.
2. Rathakrishnan E., “Fundamentals of Engineering Thermodynamics”, PrenticeHall India, 2005.
REFERENCES
1. Ramalingam K.K. “Thermodynamics”, Sci-Tech Publications, 2006
2. Holman.J.P., “Thermodynamics”, 3rd Ed. McGraw-Hill, 2007.
3. Venwylen and Sontag, “Classical Thermodynamics”, Wiley Eastern, 1987
4. Arora C.P, “ Thermodynamics”, Tata McGraw-Hill, New Delhi, 2003.
5. Merala C, Pother, Craig W, Somerton, “ Thermodynamics for Engineers”,
Schaum Outline Series, Tata McGraw-Hill, New Delhi, 2004.
AU9202 SOLID MECHANICS L T P C
3 1 0 4
UNIT I AXIAL LOADING 12
Stresses and strains – Hooke’s law – stress and strain diagrams - elastic constants
– statically determinate and indeterminate problems in tension & compression –
thermal stresses – impact loading.
UNIT II STRESSES IN BEAMS 10
Shear force & bending moment diagrams – bending stresses – shear stress variation
in beams of symmetric sections – beams of uniform strength.
UNIT III DEFLECTION OF BEAMS 12
Double integration method – Macaulay’s method – moment area method – conjugate
beam method – principle of superposition – Strain Energy in axial, bending, torsion
and shear loadings. Castigliano’s theorems and their applications.
UNIT IV TORSION – SPRINGS – COLUMNS 14
Torsion of solid and hollow circular shafts – shear stress variation – power
transmission in shafts – open and closed-coiled helical springs – stresses in helical
springs – classification of columns – Euler buckling – columns with different end
conditions.
UNIT V BIAXIAL STRESSES 12
Stresses in thin-walled pressure vessels – combined bending, torsion and axial
loading of circular shafts – Mohr’s circle and its construction – determination of
principal stresses.
TEXT BOOK
1. Gere & Timoshenko, ‘Mechanics of Materials’, McGraw Hill, 1993
2. William Nash, Strength of Materials, Tata McGraw Hill, 2004
REFERENCES:
1. Dym,C.L., and Shames,I.H., ‘Solid Mechanics’, McGraw Hill, Kogakusha, Tokyo,
1973.
2. Stephen Timoshenko, ‘Strength of Materials’, Vol I & II, CBS Publishers and
Distributors, Third Edition.
3. R.K.Rajput, ‘Strength of Materials’, S. Chand and Co., 1999.
4. Timoshenko,S. and Young,D.H., Elements of Strength of Materials,
T.Van Nostrand Co. Inc., Princeton, N.J., 1977.
EI9211 ELECTRONICS & INSTRUMENTATION L T P C
3 0 0 3
UNIT I ELECTRONIC COMPONENTS AND DEVICES 10
Resistors, Capacitors, Inductors and Transformers - properties, types. Simple
PN Junction Diodes, Zener diode, Bipolar Junction transistor and Field Effect
Transistors – operating principles and characteristics. Other Devices – UJT, SCR,
LED, Photodetectors.
UNIT II ANALOG CIRCUITS 10
Rectifier and Power Supply Circuits, clipper, clamper using diodes, Operational
Amplifiers (Ideal) – properties and typical circuits like differentiator, integrator,
summer, comparator, single-stage BJT’s and FET’s amplifiers – Multistage Amplifier
Principles(Qualitative Treatment only).
UNIT III DIGITAL CIRCUITS 10
Basics of Boolean Logic – Logic Gates, Flip-Flops, Shift-Registers, Counters,
Decoders/Drivers, Timer, Display Devices, A/D and D/A Converters.
UNIT IV MEASUREMENTS AND INSTRUMENTS 7
Definitions of Accuracy, Precision, Sensitivity, Resolution, Linearity, Range,
Measurement of Electrical Quantities – Voltmeter, Ammeter, Watt-Meter, DMM,
CRO, DSO, Transducers and signal conditioning systems for pressure,
temperature, acceleration measurements (Qualitative Treatment only).
UNIT V MICROPROCESSORS AND APPLICATIONS 8
Architecture of 8085 processors, Address Modes, Instruction set, simple
programming like addition, subtraction, multiplication, logical operation, Peripherals
and Interfacing – 8255, 8251. Applications like motor control, keyboard and PC
interface, Introduction to Microcontrollers.
TOTAL: 45 PERIODS
TEXT BOOK
1. Millman.J. and Halkias.C., “Integrated Electronics”, Tata McGraw Hill, 2004.
2. Paul Horowitz and Wilfred Hill “The Art of Electronics”, Cambridge University
press,1989.
REFERENCES
1. Donald P Leach, Albert Paul Malvino and Goutam Saha,” Digital Principles &
Applications”,6E, Tata McGraw Hill, 2006.
2. A.K.Sawhney, A course in Electrical and Electronic Measurement and
Instrumentation”, Dhanpat Raj. and Sons, New Delhi, 1999
3. Helfrick.A.D., and Cooper.W.D., ‘“Electronic Instrumentation and Measurement
techniques”, Prentice Hall of India, 1998.
4. Gaonkar. Ramesh S, “ Microprocessor Architecture Programming and
Applications with 8085”, 5th Ed. Penram International Publishing (India). 2003 .
5. Kenneth J.Ayala., “The 8051 Microcontroller Architecture Programming and
Applications”, 2ed, Penram International Publishing (India).2004.
AE9202 ELEMENTS OF AERONAUTICS L T P C
2 0 0 2
OBJECTIVE
To introduce the basic concepts of aerospace engineering and the current
developments in the field.
UNIT I HISTORICAL EVALUATION 8
Early airplanes, biplanes and monoplanes, Developments in aerodynamics,
materials, structures and propulsion over the years.
UNIT II AIRCRAFT CONFIGURATIONS 5
Components of an airplane and their functions. Different types of flight vehicles,
classifications. Conventional control, Powered control, Basic instruments for flying,
Typical systems for control actuation.
UNIT III INTRODUCTION TO PRINCIPLES OF FLIGHT 6
Physical properties and structure of the atmosphere, Temperature, pressure and
altitude relationships, Evolution of lift, drag and moment. Aerofoils, Mach number,
Maneuvers.
UNIT IV INTRODUCTION TO AIRPLANE STRUCTURES AND
MATERIALS 6
General types of construction, Monocoque, semi-monocoque and geodesic
construction, Typical wing and fuselage structure. Metallic and non-metallic
materials, Use of aluminium alloy, titanium, stainless steel and composite materials.
UNIT V POWER PLANTS USED IN AIRPLANES 5
Basic ideas about piston, turboprop and jet engines, Use of propeller and jets for
thrust production. Comparative merits, Principles of operation of rocket, types of
rockets and typical applications, Exploration into space.
TOTAL: 30 PERIODS
TEXT BOOKS
1..Anderson, J.D., “Introduction to Flight”, McGraw-Hill, 1995.
REFERENCE
1..Kermode, A.C., “Flight without Formulae”, McGraw-Hill, 1997.
PR9202 COMPUTER AIDED PART AND ASSEMBLY DRAWING L T P C
0 0 3 2
OBJECTIVE
To impart skills in construction of machine elements and assembly drawing. Also to
train the students to read and represent a geometrical tolerances in part drawing.
1. Instruction to machine drawing & production drawing classification of
drawing-BIS conventions – Orthographic and sectional views. Reviews of
the concepts of limits, tolerance, fits, surface roughness, and symbols
terminology used in Production drawing.
2. Machine element joints – Types of joints – Screw fasteners – Pin joints,
couplings welded joints.
3. Computer Aided Production Drafting
Detailed part drawing and assembly drawings (with suitable tolerances,
machine sumbols, specification of fit).
1) Screw jack
2) Shaper tool head
3) Non return valve
4) Plummer block
5) Foot step drawing
6) Machine vice
7) Four jaw chuck of lathe
8) Lathe tail stock
9) Square tool post
10) Universal coupling
11)Hydraulic & Pneumatic Assembly
TOTAL: 45 PERIODS
PR9203 MECHANICAL SCIENCES LABORATORY L T P C
0 0 3 2
OBJECTIVE
To train the students in testing and quantifying the mechanical properties of
Engineering Materials, Engines and Heat Exchangers
`
List of Experiments
Tension Test
Torsion Test
Testing of springs
Impact test i) Izod, ii) Charpy
Hardness test i) Vickers, ii) Brinell, iii) Rockwell, iv) Shore
Deflection of Beams
Dye Penetrant Test
Performance test on a 4 storke engine
Viscosity determination of the given fluid
Moment of inertial of connecting rod
Determination of Effectiveness of a parallel and counter flow heat exchangers
Valve timing of a 4 stroke engine and port timing of a 2 stroke engine
TOTAL: 45 PERIODS
(Common to all branches of BE / B.Tech) 3 0 0 3
AIM:
To facilitate the understanding of the principles and to cultivate the art of formulation
physical problems in the language of mathematics
OBJECTIVES:
1. To introduce Fourier series analysis which is central to many applications in
engineering apart from its use in solving boundary value problems
2.To acquaint the student with Fourier transform techniques used in wide variety of
situations in which the functions used are not periodic
3. To introduce the effective mathematical tools for the solutions of partial differential
equations that model physical processes
4. To develop Z- transform techniques which will perform the same task for discrete
time systems as Laplace Transform, a valuable aid in analysis of continuous time
systems
UNIT I FOURIER SERIES 9+3
Dirichlet’s conditions – General Fourier series – Odd and even functions – Half-range
Sine and Cosine series – Complex form of Fourier Series – Parseval’s identity –
Harmonic Analysis.
UNIT II FOURIER TRANSFORM 9+3
Fourier integral theorem – Fourier transform pair-Sine and Consine transforms –
Properties – Transform of simple function – Convolution theorem - Parseval’s
identity.
UNIT III PARTIAL DIFFERENTIAL EQUATIONS 9+3
Formation – Solutions of first order equations – Standard types and Equations
reducible to standard types – Singular solutions - Lagrange’s Linear equation –
Integral surface passing through a given curve – Solution of linear equations of
higher order with constant coefficients.
UNIT IV APPLICATIONS OF PARTIAL DIFFERENTIAL
EQUATIONS 9+3
Method of separation of Variables – Solutions of one dimensional wave equation and
One-dimensional heat equation – Steady state solution of two-dimensional heat
equation – Fourier series solutions in Cartesian coordinates.
UNIT V Z – TRANSFORM AND DIFFERENCE EQUATION 9+3
Z-transform-Elementary properties-Inverse z transform – Convolution theorem-Initial
and Final value theorems - Formation of difference equation-Solution of difference
equation using z transform.
TOTAL: 45+15=60 PERIODS
TEXT BOOK
1. B.S.Grewal, “Higher Engineering Mathematics”, Khanna Publications (2007)
REFERENCES
1) Glyn James, “Advanced Modern Engineering Mathematics, Pearson
Education (2007)
2) B.V.Ramana, “Higher Engineering Mathematics” Tata McGraw Hill 2007.
3) N.P.Bali, and Manish Goyal, “A Text Book of Engineering 7 thEdition (2007) Lakshmi Publications (P) Limited, New Delhi.
AE9201 ENGINEERING FLUID MECHANICS L T P C
3 1 0 4
AIM:
To introduce the concepts of Fluid Mechanics. Pre-requisite: Basics of Physics
OBJECTIVE:
To introduce the concepts of fluid statics viscosity and buoyancy. To make the
student understand the basic laws namely, mass momentum and energy. To give an
introduction on fluid machinery.
UNIT I BASIC CONCEPTS 15
Introduction – Fluid properties – Newton’s viscosity law – Classification of fluids and
fluid motion – Fluid statics – Hydrostatic force on submerged surfaces – stability of
floating bodies – Dimensional analysis – The Buckingham-Pi theorem – Significant
dimensionless groups – Flow similarity and model studies
UNIT II BASIC EQUATIONS OF FLUID FLOW ANALYSIS 15
Basic laws for a system in integral form – Conservation of mass – Newton’s 2nd law – Laws of thermodynamics – Application of the basic laws for a control volume – Kinematics – Motion of a fluid particle – Fluid deformation – Differential analysis of fluid motion – Continuity equation – Differential momentum equation – The Navier Stokes equations
UNIT III INCOMPRESSIBLE INVISCID FLOW 8
Euler’s equations of motion – Bernoulli’s equations – Applications – Methods of
pressure measurement – Flow measurement – Orifice plate – Venturi meter –
Irrotational flow – Stream function and velocity potential – Laplace equation –
Elementary plane flows
UNIT IV INCOMPRESSIBLE VISCOUS FLOW 8
Fully developed laminar flow between infinite parallel plates – Laminar and turbulent
flow through pipes – Velocity profiles – Energy considerations in pipe flow –
Calculation of head loss Pipe flow problems – Hydraulic and energy grade lines –
Moody’s diagram
UNIT V FLUID MACHINERY 14
Introduction and classification of fluid machines – Turbo machinery analysis – The
angular momentum principle – Euler turbo machine equation – Velocity triangles –
Application to fluid systems – Working principle of turbines, fans, blowers, pumps and
compressors.
L = 45, T = 15, TOTAL = 60 PERIODS
TEXT BOOKS
1. Shames I H, ‘Mechanics of Fluids’, Kogakusha, Tokyo, 1998
2. Robert W Fox & Alan T Mc.Donald, ‘Introduction to fluid Mechanics’, John Wiley
and Sons, 1995
REFERENCE BOOKS
1. Yuan S W, ‘Foundations of fluid Mechanics’, Prentice-Hall, 1987
2. Milne Thompson L M, ‘Theoretical Hydrodynamics’, MacMillan, 1985
3. Rathakrishnan, E, ‘Fundamentals of Fluid Mechanics’, Prentice-Hall, 2007
AU9201 THERMODYNAMICS AND THERMAL ENGINEERING L T P C
3 1 0 4
OBJECTIVE
To introduce fundamental concepts in thermodynamics, heat tramsfer, propulsion
and refrigeration and air conditioning.
UNIT I BASIC THERMODYNAMICS 16
Systems, Zeroth low, First law. Steady flow energy equation. Heat and work transfer
in flow and non-flow processes. Second law, Kelvin-Planck statement - Clausius
statement - Concept of Entropy, Clausius inequality, Entropy change in non-flow
processes. Properties of gases and vapours.
UNIT II AIR CYCLE AND COMPRESSORS 12
Camot, Otto, Diesel, Dual combustion and Brayton cycles. Air standard efficiency .
Mean effective pressure, Reciprocating compressors.
UNIT III STEAM AND JET PROPULSION 12
Properties of steam – Rankine cycle – Steam Nozzles – Simple jet propulsion system
– Thrust rocket motor – Specific impulse.
UNIT IV REFRIGERATION AND AIR-CONDITIONING 10
Principles of Psychrometry and refrigeration - Vapour compression - Vapour
absorption types - Co-efficient of performance, Properties of refrigerants – Basic
Principle and types Air conditioning.
UNIT V HEAT TRANSFER 10
Conduction in parallel, radial and composite wall – Basics of Convective heat transfer
- Fundamentals of Radiative heat transfer – Flow through heat exchangers.
L = 45, T = 15, TOTAL : 60 PERIODS
(Use of standard thermodynamic tables, Mollier diagram and Refrigerant property
tables are permitted)
TEXT BOOKS
1. Nag.P.K., “Engineering Thermodynamics”, Tata McGraw-Hill, New Delhi, 2007.
2. Rathakrishnan E., “Fundamentals of Engineering Thermodynamics”, PrenticeHall India, 2005.
REFERENCES
1. Ramalingam K.K. “Thermodynamics”, Sci-Tech Publications, 2006
2. Holman.J.P., “Thermodynamics”, 3rd Ed. McGraw-Hill, 2007.
3. Venwylen and Sontag, “Classical Thermodynamics”, Wiley Eastern, 1987
4. Arora C.P, “ Thermodynamics”, Tata McGraw-Hill, New Delhi, 2003.
5. Merala C, Pother, Craig W, Somerton, “ Thermodynamics for Engineers”,
Schaum Outline Series, Tata McGraw-Hill, New Delhi, 2004.
AU9202 SOLID MECHANICS L T P C
3 1 0 4
UNIT I AXIAL LOADING 12
Stresses and strains – Hooke’s law – stress and strain diagrams - elastic constants
– statically determinate and indeterminate problems in tension & compression –
thermal stresses – impact loading.
UNIT II STRESSES IN BEAMS 10
Shear force & bending moment diagrams – bending stresses – shear stress variation
in beams of symmetric sections – beams of uniform strength.
UNIT III DEFLECTION OF BEAMS 12
Double integration method – Macaulay’s method – moment area method – conjugate
beam method – principle of superposition – Strain Energy in axial, bending, torsion
and shear loadings. Castigliano’s theorems and their applications.
UNIT IV TORSION – SPRINGS – COLUMNS 14
Torsion of solid and hollow circular shafts – shear stress variation – power
transmission in shafts – open and closed-coiled helical springs – stresses in helical
springs – classification of columns – Euler buckling – columns with different end
conditions.
UNIT V BIAXIAL STRESSES 12
Stresses in thin-walled pressure vessels – combined bending, torsion and axial
loading of circular shafts – Mohr’s circle and its construction – determination of
principal stresses.
TEXT BOOK
1. Gere & Timoshenko, ‘Mechanics of Materials’, McGraw Hill, 1993
2. William Nash, Strength of Materials, Tata McGraw Hill, 2004
REFERENCES:
1. Dym,C.L., and Shames,I.H., ‘Solid Mechanics’, McGraw Hill, Kogakusha, Tokyo,
1973.
2. Stephen Timoshenko, ‘Strength of Materials’, Vol I & II, CBS Publishers and
Distributors, Third Edition.
3. R.K.Rajput, ‘Strength of Materials’, S. Chand and Co., 1999.
4. Timoshenko,S. and Young,D.H., Elements of Strength of Materials,
T.Van Nostrand Co. Inc., Princeton, N.J., 1977.
EI9211 ELECTRONICS & INSTRUMENTATION L T P C
3 0 0 3
UNIT I ELECTRONIC COMPONENTS AND DEVICES 10
Resistors, Capacitors, Inductors and Transformers - properties, types. Simple
PN Junction Diodes, Zener diode, Bipolar Junction transistor and Field Effect
Transistors – operating principles and characteristics. Other Devices – UJT, SCR,
LED, Photodetectors.
UNIT II ANALOG CIRCUITS 10
Rectifier and Power Supply Circuits, clipper, clamper using diodes, Operational
Amplifiers (Ideal) – properties and typical circuits like differentiator, integrator,
summer, comparator, single-stage BJT’s and FET’s amplifiers – Multistage Amplifier
Principles(Qualitative Treatment only).
UNIT III DIGITAL CIRCUITS 10
Basics of Boolean Logic – Logic Gates, Flip-Flops, Shift-Registers, Counters,
Decoders/Drivers, Timer, Display Devices, A/D and D/A Converters.
UNIT IV MEASUREMENTS AND INSTRUMENTS 7
Definitions of Accuracy, Precision, Sensitivity, Resolution, Linearity, Range,
Measurement of Electrical Quantities – Voltmeter, Ammeter, Watt-Meter, DMM,
CRO, DSO, Transducers and signal conditioning systems for pressure,
temperature, acceleration measurements (Qualitative Treatment only).
UNIT V MICROPROCESSORS AND APPLICATIONS 8
Architecture of 8085 processors, Address Modes, Instruction set, simple
programming like addition, subtraction, multiplication, logical operation, Peripherals
and Interfacing – 8255, 8251. Applications like motor control, keyboard and PC
interface, Introduction to Microcontrollers.
TOTAL: 45 PERIODS
TEXT BOOK
1. Millman.J. and Halkias.C., “Integrated Electronics”, Tata McGraw Hill, 2004.
2. Paul Horowitz and Wilfred Hill “The Art of Electronics”, Cambridge University
press,1989.
REFERENCES
1. Donald P Leach, Albert Paul Malvino and Goutam Saha,” Digital Principles &
Applications”,6E, Tata McGraw Hill, 2006.
2. A.K.Sawhney, A course in Electrical and Electronic Measurement and
Instrumentation”, Dhanpat Raj. and Sons, New Delhi, 1999
3. Helfrick.A.D., and Cooper.W.D., ‘“Electronic Instrumentation and Measurement
techniques”, Prentice Hall of India, 1998.
4. Gaonkar. Ramesh S, “ Microprocessor Architecture Programming and
Applications with 8085”, 5th Ed. Penram International Publishing (India). 2003 .
5. Kenneth J.Ayala., “The 8051 Microcontroller Architecture Programming and
Applications”, 2ed, Penram International Publishing (India).2004.
AE9202 ELEMENTS OF AERONAUTICS L T P C
2 0 0 2
OBJECTIVE
To introduce the basic concepts of aerospace engineering and the current
developments in the field.
UNIT I HISTORICAL EVALUATION 8
Early airplanes, biplanes and monoplanes, Developments in aerodynamics,
materials, structures and propulsion over the years.
UNIT II AIRCRAFT CONFIGURATIONS 5
Components of an airplane and their functions. Different types of flight vehicles,
classifications. Conventional control, Powered control, Basic instruments for flying,
Typical systems for control actuation.
UNIT III INTRODUCTION TO PRINCIPLES OF FLIGHT 6
Physical properties and structure of the atmosphere, Temperature, pressure and
altitude relationships, Evolution of lift, drag and moment. Aerofoils, Mach number,
Maneuvers.
UNIT IV INTRODUCTION TO AIRPLANE STRUCTURES AND
MATERIALS 6
General types of construction, Monocoque, semi-monocoque and geodesic
construction, Typical wing and fuselage structure. Metallic and non-metallic
materials, Use of aluminium alloy, titanium, stainless steel and composite materials.
UNIT V POWER PLANTS USED IN AIRPLANES 5
Basic ideas about piston, turboprop and jet engines, Use of propeller and jets for
thrust production. Comparative merits, Principles of operation of rocket, types of
rockets and typical applications, Exploration into space.
TOTAL: 30 PERIODS
TEXT BOOKS
1..Anderson, J.D., “Introduction to Flight”, McGraw-Hill, 1995.
REFERENCE
1..Kermode, A.C., “Flight without Formulae”, McGraw-Hill, 1997.
PR9202 COMPUTER AIDED PART AND ASSEMBLY DRAWING L T P C
0 0 3 2
OBJECTIVE
To impart skills in construction of machine elements and assembly drawing. Also to
train the students to read and represent a geometrical tolerances in part drawing.
1. Instruction to machine drawing & production drawing classification of
drawing-BIS conventions – Orthographic and sectional views. Reviews of
the concepts of limits, tolerance, fits, surface roughness, and symbols
terminology used in Production drawing.
2. Machine element joints – Types of joints – Screw fasteners – Pin joints,
couplings welded joints.
3. Computer Aided Production Drafting
Detailed part drawing and assembly drawings (with suitable tolerances,
machine sumbols, specification of fit).
1) Screw jack
2) Shaper tool head
3) Non return valve
4) Plummer block
5) Foot step drawing
6) Machine vice
7) Four jaw chuck of lathe
8) Lathe tail stock
9) Square tool post
10) Universal coupling
11)Hydraulic & Pneumatic Assembly
TOTAL: 45 PERIODS
PR9203 MECHANICAL SCIENCES LABORATORY L T P C
0 0 3 2
OBJECTIVE
To train the students in testing and quantifying the mechanical properties of
Engineering Materials, Engines and Heat Exchangers
`
List of Experiments
Tension Test
Torsion Test
Testing of springs
Impact test i) Izod, ii) Charpy
Hardness test i) Vickers, ii) Brinell, iii) Rockwell, iv) Shore
Deflection of Beams
Dye Penetrant Test
Performance test on a 4 storke engine
Viscosity determination of the given fluid
Moment of inertial of connecting rod
Determination of Effectiveness of a parallel and counter flow heat exchangers
Valve timing of a 4 stroke engine and port timing of a 2 stroke engine
TOTAL: 45 PERIODS
{ 0 comments... read them below or add one }
Post a Comment
Enter your comments here