ANNA UNIVERSITY :: CHENNAI 600 025
UNIVERSITY DEPARTMENTS
REGULATIONS – 2008
CURRICULUM FROM III TO VIII SEMESTERS FOR
B.E. ELECTRICAL AND ELECTRONICS ENGINEERING
SEMESTER III
CODE NO COURSE TITLE L T P C
THEORY
MA9211 Mathematics – III 3 1 0 4
EC9215 Electronic Devices and Circuits 3 1 0 4
EE9201 Control Systems 3 1 0 4
EE9202 Electromagnetic Theory 3 0 0 3
EE9203 Measurements and Instrumentation 3 0 0 3
EE9204 Digital System Design 3 1 0 4
PRACTICAL
EC9214 Electronics Laboratory 0 0 3 2
EE9205 Control and Instrumentation laboratory 0 0 3 2
EE9206 Field Measurement and Computation Laboratory 0 0 3 2
TOTAL 18 4 9 28
MATHEMATICS III L T P C
(Common to all branches of BE / B.Tech Programmes) 3 1 0 4
AIM:
To facilitate the understanding of the principles and to cultivate the art of formulating
physical problems in the language of mathematics.
OBJECTIVES:
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 Cosine transforms –
Properties – Transform of elementary functions – 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 EQUATIONS 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.
L: 45, T: 15, TOTAL: 60 PERIODS
TEXT BOOK:
1. Grewal, B.S. “Higher Engineering Mathematics”, Khanna Publications (2007)
REFERENCES:
1. Glyn James, “Advanced Modern Engineering Mathematics”, Pearson Education
(2007)
2. Ramana B.V., “Higher Engineering Mathematics” Tata McGraw Hill (2007).
3. Bali N.P. and Manish Goyal, “A Text Book of Engineering” 7th Edition (2007) Lakshmi
Publications (P) Limited, New Delhi.
EC9215 ELECTRONIC DEVICES AND CIRCUITS L T P C
3 1 0 4
AIM:
To study the characteristics and applications of electronic devices.
OBJECTIVES:
PN junction diode –structure, operation and V-I characteristic-current equation of drift
current density and diffusion current density-diffusion and transient capacitance –display
devices- LED, Laser diodes Zener breakdown-zener reverse characteristic – zener as
regulator
UNIT II BIPOLAR JUNCTION TRANSISTORS 9+3
– structure , operation and V-I characteristic- MOSFET – structure, operation and V-I
characteristic – types of MOSFET – JFET –structure, operation and V-I characteristic
UNIT III AMPLIFIERS 9+3
BJT small signal model – biasing – analysis of CE, CB, CC amplifiers- Gain and
frequency response – MOSFET small signal model – biasing – analysis of CS and
source follower – gain and frequency response.
UNIT IV MULTISTAGE AMPLIFIERS AND DIFFERENTIAL AMPLIFIER 9+3
BIMOS cascade amplifier, differential amplifier – common mode and difference mode
analysis – FET input stages – tuned amplifiers- single tuned amplifiers – gain and
frequency response – neutralization methods.
UNIT V FEEDBACK AMPLIFIERS AND OSCILLATORS 9+3
Advantages of negative feedback – voltage ./ current, series , shunt feedback – positive
feedback – condition for oscillations, phase shift – Wien bridge, Hartley, colpitts and
crystal oscillators. L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. David A. Bell ,”Electronic devices and circuits”, Prentice Hall of India, 2004.
2. Seda smith, “Microelectronic circuits “ Oxford University Press, 2004.
REFERENCES:
1. Rashid, “Micro electronic circuits” Thomson publications, 1999.
2. Floyd, “Electron devices” Pearson Asia 5th Edition, 2001.
3. Donald A Neamen, “Electronic Circuit Analysis and Design” Tata McGrawHill,
3rd Edition, 2003.
6
EE9201 CONTROL SYSTEMS L T P C
3 1 0 4
AIM
To learn the concepts of linear Systems theory and its analysis.
OBJECTIVES
To impart knowledge on
LIST OF EXPERIMENTS
1. PN Junction diode and Rectifier Applications
2. Bipolar Junction transistor - CE, CB, CC characteristics
3. JFET – characteristics and parameter determination
4. UJT & SCR Characteristics & UJT – Controlled SCR
5. Characteristics of DIAC and TRIAC
6. Characteristics of BJT Amplifier frequency response
7. Characteristics of FET amplifier frequency response
8. Characteristics of Class B amplifier – Darlington pair
9. Characteristics of Differential amplifier
10. Class D – Totempole configuration
11. PSPICE modeling of electronic circuits
TOTAL: 45 PERIODS
EE9205 CONTROL AND INSTRUMENTATION LABORATORY L T P C
0 0 3 2
AIM
To provide a platform for understanding the basic concepts of measurement and control
and its application to practical systems.
OBJECTIVES
LIST OF EXPERIMENTS:
1. Digital simulation of linear systems.
2. Digital simulation of non-linear systems.
3. Study of P, PI and PID controllers and its applications to SISO systems.
4. Study of Lead-Lag compensators and its application to SISO systems.
5. State space analysis of physical systems
6. Stability analysis using conventional techniques.
7. Study of transducers and their characterization (Electrical, and Thermal)
8. Study of transducers and their characterization (Mechanical and flow)
9. Measurement of passive elements using Bridge networks
10. Instrument Transformers – Calibration and Analysis
11. Design of signal conditioning circuits.
12. Closed loop control system design.
13. Measurement systems-Simulation& analysis using LABVIEW
TOTAL: 45 PERIODS
EE9206 FIELD MEASUREMENT AND COMPUTATION L T P C
LABORATORY 0 0 3 2
UNIVERSITY DEPARTMENTS
REGULATIONS – 2008
CURRICULUM FROM III TO VIII SEMESTERS FOR
B.E. ELECTRICAL AND ELECTRONICS ENGINEERING
SEMESTER III
CODE NO COURSE TITLE L T P C
THEORY
MA9211 Mathematics – III 3 1 0 4
EC9215 Electronic Devices and Circuits 3 1 0 4
EE9201 Control Systems 3 1 0 4
EE9202 Electromagnetic Theory 3 0 0 3
EE9203 Measurements and Instrumentation 3 0 0 3
EE9204 Digital System Design 3 1 0 4
PRACTICAL
EC9214 Electronics Laboratory 0 0 3 2
EE9205 Control and Instrumentation laboratory 0 0 3 2
EE9206 Field Measurement and Computation Laboratory 0 0 3 2
TOTAL 18 4 9 28
MATHEMATICS III L T P C
(Common to all branches of BE / B.Tech Programmes) 3 1 0 4
AIM:
To facilitate the understanding of the principles and to cultivate the art of formulating
physical problems in the language of mathematics.
OBJECTIVES:
- To introduce Fourier series analysis which is central to many applications inengineering apart from its use in solving boundary value problems
- To acquaint the student with Fourier transform techniques used in wide variety ofsituations in which the functions used are not periodic
- To introduce the effective mathematical tools for the solutions of partial differential equations that model physical processes
- To develop Z- transform techniques which will perform the same task for discrete timesystems as Laplace Transform, a valuable aid in analysis of continuous time systems
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 Cosine transforms –
Properties – Transform of elementary functions – 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 EQUATIONS 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.
L: 45, T: 15, TOTAL: 60 PERIODS
TEXT BOOK:
1. Grewal, B.S. “Higher Engineering Mathematics”, Khanna Publications (2007)
REFERENCES:
1. Glyn James, “Advanced Modern Engineering Mathematics”, Pearson Education
(2007)
2. Ramana B.V., “Higher Engineering Mathematics” Tata McGraw Hill (2007).
3. Bali N.P. and Manish Goyal, “A Text Book of Engineering” 7th Edition (2007) Lakshmi
Publications (P) Limited, New Delhi.
EC9215 ELECTRONIC DEVICES AND CIRCUITS L T P C
3 1 0 4
AIM:
To study the characteristics and applications of electronic devices.
OBJECTIVES:
- To acquaint the students with construction, theory and characteristics of the followingelectronic devices: P-N junction diode, Bipolar transistor, Field Effect transistor, LED, LCD and otherphoto electronic devices, Power control/regulator devices, Feedback amplifiers and oscillators
PN junction diode –structure, operation and V-I characteristic-current equation of drift
current density and diffusion current density-diffusion and transient capacitance –display
devices- LED, Laser diodes Zener breakdown-zener reverse characteristic – zener as
regulator
UNIT II BIPOLAR JUNCTION TRANSISTORS 9+3
– structure , operation and V-I characteristic- MOSFET – structure, operation and V-I
characteristic – types of MOSFET – JFET –structure, operation and V-I characteristic
UNIT III AMPLIFIERS 9+3
BJT small signal model – biasing – analysis of CE, CB, CC amplifiers- Gain and
frequency response – MOSFET small signal model – biasing – analysis of CS and
source follower – gain and frequency response.
UNIT IV MULTISTAGE AMPLIFIERS AND DIFFERENTIAL AMPLIFIER 9+3
BIMOS cascade amplifier, differential amplifier – common mode and difference mode
analysis – FET input stages – tuned amplifiers- single tuned amplifiers – gain and
frequency response – neutralization methods.
UNIT V FEEDBACK AMPLIFIERS AND OSCILLATORS 9+3
Advantages of negative feedback – voltage ./ current, series , shunt feedback – positive
feedback – condition for oscillations, phase shift – Wien bridge, Hartley, colpitts and
crystal oscillators. L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. David A. Bell ,”Electronic devices and circuits”, Prentice Hall of India, 2004.
2. Seda smith, “Microelectronic circuits “ Oxford University Press, 2004.
REFERENCES:
1. Rashid, “Micro electronic circuits” Thomson publications, 1999.
2. Floyd, “Electron devices” Pearson Asia 5th Edition, 2001.
3. Donald A Neamen, “Electronic Circuit Analysis and Design” Tata McGrawHill,
3rd Edition, 2003.
6
EE9201 CONTROL SYSTEMS L T P C
3 1 0 4
AIM
To learn the concepts of linear Systems theory and its analysis.
OBJECTIVES
To impart knowledge on
- Different system representation, block diagram reduction and Mason’s rule.
- Time response analysis of LTI systems and steady state error.
- The open loop and closed loop frequency responses of systems.
- Stability concept.
- State variable analysis.
UNIT I MATHEMATICAL MODELS OF PHYSICAL SYSTEMS 9+3
Definition & classification of system – terminology & structure of feedback control theory
–Analogous systems - Physical system representation by Differential equations – Block
diagram reduction– Signal flow graphs.
UNIT II TIME RESPONSE ANALYSIS & ROOT LOCUS TECHNIQUE 9+3
Standard test signals – Steady state error & error constants – Time Response of I and II
order system – Root locus – Rules for sketching root loci.
UNIT III FREQUENCY RESPONSE ANALYSIS 9+3
Correlation between Time & Frequency response – Polar plots – Bode Plots –
Determination of Transfer Function from Bode plot.
UNIT IV STABILITY CONCEPTS & ANALYSIS 9+3
Concept of stability – Necessary condition – RH criterion – Relative stability – Nyquist
stability criterion – Stability from Bode plot – Relative stability from Nyquist & Bode –
Closed loop frequency response.
UNIT V STATE VARIABLE ANALYSIS 9+3
Concept of state – State Variable & State Model – State models for linear & continuous
time systems – Solution of state & output equation – controllability & observability.
L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. Nagrath I.J & M. Gopal, Control systems Engineering, 4th Edition, New Age
International, New Delhi, 2005.
2. Benzamin C. Kuo, Automatic Control systems, 7th Edition, Prentice-Hall (Pearson
Education, Inc.), New Delhi, 2003.
REFERENCES:
1. Norman S. Nise, Control Systems Engineering, 4th Edition, John Wiley,
New Delhi, 2007.
2. Richard C Dorf, Robert H Bishop, Modern control systems , 8th edition, Prentice Hall
(Pearson education, Inc.), New Delhi 2003.
3. Benzamin C. Kuo and Farid Golnaraghi, Automatic Control systems, 8th Edition, John
Wiley, New Delhi, 2003.
4. Eronini umez – Eronini – System Dynamics & Control, Thomson, New Delhi, 1999.
7
EE9202 ELECTROMAGNETIC THEORY L T P C
3 0 0 3
AIM
To introduce the fundamentals of electromagnetic fields and their applications in
Engineering.
OBJECTIVES
To impart knowledge on vector fields - electrostatic and magnetostatic fields,
electrodynamics and electromagnetic waves.
UNIT I INTRODUCTION 6
Sources and effects of electromagnetic fields – Vector fields – Different co-ordinate
systems – Vector calculus – Gradient, Divergence and Curl – Divergence theorem –
Stoke’s theorem.
UNIT II ELECTROSTATICS 12
Coulomb’s Law – electric field intensity – Field due to point and continuous charges –
Gauss’s law and its applications – electrical potential – Electric field and equipotential
plots – electric field in free space, conductors, dielectric – dielectric polarization. Electric
field in multiple dielectrics – boundary conditions, Poisson’s and Laplace’s equations –
Capacitance – Energy density – Dielectric strength – Applications.
UNIT III MAGNETOSTATICS 9
Lorentz Law of force, magnetic field intensity – Biot – Savart Law – Ampere’s Law –
Magnetic field due to straight conductors, circular loop, infinite sheet of current –
Magnetic flux density (B) – B in free space, conductor, magnetic materials.
Magnetization-Magnetic field in multiple media – Boundary conditions – Scalar and
vector potential – Magnetic force – Torque – Inductance – Energy density – Magnetic
circuits – Applications.
UNIT IV ELECTRO DYNAMIC FIELDS 9
Faraday’s law, induced emf – transformer and motional EMF, Maxwell’s equations
(differential and integral forms)- Displacement current – Applications - Relation between
field theory and circuit theory.
UNIT V ELECTROMAGNETIC WAVES 9
Generation – electro magnetic wave equations – Wave parameters; velocity, intrinsic
impedance, propagation constant – Waves in free space, lossy and lossless dielectrics,
conductors – skin depth, Poynting vector – Plane wave reflection and refraction -
Applications
TOTAL: 45 PERIODS TEXT BOOKS:
1. Matthew. N.O. Sadiku, “Elements of Electromagnetics”, Fourth Edition, Oxford
University Press, First Indian Edition 2007.
2. Ashutosh Pramanik, “Electromagnetism – theory and application,” Prentice Hall of
India Private Ltd., New Delhi, 2006.
REFERENCES:
1. William H.Hayt Jr. and John A Buck “Engineering Electromagnetics”, Seventh Edition,
Tata McGraw Hill Publishing Company Ltd., New Delhi, 2006.
2. J.A.Edminister, Schaum’s Outlines “Theory and problems of Electromagnetics”, Tata
Mc Graw hill, Second Edition, Special Indian Edition 2006.
3. Guru and Hiziroghu “Electromagnetic field theory fundamentals”, Thomson Asia Pvt.
Ltd., 1998.
4. John D Kraus, Daniel A Fleisch “Electromagenetics with Applications”, Tata McGraw
Hill International Edition, 1999.
EE9203 MEASUREMENTS AND INSTRUMENTATION L T P C
3 0 0 3
AIM
To provide adequate knowledge of measurements techniques using electrical and
electronic instruments.
OBJECTIVES
Definition & classification of system – terminology & structure of feedback control theory
–Analogous systems - Physical system representation by Differential equations – Block
diagram reduction– Signal flow graphs.
UNIT II TIME RESPONSE ANALYSIS & ROOT LOCUS TECHNIQUE 9+3
Standard test signals – Steady state error & error constants – Time Response of I and II
order system – Root locus – Rules for sketching root loci.
UNIT III FREQUENCY RESPONSE ANALYSIS 9+3
Correlation between Time & Frequency response – Polar plots – Bode Plots –
Determination of Transfer Function from Bode plot.
UNIT IV STABILITY CONCEPTS & ANALYSIS 9+3
Concept of stability – Necessary condition – RH criterion – Relative stability – Nyquist
stability criterion – Stability from Bode plot – Relative stability from Nyquist & Bode –
Closed loop frequency response.
UNIT V STATE VARIABLE ANALYSIS 9+3
Concept of state – State Variable & State Model – State models for linear & continuous
time systems – Solution of state & output equation – controllability & observability.
L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. Nagrath I.J & M. Gopal, Control systems Engineering, 4th Edition, New Age
International, New Delhi, 2005.
2. Benzamin C. Kuo, Automatic Control systems, 7th Edition, Prentice-Hall (Pearson
Education, Inc.), New Delhi, 2003.
REFERENCES:
1. Norman S. Nise, Control Systems Engineering, 4th Edition, John Wiley,
New Delhi, 2007.
2. Richard C Dorf, Robert H Bishop, Modern control systems , 8th edition, Prentice Hall
(Pearson education, Inc.), New Delhi 2003.
3. Benzamin C. Kuo and Farid Golnaraghi, Automatic Control systems, 8th Edition, John
Wiley, New Delhi, 2003.
4. Eronini umez – Eronini – System Dynamics & Control, Thomson, New Delhi, 1999.
7
EE9202 ELECTROMAGNETIC THEORY L T P C
3 0 0 3
AIM
To introduce the fundamentals of electromagnetic fields and their applications in
Engineering.
OBJECTIVES
To impart knowledge on vector fields - electrostatic and magnetostatic fields,
electrodynamics and electromagnetic waves.
UNIT I INTRODUCTION 6
Sources and effects of electromagnetic fields – Vector fields – Different co-ordinate
systems – Vector calculus – Gradient, Divergence and Curl – Divergence theorem –
Stoke’s theorem.
UNIT II ELECTROSTATICS 12
Coulomb’s Law – electric field intensity – Field due to point and continuous charges –
Gauss’s law and its applications – electrical potential – Electric field and equipotential
plots – electric field in free space, conductors, dielectric – dielectric polarization. Electric
field in multiple dielectrics – boundary conditions, Poisson’s and Laplace’s equations –
Capacitance – Energy density – Dielectric strength – Applications.
UNIT III MAGNETOSTATICS 9
Lorentz Law of force, magnetic field intensity – Biot – Savart Law – Ampere’s Law –
Magnetic field due to straight conductors, circular loop, infinite sheet of current –
Magnetic flux density (B) – B in free space, conductor, magnetic materials.
Magnetization-Magnetic field in multiple media – Boundary conditions – Scalar and
vector potential – Magnetic force – Torque – Inductance – Energy density – Magnetic
circuits – Applications.
UNIT IV ELECTRO DYNAMIC FIELDS 9
Faraday’s law, induced emf – transformer and motional EMF, Maxwell’s equations
(differential and integral forms)- Displacement current – Applications - Relation between
field theory and circuit theory.
UNIT V ELECTROMAGNETIC WAVES 9
Generation – electro magnetic wave equations – Wave parameters; velocity, intrinsic
impedance, propagation constant – Waves in free space, lossy and lossless dielectrics,
conductors – skin depth, Poynting vector – Plane wave reflection and refraction -
Applications
TOTAL: 45 PERIODS TEXT BOOKS:
1. Matthew. N.O. Sadiku, “Elements of Electromagnetics”, Fourth Edition, Oxford
University Press, First Indian Edition 2007.
2. Ashutosh Pramanik, “Electromagnetism – theory and application,” Prentice Hall of
India Private Ltd., New Delhi, 2006.
REFERENCES:
1. William H.Hayt Jr. and John A Buck “Engineering Electromagnetics”, Seventh Edition,
Tata McGraw Hill Publishing Company Ltd., New Delhi, 2006.
2. J.A.Edminister, Schaum’s Outlines “Theory and problems of Electromagnetics”, Tata
Mc Graw hill, Second Edition, Special Indian Edition 2006.
3. Guru and Hiziroghu “Electromagnetic field theory fundamentals”, Thomson Asia Pvt.
Ltd., 1998.
4. John D Kraus, Daniel A Fleisch “Electromagenetics with Applications”, Tata McGraw
Hill International Edition, 1999.
EE9203 MEASUREMENTS AND INSTRUMENTATION L T P C
3 0 0 3
AIM
To provide adequate knowledge of measurements techniques using electrical and
electronic instruments.
OBJECTIVES
- Introduction to general instrument system, error, calibration etc.
- Emphasis is laid on analog and digital techniques used to measure voltage, current,energy, power and non-electrical parameters.
- To have an adequate knowledge of comparison methods of measurement.
- Elaborate discussion about storage & display devices.
- Exposure to various transducers and data acquisition system.
UNIT I QUALITIES OF MEASUREMENT 9
Functional elements of an instrument – Static and dynamic characteristics – Errors in
measurement – Statistical evaluation of measurement data – Standards and calibration.
UNIT II PRIMARY SENSING ELEMENTS AND SIGNAL CONDITIONING 9
Principles, Classification of sensors and transducers – Selection of transducers –
Resistive, capacitive & inductive transducers – Piezoelectric, optical and digital
transducers – Basic Instrumentation Amplifier, Sample and Hold Circuit, A/D and D/A
converters
UNIT III ELECTRICAL MEASUREMENTS AND INSTRUMENTS 9
Principle and types of analog voltmeters, ammeters, multimeters – Single and three
phase wattmeters and energy meters – Magnetic measurements –Instrument
transformers – Instruments for measurement of frequency and phase.
UNIT IV MEASUREMENT OF PASSIVE ELEMENTS 9
Resistance measurement: Conventional methods, Wheatstone bridge, sensitivity
of wheatstone bridge – Kelvin’s bridges – Kelvin’s double bridge method – Measurement
of high resistance – megohm bridge method – Inductance measurement: Maxwell’s
inductance bridge – Maxwell’s LC bridge – Hay’s bridge – Anderson’s bridge –
Capacitance measurement: De Sauty’s bridge – Schering bridge – Measurement of
frequency : Wien’s bridge.
UNIT V BASIC MEASUREMENT METHODS OF NON-ELECTRICAL 9
PARAMETERS
Measurement of Pressure: Comparison with known dead weights - Temperature:
Thermocouple – pyrometers - Flow: Flow meters – Rotameters – Electromagnetic flow
metres – Level: Mechanical, Electrical and optical level indicators - Speed: tachometers
– stroboscopic methods, gyroscopes - Acceleration, Humidity:Wet and dry bulb
hygrometer – Dunmore and pope cells, conductivity cells.
TOTAL: 45 PERIODS
TEXT BOOKS:
1. A.K. Sawhney, ‘A Course in Electrical & Electronic Measurements &
Instrumentation’, Dhanpat Rai and Co, 2004.
2. J. B. Gupta, ‘A Course in Electronic and Electrical Measurements’, S. K. Kataria &
Sons, Delhi, 2003.
REFERENCES:
1. E.O. Doebelin, ‘Measurement Systems – Application and Design’, Tata McGraw
Hill publishing company, 2003.
2. Alan S. Morris,” Measurement & Instrumentation Principles”, Elsevier Publications,
2001
3. Arun K. Ghosh, “ Introduction to Measurements and Instrumentation”, Second
Edition, PHI, 2007.
EE9204 DIGITAL SYSTEM DESIGN L T P C
3 1 0 4
AIM
To introduce the fundamentals of Digital Circuits, combinational and sequential
circuit.
OBJECTIVES
Functional elements of an instrument – Static and dynamic characteristics – Errors in
measurement – Statistical evaluation of measurement data – Standards and calibration.
UNIT II PRIMARY SENSING ELEMENTS AND SIGNAL CONDITIONING 9
Principles, Classification of sensors and transducers – Selection of transducers –
Resistive, capacitive & inductive transducers – Piezoelectric, optical and digital
transducers – Basic Instrumentation Amplifier, Sample and Hold Circuit, A/D and D/A
converters
UNIT III ELECTRICAL MEASUREMENTS AND INSTRUMENTS 9
Principle and types of analog voltmeters, ammeters, multimeters – Single and three
phase wattmeters and energy meters – Magnetic measurements –Instrument
transformers – Instruments for measurement of frequency and phase.
UNIT IV MEASUREMENT OF PASSIVE ELEMENTS 9
Resistance measurement: Conventional methods, Wheatstone bridge, sensitivity
of wheatstone bridge – Kelvin’s bridges – Kelvin’s double bridge method – Measurement
of high resistance – megohm bridge method – Inductance measurement: Maxwell’s
inductance bridge – Maxwell’s LC bridge – Hay’s bridge – Anderson’s bridge –
Capacitance measurement: De Sauty’s bridge – Schering bridge – Measurement of
frequency : Wien’s bridge.
UNIT V BASIC MEASUREMENT METHODS OF NON-ELECTRICAL 9
PARAMETERS
Measurement of Pressure: Comparison with known dead weights - Temperature:
Thermocouple – pyrometers - Flow: Flow meters – Rotameters – Electromagnetic flow
metres – Level: Mechanical, Electrical and optical level indicators - Speed: tachometers
– stroboscopic methods, gyroscopes - Acceleration, Humidity:Wet and dry bulb
hygrometer – Dunmore and pope cells, conductivity cells.
TOTAL: 45 PERIODS
TEXT BOOKS:
1. A.K. Sawhney, ‘A Course in Electrical & Electronic Measurements &
Instrumentation’, Dhanpat Rai and Co, 2004.
2. J. B. Gupta, ‘A Course in Electronic and Electrical Measurements’, S. K. Kataria &
Sons, Delhi, 2003.
REFERENCES:
1. E.O. Doebelin, ‘Measurement Systems – Application and Design’, Tata McGraw
Hill publishing company, 2003.
2. Alan S. Morris,” Measurement & Instrumentation Principles”, Elsevier Publications,
2001
3. Arun K. Ghosh, “ Introduction to Measurements and Instrumentation”, Second
Edition, PHI, 2007.
EE9204 DIGITAL SYSTEM DESIGN L T P C
3 1 0 4
AIM
To introduce the fundamentals of Digital Circuits, combinational and sequential
circuit.
OBJECTIVES
To study various number systems and to simplify the mathematical expressions
using Boolean functions – simple problems.
using Boolean functions – simple problems.
To study implementation of combinational circuits
To study the design of various synchronous and asynchronous circuits.
To expose the students to various memory devices.
To introduce digital simulation techniques for development of application oriented
logic circuit.
UNIT I BOOLEAN ALGEBRA AND COMBINATIONAL CIRCUITS 9+3
Boolean algebra: De-Morgan’s theorem, switching functions and simplification using Kmaps
& Quine McCluskey method, Design of adder, subtractor, comparators, code
converters, encoders, decoders, multiplexers and demultiplexers.
UNIT II SYNCHRONOUS SEQUENTIAL CIRCUITS 9+3
Flip flops - SR, D, JK and T. Analysis of synchronous sequential circuits; design of
synchronous sequential circuits – Counters, state diagram; state reduction; state
assignment.
UNIT III ASYNCHRONOUS SEQUENCTIAL CIRCUIT 9+3
Analysis of asynchronous sequential machines, state assignment, asynchronous design
problem.
UNIT IV PROGRAMMABLE LOGIC DEVICES, MEMORY AND LOGIC
FAMILIES 9+3
Memories: ROM, PROM, EPROM, PLA, PLD, FPGA, digital logic families: TTL, ECL,
CMOS.
UNIT V VHDL 9+3
RTL Design – combinational logic – Types – Operators – Packages – Sequential circuit
– Sub programs – Test benches. (Examples: adders, counters, flipflops, FSM,
Multiplexers / Demltiplexers).
L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. M. Morris Mano, ‘Digital Design’, Pearson Education, 2006.
2. John M.Yarbrough, ‘Digital Logic, Application & Design’, Thomson, 2002.
REFERENCES:
1. Raj Kamal, ‘Digital systems-Principles and Design’, Pearson education 2nd edition,
2007
2. Charles H.Roth, ‘Fundamentals Logic Design’, Jaico Publishing, IV edition, 2002.
3. Floyd and Jain, ‘Digital Fundamentals’, 8th edition, Pearson Education, 2003.
4. John F.Wakerly, ‘Digital Design Principles and Practice’, 3rd edition, Pearson
Education, 2002.
5. Tocci, “Digital Systems: Principles and applications”, 8th Edition” Pearson Education.
EC9214 ELECTRONICS LABORATORY L T P C
0 0 3 2
AIM
To provide hands on experience in characterization of electronic devices and
development of electronic circuits.
OBJECTIVES
To expose the students to various memory devices.
To introduce digital simulation techniques for development of application oriented
logic circuit.
UNIT I BOOLEAN ALGEBRA AND COMBINATIONAL CIRCUITS 9+3
Boolean algebra: De-Morgan’s theorem, switching functions and simplification using Kmaps
& Quine McCluskey method, Design of adder, subtractor, comparators, code
converters, encoders, decoders, multiplexers and demultiplexers.
UNIT II SYNCHRONOUS SEQUENTIAL CIRCUITS 9+3
Flip flops - SR, D, JK and T. Analysis of synchronous sequential circuits; design of
synchronous sequential circuits – Counters, state diagram; state reduction; state
assignment.
UNIT III ASYNCHRONOUS SEQUENCTIAL CIRCUIT 9+3
Analysis of asynchronous sequential machines, state assignment, asynchronous design
problem.
UNIT IV PROGRAMMABLE LOGIC DEVICES, MEMORY AND LOGIC
FAMILIES 9+3
Memories: ROM, PROM, EPROM, PLA, PLD, FPGA, digital logic families: TTL, ECL,
CMOS.
UNIT V VHDL 9+3
RTL Design – combinational logic – Types – Operators – Packages – Sequential circuit
– Sub programs – Test benches. (Examples: adders, counters, flipflops, FSM,
Multiplexers / Demltiplexers).
L: 45 T: 15 TOTAL: 60 PERIODS
TEXT BOOKS:
1. M. Morris Mano, ‘Digital Design’, Pearson Education, 2006.
2. John M.Yarbrough, ‘Digital Logic, Application & Design’, Thomson, 2002.
REFERENCES:
1. Raj Kamal, ‘Digital systems-Principles and Design’, Pearson education 2nd edition,
2007
2. Charles H.Roth, ‘Fundamentals Logic Design’, Jaico Publishing, IV edition, 2002.
3. Floyd and Jain, ‘Digital Fundamentals’, 8th edition, Pearson Education, 2003.
4. John F.Wakerly, ‘Digital Design Principles and Practice’, 3rd edition, Pearson
Education, 2002.
5. Tocci, “Digital Systems: Principles and applications”, 8th Edition” Pearson Education.
EC9214 ELECTRONICS LABORATORY L T P C
0 0 3 2
AIM
To provide hands on experience in characterization of electronic devices and
development of electronic circuits.
OBJECTIVES
- To obtain the characteristics of electronic devices
- To obtain the characteristics of amplifier circuits
- To simulate electronic circuits using standard software packages
LIST OF EXPERIMENTS
1. PN Junction diode and Rectifier Applications
2. Bipolar Junction transistor - CE, CB, CC characteristics
3. JFET – characteristics and parameter determination
4. UJT & SCR Characteristics & UJT – Controlled SCR
5. Characteristics of DIAC and TRIAC
6. Characteristics of BJT Amplifier frequency response
7. Characteristics of FET amplifier frequency response
8. Characteristics of Class B amplifier – Darlington pair
9. Characteristics of Differential amplifier
10. Class D – Totempole configuration
11. PSPICE modeling of electronic circuits
TOTAL: 45 PERIODS
EE9205 CONTROL AND INSTRUMENTATION LABORATORY L T P C
0 0 3 2
AIM
To provide a platform for understanding the basic concepts of measurement and control
and its application to practical systems.
OBJECTIVES
- To model, analyze and design linear and nonlinear systems.
- To study different measurement techniques and to give exposure in design of aclosed loop control system.
LIST OF EXPERIMENTS:
1. Digital simulation of linear systems.
2. Digital simulation of non-linear systems.
3. Study of P, PI and PID controllers and its applications to SISO systems.
4. Study of Lead-Lag compensators and its application to SISO systems.
5. State space analysis of physical systems
6. Stability analysis using conventional techniques.
7. Study of transducers and their characterization (Electrical, and Thermal)
8. Study of transducers and their characterization (Mechanical and flow)
9. Measurement of passive elements using Bridge networks
10. Instrument Transformers – Calibration and Analysis
11. Design of signal conditioning circuits.
12. Closed loop control system design.
13. Measurement systems-Simulation& analysis using LABVIEW
TOTAL: 45 PERIODS
EE9206 FIELD MEASUREMENT AND COMPUTATION L T P C
LABORATORY 0 0 3 2
AIM
To study about the computational and measurement techniques of electromagnetic
fields.
LIST OF EXPERIMENTS :
To study about the computational and measurement techniques of electromagnetic
fields.
LIST OF EXPERIMENTS :
1. A study of solution techniques for electromagnetic field problem using analytical
and numerical methods (FDM and FEM).
Graphical Representation of fields (using MATLAB)
2. Plotting of vector, divergence and curl fields.
3. Plotting of electric field and equipotential lines
4. Plotting of Magnetic fields
Computation of Electric (E) and Magnetic (H) fields (using FEM/FDM packages)
for simple configurations
5. Computation of Electric field intensity, voltage distribution and capacitance.
6. Computation of Magnetic field intensity and inductance
7. Calculation of Skin depth Measurement using field meter
8. Measurement of Electrical Fields
9. Measurement of Magnetic fields
10. Measurement of E and H around practical appliances
TOTAL: 45 PERIODS
and numerical methods (FDM and FEM).
Graphical Representation of fields (using MATLAB)
2. Plotting of vector, divergence and curl fields.
3. Plotting of electric field and equipotential lines
4. Plotting of Magnetic fields
Computation of Electric (E) and Magnetic (H) fields (using FEM/FDM packages)
for simple configurations
5. Computation of Electric field intensity, voltage distribution and capacitance.
6. Computation of Magnetic field intensity and inductance
7. Calculation of Skin depth Measurement using field meter
8. Measurement of Electrical Fields
9. Measurement of Magnetic fields
10. Measurement of E and H around practical appliances
TOTAL: 45 PERIODS
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