electrical cluster syllabus iii

8/8/2019 Electrical Cluster Syllabus III

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BMS COLLEGE OF ENGINEERING, BANGALOREAutonomous College under VTU

Cluster: Electrical Sciences Program: EE/EC/TC/ML/IT Semester: III

L Lecture Hours / week; T- Tutorial Lecture Hours / week; P-Practical Lecture Hours / week.

CIE- Continuous Internal Evaluation; SEE- Semester End Examination (of 3 Hours duration)

*The contact hours for ML

Subject Code Subject Title

Credit Hours/Week Contact

hrs/wk

Marks Page

L T P Total CIE SEE Total

M A 3 I C M A T Engineering Mathematics-III 3 2 0 4 5 50 50 100

E S 3 G C N A L Network Analysis 4 0 0 4 4 50 50 100

E S 3 G C A E C Analog Electronic Circuits 4 0 2 5 6 50 50 100

E S 3 G C D E C Digital Electronics 4 0 2 5 6 50 50 100

E S 3 G C

F T HField Theory (EE/EC/TC/IT)

4 0 0

4

4

50 50 100

F M PFundamentals of Microprocessors

(ML Only)3 0 2 5*

E S 3 G C

M S T Measurement Techniques (EE/IT/ML)

3 0 0 3 3 50 50 100E I M

Electronic Instrumentation and Measurements

(EC/TC) Total 25 28/29*600


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BMS COLLEGE OF ENGINEERING, BANGALORE

Autonomous College under VTU

Cluster: Electrical Sciences Program: EE/EC/TC/ML/IT Semester: IV

Subject Code

Subject Title

Credit Hours/Week Contact

hrs/wk

Marks Page

No.

L T P Total CIE SEE Total

M A 4 I C M A T Engineering Mathematics-IV 3 2 0 4 5 50 50 100

E S 4 G C L I C Op-amps and Linear ICs 4 0 2 5 6 50 50 100

E S 4 G CM P R 8086 Microprocessor (EE/EC/IT/TC)

3 0 2 4 5 50 50 100M C L Microcontrollers (ML Only)

E S 4 G CS A S Signals and Systems (EE/EC/IT/ML) 4 0 0 4 4

50 50 100A S P Analog Signal Processing (TC only) 4 0 0 4 4

E S 4 G C C S T Control Systems 4 0 0 4 4 50 50 100

E S 4 G C H D L Fundamentals of HDL 3 0 2 4 5 50 50 100

Total 25 29 600


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THIRD SEMESTER B.E COURSE - (Common to all branches except CSE / ISE)

MA3ICMAT

Engineering Mathematics - III

UNIT 1

FOURIER SERIES [9 hours]

Infinite series, convergence and divergence of infinite series of positive terms, power series,

periodic function, Dirichlets conditions, statement of Fourier Theorem, Fourier series of

periodic function of period 2 and arbitrary period, half range Fourier series, complex form of

Fourier series, practical harmonic analysis. (7L+2T)

UNIT 2

FOURIER TRANSFORM [9 hours]

Infinite Fourier transform, Fourier Sine and Cosine transforms, properties, Inverse transforms,

Convolution theorem (statement only), Parsevals identities for Fourier transform. Fourier

transforms of the derivatives of a function. (7L+2T)

UNIT 3

PARTIAL DIFFERENTIAL EQUATIONS [12 hours]

Formation of Partial differential equations-elimination of arbitrary constants, elimination of

arbitrary functions. Equations of first order- The linear equation P p + Q q = R (Lagrangespartial differential equation). Method of separation of variables (5L+2T)

APPLICATIONS OF PARTIAL DIFFERENTIAL EQUATIONS

Derivation of one-dimensional heat equation, wave equation, various possible solutions of these

by the method of separation of variables, DAlemberts solution of wave equation. (4L+1T)

UNIT 4

NUMERICAL METHODS [11 hours]

Finite Differences and interpolation: Forward differences, Backward differences.

Interpolation: Newton-Gregory forward interpolation formula, Newton-Gregory backward

interpolation formula, Newtons general interpolation formula, Lagranges interpolationformula, Lagranges inverse interpolation.

Numerical differentiation: Numerical differentiation using Newton-Gregory forward and

backward interpolation formula. (4L+2T)

Numerical integration: Trapezoidal rule, Simpsons 1/3rd rule, Simpsons 3/8th rule, Weddles

rule.


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Solution of algebraic and transcendental equations: Ramanujans method, Newton-Raphson

method, deductions.

Numerical solution of ordinary differential equations: Eulers modified method, Runge-Kutta

method of fourth order. (4L+1T)

UNIT 5

Z TRANSFORMS [11 hours]

Definition, Properties, Transforms of standard functions, Inverse transforms.

APPLICATIONS OF Z -TRANSFORMS

Solution of difference equations using Z- transforms. (4L+2T)

CALCULUS OF VARIATIONS

Variation of function and functional, Eulers equation, variational problem.

APPLICATIONS OF CALCULUS OF VARIATIONS

Geodesics, minimal surface of revolution, hanging chain, Brachistochrone problem.(4L+1T)

TEXT BOOKS:

1. Higher Engineering Mathematics, B.S. Grewal, 40th edition, 2007, Khanna Publishers.

2. Advanced Engineering Mathematics, Erwin Kreyszig, 8th edition, 2007, Wiley-India

3. Introductory methods of Numerical Analysis, S. S. Sastry, 3rd edition, 1999, Prentice-Hallof India.

Unit

No.

Text Book Chapter

No.

Article Number Page Nos.

I B.S. Grewal 10 10.1 to 10.7 429 454

10.10 to 10.11 456 - 463

II B.S. Grewal 22 22.1 to 22.2, 22.4 to 22. 7 836 - 851

III B.S. Grewal 17 17.1 to 17.3, 17.5 632 - 639

18 18.1 to 18.5 657 - 678

IV B.S. Grewal 29 29.1(1) to 29.1(2) 1038-1039


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29.5 (1) to 29.5(2) 1050-1055

29.8 to 29.10 1064-1071

29.12 1075-1083

28 28.2(3) 1011-1016

31 31.1, 31.4 to 31.5, 31.7 1096-1109

IV S.S. Sastry 2 2.6 38 - 43

V B.S. Grewal 23 23.1 to 23.11, 23.15(I), 23.15(II), 23.16 866 - 885

34 34.1 to 34.5 1204-1213

REFERENCE BOOKS:

1. Advanced Modern Engineering Mathematics, Glyn James, 3rd edition, 2004, Pearson

Education.2. Higher Engineering Mathematics, B.V. Ramana, 2007, Tata Mc. Graw Hill.

3. Advanced Engineering Mathematics, P. V. ONeil, 5th

Indian reprint, 2009, Cengagelearning India Pvt. Ltd.

Question Paper Pattern:

1. Each unit consists of one full question.

2. Each full question consists of three or four subdivisions.3. Five full questions to be answered.

4. Internal Choice in Unit 3 and Unit 5


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III SEMESTER ELECTRICAL CLUSTER

ES3GCNAL

Network Analysis

UNIT 1 :

Basic Concepts:Practical sources, Source transformations, Network reduction using Star Delta transformation,

Loop and node analysis With linearly dependent and independent sources for DC and AC networks,

Concepts of super node and super mesh. 08 Hrs

UNIT 2 :

(a)Network Topology: Graph of a network, Concept of tree and co-tree, incidence matrix, tie-set,

tie-set & cut-set schedules, Formulation of equilibrium equations, Principle of duality.

(b)Resonant Circuits: Series and parallel resonance, frequency response of series and Parallelcircuits, Q factor, Bandwidth. 10 HrsUNIT 3 :

Network Theorems :

Superposition, Reciprocity , Millmans Thevinins and Nortons theorems; Maximum Power transfertheorem. 12 HrsUNIT 4 :

Transient behavior and initial conditions:

Behavior of circuit elements under switching condition and their representation, evaluation of initial

and final conditions in RL, RC and RLC circuits

Laplace Transformation & Applications

Review of Laplace transforms, waveform Synthesis, initial and final value theorems, step, ramp and

impulse responses ,convolution theorem, solution of simple R-L,R-C,R-L-C networks for AC and

DC excitations using Laplace transforms. 12 Hrs

UNIT 5 :

Two port network parameters and State Variable analysis:

Definition of z, y, h and transmission parameters, modeling with these parameters, relationship between parameters sets. Writing State equations and solution using Laplace transforms.

10 Hrs

TEXT BOOKS:

1. Network Analysis, M. E. Van Valkenburg, PHI / Pearson Education, 3rd Edition. Reprint

2002.

2. Networks and systems, Roy Choudhury, 2nd edition, 2006 re-print, New Age

International Publications.3. Theory and Problems of Electric Circuits (Schaum Series), 2nd Edition Mc Graw Hill

REFERENCE BOOKS:

1. Engineering Circuit Analysis, Hayt, Kemmerly and Durbin,TMH 6th Edition, 2002

2. Network analysis and Synthesis, Franklin F. Kuo, Wiley

3. Analysis of Linear Systems, David K. Cheng, Narosa Publishing House, 11th reprint,2002

4. Circuits, Bruce Carlson, Thomson Learning, 2000. Reprint 2002


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ES3GCAEC

Analog Electronic Circuits

UNIT 1

Semiconductor Diodes Semiconductor diode, ideal versus practical, resistance levels, diode

equivalent circuits, transition and diffusion capacitance, reverse recovery time, diode

specification sheets, semiconductor diode notation, diode testing.

Diode Applications Introduction, load line analysis, series diode configurations, parallel and

series parallel configurations, AND/OR gates, clippers, clampers, voltage multipliers.

10

hours

UNIT 2

DC biasing of BJTS Introduction, operating point, fixed bias circuit, emitter bias, voltage

divider bias, dc bias with voltage feedback, miscellaneous bias configurations, design operations,transistor switching networks, troubleshooting techniques, PNP transistors, bias stabilization.

BJT AC Analysis Introduction, amplification in the ac domain, BJT transistor modeling, retransistor model, the hybrid equivalent model, CE fixed bias, voltage divider bias, CE emitter

bias, Determining the current gain, Effect of RL and RS, two-port system approach, summarytables, complete hybrid equivalent model , problems on h parameters(only CE configuration)

12hours UNIT 3Power amplifiers Introduction definitions and amplifier types, series fed class A amplifier,

transformer coupled class A amplifier, class B amplifier operation, class B amplifier circuits.Amplifier distortion, Power transistor heat sink, class C and class D amplifiers. Cascaded

systems, Darlington connections. 10 hours

UNIT 4

Feedback and Oscillator Circuits (BJT version only) Feedback concepts, feedback

connection types, practical feedback circuits, feedback amplifier phase and frequency

considerations, oscillator operation, phase shift oscillator, Wein bridge oscillator, tuned oscillatorcircuit, crystal oscillator, unijunction oscillator. 10hoursUNIT 5

BJT frequency response Introduction, logarithms, decibels, general frequency considerations,

low frequency analysis bode plot, BJT low frequency response, miller effect capacitance, BJT

high frequency response.

FETs Introduction, construction and characteristics of JFETs, transfer characteristics,

important relationships, Depletion and Enhancement type MOSFETS. 10 hours

LAB EXPERIMENTS- Clipping, clamping, half wave and full wave rectifiers, RC coupled

amplifiers, Darlington emitter follower, RC phase shift oscillator, crystal oscillator, Hartley and

Colpitts oscillator, voltage series feedback amplifier, Simulation experiments using Multisim/P-Spice.


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Text Book

1. Electronic Devices and Circuit Theory - Robert L.Boylestad and Louis Nashelsky -9th edition - Pearson

Reference Books

1. Integrated Electronics - Jacob Millman and Christos C. Halkias - TMH

2. Electronic Devices and Circuits - David A. Bell - PHI 4th edition


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ES3GCDEC

Digital Electronics

UNIT 1 :Introduction :

Review of Boolean algebra, logic gates.

Simplification of Boolean functions : The Map Method, Two and Three Variable Maps, FourVariable Map, Product of sums simplification, NAND and NOR implementation, Other Two level

implementations, Dont care conditions, The Tabulation Method, Determination of Prime

Implicants, Selection of prime implicants , Concluding Remarks. 10 Hrs

Unit 2 :

Combinational Logic Circuits:

Introduction, Design Procedure, Adders, Subtractors, Code conversion ( binary to gray, BCD to

Excess-3)

,Combinational Logic with MSI and LSI:Introduction, Binary Parallel Adder, Decimal Adder, Magnitude Comparator, Decoders,

Multiplexers. 11 Hrs

Unit 3:

Flip-Flops and Simple Flip Flops Applications:

The Basic Bistable Element, Latches, Timing Considerations, Master Slave Flip-Flops (Pulse-

Triggered Flip-flops), Edge Triggered Flip Flops, Characteristic Equations. 10 Hrs

Unit 4:

Sequential Logic Circuits:

Registers, Counters, Design of Synchronous Counters. 10 Hrs

Unit 5:

Synchronous Sequential circuits:

Structure and Operation of Clocked Synchronous sequential Networks, Analysis of clocked

synchronous sequential networks, Modeling clocked synchronous sequential network behavior, statetable reduction, The state assignment, Completing the design of clocked synchronous sequential

networks. 11 Hrs

LAB experiments: Verification of gates, implementation of Boolean expressions using basicgates and universal gates, code conversion (binary to gray and BCD to Excess-3), adders,

subtracters, multiplexers, demultiplexers, comparators & code converters, Flipflops, counters,

shift registers.

TEXT BOOKS:

1. Digital logic and computer design- Morris Mano, Prentice Hall

2. Digital Principles and Design- Donald Givone, Tata Mc Graw Hill

REFERENCE BOOKS:

1. Fundamental of Logic Design- Charles Roth Jr., Thomas Learning


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2. Digital Logic Applications and principles- John Yarbrough, Pearson Education


ES3GCFTH

Field Theory (EE/EC/TC/IT only)

UNIT-1:

Coulombs Law, Electric Field Intensity (EFI):

Experimental Law, EFI, due to Line Charge , Surface and Volume Charge.

Electric Flux Density (EFD), Gauss Law, Divergence:

Electric Flux Density (EFD), Gauss Law, Application, Divergence and Divergence Theorem.

10 Hrs

UNIT-2:

Energy and Potential:Energy spent in moving charge, Definition of Potential Difference (PD), PD due to Point Charge and

System of Charge, Energy Density

Current and current density:

Current and Current Density, Continuity of Current, Conductor, Properties, and Boundary

Conditions.

10 Hrs

UNIT-3:

Dielectric and capacitance:

Dielectric materials, boundary conditions, capacitance of different configuration.

Poissons and Laplaces equations:

Derivations of Poissons and Laplaces Equations, solution of Poissons and Laplaces for Single

Variables. 10 Hrs

UNIT-4:

Steady Magnetic Field:- Biot-Savart Law, Amperes circuital law, curl, Magnetic Flux, FluxDensity, Scalar and Vector Magnetic Potentials. 10 Hrs

UNIT-5:

Magnetic forces and Inductance: Force on a moving charge, Force on different current element,

Magnetic Boundary Condition, Inductance and Mutual Inductance.

Time varying fields and Maxwells equations: Faradays Law, Displacement Current, Maxwells

Equations in Point and Integral Form, Uniform plane waves, Wave equations , solution of wave

equation, wave propagation through good dielectric, good conductor, skin depth, Poynting Theorem.

12 Hrs

TEXT BOOK:

1. Engineering Electromagnetics, William J Hayt Jr. and John A Buck, Tata McGraw-Hill,

7th Edition, 2006.

REFERENCE BOOKS:


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2. Electromagnetics with Applications, John Krauss and Daniel A Fleisch, McGraw-Hill, 5th

Edition, 1999.


ES3GCFMPFundamentals Of Microprocessors (ML only)

UNIT 1

Architecture and Operation: Introduction to 8085, Microprocessor organization/architecture

& its operation, Microprocessor-based system, Memory interfacing, basic interfacing concepts,

Interfacing I/O devices

Programming: Programming model. Instruction classification, Instruction Format, addressing

modes. Writing Assembly level programs - overview of instruction set, timing diagrams. Data

Transfer, Arithmetic, Logic branch operations.. 08 Hours

UNIT 2Programming Techniques - Looping, Counting and Indexing, 16 bit arithmetic operations,

logic operations, Compare and rotate operations. Counters and Time Delays, Generation of pulsewaveforms. Stacks and subroutines - Conditional CALL and RETURN instructions. Advanced

Subroutine concepts. BCD to Binary and Binary to BCD conversions, BCD to 7 segment

conversion. Binary to ASCII and ASCII code conversion, BCD addition and subtraction,

multiplication and division. 08 Hours

UNIT 3

Memory Interface: Memory and I/O mapping and interfacing concepts.

Interrupts: 8085 vectored interrupts, Restart as software instructions, Additional I/O concepts

and processes. 07 Hours

UNIT 4

Interfacing of peripherals (1/Os) and applications: Interfacing Keyboard and 7 segment

display including multiplexers, The 8279 programmable keyboard / display interface. 8255Programmable Peripheral Interface 08 Hours

UNIT 5

8253 interfacing, 8259 Programmable interrupt controller, DMA and 8257 DMA controller,

Serial communication using 8251, D to A converters, A to D converters and interfacing.

08

Hours

Lab experiments- Data transfer instructions,block move block exchange, sorting an array,

addition, subtraction, multiplication, division, counters logic and rotate instructions, conditional

CALL and RETURN instructions, code conversion

TEXT BOOK:

R. S. Gaonkar, "Microprocessor Architecture, Programming and Application with 8085",Penram Int.3rd Edn.

REFERENCE BOOKS:

Douglas V. Hall, "Microprocessors and digital systems", MIL


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Aditya P. Mathur, /'Introduction to microprocessors", 3rd edition, TMH


ES3GCMST

Measurement Techniques (EE/IT/ML only)

UNIT 1:

Fundamentals of Measurement:

Introduction, Static Characteristics, Dynamic Characteristics, Errors in measurement, Types of

errors, Sources of error.

Electrical Measuring Instruments :

Types of Instruments, Principle of Operation, Constructional features of PMMC instrument, shunts

& multipliers, universal shunt, multi range voltmeters. 07 Hrs

UNIT 2:

Electronic Measuring Instruments:

Need for electronic measuring instruments, True RMS responding voltmeter, Digital voltmeters-Ramp Type, Integrating Type, Successive Approximation Type, Q meter, Digital Multimeter -

Block Diagram description. 08 HrsUNIT 3:

Measurement of Resistance, Inductance & Capacitance:Wheatstones Bridge- Sensitivity analysis, Limitations, Kelvins Double Bridge, Maxwells Bridge,

Schering Bridge, sources & Detectors, Minimization of AC Bridge Errors, Problems. 08 Hrs

UNIT 4 :

Transducers -I:

Classification & Selection, Principle of operation of Thermocouples, Resistance Temperature

Detectors, Thermistors, LVDT, Capacitive Transducers, Piezoelectric Transducers. 08 HrsUNIT 5 :

Transducers -II:

Strain Gauges- Types, Expression for gauge factor, Photosensitive Devices.Display Devices & Recorders : Method of Measuring Amplitude, Phase, Frequency & Period using

CRO. Use of Lissajous Patterns. LCD & LED displays, Strip Chart & X-Y Recorders. Introduction

to Printers. 08 Hrs

TEXT BOOKS:

1. Modern Electronic Instrumentation & Measurement Technique- Albert D.

Helfrick, William D. Cooper, 3/e, Pearson, Prentice Hall .

2. Electronic Instrumentation- H. S. Kalsi, Tata McGraw Hill.

REFERENCE BOOKS:1. A Course in Electrical & Electronic Measurements & Instrumentation- A. K.

Sawhney, 18/e, Dhanpat Rai & Co., New Delhi.

2. Electronic Instrumentation & Measurement- by David A. Bell, 2/e, PHI Publications.


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ES3GCEIM

Electronic Instrumentation And Measurement (EC/TC only)

UNIT 1:

Introduction and Measurement Errors: Introduction, Instrumentation system , Advantages

of electronic measurement, Errors in measurement, Gross errors and systematic errors, Absoluteand relative errors, Static Characteristics., Introduction to Signal conditioning, Computer based

Data Acquisition, virtual instrumentation 8 hoursUNIT 2:

Voltmeters and Multimeters: Introduction, Deflection instrument fundamentals, DC Ammeter,DC Voltmeter, AC Voltmeter, True RMS Voltmeters, peak response Voltmeter DigitalVoltmeters Introduction, DVMs based on V T, V F and Successive approximation

principles, Digital Multi-meters 8 hours

UNIT 3:

Signal Generators. Low frequency signal generator, Function generator, Pulse generator, RF

Signal generator, sweep frequency generator, frequency synthesizer, arbitrary waveformgenerator. Oscilloscopes. Cathode ray tube, Dual trace oscilloscope, Measurements with CRO,

Digital storage oscilloscope, DSO applications, Spectrum Analyzer

8hours

UNIT 4:

Measurement of resistance, inductance and capacitance

Introduction, Voltmeter and ammeter methods, substitution method, Wheatstone bridge, Low

resistance measurement using kelvins bridge, AC bridges, Capacitance Comparison Bridge,

Maxwells bridge, Digital L, C and R measurements, Q meter 8 hours

UNIT 5:

Transducers

Introduction, Strain gauges, RTD, Thermistor, LVDT, capacitive transducer, Thermocouple,Piezoelectric transducer, Photoelectric transducer, Photovoltaic transducer, Semiconductor photo

devices, IC sensor 7 hours

TEXT BOOKS:

1. Electronic Instrumentation and Measurements, David A Bell, PHI / Pearson Education,

2006.Electronic Instrumentation, H. S. Kalsi, TMH, 2004

REFERENCE BOOKS:

Electronics & Electrical measurements, A K Sawhney, Dhanpat Rai & sons, 9th edition


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IV Semester Electrical Cluster (Common to all branches except CSE / ISE / BT)

MA4ICMAT

Engineering Mathematics - IV

UNIT 1

STATISTICS [11 hours]

Curve fitting Fitting a straight line, fitting of a parabola, fitting of curves of the form

, , x b bx

a b a x ae . Correlation, regression. (4L+1T)

PROBABILITY 1

Probability of an event, axiomatic definition, addition theorem, conditional probability,multiplication theorem, Bayes theorem. (4L+2T)UNIT 2

PROBABILITY 2 [9 hours]Probability distributions: Random variables, Discrete probability distributions, continuous

probability distributions, Some standard distributions: Binomial distribution, Poisson

distribution, exponential distribution, normal distribution. (7L+2T)

UNIT 3

COMPLEX ANALYSIS 1 [10 hours]

Function of a complex variable, Analytic functions, Cauchy-Riemann equations, construction of

analytic functions, Cauchy-Reimann equations in Polar form.

APPLICATION TO FLOW PROBLEMS

Complex potential, velocity potential, equipotential lines, stream functions, stream lines.

Transformations-2

,

z

w z w e= = and ( )

2

0

a

w z zz

= + , Bilinear transformations. (8L+2T)

UNIT 4

COMPLEX ANALYSIS 2

[12 hours]

Complex integration-Cauchys theorem, Cauchys integral formula, Taylors and Laurents

series, Singular points, poles, residues, the residue theorem.

(5L+2T)

SERIES SOLUTION OF DIFFERENTIAL EQUATIONS

Series solution-Frobenius method, series solution of Bessels differential equation leading to

Bessel function of first kind, equations reducible to Bessels differential equation, series solutionof Legendres differential equation leading to Legendre polynomials, Rodrigues formula.

(4L+1T)

UNIT 5

OPTIMIZATION

[10 hours]

Linear programming, mathematical formulation of linear programming problem (LPP), graphicalmethod, simplex method, artificial variable technique- M method, two phase method. (7L+3T)


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TEXT BOOKS:

1. Higher Engineering Mathematics, B.S. Grewal, 40th edition, 2007, Khanna Publishers.

2. Advanced Engineering Mathematics, Erwin Kreyszig, 8th edition, 2007, Wiley-India

Unit

No.

Text Book Chapter

No.

Article Number Page Nos.

I B.S. Grewal 24 24.1, 24.4 to 24.6 886 899

25 25.12 to 25.14 924 932

935 -936

26 26.2 to 26.6 938 - 952

II B.S. Grewal 26 26.7 to 26.10(2), 26.14 to 26.16,26.19(6)

952 - 981

III B.S. Grewal 20 20.1 to 20.7, 20.8(4), 20.9 to 20.10 738 - 760

IV B.S. Grewal 20 20.12 to 20.14, 20.16 (2) to 20.19 762 - 784

16 16.1 to 16.5, 16.8, 16.13 to 16.14 591- 617

V B.S. Grewal 33 33.1 to 33.9(1) 1144

1172

1176-1177

REFERENCE BOOKS:

1. Advanced Modern Engineering Mathematics, Glyn James, 3rd edition, 2004, Pearson

Education.

2. Higher Engineering Mathematics, B.V. Ramana, 2007, Tata Mc. Graw Hill.

3. Advanced Engineering Mathematics, P. V. O Neil, 5th Indian reprint, 2009, Cengage

learning India Pvt. Ltd.


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Question Paper Pattern

1. Each unit consists of one full question.2. Each full question consists of three or four subdivisions.

3. Five full questions to be answered.

4. Internal Choice in Unit 2 and Unit 4


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IV Semester Electrical Cluster

ES4GCLIC

OP AMPS and Linear ICS

UNIT 1:

OPERATIONAL AMPLIFIER FUNDAMENTALS: Operational Amplifier Description,

basic operational Amplifier circuit, input and output voltage, common mode and supply

rejection, offset voltages and currents, input and output impedances, slew rate and Frequencylimitations.

.

OPAMPS AS DC AMPLIFIERS: Biasing operational :Amplifiers, Direct coupled voltage

followers, Direct coupled non-inverting amplifiers, Direct coupled inverting amplifiers, summingamplifiers, Difference amplifiers. 11 Hrs

UNIT 2 :

DIFFERENTIATING AND INTEGRATING CIRCUITS: Differentiating circuit,

Differentiator Design, Differentiating circuit Performance, Integrating Circuit, Integrator Design,

Integrating Circuit performance

SIGNAL PROCESSING CIRCUITS : Precision Half wave and Full wave Rectifiers, Limiting

Circuits, Clamping circuits, peak Detectors, sample and hold circuit 11 Hrs

UNIT 3 :

OP-AMP NON LINEAR CIRCUITS: op-amp and switching circuits, crossing detectors,

inverting and non-inverting Schmitt trigger circuits, Astable and Monostable Multivibrator.

SIGNAL GENERATORS: Triangular/rectangular wave generator , waveform GeneratorDesign, phase shift oscillator, oscillator amplitude stabilization, wien bridge oscillator, Signal

Generator output control. 10 Hrs

UNIT 4 :

ACTIVE FILTERS: All pass phase shifting circuits, 1st order low:pass active filter, 2nd orderlow pass filter, 1st & 2nd order high pass filter

VOLTAGE REGULATORS: Introduction, Series Op-Amp Regulator, IC voltage Regulators,723 General purpose Regulator. 10 Hrs

UNIT 5 :

555 TIMER: Introduction, Description of Functional Diagram, Monostable and Astable

Operation, Schmitt trigger.


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A/D AND D/A CONVERTERS: Introduction, Basic DAC Techniques, A:D Converters,

DAC/ADC Specifications.

10 Hrs

LAB EXPERIMENTS:

Inverting amplifier, non:inverting amplifier, summing amplifier and voltage follower, precision

halfwave and full wave rectifier, limiting circuits, clamping circuits, peak detectors, sample andhold circuits, differentiator and integrator, Schmitt trigger and zero crossing detector, Wien

bridge oscillator, first order low:pass and high pass filter, IC 723 low voltage and high voltage

regulator Simulation experiments using Labview/PSPICE.

TEXT BOOKS:

1. Operational Amplifiers and Linear ICs : David A.Bell, 2nd ed, PHI/Pearson, 2004.

2. Linear Integrated circuits: D.Roy Choudhury and Shail B.Jain,2nd ed, Reprint 2006, New

Age International.

REFERENCE BOOK:

1. Op Amps and Linear Integrated Circuits: Ramakanth A.Gayakwad,4th ed,PHI


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IV SEMESTER ELECTRICAL CLUSTER

ES4GCMPR

8086 Microprocessor (EE/EC/TC/IT)

UNIT 1Introduction, Microprocessor based computer system, Architecture of 8086 Microprocessor, Pin

functions, Clock generator, Minimum /Maximum mode of operation. 8 HrsUNIT 2

Read /Write Timing diagrams, Assembly level programming of 8086, 8086 instruction set,

addressing modes. Assembler directives, Programming examples. 8 HrsUNIT 3

Stacks, Procedures and Interrupts. Interfacing 8086 with Memory devices. 8 Hrs

UNIT 4

Interfacing 8086 with I/O devices. 8255 PPI device, modes of operation. Interfacing. Keyboard,

display, ADC, DAC, Stepper motor and Printer interfacing using 8255. 8 Hrs

UNIT 5Programmable Interval Timer modes of operation of 8253 and interfacing. 8087 Numeric data

processor and interfacing, 8087 Data types. 7 Hrs

LAB Experiments

Data and address transfer operations, unsigned and signed arithmetic operations using

instructions for add/sub/mul/div, logical operations, linear search and sorting, code conversionprograms using procedures, interfacing I/O devices like DSC, stepper motors, Keyboard, 7

segment display to 8086 using 8255 PPI, realization of ALU, Counters and multiplexer using

8086

TEXTBOOKS:1. Advanced Microprocessor and Peripherals- A.K.Ray and K.M. Bhurchandi, Tata

McGraw Hill.

1. Microcomputer systems 8086/8088 family, Architecture, Programming and

Design - Yu-Cheng Liu & Glenn A Gibson, 2nd ed, July 2003, PHI

REFERENCE BOOKS:

1. Microprocessor and Interfacing, Programming & Hardware- Douglas V Hall,

2nd ed, TMH

2. Microprocessor Architecture, Programming and Applications with the 8085-

Ramesh S Gaonkar, 4th ed, Penram International.


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ES4GCMCL

Microcontrollers (ML only)

UNIT 1

INTRODUCTION TO MICROCONTROLLERS:Microprocessors and microcontroller. Introduction,Difference between Microprocessors and

Microcontrollers, A. RISC & CISC CPU Architectures, Harvard & Von-Neumann CPU

architecture. Embedded Electronic Systems and Microcontrollers, comparison of Differentmicrocontrollers and applications.

The 8051 Architecture: Introduction, 8051 Microcontroller Hardware, Input / Output Pins,

Ports and Circuits, External Memory. 8 Hrs

UNIT 2

ASSEMBLY LANGUAGE PROGRAMMING IN 8051

Addressing Modes and Instruction set: Introduction, Addressing modes, Data transfer

instructions, Example Problems, Arithmetic instructions, Logical instructions, Example

Problems, JUMP and CALL Program range, Jumps, calls and Subroutines, Returns, ExampleProblems . 8 HrsUNIT 3

EMBEDDED C PROGRAMMING :

8051 programming in C: Data types and time delays in 8051 C, I/O programming, logic

operations, data conversion programs, accessing code ROM space, data serialization.

Timer / Counter Programming in 8051: Counters and timers programming 8051 Timers,Counter Programming, programming timers 0 and 1 in 8051 C. 8hrsUNIT 4

8051 Serial Communication: Basics of Serial Communication- Serial data input/output, 8051connections to RS-232, 8051 Serial communication Programming,

Interrupts Programming:, 8051 Interrupts, Programming Timer Interrupts, Programming

External Hardware Interrupts, Programming the Serial Communication Interrupts, Interruptprogramming in C. 8 hrs

UNIT 5

8051 INTERFACING AND APPLICATIONS:

Interfacing 8051 to LCD, Keyboard, DAC, ADC, Stepper motor, DC motor interfacing and

PWM. 07 Hrs

LABORATORY EXPERIMENTS:

A. Data Transfer , Logical-Byte/Bit manipulations ,Jump and Subroutine Calls using Assembly.

B. Interfacing: Counters and generate delay using timers, LCD Display, Stepper motor controlusing interrupt, Serial transmission/Receiving of Number of characters using serial interrupt ,

Temperature Controller interface, Elevator interface and & segment interface.

The Experiments will be implemented using Keil software with Embedded IDE. For

interfacing 8051 target board is used.

TEXT BOOKS:


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1. The 8051 Microcontroller Architecture, Programming & Applications, Kenneth J.

Ayala 2e, Penram International, 1996 / Thomson Learning 2005

2.The 8051 Microcontroller and Embedded Systems using assembly and C,

Muhammad Ali Mazidi and Janice Gillespie Mazidi and Rollin D. McKinlay; PHI, 2006 /

Pearson, 2006

REFERENCE BOOKS:

1.Programming and Customizing the 8051 Microcontroller, Predko, TMH

2.Microcontrollers: Architecture, Programming, Interfacing and System Design, RajKamal, Pearson Education, 2005

3. PIC Microcontrollers, J.B. Peatman, PHI, 2006


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ES4GCSAS

Signals And Systems (EE/EC/IT/ML)

UNIT 1:INTRODUCTION: Definitions of a signal and a system, classification of signals, basicOperations on signals, elementary signals, Systems viewed as Interconnections of operations,

properties of systems. 10 Hrs

UNIT 2:

TIME-DOMAIN REPRESENTATIONS FOR LTI SYSTEMS: Convolution, impulse

response representation, Convolution Sum and Convolution Integral. Properties of impulseresponse representation, Differential and difference equation Representations, Block diagram

representations. 12 Hrs

UNIT 3:

FOURIER REPRESENTATION FOR SIGNALS - 1 : Introduction, Discrete time andcontinuous time Fourier series (derivation of series excluded) and their properties .

FOURIER REPRESENTATION FOR SIGNALS 2: Discrete and continuous Fouriertransforms(derivations of transforms are excluded) and their properties. 12 Hrs

UNIT 4:

APPLICATIONS OF FOURIER REPRESENTATIONS: Introduction, Frequency response

of LTI systems, Fourier transform representation of periodic signals, Fourier transform

representation of discrete time signals. 8Hrs

UNIT 5:

Z-TRANSFORMS 1: Introduction, Z transform, properties of ROC, properties of Z

transforms,inversion of Ztransforms.

Z-TRANSFORMS 2: Transform analysis of LTI Systems, unilateral Z- Transform and itsapplication to solve difference equations. 10 Hrs

TEXT BOOK:

Simon Haykin and Barry Van Veen Signals and Systems, John Wiley & Sons, 2001.Reprint

2002

REFERENCE BOOKS:


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1. Alan V Oppenheim, Alan S, Willsky and A Hamid Nawab, Signals and Systems PearsonEducation Asia / PHI, 2nd edition, 1997. Indian Reprint 2002

2. H. P Hsu, R. Ranjan, Signals and Systems, Schams outlines, TMH, 2006

3. B. P. Lathi, Linear Systems and Signals, Oxford University Press, 2005

4. Ganesh Rao and Satish Tunga, Signals and Systems, Sanguine Technical Publishers, 2004


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ES4GCASP

Analog Signal Processing

UNIT 1

INTRODUCTION

Signal definition; signal classification; signal transformation: independent, dependent variable;elementary signals; transformation of elementary signals. System definition; system

classification; the Linear Time Invariant (LTI) system; properties of the LTI system.

11

hours

UNIT 2

TIME-DOMAIN REPRESENTATION & ANALYSIS OF LTI SYSTEMS Impulse

response; the convolution integral; methods of evaluating the convolution integral; Properties ofimpulse response. The constant coefficient differential equation; Block diagram representation;

State-variable description. 11 hours

UNIT 3

FREQEUNCY-DOMAIN REPRESENTATION OF CONTINUOUS TIME SIGNALSFourier transform of continuous time non-periodic signals; the frequency response; properties of

Fourier transform. Fourier series of continuous time periodic signals; the spectrum of theperiodic signal, Fourier transform of the periodic signal. 10 hours

UNIT 4

REPRESENTATION OF LTI SYSTEMS

Time domain representation: impulse response; differential equation; block diagram; state-spacedescription.

Transform domain representation: Laplace transform; pole-zero plot.

Frequency domain representation: frequency response;Relating all above representations; to obtain different representations for a given passive (R-L-C)

circuit.

Practical measurement of impulse response, step response, frequency response. To test a blackbox for LTI. 10 hours

UNIT 5

ANALOG SYSTEMS

Condition for Distortion-less transmission; definition of equalizer.

Ideal filters characteristics;

Design of practical passive filters: LP, HP, BP, BE, Notch

Design of LP Butterworth & Chebychev filters. Frequency transformation for LP to HP, BP, BP,BE.

Op-AMP realization of a given filter. 10 hours

Text Book:

1. Signals & Systems, Simon Haykin and Barry Van Veen, John Wily and Sons

Reference Books:

1. Signals & Systems, Allan V Oppenheim, Alan S Willsky, and A Hamid Nawab,

Pearson Education Asia/ PHI

2. Signals and Systems, Schaums Outline series3. Linear systems and signals, B P Lathi, Oxford University Press


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ES4GCCST

Control Systems

UNIT-1

INTRODUCTION: Examples of Control Systems, open loop vs Closed loop Systems,

Classifications of Control Systems.Mathematical Modeling of Linear Systems: Transfer functions, Mechanical Systems, Analogous

Systems, Block diagram, Signal Flow graph (excluding gear trains lever) 12 HrsUNIT-2

TIME RESPONSE ANALYSIS OF CONTROL SYSTEMS : Step response of first order,second order systems, response specification , steady state error and error constants 10 Hrs

UNIT-3STABILITY ANALYSIS: Concept of stability, RH criterion, applications of RH criterion with

limitations, Nyquist plot, Polar plots, Stability Analysis using Nyquist criterion 10 Hrs

UNIT-4

ROOT LOCUS TECHNIQUE: Introduction to root locus concepts, Construction rules, Analysis of

stability by root locus plot 10 Hrs

UNIT-5

FREQUENCY RESPONSE ANALYSIS: Bode plots, Relative stability, Frequency domain

specification. 10 Hrs

TEXT BOOKS:

1. Control Engineering by Nagrath & Gopal, New Age International Publishers

REFERENCES:

1. Modern control Engineering- Ogata, Prentice Hall

2. Automatic Control Systems- B.C Kuo, John Wiley and Sons


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ES4GCHDL

Fundamentals of HDL

UNIT-1

INTRODUCTION:

Why HDL? , A Brief History of HDL, Structure of HDL Module, Operators, Data types, Types ofDescriptions, simulation and synthesis, Brief comparison of VHDL and Verilog. 7 Hrs

UNIT-2

DATA-FLOW DESCRIPTIONS:

Highlights of Data-Flow Descriptions, Structure of Data-Flow Description, Data Type Vectors.

Behavioral Descriptions: Behavioral Description highlights, structure of HDL behavioral

Description, The VHDL variable Assignment Statement, sequential statements. 8 Hrs

UNIT-3

STRUCTURAL DESCRIPTIONS:

Highlights of structural Description, Organization of the structural Descriptions, Binding, state

Machines, Generate, Generic, and Parameter statements. 8 Hrs

UNIT-4PROCEDURES AND FUNCTIONS: Procedures, Tasks, and Functions: Highlights of Procedures,

tasks, and Functions, Procedures and tasks, Functions. Advanced HDL Descriptions: FileProcessing, Examples of File Processing. 8 Hrs

UNIT-5

SYNTHESIS BASICS: Highlights of Synthesis, Synthesis information from Entity and Module,

Mapping Process and Always in the Hardware Domain. 8 Hrs

LAB Experiments

Verification of combinational logic circuits, sequential circuits using data flow and sequential

descriptions & structural descriptions. Interfacing experiments : stepper motor, dc motor, relay,

waveform generation.

TEXT BOOKS:

1. HDL Programming (VHDL and Verilog)- Nazeih M.Botros- Dreamtech Press(Available through John Wiley India and Thomson Learning), 2006 Edition

REFERENCE BOOKS:

1. Verilog HDL -Samir Palnitkar, Pearson Education

2. VHDL -Douglas Perry,TMH3. Fundamentals of Digital Logic with Verilog Design-Stephen Brown, TMH

4. Circuit Design with VHDL-Volnei A.Pedroni, PHI

electrical cluster syllabus iii

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