syllabus for the academic year 2019 - 2020 - ssit.edu.in sem syllabus.pdf · syllabus for the...

SRI SIDDHARTHA INSTITUTE OF TECHNOLOGY- TUMAKURU (A constituent College of Siddhartha Academy of Higher Education, Tumakuru)

Department of Electrical & Electronics Engineering.

Syllabus for the Academic Year – 2019 - 2020

Department: Electrical & Electronics Engineering Semester: III

Subject Name: ENGINEERING MATHEMATICS-III

INTEGRAL TRANSFORMS AND NUMERICAL TECHNIQUE

Subject Code: BS-18MA301 L-T-P-C: 4-0-0-4

Course Objectives:

Course Outcomes

Sl.No Course Objectives

1 Introduce the concept of Laplace Transform and problems

on periodic function.

2 Introduce the concept of solving Linear Differential

Equations by the method of Laplace Transform.

3 Represent a periodic function as a Fourier Series and

Compute the Fourier coefficients numerically.

4

To develop the proficiency in numerical techniques and

solving ordinary Differential Equations arising in

engineering applications.

Course outcome

Descriptions

CO1 Understand the basic concepts of Fourier series and Integral transforms.

CO2

Apply Laplace transform and inverse Laplace transform in solving

differential equation and integral equation arising in network analysis,

control system and others fields of engineering.

CO3

Demonstrate Fourier series and Integral transforms to study behavior of

periodic functions, discrete/continuous functions arising in single and

system, field theory and system communication.

CO4 Analyze and apply single step and multistep numerical methods in

engineering problems.



UNIT Description Hours

I

Laplace Transforms

Definition, Laplace transforms of elementary functions and problems, periodic

functions, unit step functions, inverse Laplace transforms-problems. Solution

of linear differential equations by Laplace transform method.

10

II

Fourier Series Periodic functions, Dirichlet’s conditions. Fourier series of periodic functions

with period 2 and with arbitrary period .2l Fourier series of even and odd

functions. Half range Fourier series. Practical harmonic analysis.

Applications- frequency spectrum and examples from engineering field.

12

III

Fourier Transforms

Infinite Fourier transforms. Fourier Sine and Cosine transforms. Inverse

Fourier transforms, and simple problems.

Z-Transforms: Difference equations, basic definitions, Z-transform-

definition, Standard Z-transforms, Damping rule, Shifting rule, Initial value

and Final value theorems(without proofs) and problems, Inverse Z-transform,

Simple problems.

Applications-solutions of difference equations using Z-transforms.

10

IV

Numerical solution of ordinary differential equations of first order and

first degree- Taylor’s series method, Modified Euler’s method, Runge- Kutta

method of fourth order, Milne’s and Adams-Bash forth Predictor and

Corrector methods (No derivation of formulae).

10

V

Numerical solution of second order ODE: Runge- Kutta method and

Milne’s Predictor and Corrector method (No derivation of formulae).

Numerical Integration: Trapezoidal rule, Simpson’s thrd 83,31 rule,

Weddle’s rule, Romberg integration, Newton-cotes integration (without

proof)-problems.

10

Question paper Pattern:

1. The Question paper consists of 10 Questions (20 Marks each)

2. Two main Questions to be set in each unit and student will have a choice to select one of

them for answering.

Use Bloom’s taxonomy while preparing Question Paper.



Text Books:

Sl No

Text Book title Author Volume and Year of Edition

1 Higher Engineering Mathematics B.S. Grewal 43

rd Ed., 2015.

2 Advanced Engineering Mathematics E. Kreyszig 10

th Ed., 2015.

Reference Book:

Sl No


1 A text book of Engineering Mathematics N.P.Bali and Manish

Goyal

7th

Ed.,2010.

2 Higher Engineering Mathematics B.V.Ramana 2006

3 Higher Engineering Mathematics H.K.Das and

Er.Rajnish Verma

1st edition 2011




Department: MATHEMATICS Semester: III

Subject Name: FUNDAMENTAL MATHEMATICS

Subject Code: MA-18DIP300 L-T-P-C: 3 – 0 – 0 - 3

Course Objectives:

Course Outcomes

After the successful completion of the course, the students are able

Course Objectives

The purpose of this course is to make students to develop a

basic Mathematical knowledge required for higher

semesters with few examples of its engineering

applications.

Course outcome

Descriptions

CO1 Understanding the basic concept of calculus like differentiation and

integration.

CO2 Understanding the concepts of partial differentiation and differential

equations arising in a variety of engineering applications.

CO3 Understanding the practical importance of Laplace transforms and their

utility in network analysis, circuit theory and convection problems.

CO4 To apply the concept of probability in problem solving and relate the

solutions to the various engineering streams.




I

Differential Calculus: nth derivatives of some standard functions (without proof), Leibnitz’s Theorem (statement), Polar curves–angle between the radius vector and the tangent pedal equation-Problems. Taylor’s and Maclaurin’s series expansions of one variable - Illustrative examples.

Partial Differentiation: Partial derivatives, Euler’s theorem for homogeneous

functions of two variables. Total derivatives, Total differential, differentiation of

composite and implicit function, Jacobians.

8

II

Integral Calculus: Statement of reduction formulae forsinnx, cos

nx, and sin

mx

cosnx and evaluation of these with standard limits-Examples. Double and triple

integrals-Simple examples.

8

III

Ordinary differential equations (ODE’s): Introduction-solutions of first order

and first degree differential equations, exact, linear differential equations. Higher order ODE’s: Linear differential equations of second and higher order

equations with constant coefficients. Homogeneous /non-homogeneous

equations. Solutions of initial value problems.

9

IV

Laplace transforms: Definition, Laplace transforms of elementary functions. Properties, Transforms of derivatives and integrals, transforms of periodic function and unit step function-Problems only. Inverse Laplace Transforms.

8

V

Probability: Introduction, Sample space and events. Axioms of probability.

Addition and multiplication theorems, Conditional probability-illustrative

examples. Baye’s theorem-problems.

7




them for answering.




Text Books:

Sl No


1 Higher Engineering Mathematics

B.S.Grewal 43rd

Ed.,2015

2 Advanced Engineering Mathematics E.Kreyszig 10

th Ed.,2015

Reference Book:

Sl No


1 Advanced Engineering Mathematics Peter V. O’Neil 7th

Edition

2 Advanced Modern Engineering

Mathematics

Glyn James 4th

Edition, 2011

3 Higher Engineering Mathematics B.V.Ramana 2006





Subject Name: ANALOG ELECTRONIC CIRCUITS

Subject Code: PC-18EE302 L-T-P-C: 2-0-2-3

Course Objectives:

Course Outcomes


1 To understand the concept of Diode Circuits, Biasing and

stabilization, Amplifiers and Oscillators

2 To apply the concept of clipping/clamping, operating point,

amplifier efficiency & stability of oscillator.

3 To design & analyze the rectifier circuits, Transistor

circuits, Amplifiers and Oscillators

4 To evaluate the performance of Rectifiers, Amplifiers and

Oscillators

Course outcome

Descriptions

CO1 Understand the concept of Diode Circuits, Biasing and stabilization,

Amplifiers and Oscillators

CO2 Apply the concept of clipping/clamping, operating point, amplifier

efficiency & stability of oscillator.

CO3 Design & analyze the rectifier circuits, Transistor circuits, Amplifiers and

Oscillators

CO4 Evaluate the performance of Rectifiers, Amplifiers and Oscillators




I Diode Circuits: Introduction, Diode equivalent circuits/model, clipping and

clamping circuits, full wave rectifier without and with C filter. 05

II

Transistor Biasing: Operating point, analysis and design of fixed bias circuit,

self bias circuit, Emitter stabilized bias circuit, voltage divider bias circuit, DC

bias with voltage feedback.

05

III

Multistage Amplifiers: Classification of amplifiers, Distortion in amplifiers,

frequency response of an amplifier, RC Coupled amplifier, Cascade and

cascade connections, Darlington circuits.

05

IV

Power Amplifiers: Introduction, Classification, Class A Power Amplifiers,

series fed Class A power amplifier-distortion, efficiency. Transformer coupled

Class A push-pull amplifiers: distortion, efficiency. Class B push-pull power

amplifier-distortion, Efficiency.

06

V Oscillators: Oscillator operation, phase-shift oscillator, Wein-bridge

oscillator, Tuned oscillator, Crystal oscillator. 05

LABORATORY EXPERIMENTS

1 Diode Clipping Circuits

2 Diode Clamping Circuits

3 Half wave Rectifier Circuit without and with filter

4 Full wave Rectifier Circuit without and with filter

5 BJT RC Coupled Amplifier.

6 Class B Push-Pull Amplifier

7 BJT -RC phase shift Oscillator

8 BJT –Hartley Oscillator

9 BJT –Colpitts Oscillator.

10 BJT -Crystal Oscillator




them for answering.


Text Books:



Sl No


1 Electronic Devices and Circuits Millman, Halkias 4th Edition, 2015

2 Electronic Devices and Circuits David A Bell 5th Edition, 2008

Reference Book:

Sl No


1 Fundamentals of Analog Circuits Thomas L Floyd 2nd Edition, 2012

2 Electronic Devices and Circuits S.Salivahanan,

N.Suresh

3rd Edition, 2013

3 A Text Book of Electrical Technology,

Electronic Devices and Circuits

B.L. Theraja,

A.K. Theraja,

Reprint, 2013





Subject Name: ELECTRIC CIRCUIT ANALYSIS


Course Objectives:

Course Outcomes


1 To Develop the Analytical Skills to solve electrical Networks

2 To lay strong foundation in Mathematical and Electrical

Engineering fundamentals

3 To obtain the solution of Networks for steady state and transient

state conditions.

4

To apply different techniques/theorems to solve the circuit

problems.

Course outcome

Descriptions

CO1 Understanding the concept of circuit analysis using different techniques.

CO2 Applying different techniques/theorems to solve the circuit problems.

CO3 Analyze the circuit, for different condition using known methods.

CO4 Evaluate the electrical quantities for the circuit.




I

Basic Concepts: Practical sources, Source transformations, Network reduction

using Star-Delta transformation, Loop and node analysis with linearly

dependent and independent sources.

08

II

Network Topology: Graph of a network, Concept of tree and co-tree,

Incidence matrix, tie –set & cut- set schedule, Formulation of equilibrium

equations for resistive networks, Principle of duality.

Resonant Circuits: Series and parallel resonance, Frequency response of series

and parallel circuits, Q factor, Bandwidth.

08

III

Network Theorems: Superposition, Reciprocity, Millman's, Thevenin's and

Norton's theorem, Maximum Power transfer theorem (independent sources

only).

08

IV

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.

08

V

Two port network parameters: Definition of z, y, h and transmission

parameters, modeling with these parameters, relationship between parameters

sets, Problems

08




them for answering.




Text Books:

Sl No


1 Network Analysis M.E. VanValkenburg 3

rd Edition, Reprint

2002

2 Network and systems Roy Choudhury 2

nd edition, 2006

reprint, New Age

3 Theory and Problems of Electric

Circuits

Schaum`s Series 2nd

Edition

Reference Book:

Sl No


1 Engineering Circuit Analysis Hayt, Kemmerly and

Durbin

6th

Edition, 2002

2 Network analysis and Synthesis F ranklin F. Kuo 2

nd Edition

3 Network Theory: Analysis and Synthesis Smarajit Ghosh PHI, 2005

4 Fundamentals of Electric Circuits Charles K, Alexander

and Mathew NO

Sadiku

3rd

Edition, TMH





Subject Name: DC MACHINES AND SYNCHRONOUS MACHINES


Course Objectives:

Course Outcomes


1 To Understand the concepts of excitation, characteristics,

Armature reaction and Commutation of DC Generator.

2 Have the Knowledge on Testing of DC motors and

methods of speed control.

3 To Analyzing the constructional details of synchronous machines

and salient pole theory.

4 To Evaluation of performance of synchronous machine

with the knowledge of their operating characteristics.

Course outcome

Descriptions

CO1 Understand the concepts of excitation, characteristics, Armature reaction

and Commutation of DC Generator.

CO2 Knowledge on Testing of DC motors and methods of speed control.

CO3 Analyzing the constructional details of synchronous machines and salient pole

theory.

CO4 Evaluation of performance of synchronous machine with the knowledge of their

operating characteristics.




I

DC Generator: Types of excitation, No load & Load characteristics,

Armature reaction and its effects, Commutation, use of Inter poles and

compensating winding.

08

II

DC Motors:

(A) Characteristics of shunt, series, compound motors & their applications.

Speed control of shunt and series motors. Permanent magnet DC motor.

(B) Testing of DC machine: Losses & efficiency, direct loading, Swinburne’s

test and Hopkinson’s test.

08

III

Synchronous Machines: Basic Principles of Operation, Construction of Salient &

Non - Salient Pole Synchronous Machines, Generated Emf in a Concentrated

Winding, Effect of Distribution of Winding,

Salient Pole Synchronous Machines: Two Reaction Theory, Power- Angle

Diagram, Reluctance Power, Slip Test.

08

IV

Regulation by EMF, MMF and ZPF methods, Synchronizing to infinite bus

bars, parallel operation of alternators. 08

V

(A)Operating characteristics of synchronous Machine: Power-Angle

Characteristics, excluding armature resistance, operation at constant load with

variable excitation and vice versa for generating and motoring mode. V and Ʌ

curves of synchronous machines.

(B) Synchronous condenser, Power flow equation including armature

resistance, capability curves of synchronous generators. Hunting in

synchronous machines, damper windings, starting methods of synchronous

motor.

08




them for answering.




Text Books:

Sl No


1 Principles of Electrical Machines

V.K. Mehta & Rohith

Mehta

Reference Book:

Sl No


1 Electric Machines I J Nagrath and D P

Kothari

3rd

edition

2 Electric Machines, Ashfaq Hussian

3 Electrical Machinery Bhimbra 5

th edition





Subject Name: ELECTRICAL MEASUREMENTS AND MEASURING

INSTRUMENTS


Course Objectives :

Course Outcomes


1 To Provide detailed study of resistance, inductance and

capacitance measuring methods.

2 To provide elaborate discussion about extension of

instrument ranges.

3 To have an adequate knowledge in the measurement of

power and its related parameters.

4 To provide detailed study of analog, digital measuring

instruments and transducers.

Course outcome

Descriptions

CO1

Understanding the concept of transducers & measuring electrical

quantities.

CO2

Applying the measurement techniques to measure circuit parameters and

electrical quantities

CO3 Apply knowledge to select proper measuring instruments.

CO4 Design the proper instruments for measuring the electrical quantities.




I

Measurement of Impedance : Classification of resistance ,Wheatstone

bridge- sensitivity analysis, limitations, Kelvin’s double bridge, Megger,

Measurement of earth resistance by fall of potential method, Andersons

bridge, Maxwell’s bridge, Schering’s bridge, Sources and detectors

09

II

Extension of Instrument ranges- shunts and multipliers, construction and

theory of instrument transformers, equations of ratio and phase angle errors of

C.T and P. T (derivation excluded), illustrative examples 08

III

Measurement of Power & Energy related Parameters: Construction and

operation – Dynamometer type wattmeter, LPF wattmeter, Digital energy

meter, Maximum demand indicator, Tri-vector meter, single phase power

factor meter(electrodynamometer type), Weston frequency meter and phase

sequence indicators.

08

IV

Electronic Instruments- Introduction, True RMS responding voltmeter,

Electronic multimeters, Digital Voltmeters – Ramp type, Successive

approximation, LCR meter, Dual trace Oscilloscope- introduction, basic

principle, block diagram, Dual beam and dual trace CROs.

08

V

Transducers - Introduction, electrical transducers, selection, resistive

transducers, strain gauges, expression for gauge factor, thermocouples, LVDT,

inductive transducers, capacitive transducers, Piezoelectric transducers, photo

electric transducers, Hall effect sensors, introduction to data acquisition system

07




them for answering.




Text Books:

Sl No


1 A course in Electrical and Electronic

Measurements and Instrumentation

A K Sawhney 2009

Reference Book:

Sl No


1 Electrical and Electronics Measurements

and instrumentation

J B Guptha 10th edition

2 Principles of measuring systems John P Beatly 3rd edition





Subject Name: ELECTRICAL POWER GENERATION TECHNOLOGY

Subject Code: ES-18EE306 L-T-P-C: 3-0-0-3

Course Objectives:

Course Outcomes


1 Knowledge of various forms of electrical energy and its

utilization for both domestic & industrial applications

2 To understand the various methods of electrical power

generation using non-conventional energy sources

3 To understand the various methods of electrical power

generation using conventional energy sources

4 To analyze the environmental and cost economics of using

various conventional and non-conventional energy sources

Course outcome

Descriptions

CO1 Understanding the concept of energy sources and power generation

techniques.

CO2 Interpret the different methods of power generation.

CO3

Discriminate with different methods of power generations and its

implications.

CO4 Evaluate the economic aspects of power generations.




I

Introduction to energy sources- Conventional energy sources-nuclear,

thermal, diesel, gas. Non-conventional energy sources- solar, wind, ocean,

tidal, geothermal. Energy scenario.

Solar Power Generation- Solar cell principle, basic Photovoltaic power plant,

applications of solar PV systems, advantages & disadvantages of PV energy

conversion, Solar pond electric power plant.

08

II

Wind and Biogas power generation- Basic components of wind energy

conversion system, classification of WECS- Horizontal axis & Vertical axis

machines, advantages & disadvantages of WECS, Biogas power generation,

types, advantages and disadvantages.

Ocean & Tidal power generation- Basic principle of ocean thermal energy

conversion, open cycle, closed cycle & hybrid cycle OTEC system, Tidal

power plants- Single basin & double basin arrangements, advantages &

limitations of tidal power generation.

08

III

Hydro-Electric Power Plant- Selection of site, classification of hydro electric

plants, general arrangement and operation of hydro electric plant.

Thermal Power Plant- Schematic layout & working of Thermal Power

Station, description of main parts of Thermal Power Plant.

08

IV

Nuclear Power Plant- Components of nuclear reactors, Schematic layout &

operation of nuclear power plant, types of nuclear reactors, radiation hazards

& safety precautions.

Diesel Power Plant- Components of diesel power plant, plant layout &

maintenance.

08

V

Economic aspects- Terms commonly used in system operation: Diversity

factor, load factor, plant capacity factor, plant use factor, plant utilization

factor, loss factor, load duration curve, energy-load curve, numerical problems.

Power factor improvement and tariffs.

08




them for answering.




Text Books:

Sl No


1 Non conventional sources of energy G. D. Rai 1994 edition

2 Electric Power Generation

Transmission and Distribution

S M Singh 2nd

edition

Reference Book:

Sl No


1 Solar energy Sukhatme 2

nd edition

2 Power System Engineering A Chakrabarthi, M L

Soni, P V Guptha &

Dhanpat,

US Bhatnaga

2009 edition

3 Elements of Power System Design M V Deshpande 2004 edition





Subject Name: CIRCUIT SIMULATION AND MEASUREMENTS LABORATORY

Subject Code: PC-18EE3L01 L-T-P-C: 0-0-3-1.5

Course Objectives:

Course Outcomes


1 To Provide detailed experiment on measurement of

resistance, inductance & capacitance

2 To provide usage of PSPICE software package for the

analysis of Network Theorems

3 To provide detailed study on Resonant circuits.

4

Course outcome

Descriptions

CO1 Verify network theorems using software package.

CO2 Knowledge on Resonant Phenomenon using software package.

CO3

Perform experiments to measure resistance, Inductance & capacitance

using DC and AC bridges.

CO4



UNIT Description

I Measurement of low resistance using Kelvin’s double bridge

II Measurement of Inductance and quality factor of coil using Maxwell's Inductance

bridge

III Measurement of Capacitance and its dissipation factor using Desauty's bridge.

IV Verification of KCL & KVL for DC circuits using software package (PSPICE)

V Verification of Superposition theorem using software package.

VI Verification of Reciprocity theorem using software package.

VII Verification of Millman’s theorem using software package.

VIII Verification of Maximum Power Transfer theorem by:

i) conventional method ii) software package

IX Verification of Thevenin’s theorem by:

:i) conventional method ii)software package

X

Resonance characteristics for series and parallel circuits by:

i) Conventional method

ii) Software package





Subject Name: DC MACHINES AND SYNCHRONOUS MACHINES LABORATORY

Subject Code: PC-18EE3L02 L-T-P-C: 0-0-3-1.5

Course Objectives:

Course Outcomes


1 To provide a strong foundation on the no-load & load

characteristics of DC generator.

2 To impart knowledge on testing of DC machines

3 To evaluate the performance of Synchronous machines.

4 To have the knowledge of parallel operation of

synchronous generators.

Course outcome

Descriptions

CO1

Able to understand the basic concepts of DC Machines and Synchronous

Machines.

CO2

Formulate, analyze the working of DC Machines and Synchronous

Machines under no-load and load conditions.

CO3 Conduct tests and predetermine the performance of DC Machines and

Synchronous Machines. CO4



LIST OF EXPERIMENTS FOR

DC MACHINES AND SYNCHRONOUS MACHINES LAB

UNIT Description

I No load and Load characteristics of DC shunt generators.

II Load test on DC shunt motor and determination of speed-torque & BHP-efficiency

characteristics

III Speed control of dc motor by armature voltage control and flux control.

IV Swinburne’s test or No Load Test.

V Ward Leonard method of speed control of dc motor.

VI Hopkinson’s test or Back to Back Test or Regenerative Test

VII Voltage Regulation of an Alternator by EMF or Synchronous Impedance Method.

VIII Voltage Regulation of an Alternator by MMF or Ampere Turn Method

IX Voltage Regulation of an Alternator by ZPF or Potier Triangle Method

X Slip Test on a salient Pole Synchronous Machine.

XI Performance of synchronous generator connected to infinite bus, constant power –

variable excitation and vice-versa.

XII V & inverted V curve of synchronous motor.



PC-18EE3L02: DC MACHINES AND SYNCHRONOUS MACHINES LAB

UNIT Description

FIRST CYCLE EXPERIMENTS

I No load and Load characteristics of DC shunt generators.

II Load test on DC shunt motor and determination of speed-torque & BHP-efficiency

characteristics

III Speed control of dc motor by armature voltage control and flux control.

IV Swinburne’s test or No Load Test.

V Slip Test on a salient Pole Synchronous Machine.

VI Voltage Regulation of an Alternator by EMF or Synchronous Impedance Method.

SECOND CYCLE EXPERIMENTS

VII Ward Leonard method of speed control of dc motor.

VIII Hopkinson’s test or Back to Back Test or Regenerative Test

IX Voltage Regulation of an Alternator by MMF or Ampere Turn Method

X Voltage Regulation of an Alternator by ZPF or Potier Triangle Method

XI Performance of synchronous generator connected to infinite bus, constant power –

variable excitation and vice-versa.

XII V & inverted V curve of synchronous motor.

syllabus for the academic year 2019 - 2020 - ssit.edu.in sem syllabus.pdf · syllabus for the...

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