RGPV CBGS 3rd Sem Electrical & Electronics Syllabus | EX Engineering Syllabus RGPV Credit Based Grading System B.Tech.
The Rajiv Gandhi Prodhoyogiki Vishavdhyalaya i.e RGPV now disclose the new scheme for 2nd year students who are admitted into the RGPV University as well as their affiliated institutes. The new scheme name is Credit Based Grading System (CBGS); under these scheme the university will give BTech degree to all 2nd year admitted students. It is very good news for all students and as we also known as the RGPV is one the largest government technical university of MP. More than 1 lacks candidates get Graduation as well as master degree from that university.
In this article we are going to share RGPV CBGS 3rd Sem Electrical & Electronics Engineering Syllabus for 2nd year students. In the RGPV CBGS 3rd sem there are 7-8 subjects in Electrical & Electronics branch i.e. Energy, Environment, Ecology & Society, Electrical Measurements and
Instrumentation, Network Analysis, Analog Electronics, Signals and Systems, Computer
Programming-I (Java), Rural Outreach (Internal Assessment), and NSS/NCC/Social
Work (Internal Assessment).
Click to
go >>>
|
|
Download RGPV CBGS
|
|
RGPV CBGS 3rd Sem EX Syllabus
RAJIV GANDHI PROUDYOGIKI VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics Engineering, III-Semester
BE-3001 Mathematics-III
(Syllabus
for EX, EE, EI, & BM Branches)
COURSE OBJECTIVE- The objective
of this course is to fulfill the needs of Engineers to understand the
Applications of Fourier Series, Different Transforms, and Complex Analysis
& Vector Calculus in order to enable young technocrats to acquire
Mathematical thinking of Formulating, Analyzing and Solving a wide range of
Practical Problems Appearing in Science & EX/EE/EI/BM Engineering.
Course Contents
Fourier Series: Fourier Series
for Continuous & Discontinuous Functions, Expansion of odd and even
periodic functions, Half range Fourier series, Complex form of Fourier Series.
Integral Transforms:
Fourier Transform-Complex
Fourier Transform, Fourier Sine and Cosine Transforms, Applications of Fourier
Transform in Solving the Ordinary Differential Equation.
Laplace Transform- Introduction
of Laplace Transform, Laplace Transform of elementary Functions, Properties of
Laplace Transform, Change of Scale Property, First and Second Shifting
Properties, Laplace Transform of Derivatives and Integrals. Inverse Laplace
Transform & its Properties, Convolution theorem, Applications of Laplace
Transform in solving the Ordinary Differential Equations.
Functions of Complex Variables:
Analytic functions, Harmonic Conjugate, Cauchy-Riemann Equations, Line
Integral, Cauchy’s Theorem, Cauchy’s Integral Formula, Singular Points, Poles
& Residues, Residue Theorem , Application of Residues theorem for
Evaluation of Real Integrals.
Vector Calculus:
Differentiation of Vectors, Scalar and Vector Point functions, Gradient,
Directional derivative, Divergence and Curl. Line Integral, Surface Integral
and Volume Integral, Stoke’s Theorem and Gauss divergence theorem.
COURSE OUTCOMES- The curriculum
of the Department is designed to satisfy the diverse needs of students.
Coursework is designed to provide students the opportunity to learn key
concepts of Fourier Series, Different Transforms, Complex Analysis & Vector
Calculus.
EVALUATION- Evaluation will be
continuous, an integral part of the class as well as through external
assessment.
References:
1. Erwin Kreyszig: Advanced Engineering Mathematics, Wiley
India.
2. H C Taneja: Advanced Engineering Mathematics, I.K.
International Publishing House Pvt. Ltd.
3. C B Gupta & S R Singh : Engineering Mathematics , Mc
Graw Hill Education.
4. S S Sastri: Engineering Mathematics, PHI
5. Ramana: Advance Engg. Mathematics, TMH New Delhi
6. Engineering Mathematics By Samnta Pal and
Bhutia, Oxford Publication
RGPV CBGS 3rd Sem
EX Syllabus RGPV CBGS 2nd year Scheme
RAJIV GANDHI PROUDYOGIKI
VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics
Engineering, III-Semester
EX-3002 Electrical
Measurements and Instrumentation
COURSE OBJECTIVE
The primary objective of the
course is to introduce operation principles of instruments, terminology related
to measurements and to have an adequate knowledge in measurement techniques for
voltage, current, power and energy.
COURSE CONTENT
Introduction, History and
overview of measurement system, Fundamentals of Measurement system, Static and
Dynamic Characteristics of measurement systems: Systematic Characteristics,
Generalized model, Transfer function, Techniques for dynamic compensation,
Accuracy of measurement systems in steady state: Measurement error, Error
probability function, Error reduction techniques, Reliability, Choice and
Economics of measurement systems. Loading effects due to shunt connected and
series connected instruments, calibration curve, Testing & calibration of
instruments.
Galvanometers – Theory,
principle of operation and construction of ballistic galvanometer, D’arsonal
galvanometer, Definition of analog & digital instruments, Classification of
analog instruments, their operating principle, Operating force, Types of
supports, Damping, Controlling.
Different types of Ammeter
& Voltmeter – PMMC, MI, Electrodynamometer, Induction, Expression for
control & deflection torque, their advantages, disadvantages & error,
Extension of range of instruments using shunt & multiplier.
Digital Voltmeter, Ammeter, Multimeter and Wattmeter.
Instrument transformers:
Potential and current transformers, ratio and phase angle errors, testing of
instrument transformers, Difference between CT and PT, errors and reduction of
errors.
Measurement of power: Power in
AC and DC Circuit, Electrodynamometer type of wattmeter, Construction, theory,
operation & error, Low power factor & UPF wattmeter, Double element and
three element dynamometer wattmeter, Measurement of power in three phase
circuit, one, two & three wattmeter method, Measurement of reactive power
by single wattmeter, Measurement of power using CTs & PTs.
Measurement of Energy: Single
phase and three phasedigital / Electronic energy meter – construction &
operation – Energy flow and power calculations, errors – Testing by phantom
loading, Tri-vector meter, Maximum demand meter, Ampere hour meter.
Power factor meter– Single
phase and three phase Electro-dynamometer type & moving iron type.
Frequency meter – Vibrating reed, Resonance type & Weston type,
Synchronoscope,
Ohmmeter –series & stunt
type, Megger & Ratio meter.
Resistance Measurement –
Classification of low, medium & high resistance – Voltmeter-Ammeter method,
Wheatstone Bridge, Kelvin’s double bridge & loss of charge methods for
resistance measurement, Earth resistance measurement.
Magnetic Measurement – B-H
Curve, Hysteresis Loop determination, Power loss in sheet metal – Lloyd Fischer
square for measurement of power loss.
COURSE OUTCOME:
After successful completion of
course, Students are expected to possess an in-depth understanding and
Knowledge of the concepts and principles of measurement of electrical and non
electrical viz. physical quantities and instruments.
EVALUATION
Evaluation will be continuous
an integral part of the class as well through external assessment. Laboratory
assessment will be based on external assessment, assignments, presentations,
and interview of each candidate.
Text book:-
1. A.K. Sawhney; ‘A course in Electrical & Electronic
Measurements & Instrumentation’; Dhanpat Rai & co(p) Ltd ,New Delhi
Reference books:-
1. G. K. Banerjee,’ Electrical and Electronic Measurements’.
PHI Learning Pvt.Ltd.
2. R. B. Northrop,’ Introduction to Instrumentation and
Measurement’; CRC press Taylor & Francis
3. Vijay Singh;’ Fundamentals of Electrical & Electronic
Measurements’, New Age International Publishers.
Topics for the laboratory (Expandable):
1. Measurement
of low resistance using Kelvin’s Double bridge
2. Measurement
of medium resistance using Wheatstone’s bridge
3. Measurement
of high resistance by loss of charge method
4. Measurement
of Insulation resistance using Megger
5. Measurement
of earth resistance by fall of potential method and verification by using earth
tester
6. Measurement
of power in a single phase ac circuit by 3 voltmeter/ 3 Ammeter method
7. Calibration
of a dynamometer type of wattmeter with respect to a standard/Sub Standard
wattmeter
8. Calibration
of single phase digital/ Electronic type energy meter.
9. Calibration
of a dynamometer type of wattmeter by Phantom Loading method.
10. Measurements
using Instrument Transformers.
11. Study
of various types of Indicating Instruments.
12. Measurement
of Power in three phase circuit by one, two & three wattmeters.
RAJIV GANDHI PROUDYOGIKI VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics Engineering, III-Semester
EX-3003 Network Analysis
COURSE OBJECTIVE
This Course introduces
examination of electrical & electronic circuit analysis & synthesis
tools & techniques such as the Laplace transform, nodal analysis & two
port network theory.
COURSE CONTENT
Introduction to circuit
elements R,L,C and their characteristics in terms of linearity & time
dependent nature, voltage & current sources controlled & uncontrolled
sources KCL and KVL analysis, Nodal & mesh analysis, analysis of
magnetically coupled circuits, Transient analysis :-Transients in RL,
RC&RLC Circuits, initial conditions, time constants. Steady state
analysis-Concept of phasor & vector, impedance & admittance, Network
topology, concept of Network graph, Tree, Tree branch & link, Incidence
matrix, cut set and tie set matrices, dual networks, Dot convention, coupling
co- efficient, tuned circuits, Series & parallel resonance.
Network Theorems for AC &
DC circuits- Thevenins & Norton’s, Superpositions, Reciprocity,
Compensation, Substitution, Maximum power transfer, and Millman’s theorem,
Tellegen’s theorem, problems with dependent & independent sources.
Frequency domain analysis –
Laplace transform solution of Integro-differential equations, transform of waveform
synthesized with step ramp, Gate and sinusoidal functions, Initial & final
value theorem, Network Theorems in transform domain
Concept of signal spectra,
Fourier series co-efficient of a periodic waveform, symmetries as related to
Fourier coefficients, Trigonometric & Exponential form of Fourier series.
Network function & Two port
networks – concept of complex frequency, Network & Transfer functions for
one port & two ports, poles and zeros, Necessary condition for driving
point & transfer function. Two port parameters – Z, Y, ABCD, Hybrid
parameters, their inverse & image parameters, relationship between
parameters, Interconnection of two ports networks, Terminated two port network.
COURSE OUTCOME
Student after successful
completion of course must be able to apply the Thévenin, Norton, nodal and mesh
analysis to express complex circuits in their simpler equivalent forms and to
apply linearity and superposition concepts to analyze RL, RC, and RLC circuits
in time and frequency domains and also to analyze resonant circuits both in
time and frequency domains.
EVALUATION
Evaluation will be continuous
an integral part of the class as well through external assessment. Laboratory
assessment will be based on external assessment, assignments, presentations,
and interview of each candidate.
REFERENCES
1. M.E. Van Valkenburg, Network Analysis,Pearson
2. William H Hayt. & Jack E. Kemmerly, Steven M Durbin;
Engineering Circuit Analysis;McGrawHill
3. Richard C Dorf, James A Svoboda, Introduction to Electric
Circuits, Wiley India, 2015
4. Charles K. Alexander & Matthew N.O. Sadiku:
Electrical Circuits; McGrawHill
5. J David Irwin, Robert M Nelms, Engineering Circuit
Analysis, Wiley India,2015
6. Robert L Boylestad, introductory circuit analysis,
Pearson,2016
7. M S Sukhija, T K Nagsarkar; Circuits and Networks, Oxford
University Press, 2015
8. Samarajit Ghosh, Network Theory Analysis and Synthesis
Topics for the laboratory (Expandable):
1. To
Verify Thevenin Theorem.
2. To
Verify Superposition Theorem.
3. To
Verify Reciprocity Theorem.
4. To
Verify Maximum Power Transfer Theorem.
5. To
Verify Millman’s Theorem.
6. To
Determine Open Circuit parameters of a Two Port Network and to Determine Short
Circuit parameters of a Two Port Network.
7. To
Determine A,B, C, D parameters of a Two Port Network
8. To
Determine h parameters of a Two Port Network
9. To
Find Frequency Response of RLC Series Circuit.
10. To Find
Frequency Response of RLC parallel Circuit.
RAJIV GANDHI PROUDYOGIKI
VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics
Engineering, III-Semester
EX-3004 Analog Electronics
COURSE OBJECTIVE
The primary objective of this
course is to develop an in-depth understanding of the design principles and
applications of integrated analog circuits.
COURSE CONTENT
Semiconductor Diodes: Theory of
P-N junction, temperature dependence and break down characteristics, junction
capacitances, Zener diode, Varactor diode, Tunnel diode, PIN diode, LED, Photo
diode, Schottky diode, Diode applications: series –parallel configurations,
full wave and half wave rectification, voltage multiplier circuits, diode
testing
Transistors: BJT, types&
configuration, working principal, characteristics, and region of operation,
load line, biasing methods, Small signal analysis of transistor (low frequency)
using h-parameters, thermal runaway and thermal stability.FET, MOSFET,
Transistor as an amplifier, gain,bandwidth, frequency response,
Feedback amplifierand Oscillators:
Feedback amplifier, negative feedback, voltage-series, voltage shunt,current
series and current shunt feedback, Sinusoidal oscillators, L-C
(Hartley-Colpitts) oscillators, RC phase shift, Wien bridge, and Crystal
oscillators. Power amplifiers, class A, class B, class A B, C amplifiers, their
efficiency and power Dissipation, Push-pull and complimentary symmetry
push-pull amplifier.
Wave Shaping circuits:
Switching characteristics of diode and transistor, turn ON, OFF time, reverse
recovery time, transistor as switch, Multivibrators, Bistable, Monostable,
Astable multivibrators. Clipper and clamper circuit, Differential amplifier,
calculation of differential, common mode gain and CMRR using h- parameters,
Darlington pair, Boot strapping technique. Cascade and cascade amplifier.
Operational Amplifier:
Operational amplifier basics, practical Op-amp circuits & characteristics,
slew rate , bandwidth, offset voltage ,basic current, application, inverting,
non-inverting amplifier, summer, average, differentiator, integrator,
differential amplifier, instrumentation amplifier, log and antilog amplifier,
voltage to current and current to voltage converters, comparators Schmitt
trigger , active filters, 555 timer and its application.
COURSE OUTCOME:
After successful completion of
course, Students are expected to able in applying theory and realize analog
filter circuits, Understand the circuit operation of the 555 timer IC and
regulator IC and identifying the faulty components within a circuit.
EVALUATION
Evaluation will be continuous
an integral part of the class as well through external assessment. Laboratory
assessment will be based on external assessment, assignments, presentations,
and interview of each candidate.
REFERENCES
1. Robert L Boylestad, Louis Nashelsky; Electronic Devices
and Circuits; Pearson
2. Jacob Millman, Cristos C Halkias, Satyabrata Jit;
Electronic Devices and Circuits; McGraw- Hill
3. Anil K Maini, Electronic Devices and Circuits, Wiley
4. S Salivahanan, N Suresh Kumar; Electronic Devices and
Circuits; McGraw- Hill
Topics for the laboratory (Expandable):
1. Design &
measure the frequency response of an RC coupled amplifier using discrete
components.
2. Design a two
stage RC coupled amplifier and determine the effect of cascading on gain and
bandwidth.
3. Study the effect
of voltage series, current series, voltage shunt and current shunt feedback on
amplifier using discrete components.
4. Design &
realize inverting, non‐inverting and buffer amplifier using 741 op‐amps.
5. Verify the
operation of a differentiator circuit using op amp IC 741 and show that it acts
as a high pass filter.
6. Verify the
operation of a integrator circuit using op amp 741 and show that it acts as a
low pass filter.
7. Design &
Verify the operation of adder and subtractor circuit using op amp 741.
8. Plot frequency
response of AC coupled amplifier using op amp 741 and study the effect of
negative feedback on the bandwidth and gain of the amplifier.
9. Study of IC 555
as astable and monostable multivibrator.
10. Design &
realize using op amp 741, wein‐bridge oscillator
RAJIV GANDHI PROUDYOGIKI
VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics
Engineering, III-Semester
EX-3005 Signals and Systems
COURSE OBJECTIVE
This course introduces students
about the signals and systems mathematically and understands how to perform
mathematical operations on them.
COURSE CONTENT
Classification of signals and
systems: Continuous time signals (CT signals), Discrete time signals (DT
signals) - Step, ramp, pulse, impulse, sinusoidal and exponential signals,
basic operations on signals, classifications of CT and DT signals- Periodic and
aperiodic signals, energy and power signals, random signals, CT systems and DT
systems, basic properties of systems, basic properties of systems, linear time
invariant systems and properties.
Analysis of continuous time
signals: Time and frequency domain analysis, Fourier series analysis, spectrum
of CT signals, Fourier transform and Laplace transform, region of convergence,
wavelet transform.
Linear time invariant
continuous time systems: Differential equations representation, block diagram
representation, state variable representation and matrix representation of
systems, impulse response, step response, frequency response, relizability of
systems, analog filters.
Analysis of discrete time
signals: Convolution sum and properties, sampling of CT signals and aliasing,
DTFT and properties, Z transform and properties, inverse Z transform.
Linear time invariant discrete
time systems: Difference equations, block diagram representation, impulse
response, analysis of DT LTI systems using DTFT and Z transform, state variable
equations and matrix representation of systems, Digital filters.
COURSE OUTCOME
Student after successful
completion of course must possess an Understanding of various signals and
systems properties and be able to identify whether a given system exhibits
these properties and its implication for practical systems.
EVALUATION
Evaluation will be continuous
an integral part of the class as well through external assessment.
REFERENCES
1. Alan V. Oppenheim, Alan S. Willsky, S Hamid Nawab,
‘Signals and Systems’, 2nd edition 2015 Pearson New International Edition
2. A. Anand Kumar, Signals and Systems, PHI, III edition,
2015
3. Mahmood Nahvi, Signals and Systems, McGraw Hill
4. Simon Haykins and Barry Van Veen, Signals and Systems,
Wiley India
5. A. Nagoor Kani; ‘Signals and Systems’ McGraw Hill
6. Robert A. Gabel and Richard A.Roberts, Signals &
Linear Systems, Wiley.
7. Rodger E. Ziemer, William H. Tranter, D. Ronald Fannin.
Signals & systems, Pearson Education.
RAJIV GANDHI PROUDYOGIKI
VISHWAVIDYALAYA, BHOPAL
Credit Based Grading System
Electrical & Electronics
Engineering, III-Semester
EX-3006 Computer Programming
(JAVA)
Basic Java Features - C++ Vs
JAVA, JAVA virtual machine, Constant & Variables, Data Types, Class,
Methods, Objects, Strings and Arrays, Type Casting, Operators, Precedence
relations, Control Statements, Exception Handling, File and Streams,
Visibility, Constructors, Operator and Methods Overloading, Static Members,
Inheritance: Polymorphism, Abstract methods and Classes
Java Collective Frame Work -
Data Structures: Introduction, Type-Wrapper Classes for Primitive Types,
Dynamic Memory Allocation, Linked List, Stack, Queues, Trees, Generics:
Introduction, Overloading Generic Methods, Generic Classes, Collections:
Interface Collection and Class Collections, Lists, Array List and Iterator,
Linked List, Vector. Collections Algorithms: Algorithm sorts, Algorithm
shuffle, Algorithms reverse, fill, copy, max and min Algorithm binary Search,
Algorithms add All, Stack Class of Package java. Util, Class Priority Queue and
Interface Queue, Maps, Properties Class, Un-modifiable Collections.
Advance Java Features -
Multithreading: Thread States, Priorities and Thread Scheduling,
Life Cycle of a Thread, Thread
Synchronization, Creating and Executing Threads, Multithreading
with GUI, Monitors and Monitor
Locks. Networking: Manipulating URLs, Reading a file on a Web
Server, Socket programming,
Security and the Network, RMI, Networking, Accessing Databases with JDBC:
Relational Database, SQL, MySQL, Oracle
Advance Java Technologies -
Servlets: Overview and Architecture, Setting Up the Apache Tomcat Server,
Handling HTTP get Requests, Deploying a web Application, Multitier
Applications,
Using JDBC from a Servlet, Java
Server Pages (JSP): Overview, First JSP Example, Implicit Objects, Scripting,
Standard Actions, Directives, Multimedia: Applets and Application: Loading,
Displaying and Scaling Images, Animating a Series of Images, Loading and
playing Audio clips
Advance Web/Internet
Programming (Overview): J2ME, J2EE, EJB, XML.
References:
1. Deitel & Deitel, ”JAVA, How to Program”; PHI,
Pearson.
2. E. Balaguruswamy, “Programming In Java”; TMH Publications
3. The Complete Reference: Herbert Schildt, TMH
4. Peter Norton, “Peter Norton Guide To Java Programming”,
Techmedia.
5. Merlin Hughes, et al; Java Network Programming , Manning
Publications/Prentice Hall
List of Program to be perform
(Expandable)
1. Installation
of J2SDK
2. Write
a program to show Concept of CLASS in JAVA
3. Write
a program to show Type Casting in JAVA
4. Write
a program to show How Exception Handling is in JAVA
5. Write
a Program to show Inheritance and Polymorphism
6. Write
a program to show Interfacing between two classes
7. Write
a program to Add a Class to a Package
8. Write
a program to demonstrate AWT.
9. Write
a program to Hide a Class
10. Write
a Program to show Data Base Connectivity Using JAVA
11. Write
a Program to show “HELLO JAVA ” in Explorer using Applet
12. Write
a Program to show Connectivity using JDBC
13. Write
a program to demonstrate multithreading using Java.
14. Write
a program to demonstrate applet life cycle.
RGPV CBGS 3rd Sem EX Subject list
RGPV CBGS 3rd Sem Subjects EX | Bachelor of Technology B.Tech. (Electrical & Electronics Engineering) |
||
S. NO.
|
Subject Code
|
Subject Name
|
1
|
BT-3001
|
Energy, Environment, Ecology & Society
|
2
|
EX-3002
|
Electrical Measurements and
Instrumentation
|
3
|
EX-3003
|
Network Analysis
|
4
|
EX-3004
|
Analog Electronics
|
5
|
EX-3005
|
Signals and Systems
|
6
|
EX-3006
|
Computer Programming-I (Java)
|
7
|
EX-3007
|
Rural Outreach (Internal Assessment)
|
8
|
EX-3008
|
NSS/NCC/Social Work (Internal Assessment)
|
Download RGPV CBGS 3rd Sem Electrical & Electronics Engineering Syllabus
0 comments:
Post a Comment