RGPV CBGS 3rd Sem ECE Syllabus  Electronics & Communication 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 ECE Engineering Syllabus for 2nd year students. In the RGPV CBGS 3rd sem there are 78 subjects in Electronics & Communication Engineering branch i.e. Energy, Environment, Ecology & Society, Digital circuits & system, Network Analysis, Electronic Devices & Circuits, Measurements
and Instrumentation, Rural Outreach (Internal Assessment), and NSS/NCC/Social
Work (Internal Assessment).
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RGPV CBGS 3rd Sem ECE Syllabus
RGPV Credit
Based Grading System
Electronics
& Communication Engineering, IIISemester
BE3001 Energy,
Environment, Ecology & Society
Unit –I
Energy Sources of Energy
: Renewable & Non Renewable, Fossil fuel, Biomass Geothermal, Hydrogen,
Solar, Wind, hydal, nuclear sources.
Unit –II
Ecosystem – Segments of
Environment: Atmosphere, hydrosphere, Lithosphere, biosphere. Cycles in
Ecosystem – Water, Carbon, Nitrogen. Biodiversity: Threats
Unit –III
Air Pollution & Sound
Pollution 
Air Pollution: Air pollutants,
classification, (Primary & secondary Pollutants) Adverse effects of
pollutants. Causes of Air pollution chemical, photochemical, Green house
effect, ozone layer depletion, acid Rain.
Sound Pollution: Causes,
controlling measures, measurement of sound pollution (deciblage), Industrial
and non – industrial.
Unit –IV
Water Pollution– Water
Pollution: Pollutants in water, adverse effects. Treatment of Domestic &
Industrial water effluent.
Soil Pollution – Soil
Profile, Pollutants in soil, their adverse effects, controlling measures.
Unit –V
Society, Ethics &
Human values– Impact of waste on society. Solid waste management (Nuclear,
Thermal, Plastic, medical, Agriculture, domestic and ewaste). Ethics and moral
values, ethical situations, objectives of ethics and its study . Preliminary
studies regarding Environmental Protection Acts , introduction to value
education, self exploration, sanyam & swasthya.
References:
1. Harris, CE, Prichard MS, Rabin’s MJ, “Engineering
Ethics”; Cengage Pub.
2. Rana SVS ; “Essentials of Ecology and Environment”; PHI Pub.
3. Raynold, GW “Ethics in information Technology”; Cengage.
4. Svakumar; Energy Environment & Ethics in society; TMH
5. AK De “Environmental Chemistry”; New Age Int. Publ.
6. BK Sharma, “Environmental Chemistry” ; Goel Publ. House.
7. Bala Krishnamoorthy; “Environmental management”; PHI
8. Gerard Kiely, “Environmental Engineering” ; TMH
9. Miller GT JR; living in the Environment Thomson/cengage
10. Cunninghan WP and MA; principles of
Environment Sc; TMH
11. Pandey, S.N. & Mishra, S.P.
Environment & Ecology, 2011, Ane Books , Pvt. Ltd, New Delhi
12. Joseph, B. Environmental Studies, 2009
Tata Mcgraw Hill, Edu India Ltd. New Delhi.
13. Gour R.R, Sangal, R &Bagaria, G.P. ,
Excel Books, A45, Naraina PhaseI ,New Delhi.110028
Electronics
& Communication Engineering, IIISemester
EC3002 Digital
Circuits & System
Course Objective
To learn the basic
methods for the design of digital circuits and provide the fundamental Concepts
used in the design of digital systems.
To introduce basic
postulates of Boolean algebra and shows the correlation between Boolean
expressions To introduce the methods for simplifying Boolean expressions
To outline the formal
procedures for the analysis and design of combinational circuits andsequential
circuits To introduce the concept of memories and programmable logic devices.
To illustrate the concept of synchronous and asynchronous sequential circuits
Course contents:
Review of Logic gates and
binary operations AND, OR, NOT, NAND, NOR, Exclusive–OR and Exclusive– NOR
Implementations of Logic Functions using gates, NAND–NOR implementations –
Multi level gate implementations Multi output gate implementations.Introduction
to number systems and binary operations.
Boolean postulates and
laws – DeMorgan’s Theorem  Principle of Duality, Boolean function, Canonical
and standard forms,Minimization of Boolean functions, Minterm,Maxterm, Sum of
Products (SOP), Product of Sums (POS),Karnaugh map Minimization, Don’t care
conditions, QuineMcCluskey method of minimization.
Combinational logic
circuits:Half adder – Full Adder – Half subtractor  Full subtractor–
Parallelbinary adder, parallel binary Subtractor – Fast Adder  Carry Look
Ahead adder– Serial. Adder/Subtractor  BCD adder – Binary Multiplier – Binary
Divider  Multiplexer/Demultiplexer – decoder  encoder – parity checker –
parity generators – codeconverters  Magnitude Comparator.
Sequential logic
circuits:Latches, Flipflops  SR, JK, D, T, and MasterSlave, Characteristic
table and equation– Application table – Edge triggering – Level Triggering –
Realization of one flip flopusing other flip flops – serial adder/subtractor.
Registers and Counters:
Asynchronous Ripple or serial counter. Asynchronous Up/Down counter 
Synchronous counters – Synchronous Up/Downcounters – Programmable counters –
Design of Synchronous counters: state diagramState table –State minimization
–State assignment  Excitation table and mapsCircuit. Implementation 
Modulo–n counter, Registers – shift registers  Universal shift registers.
Shift register counters – Ring counter – Shift counters  Sequence generators.
Logic
Families:Introduction to different logic families and their characteristics
,RTL,DTL,TTL, ECL, IIL,TTL inverter – circuit description and operation, CMOS
inverter – circuit description and operation, other TTL and CMOS gates,
Memories – ROM  ROM
organization  PROM – EPROM – EEPROM –EAPROM, RAM – RAM organization Static
RAM, Dynamic RAM, Programmable Logic Array (PLA)  Programmable Array Logic
(PAL)
Course outcome
Students who are
successful in this class will demonstrate at least the abilities:
1. To introduce the
concepts and techniques associated with the number systems and codes. To
minimize the logical expressions using Boolean postulates.
2. To design various
combinational and sequential circuits.
TEXT BOOKS
1. M. Morris Mano, Digital Design, 3rd Edition, Prentice Hall
of India Pvt. Ltd., 2003 Pearson Education (Singapore) Pvt. Ltd., New Delhi,
2003.
2. Donald P.Leach and Albert Paul Malvino, Digital Principles
and Applications, 6thEdition, TMH, 2003.
3. http://www.nptelvideos.in/2012/12/digitalcircuitsandsystems.html
REFERENCES
1. Anil K. Maini, Digital electronics Principles and Integrated
circuits Wiley India Pvt. Ltd.
2. Anandkumar fundamental of digital circuit. 3rd edition. PHI
3. John. F. Wakerly, Digital Design, Principles and Practices,
Pearson Prentice Hall
4. John.M Yarbrough, Digital Logic Applications and Design,
Thomson Learning, 2002.
5. Comer: Digital Logic & State Machine Design, Oxford
Publication.
6. Donald D.Givone, Digital Principles and Design, TMH, 2003.
7. Ghosal Digital electyronis, cengage learning.
Graphical
Programming using Lab
1. To verify the truth table
of all basic logic gates and to implement all gate using universal gate.
2. Design of 4 bit Adders
(CLA, CSA, CMA, Parallel adders)
3. Design of Binary
Subtractors
4. Design of Encoder (8X3),
Encoder(3X8)
5. Design of Multiplexer
(8X1), and Demultiplexer (1X8)
6. Design of code converters
& Comparator
7. Design of FF (SR, D, T,
JK, and Master Slave with delays)
8. Design of registers using
latches and flipflops
Electronics
& Communication Engineering, IIISemester
EC3003 Network
Analysis
COURSE OBJECTIVE:
To make the students
capable of analyzing any given electrical network.
To make the students
learn how to synthesize an electrical network from a given impedance/admittance
function.
Understand the
fundamental concepts and theories about networks.  Apply this knowledge to
solve realworld, networkcentric problems.  Use advanced network analysis
methods and tools to visualize and analyze networks. Interpret the results with
respect to exploratory, quantitative and substantive questions.  Design and
execute a smallscale network analysis project in a systematic fashion.
COURSE CONTENTS:
Introduction to circuit
theory: basic circuit element R,L,C and their characteristics in terms of
linearity & time dependant nature, voltage & current sources,
controlled & uncontrolled sources KCL and KVL analysis, Concept of phasor
& vector, impedance & admittance, Nodal & mesh analysis, analysis
of magnetically coupled circuits. Dot convention, coupling coefficient, tuned
circuits, Series & parallel resonance.
Network Graph theory:
Concept of Network graph, Tree, Tree branch & link, Incidence matrix, cut
set and tie set matrices, dual networks.
Network Theorems:
Thevenins & Norton’s, Super positions, Reciprocity, Compensation,
Substitution, Maximum power transfer, and Millman’s theorem, Tellegen’s
theorem, problems with dependent & independent sources.
Transient analysis:
Transients in RL, RC&RLC Circuits, initial& final conditions, time
constants. Steady state analysis
Laplace transform:
solution of Integrodifferential equations, transform of waveform synthesized
with step ramp, Gate and sinusoidal functions, Initial & final value
theorem, Network Theorems in transform domain.
Two port parameters: Z,
Y, ABCD, Hybrid parameters, their inverse & image parameters, relationship
between parameters, Interconnection of two ports networks, Reciprocity and
Symmetry in all parameter.
COURSE OUTPUT:
After successful
completion of the course, student will be able to
Apply the fundamental
concepts in solving and analyzing different Electrical networks
Select appropriate and
relevant technique for solving the Electrical network in different conditions
Apply mathematics in analyzing and synthesizing the networks in time and
frequency domain
Estimate the performance
of a particular network from its analysis
TEXT BOOKS:
1. M.E. Van Valkenburg, Network Analysis, (Pearson)
2. S P Ghosh A K Chakraborty Network Analysis & Synth.
(MGH).
3. http://www.nptelvideos.in/2012/11/networksandsystems.html
REFERENCE:
1. SudhakarCircuit Network Analysis & Synth(TMH).
2. J. David Irwin Engineering Circuit analysis tenth edition,
Wiley india.
3. Kuo Network Analysis & Synthesis, Wiley India.
4. Robert L Boylestad introductory Circuit analysis, Pearson
5. Smarajit Ghosh, NETWORK THEORY: ANALYSIS AND SYNTHESIS
(PHI).
6. Roy Choudhary D; Network and systems; New Age Pub.
7. Bhattacharya and Singh Network Analysis & Synth
(Pearson).
EXPERIMENTS LIST:
1. To Verify Thevenin
Theorem and Superposition Theorem.
2. To Verify Reciprocity
Theorem and Millman’s Theorem.
3. To Verify Maximum Power
Transfer Theorem.
4. To Determine Open Circuit
and Short Circuit parameters of a Two Port Network.
5. To Determine A,B, C, D
parameters of a Two Port Network.
6. To determine h parameters
of a Two Port Network.
7. To Find Frequency
Response of RLC Series Circuit RLC parallel Circuit and determine resonance and
3dB frequencies.
8. To determine charging and
discharging times of Capacitors.
Electronics
& Communication Engineering, IIISemester
EC3004
Electronic Devices & Circuits
COURSE OBJECTIVE: Any electronic trade has its basis on a certain
number of components and some basic standard circuits. These common circuits
are applied in all sections of the Electronics technology. A good understanding
of the basic functioning of all these components and circuits will be a solid
platform to enter into the more complex portion and specialized field of
Electronics Engineering. Emphasis has been given on the characteristics and
application of semiconductor devices/ components. In the case of basic standard
circuits, the focus has been made on the interaction of active and passive
components and overall performance according to the stated requirements.
COURSE CONTENTS:
Introduction to
semiconductor physics: insulator, conductor, semiconductor and semiconductor
types. Drift and diffusion carries, Hall Effects.
Review of PN junction
diode: PN junction diode in forward and reverse bias, temperature dependence of
VI characteristics, diode resistances, diode junction capacitance. Types of
diodes: Zener Diode, Varactor Diode, Tunnel Diode, PIN Diode, Schottky Diode,
LED and Photo Diodes, Switching characteristics of diode.
Bipolar junction
transistor  Construction, basic operation, current components and
equations,CB, CE and CCconfiguration, input and output characteristics, Early
effect, Region ofoperations: active, cutoff and saturation region. BJT as an
amplifier. EbersMoll model, Power dissipation intransistor (Pd, max rating),
Photo transistor.
Transistor biasing
circuits and analysis: Introduction, various biasing methods:Fixed bias,Self
bias, Voltage Divider bias, Collector to base bias, Loadline analysis: DC and
AC analysis, Operating Point and Bias Stabilization and Thermal Runaway.
Transistor as a switch.
Small Signal analysis:
Small signal Amplifier,Amplifier Bandwidth, Hybrid model, analysis of
transistor amplifier using hparameter, Multistage Amplifier: Cascading
amplifier, Bootstrapping Technique, Darlington amplifier and cascode
amplifier, Coupling methods in multistage amplifier,Low and high frequency
response, Hybrid Ï€model,
Current Mirror circuits.
LargeSignal analysis and Power
Amplifiers:Class A,Class B,Class AB,Class C,Class D, Transformer coupled and
PushPull amplifier.
FET construction JFET:
Construction, nchannel and pchannel, transfer and drain characteristics,
parameters,Equivalent model and voltage gain, analysis of FET in CG, CS and CD
configuration. Enhancement and Depletion MOSFET drainand transfer
Characteristics.
Unijunction Transistor
(UJT) and Thyristors:UJT: Principle of operation, characteristics, UJT
relaxation oscillator, PNPN Diode and its characteristics, Silicon controlled
rectifier: VI characteristics, DIAC and TRIAC,Thyristors parameters and
applications.
COURSE OUTCOMES:
Students who are
successful in this class will be able to:
1. Understand the basic physics of carrier transport in bulk
semiconductors and real device structures.
2. Understand the fundamentals of operation of the main
semiconductor electronic devices.
3. Understand the basic parameters of electronic devices, their
performance, and limiting factors.
4. Understand the basic principles of electronic device
operation with emphasis on bipolar transistors, and unipolar microwave devices.
TEXTBOOKS
1. Millman and Halkias: Integrated electronics, TMH.
2. Boylestad and Nashelsky: Electronic Devices and Circuit
Theory, Pearson Education.
3. http://www.nptelvideos.in/2012/12/basicelectronicsdrchitralekhamahanta.html
REFERENCES:
1. Sedra and Smith: Microelectronics, Oxford Press.
2. Anil K. Maini, VarshaAgarwal: Electronic Devices and
Circuits, Wiley Publications.
3. Rashid: Electronic Devices and Circuits, Cengage learning.
4. Donald A Neamen: Electronic Circuits Analysis and Design,
TMH
5. Salivahanan: Electronic Circuits Analysis and Design, TMH
6. Mottershead: Electronic Devices and Circuits an
introduction, PHI
7. Kumar and Jain: Electronic Devices and Circuits, PHI.
8. David A. Bell Electronic Devices and Circuits Oxford
University press.
LIST OF
EXPERIMENTS:
1. To determine and analyze the VI
characteristics of PN Junction diode and Zener diode.
2. To determine input and output
characteristics of transistor amplifiers in CE, CB &CC configurations.
3. To determine the frequency response of
transistor CE amplifier, direct coupled and RC coupled amplifier.
4. To determine characteristics of UJT as
relaxation Oscillator.
5. To determine Drain and Transfer
Characteristics of JFET Amplifier.
6. To determine Drain and Transfer
Characteristics of MOSFET Amplifier.
7. To determine characteristics of class A
and B power amplifiers.
8. To determine characteristics of class C
and AB power amplifiers.
Electronics
& Communication Engineering, IIISemester
EC3005
Measurements and Instrumentation
COURSE OBJECTIVE:
This course is
electronics based course dealing with measurements and instrumentation designed
for students. The objectives of this course are to introduce students to the
use of various electrical/electronic instruments, their construction,
applications, and principles of operation, standards and units of measurements
and provide students with opportunities to develop basic skills in the design
of electronic equipments.
COURSE CONTENTS:
Accuracy and Precision,
Sensitivity, Linearity, Resolution, Hysteresis, Loading Effect. Measurements of
Current, Voltage, Power and Impedance: DC and AC Ammeter, DC Voltmeter Chopper
type and solidstate, AC voltmeter using Rectifier.Average, RMS, Peak responding
voltmeters, Multimeter, Power meter, Bolometer and Calorimeter.
Different parts of CRO,
Block diagram, Electrostatic focusing, Electrostatic deflection, Post
deflection acceleration. Screen for CRTs, Graticules, Vertical and Horizontal
deflection system, Time base circuit, Oscilloscope Probes, Applications of CRO,
Special purpose CROs Multi input, Dual trace, Dual beam, Sampling, Storage
(Analog and Digital) Oscilloscope.
Maxwell’s bridge
(Inductance and InductanceCapacitance), Hay’s bridge, Schering bridge (High
voltage and Relative permittivity), Wein bridge. Impedance measurement by
Qmeter.
NonElectrical Quantities
(Transducer): Classification of Transducers, Strain gauge, Displacement
TransducerLinear Variable Differential Transformer (LVDT) and Rotary Variable
Differential Transformer (RVDT), Temperature Transducer Resistance Temperature
Detector (RTD), Thermistor, Thermocouple, Piezoelectric transducer, Optical
Transducer Photo emissive, Photo conductive, Photo voltaic, Photodiode, Photo
Transistor.
Signal and Function
Generators, Sweep Frequency Generator, Pulse and Square Wave Generator, Beat
Frequency Oscillator, Digital display system and indicators, Classification of
Displays, Display devices: Light Emitting diodes (LED) and Liquid Crystal
Display(LCD).
Advantages of Digital
Instrument over Analog Instrument, Digitaltoanalog conversion (DAC) 
Variable resistive type, R2R ladder Type, Binary ladder, Weighted converter
using Opamp and transistor, Practical DAC. Analogtodigital Conversion (ADC)
Ramp Technique, Dual Slope Integrating Type, Integrating Type (voltage to
frequency), Successive Approximations. Digital voltmeters and multimeters,
Resolution and sensitivity of digital multimeter.
COURSE OUTPUT:
Upon successful
completion of this course, the student will be able to:
Identify electronics/
electrical instruments, their use, peculiar errors associated with the
instruments and how to minimize such errors.
Explain the industrial
and laboratory applications of such instruments.
Service and maintain such
instruments in case of damage or misuse. Understand the basic design techniques
of electronic equipment.
TEXTBOOKS
1. H.S. Kalsi: Electronics Instrumentation, TMH
2. A.K. Sawhney: Instrumentation and Measurements, Dhanpat Rai
and Co.
REFERENCES:
1. Oliver: electronic Measurements introduction TMH
2. Helfric and Cooper: Modern Electronic Instrumentation and
Measurement Techniques, Pearson.
3. Ghosh: introduction to measurements and instrumentation 4th
edition PHI
4. Bell: electronic Instrumentation and Measurement oxford
press.
5. Banerjee: electrical and electronics Measurement 2nd PHI.
6. Anand: electronics and Instrumentation technology, PHI.
List of
Experiments:
1. Study of Cathode Ray Oscilloscope and
Function Generator.
2. Study of displacement measurement by
LVDT.
3. Force measurement by strain gauge.
4. Measurement of Capacitor using Qmeter.
5. Measurement of Selfinduction using
Qmeter.
6. Temperature measurement by thermistor,
RTD and thermocouple.
7. Study of optical Transducers: Photo
conductive, Photo voltaic, Photodiode, PhotoTransistor.
8. Design of digital to analog
converter,R2R ladder Type and analysis of its characteristics.
RGPV CBGS 3rd Sem ECE Subject list
RGPV CBGS 3^{rd} Sem Subjects ECE  Bachelor of Technology B.Tech. (Electronics & Communication Engineering) 

S. NO.

Subject Code

Subject Name

1

BT3001

Energy, Environment, Ecology & Society

2

EC3002

Digital circuits & system

3

EC3003

Network Analysis

4

EC3004

Electronic Devices & Circuits

5

EC3005

Measurements and Instrumentation

6

EC3006

Rural Outreach (Internal Assessment)

7

EC3007

NSS/NCC/Social Work (Internal Assessment)

Download RGPV CBGS 3rd Sem Electronics & Communication Engineering Syllabus
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