SRI KRISHNA COLLEGE OF ENGINEERING AND TECHNOLOGY
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING
CURRICULUM DEVELOPMENT CELL
CURRICULUM DESIGN FOR DEPARTMENT OF EEE
SEMESTER 1:
S.NO CATEGORY
SUB
SUB NAME
L
T
P
C
CODE
MAX
MARKS
1
FCG
15HS101
Communication Skills – I
2
0
2
3
100
2
FCBS
15PH101
Engineering Physics
3
0
0
3
100
3
FCBS
15CY101
Engineering Chemistry
3
0
0
3
100
4
FCBS
15MA101
Mathematics – I
2
2
0
3
100
5
FCES
15CS101
Fundamentals
Programming
C 3
0
0
3
100
6
FCES
15EE101
Basics of Electrical and Electronics Engineering
3
0
0
3
100
7
FCES Lab
15ME126
Engineering Graphics Laboratory
2
0
2
3
100
8
FCES Lab
15CS111
Fundamentals
of
Computing
Programming Laboratory
C 0
0
3
2
100
9
FCES Lab
15ME127
Engineering Practices Laboratory
0
0
3
2
100
10
25 900
P
C
of
Computing
and
and
Total 18 2
SEMESTER 2:
S.NO
CATEGORY
SUB
SUB NAME
L
T
CODE
MAX
MARKS
1
FCG
15HS201 Communication Skills – II
2
0
2
3
100
2
FCES
15PH201 Materials Science
3
0
0
3
100
3
FCES
Environmental Science
3
0
0
3
100
4
FCBS
Mathematics – II
2
2
0
3
100
5
FCES
15CY20
1
15MA20
1
15CS201
Advanced C Programming
3
0
0
3
100
1
6
FCES
15EE201 Circuit Theory
3
0
0
3
100
7
FCBS Lab
15BS111
Physical Science Laboratory
0
0
4
2
100
8
FCES Lab
15CS211
Advanced C Programming Laboratory
0
0
3
2
100
9
FCES Lab
15EE211
Circuit Theory Laboratory
0
0
3
2
100
2
12
24
900
P
C
MAX
Total 16
FCG - Foundation Compulsory General
FCBS - Foundation Compulsory Basic Science
FCES - Foundation Compulsory Engineering Science
SEMESTER 3:
S.NO
CATEGORY
SUB
SUB NAME
L
T
CODE
MARKS
1
FCBS
15MA302 Transforms and Applied Scientific Computing
2
2
0
3
100
2
FCES
15CS301
Data Structures & Algorithm
2
2
0
3
100
3
PC
15EE301
Theory and Computation of Electromagnetic
Fields
3
0
0
3
100
4
PC
15EE302
Electrical Machines I
3
0
0
3
100
5
PC
15EE303
Electron Devices & Circuits
3
0
0
3
100
6
FE
15EE0YY FE- I
2
0
0
2
100
7
FCES Lab
15CS311
Data Structures & Algorithm Laboratory
0
0
3
2
100
8
PC Lab
15EE311
Electrical Machines I Laboratory
0
0
3
2
100
9
PC Lab
15EE312
Electron Devices & Circuits Laboratory
0
0
3
2
100
8
9
23 900
T
P
C
Total 16
SEMESTER 4:
S.NO CATEGORY
SUB
SUB NAME
L
CODE
MAX
MARKS
1
FCBS
15MA402 Random Processes
2
2
0
3
100
2
FCES
15IT302
3
0
0
3
100
Programming in C++
2
3
PC
15EC403
Linear Integrated Circuits
3
0
0
3
100
4
PC
15EE401
Principles of Digital Electronics
3
0
0
3
100
5
PC
15EE402
Electrical Machines II
3
0
0
3
100
6
FE
15EE0YY FE - II
2
0
0
2
100
7
FCES Lab
15IT312
C++ Laboratory
0
0
3
2
100
8
PC Lab
15EE411
Electrical Machines II Laboratory
0
0
3
2
100
9
PC Lab
15EE412
Linear & Digital Integrated Circuits Laboratory 0
0
3
2
100
4
9
23 900
Total 17
FCBS - Foundation Compulsory Basic Science
PC
- Programme Core
FCES - Foundation Compulsory Engineering Science
FE
– Foundation Elective
3
SEMESTER 5:
S.NO
CATEGORY
SUB
SUB NAME
L
T
P
C
CODE
MAX
MARKS
1
FCBS
15MA501 Vector Spaces and Optimization Techniques
2
2
0
3
100
2
FCES
15ME521
Thermal & Fluid Mechanics
2
2
0
3
100
3
PC
15EE501
Measurements & Virtual Instrumentation
2
0
0
2
100
4
PC
15EE502
Control Systems
3
0
0
3
100
5
PSC
15EE0ZZ
PSC - I
3
0
0
3
100
6
PE
15EE0XX PE - I
3
0
0
3
100
7
PC Lab
15EE511
Control Systems Laboratory
0
0
3
2
100
8
PC Lab
15EE512
Measurements
Laboratory
Instrumentation 0
0
3
2
100
9
PROJECT
15EE513
Mini Project – I
0
0
4
2
100
Total 16
6
10 23 900
L
T
P
&
Virtual
SEMESTER 6:
S.NO CATEGORY SUB
SUB NAME
C
CODE
MAX
MARKS
1
FCES
15EC621
Communication Engineering
3
0
0
3
100
2
PC
15EE601
Power Transmission & Distribution
3
0
0
3
100
3
PC
15EE602
Power Electronics
3
0
0
3
100
4
PC
15EC402
Microprocessor & Microcontroller
3
0
0
3
100
5
PSC
15EE0ZZ
PSC - II
3
0
0
3
100
6
PE
15EE0XX PE - II
3
0
0
3
100
7
PC Lab
15EE611
Power Electronics Laboratory
0
0
3
2
100
8
PC Lab
15EC412
Microprocessor & Microcontroller Laboratory 0
0
3
2
100
9
PROJECT
15EE613
Mini Project - II
0
0
4
2
100
2
10 24 900
Total 18
4
FCBS - Foundation Compulsory Basic Science
PC
- Programme Core
FCES - Foundation Compulsory Engineering Science
PE – Programme Elective
PSC – Programme Soft Core
5
SEMESTER 7:
S.NO
CATEGORY
SUB
SUB NAME
L
T
P
C
CODE
MAX
MARKS
1
PC
15EE701
Power System Analysis
3
0
0
3
100
2
PC
15EE702
Electrical Machine Design
3
0
0
3
100
3
PSC
15EE0ZZ
PSC - III
3
0
0
3
100
4
PE
15EE0XX PE – III
3
0
0
3
100
5
PE
15EE0XX PE - IV
3
0
0
3
100
6
PC Lab
15EE711
Power System Simulation Laboratory
0
0
3
2
100
7
PC Lab
15EE712
Computer Aided Design of Electrical Machines 0
Laboratory
0
3
2
100
8
PROJECT
15EE713
Project Work- Phase I
0
0
8
4
100
Total 15
4
14 23 800
L
T
P
SEMESTER 8:
S.NO
CATEGORY
SUB
SUB NAME
C
CODE
1
PC
15EE801
2
PE
3
4
MAX
MARKS
2
0
0
2
100
15EE0XX PE – V
3
0
0
3
100
PE
15EE0XX PE - VI
3
0
0
3
100
PROJECT
15EE811
0
0
24 12 100
Total 9
0
24 20 400
Protection & Switchgear
Project Work -Phase II
PC - Programme Core
PE – Programme Elective
PSC – Programme Soft Core
6
Programme Elective (PE) Groups:
S.no
1
2
3
4
5
6
7
8
Group Name
Power Systems
Advanced Power Systems
Soft Computing
Electrical Machines
Power Electronics
Analog Electronics
VLSI
Control & Automation
Subject Code
List of Subjects
15EE001
Electrical Energy Utilization &
Conservation
15EE002
Renewable Energy Systems
15EE003
Power System Operation & Control
15EE004
Power Quality
15EE005
FACTs Technology
15EE006
Smart Grid Evolution
15EE007
Genetic Algorithms
15EE008
Neural Networks
15EE009
Fuzzy Logic
15EE010
Special Machines
15EE011
Analysis of Electrical Machines
15EE012
Computer Aided Design of Machines
15EE013
Power Semiconductor Devices
15EE014
Nano Electronics Principles and
Devices
15EE015
Application of Power Electronics in
Renewable Energy Systems
15EE016
Analysis & design of Analog
Integrated Circuits
15EE017
Analog VLSI
15EE018
Industrial Electronics
15EE019
Digital System Design using VHDL
15EE020
Low Power VLSI Design Techniques
15EE021
Principles of ASIC Design
15EE022
PLC & Industrial Automation
15EE023
Robotics
15EE024
MEMS
7
9
Signal Processing
10
11
12
Embedded Systems
Software Packages
Management
15EE025
Digital Image Processing and its
Applications
15EE026
Advanced Discrete Time Signal
Processing
15EE027
Digital VLSI Signal Processing
15EE028
Advanced Microcontrollers
15EE029
Wireless Sensor Network and its
Applications
15EE030
Real Time Embedded Systems
15EE031
Fundamentals of Database Systems
15EE032
MATLAB & Its Applications
15EE033
Electronic Design Automation Tools
15EE034
Enterprise Resource Planning
Techniques
15EE035
Human Resource and Personal
Management
15EE036
Random Variables and Resource
Management Techniques
Programme Soft Core Group (PSC ):
SS
Subject Code
Subject Name
1
15EE081
Power Generation Systems
2
15EE082
Discrete Time Signal Processing
3
15EE083
VLSI Systems
4
15EE084
Advanced Control Theory
5
15EE085
Solid State Drives
8
Course Code
15EE101
Course Name
L
3
BASICS OF ELECTRICAL AND ELECTRONICS
ENGINEERING
1. Course pre-requisites
Contact Hours
T
P C
2
0 2
: Nil
2.Course Objectives
i.
ii.
iii.
iv.
v.
To expose the rudiments of electric circuits
To know various types and working of measuring equipments and transducers
To familiarize with the constructional details of different types of electrical machines,
working principle and their performances.
To learn the construction and characteristics of diodes and bipolar transistors.
To learn the basic principles of opto electronic devices.
UNIT -I
BASICS OF CIRCUIT ANALYSIS ( DC Analysis only)
9
Ohm’s Law - Kirchoff’s laws – Source transformation - Resistors in series and parallel –
Voltage and current division - Introduction to AC Circuits – RMS value – Average valuePower and Power factor.
UNIT II – MEASURING INSTRUMENTS AND TRANSDUCERS
9
Basic principles of indicating instruments- Classification- Operating Principle-Ammeter and
Voltmeter- Dynamometer type Watt meters and Energy meters – Megger –TransducersThermistor – Thermocouple – Piezo and photo electric transducer.
UNIT III - ELECTRICAL MACHINES
9
Construction -Principle of Operation- Basic equations and applications of Dc machinesSingle phase transformer- Three phase and single phase induction motors.
UNIT IV – DIODES AND BIPOLAR JUNCTION TRANSISTORS
9
PN junction diode – Zener Diode - Characteristics – Half wave and Full wave rectifiersBipolar Junction Transistor – CB, CE and CC configurations-Characteristics.
UNIT –V
OPTO ELECTRONIC DEVICES
9
Photo conductive, Photo voltaic, Photo emissive sensors- LED-LCD-LDR-Laser diodes – Opto
couplers- Fibre optics.
Total: 45 Hours
9
3.Course outcomes:





Calculate current flow through any branch of the circuit, voltage across the device and
power dissipation across the resistors and they can find average and RMS values of AC
voltage and current.
Indentify and understand the principle of operation of various measuring instruments and
Transducers.
Understand the Principle of operation of Electrical Machines and their applications.
Understand the characteristics of Basic Electronic Devices
Understand the Principle and characteristics of Opto Electronic Devices
Text Book
A. Muthusubramanian R, Salivahanan S and Muraleedharan K A, “Basic Electrical
and Electronics”, Tata McGraw Hill, Fourth Edition, 2010.
B. S. Salivahanan, N. Suresh Kumar and A. Vallavaraj, “Electronic Devices and Circuits”,
2nd Edition, Tata McGraw Hill. Ninth reprint 2010
References
C. A.E.Fitzgerald, Charles Kingsley and Stephan.D.Umans, “ Electric Machinery”,
Mc Graw Hill, Seventh Edition, 2013
D. Thomas.L.Floyd, “Electronic Devices”, Prentice Hall, Ninth Edition, 2012
E. Sudhakar.A and Shyam mohan.S Palli “Circuits and Networks: Analysis &
Synthesis” 4th Edition, Tata Mc Graw Hill. 2010
F. Ravish Singh, “Electrical Networks”, Tata Mc Graw Hill, New Delhi, 2008.
10
Course Code
15ME127
Course Name
Contact Hours
ENGINEERING PRACTICES LAB
1. Course pre-requisites
L
T
P
C
0
0
3
2
: NIL
2. Course learning objectives
:
i.
To provide exposure to the students with hands on experience on various basic
engineering practices in Civil, Mechanical, Electrical and Electronics Engineering.
ii.
To provide fundamental knowledge and hands on experience to the students on
various basic engineering practices in Civil, Mechanical, Electrical and Electronics
Engineering.
3. Expected Level of Output
: Practical
4. Department Offered
: Mechanical Engineering
5. Nature of the Course
: Group 5 - Practical
Continuous Internal Assessment (CIA)
: 40 Marks
Semester End Examination (SEE)
: 60 Marks
6. List of Experiments:
GROUP A (MECHANICAL & CIVIL)
MECHANICAL ENGINEERING PRACTICE
1. Sheet Metal: Study of tools, equipments and safety precautions, Different types of joints
- knocked up, double grooving joints, Model making –Tray and Funnel.
6
2. Welding: Arc welding practice - butt joint, lap joints and tee joints, Demonstration of gas
welding.
4
11
CIVIL ENGINEERING PRACTICE
1. Plumbing: Preparation of plumbing line sketches for (i) water supply lines (ii) sewage
lines, cutting and threading of PVC pipes, Basic pipe connection using valves, taps,
couplings, unions, reducers, and elbows in household fitting.
6
2. Wood Work: Sawing, planning, making common joints like T joint, dovetail joint, etc.
using power tools, Study of joints in door panels and wooden furniture.
5
3. Basic Construction Tools: Demonstration of power tools like rotary hammer,
demolition hammer, hand drilling machine, etc.
GROUP B (ELECTRICAL AND ELECTRONICS)
III ELECTRICAL ENGINEERING PRACTICE
9
1. Identification of meters and electrical components and Residential house wiring using
switches, fuse, indicator, lamp and energy meter.
2. Fluorescent lamp wiring and Stair case wiring.
3. Measurement of electrical quantities – voltage, current, power & power factor in RLC
circuit.
4. Measurement of energy using single phase energy meter.
5. Measurement of earth resistance.
IV ELECTRONICS ENGINEERING PRACTICE
12
1. Study of Electronic components using multimeter.
2. Measurement of AC signals parameters using CRO.
3. Study of logic gates.
4. Soldering practice – Components Devices and Circuits – Using general purpose
PCB.
5. Half wave rectifier and Full Wave Rectifier
7. Expected outcome of the course:
i.
Ability to fabricate carpentry components and pipe connections including plumbing works.
ii.
Ability to use welding equipments to join the structures.
iii.
Ability to fabricate electrical and electronics circuits.
12
Course Code
Course Name
15EE201
1.Course pre-requisites
Contact Hours
CIRCUIT THEORY
L
T
P
C
3
0
0
3
: Basic circuit concepts
2.Course learning objectives
:
i.
To understand the basic circuit concepts and analyze the dc and ac circuits by applying mesh
and nodal analysis
ii.
To analyze the dc and ac circuits by applying network reduction techniques and network
theorems.
iii.
To understand and analyze the concepts of transient analysis in RLC circuits.
iv.
To understand the concepts of resonance and coupled circuits
v.
To know the basic concepts in three-phase circuits and the methods to measure three phase
power.
UNIT I-BASIC CIRCUIT ANALYSIS
9
Mesh Analysis & Super Mesh Analysis for DC Circuits- Mesh Analysis & Super Mesh Analysis for
AC Circuits - Nodal and Super Nodal Analysis for DC circuits- Nodal and Super Nodal Analysis for
DC circuits- Principle of Duality
UNIT II-NETWORK REDUCTION AND NETWORK THEOREMS FOR DC AND AC 9
CIRCUITS
Network reduction: Voltage and Current division Source Transformation – Star Delta conversionSuperposition Theorem for DC and AC circuits- Thevenin’s and Norton Theorem for DC and AC
circuits- Maximum Power Transfer Theorem and Reciprocity Theorem for DC and AC circuits
UNIT III- TRANSIENT ANALYSIS FOR DC AND AC CIRCUITS
9
Transient response of RL and RC circuits for DC input- Transient response of RL and RC circuits for
AC input- Transient response of RLC circuits for DC input- Transient response of RLC circuits for
AC input .
UNIT IV-RESONANCE AND COUPLED CIRCUITS
9
Resonance : Series and Parallel Resonance- Phasor diagram, Frequency Response ,Q-factor,
Bandwidth and Problems- Self and Mutual Inductance , Coefficient of Coupling- Tuned Circuits –
Single Tuned Circuits.
13
UNIT V- THREE PHASE CIRCUITS
9
Analysis of Three Phase 3-Wire & 4 Wire circuits with Star connected Loads- Phasor diagram of
Voltages and Currents- Analysis of Three Phase 3-Wire & 4 Wire circuits with Delta connected
Loads- Phasor diagram of Voltages and Currents- Solving of Balanced and Unbalanced Load
Problems- Power and Power Factor measurements in Three Phase Circuits.
Total:45 Hours
Cc3.Course Outcomes:

Understand the basic circuit concepts and analyze the circuits by applying mesh
analysis and nodal analysis for dc and ac input.

Analyze the circuits by applying network reduction techniques and network theorems
for dc and ac input.

Analyze the transient response characteristics in RLC circuits.

Understand the resonance characteristics in RLC circuits and coupled circuits.

Analyze three phase circuits in star and delta connected loads and the methods to
measure three phase power and power factor.
TEXT BOOKS
A. Sudhakar A and Shyam Mohan SP, “Circuits and Network Analysis and Synthesis”, Tata
McGraw Hill, 2010
B. Ravish Singh, “Electrical Networks”, Tata Mc Graw Hill, New Delhi, 2008.
REFERENCE BOOKS
C. William H. Hay Jr, Jack E. Kemmerly and Steven M. Durbin, “Engineering Circuits Analysis”,
TMH publishers, 7th edition, New Delhi, 2010
D. Joseph A. Edminister, Mahmood Nahvi, “Electric circuits”, Schaum’s series, Tata McGraw
Hill,
E. New Delhi ,5th edition,2010.
F. Charles K. Alexander, Mathew N.O. Sadik, “Fundamentals of Electric Circuits”, 3rd Edition, McGraw
Hill, (2011).
14
Course Code
Course Name
15EE211
Contact Hours
CIRCUIT THEORY LABORATORY
1. Course pre-requisites
and Inductors in Series and Parallel.
2. Course learning objectives
L
T
P
C
0
0
3
2
: Study of circuit elements – Resistors, Capacitors
:
i.
ii.
iii.
To verify the circuit parameters using Basic laws, Mesh and Nodal methods.
To verify the circuit parameters using Network Theorems.
To analyze the Transient Response characteristics and Resonance conditions of RLC
circuits.
iv.
To determine the Three Phase Power using Wattmeter method and parameter analysis
in Series RLC circuits
v.
To understand the Multisim software and its application in Electrical Circuits
simulation.
3. Expected Level of Output
: Practical
4. Department Offered
: Electrical and Electronics Engineering
5. Nature of the Course
: Group 5 - Practical
Continuous Internal Assessment (CIA)
: 40 Marks
Semester End Examination (SEE)
: 60 Marks
6. List of Experiments:
1. Experimental Verification of laws – Ohms Law and Kirchhoff’s Law.
2. Experimental Verification of Mesh and Nodal Analysis.
3. Experimental Verification of Superposition Theorem.
4. Experimental Verification of Thevenin’s and Norton’s theorems.
5. Experimental Verification of Maximum Power Transfer and Reciprocity Theorem.
6. Experimental determination of Transient response of RL, RC and RLC Circuits.
7. Experimental determination of Frequency Response of Series and Parallel resonance
circuits.
8. Measurement of power in series RLC circuit.
9. Measurement of power in Three Phase Circuits by Two Watt Meter method.
10. Introduction to Electrical Circuits simulation using Multisim.
11. Verification of Ohms Law and Kirchhoff’s Law using Multisim.
12. Verification of Mesh and Nodal Analysis using Multisim.
13. Verification of Superposition Theorem Using Multisim.
15
7. Expected outcome of the course:
Students will be able to:
CO1: Verify the circuit parameters practically using basic Laws, Mesh and Nodal methods.
CO2: Verify the circuit parameters practically using Network Theorems.
CO3: Analyze the Transient Response characteristics and Resonance Conditions in RLC circuits.
CO4: Measure the Three Phase Power using Wattmeter methods
CO5: Exposed to Multisim software and its application in Circuit simulation.
16
Course Code
15EE221
Course Name
BASICS OF ELECTRICAL AND MECHANICAL ENGINEERING
1. Course pre-requisites
2. Course learning objectives
i.
ii.
iii.
iv.
v.
vi.
Contact Hours
L
T
P
C
3
0
0
3
: NIL
:
To expose the rudiments of Electric Circuits
To know various types and working of Measuring Equipments and Transducers
To familiarize with the constructional details of different types of Electrical Machines,
working principle and their performances.
To know about the working of basic Thermal Systems.
To learn the working principle of IC Engines and basic manufacturing process.
UNIT -I
BASICS OF CIRCUIT ANALYSIS ( DC anlaysis only)
9
Ohm’s Law - Kirchoff’s laws – Source transformation - Resistors in series and parallel –
Voltage and current division - Introduction to AC Circuits – RMS value – Average valuePower and Power factor.
UNIT II – MEASURING INSTRUMENTS AND TRANSDUCERS
9
Basic principles of indicating instruments- Classification- Operating Principle-Ammeter and
Voltmeter- Dynamometer type Watt meters and Energy meters – Megger –TransducersThermistor – Thermocouple – Piezo and photo electric transducer.
UNIT III - ELECTRICAL MACHINES
9
Construction -Principle of Operation- Basic equations and
applications of Dc machines- Single phase transformer- Three phase and single phase
induction motors.
UNIT IV - MECHANICAL ENGINEERING- BASIC THERMAL SYSTEMS
9
Introduction, Classification of Power Plants – Working principle of steam, Gas, Diesel, Hydroelectric and Nuclear Power plants – Merits and Demerits - Boilers – Classification - Operation of
Simple Vertical Boiler- Terminology of Refrigeration and Air Conditioning, Layout of typical
domestic refrigerator – Principle of Window and Split type room Air conditioner – Central Air
conditioner.
UNIT –V I.C ENGINES & BASIC MANUFACTURING TECHNOLOGY
9
Internal combustion engines - Components – Working principle of Petrol and Diesel Engines Sand casting –– Sand moulds - Type of patterns – Pattern materials–Pressure die casting, Sand
17
Casting defects – Inspection methods - Sheet metal characteristics - Typical sheet metal
operations - CNC Machines – Classification – Working Principle – Merits & Demerits.
TOTAL HOURS: 45
3. Course outcomes:
Upon successful completion of this course, the student will be able to:
 Calculate current flow through any branch of the circuit, voltage across the device and
power dissipation across the resistors and they can find average and RMS values of AC
voltage and current.
 Indentify and understand the principle of operation of various measuring instruments and
Transducers.
 Understand the Principle of operation of Electrical Machines and their applications.
 To understand the basic working of thermal systems.
 To Know the manufacturing of basic engineering components
TEXT BOOKS
A. Muthusubramanian R, Salivahanan S and Muraleedharan K A, “Basic Electrical
and Electronics”, Tata McGraw Hill, Fourth Edition, 2010.
B. Venugopal K and Prabhu Raja V, “Basic Mechanical Engineering”, Anuradha
Publishers, Kumbakonam, Reprint (2010)
REFERENCE BOOKS
C. Sudhakar.A and Shyam mohan.S Palli “Circuits and Networks: Analysis &
Synthesis” 4th Edition, Tata Mc Graw Hill. 2010
D. Ravish Singh, “Electrical Networks”, Tata Mc Graw Hill, New Delhi, 2008.
E. Hajra Choudhury, “Elements of Workshop Technology, Vol. I and II”, Media Promotors
Pvt Ltd., Mumbai, Reprint (2012)
18