SHRI VISHNU ENGINEERING COLLEGE FOR WOMEN:: BHIMAVARAM (AUTONOMOUS)
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING COURSE STRUCTURE – B. TECH
2018 – 2019
I YEAR - I SEMESTER
Sl. No
Sub. Code Subject Title L T P C I E TM CAT
1 UGBS1T0118 English – I 3 - - 3 40 60 100 HS
2 UGBS1T0218 Mathematics – I 2 1 - 3 40 60 100 BS
3 UGBS1T0418 Applied Chemistry (ECE & EEE)
3 - - 3 40 60 100 BS UGBS1T0518 Engineering Chemistry - (ME)
4 UGCS1T0118 Programming for Problem solving 3 - - 3 40 60 100 ES
5 UGBS1P0618 English communication skills lab - - 3 1.5 25 50 75 HS
6 UGBS1P0818
Applied Chemistry Lab (ECE & EEE) - - 3 1.5 25 50 75 BS
UGBS1P0918 Engineering Chemistry Lab (ME)
7 UGCS1P0218 Programming for Problem solving Lab
- - 3 1.5 25 50 75 ES
8 UGBS1A1118 Indian Constitution 2 - - - - - - MC
Total 13 1 9 16.5 235 390 625
I YEAR - II SEMESTER
Sl. No
Sub. Code Subject Title L T P C I E TM CAT
1 UGBS2T0118 English – II 3 - - 3 40 60 100 HS
2 UGBS2T0218 Mathematics – II 2 1 - 3 40 60 100 BS
3 UGBS2T0318 Waves, Oscillations and Quantum Mechanics
3 - - 3 40 60 100 BS
4 UGME2T0118 Engineering Drawing 2 - 2 3 40 60 100 ES
5
UGEE2T0118 Basic Electrical Engineering (ECE, EEE)
3 - - 3 40 60 100 ES
UGEE2T0218 Basic Electrical and Electronics Engineering (CSE, IT, ME, CE)
6 UGBS2P0618 Business Communication lab - - 3 1.5 25 50 75 HS
7 UGBS2P0718 Waves, Oscillations and Quantum Mechanics Lab
- - 3 1.5 25 50 75 BS
8 UGME2P0218 Workshop Practice and Innovation Lab
- - 3 1.5 25 50 75 ES
9 UGBS2A1018 Environmental Science 2 - - - - - - MC
Total 15 1 11 19.5 275 450 725
L-Lecture Hours, T-Tutorial Hours, P-Practical Hours, C-Credits, I-Internal Marks, E-External Marks, TM-Total Marks
SHRI VISHNU ENGINEERING COLLEGE FOR WOMEN:: BHIMAVARAM (AUTONOMOUS)
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING COURSE STRUCTURE – B. TECH
2018 – 2019
II YEAR - I SEMESTER
Sl. No
Subject Code
Subject Title L T P C I E TM CAT
1 UGEE3T0118 Electrical Circuit Analysis 2 2 - 4 40 60 100 PC
2 UGEE3T0218 Electro Magnetic Fields 3 - - 3 40 60 100 PC
3 UGEE3T0318 Electrical Machines – I 2 1 - 3 40 60 100 PC
4 UGEE3T0418 Analog Electronics – I 3 - - 3 40 60 100 PC
5 UGBS3T0218 M-III: Transform Calculus & Complex Variables
2 1 - 3 40 60 100 BS
6 UGEE3P0518 Electrical Circuits and simulation Lab
- - 3 1.5 25 50 75 PC
7 UGEE3P0618 Analog Electronics – I Lab - - 3 1.5 25 50 75 PC
8 UGEE3P0718 Electrical Machines – I Lab - - 3 1.5 25 50 75 PC
9 UGBS3A0418 Effective Technical Communication
2 - - - - - - MC
Total 14 4 9 20.5 275 450 725
II YEAR - II SEMESTER
Sl. No
Subject Code
Subject Title L T P C I E TM CAT
1 UGEE4T0118 Electrical Machines – II 2 2 - 4 40 60 100 PC
2 UGEE4T0218 Analog Electronics – II 3 - - 3 40 60 100 PC
3 UGEE4T0318 Digital Electronics 3 - - 3 40 60 100 PC
4 UGEE4T0418 Electrical Measurements 2 2 - 4 40 60 100 PC
5 Open Elective 1 3 - - 3 40 60 100 OE
6 UGEE4P0518 Electrical Measurements Lab - - 3 1.5 25 50 75 PC
7 UGEE4P0618 Digital Electronics Lab - - 3 1.5 25 50 75 PC
8 UGEE4P0718 Analog Electronics – II Lab - - 3 1.5 25 50 75 PC
9 UGEE4J0718 Mini Project – 1 - 1 2 2 50 - 50 PW
10 UGBS4A0418 Essence of Indian Traditional Knowledge
2 - - - - - - MC
Total 14 4 13 23.5 325 450 775
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 1
ELECTRICAL CIRCUIT ANALYSIS
Subject Code: UGEE3T0118 L T P C
II Year / I Semester 2 2 0 4
Prerequisites: Laplace Transforms, Vectors, Complex numbers
Course Objective: This course aims at study of basic circuit laws, theorems, three phase
systems, transient analysis and two port networks for the future study and analysis of power
systems.
Syllabus
UNIT I: Network Theorems (DC & AC Excitations) 10hrs
Superposition theorem, Thevenin’s theorem, Norton’s theorem, Maximum Power Transfer
theorem, Reciprocity theorem, Millman’s theorem and compensation theorem- Super Node
and Super Mesh Analysis with both independent and dependent sources. Concept of duality
and dual networks.
UNIT II: Three Phase Circuits 10hrs
Three phase circuits: Phase sequence- Star and delta Connection-Relation between line and
phase voltages and currents in balanced Systems-Analysis of balanced three phase circuits-
Measurement of Active and Reactive power in balanced three phase systems. Analysis of Three
Phase unbalanced circuits-Loop Method- Application of Millman‘s Theorem- Star Delta
Transformation Technique
UNIT III: Time Domain Analysis of Electrical Circuits 8hrs
Time-domain analysis of first and second order differential equations for Series and parallel
R-L, R-C, RLC circuits, initial and final conditions in network elements, forced and free
response, time constants, steady state and transient state response.
UNIT IV: Electrical Circuit Analysis Using Laplace Transforms 8hrs
Analysis of electrical circuits using Laplace Transform for standard inputs, convolution integral,
inverse Laplace transform, transformed network with initial conditions. Transfer function
representation. Poles and Zeros, Frequency response (magnitude and phase plots).
UNIT V: Analysis of Coupled Circuits 8hrs
Dot Convention, Self, mutual Inductance, coupling coefficient, Self, Mutual Inductance and
their relation. Series and parallel aiding and opposing. Determination of Inductance in
transformer connections. Analysis of Coupled circuits using mesh analysis
UNIT VI: Two Port Networks 8hrs
Z parameters, Y parameters, ABCD parameters and hybrid parameters and their relations.
Interconnections of two port networks.
Course Outcomes:
CO1: Able to Apply network theorems for the analysis of electrical circuits
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 2
CO2: Able to solve three phase balanced and unbalanced circuits
CO3: Able to obtain the transient and steady-state response of electrical circuits
CO4: Able to solve circuits using Laplace transforms
CO5: Able to compute self and mutual inductance in a coupled circuit
CO6: Able to determine Z, Y and ABCD parameters for two port networks
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1 2 1
CO2 1 1 1 2
CO3 1 2 2 1 1
CO4 1 2 2
CO5 1 1 2 1 2 2
CO6 1 2 1
TEXT BOOKS:
1. “Engineering Circuit Analysis” by William Hayt and Jack E. Kemmerley, 6thedition, McGraw
Hill Company,
2. “Network Analysis” by Van Valkenburg, 3rd edition, PHI Learning, 2006.
3. “Fundamentals of Electric circuits” by C. K. Alexander and M. N. O. Sadiku, 5th edition, Mc
Graw hill Publishers, 2013
REFERENCE BOOKS:
1. “Circuit Theory (Analysis and Synthesis) by A. Chakrabarthi, 7th edition, Dhanpat Rai & co.
2015
2. “Introductory circuit analysis” by Robert L Boylestad, 12th edition, Pearson Eductaion, 2013
3. “Network analysis & synthesis” by Ravish. R. Singh, 1st edition, Mc-Graw Education, 2016
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 3
ELECTROMAGNETIC FIELDS
Subject Code: UGEE3T0218 L T P C
II Year / I Semester 3 0 0 3
Prerequisites: Engineering Physics
Course Objective: Electromagnetic fields are the foremost pre-requisite course for most of
the subjects in Electrical Engineering. Either in the enunciation of basics of electrical elements
R, L and C that are the building blocks of any electrical device or in the illustration of Energy
transfer from mechanical to electrical and vice versa its role is crucial. This course also includes
the famous works of Coulomb, Ampere, Faraday, Maxwell etc. to the field of Electrical
Engineering.
Syllabus
UNIT I: Coordinate Systems & Vector Calculus 8 hrs
Vector Algebra: Scalars and Vectors, Unit Vector, Vector Addition, Subtraction and
multiplication - Coordinate Systems and Transformation: Cartesian Coordinates, Circular
Cylindrical Coordinates, Spherical Coordinates, and Conversion of a vector from one coordinate
system to another - Vector calculus: Differential Length, Area, and Volume - Line, Surface,
and Volume Integrals - Del Operator, Gradient of a Scalar, Divergence of a Vector and
Divergence Theorem, Curl of a Vector and Stokes's Theorem, Laplacian of a Scalar
UNIT II: Steady Electric Fields 10 hrs
Coulomb’s law, Electric field intensity (EFI), Electrical field due to point charge, Line, Surface
and Volume charge distributions. Calculation of EFI for different configurations, electric flux
and flux density, Gauss law and its applications. Work done in moving a point charge, Electric
potential, potential difference, relation between E and V. Calculation of potential differences
for different configurations. Potential due to Electric dipole, Electrostatic Energy and Energy
density.
UNIT III: Conductors, Dielectrics and Capacitance 10 hrs
Current and current density - Convection current density, conduction current density,
properties of a perfect conductor, Ohms Law in Point form, Continuity equation, Dielectrics –
Polarization, dielectric constant and dielectric strength, Boundary conditions. Permittivity of
dielectric materials, Poisson’s equation, Laplace’s equation, Solution of Laplace equation (one
variable), Capacitance, capacitance of various geometries – energy stored in capacitance
UNIT IV: Steady Magnetic Fields 8 hrs
Biot-Savart Law, Magnetic field intensity (MFI) – MFI due to a straight current carrying
filament, circular, square and solenoid current carrying wire - Ampere’s Circuital Law –
applications of amperes law -Magnetic Flux and Magnetic Flux Density. Scalar and vector
magnetic potentials
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 4
UNIT V: Magnetic Forces and Inductance 8 hrs
Force on a Moving Charge – Lorentz force equation, Force on a Differential Current Element,
Force between Differential Current Elements, Torque on a rectangular current loop in a
magnetic field, Magnetization and Permeability, self-inductance - of a solenoid, toroid, co-axial
cable and two wire transmission line - Mutual Inductance-Neumann’s formula, energy density
&energy stored in magnetic field
UNIT VI: Time-Varying Fields 8hrs
Faraday’s Law – motional emf, transformer emf, Displacement Current – its significance,
modification of Maxwell’s Equations in Point Form and Integral Form, Poynting Theorem and
Poynting vector
Course Outcomes:
CO1: Able to understand vector algebra and various coordinate systems
CO2: Able to obtain static electric field by applying Gauss law for simple configurations
CO3: Able to determine capacitance of various geometries
CO4: Able to calculate static magnetic field by applying Amperes law for simple
configurations
CO5: Able to calculate self and mutual inductances of various geometries
CO6: Able to analyze time varying electric and magnetic fields.
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 1
CO2 1 1
CO3 1 1 2
CO4 1 1
CO5 1 1 2
CO6 1 1 TEXT BOOKS:
1. “Engineering Electromagnetics”, by William H. Hayt & John. A. Buck, 7thEditon, Mc. Graw-
Hill Companies, 2006.
2. “Elements of electromagnetics”, by Matthew N. O. Sadiku, 4th Edition, Oxford University
Press, 2007.
3. “Introduction to Electro Dynamics” by D J Griffiths, 2nd edition, Prentice-Hall of India Pvt.
Ltd, 2014.
REFERENCE BOOKS:
1. “Electromagnetism - Theory and applications”, A. Pramanik, 2nd edition, PHI Learning Pvt.
Ltd, 2009.
2. “Engineering Electromagnetics (Theory, Problems and Application)”, by J. P. Tewari, 2nd
edition, Khanna publishers, 2013.
3. “Electromagnetics” by J. D Kraus 4th edition, McGraw-Hill Inc. 1992.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 5
ELECTRICAL MACHINES-I
Subject Code: UGEE3T0318 L T P C
II Year / I Semester 2 1 0 3
Prerequisites: Fundamental Laws in Electromagnetism, Basic Electrical Engineering
Course Objective: To understand the concepts of Magnetic circuits, DC Machines and
Transformers.
Syllabus
UNIT I: ELECTROMAGNETIC FORCE AND TORQUE 10hrs
Principles of Electromechanical Energy conversion – Forces and Torque in magnetic field
systems – energy balance- energy and force in a singly excited magnetic field system,
determination of magnetic force - CO-energy – Multi excited magnetic field systems-
construction features of conventional and modern DC machines.
UNIT II: DC MACHINES 10hrs
Visualization of magnetic field produced by the field winding excitation with armature winding
open, air gap flux density distribution, flux per pole. Armature windings–lap and wave
windings- equalizer rings. Commutation Process, methods of improving commutation.
Armature MMF wave, Armature reaction, air gap flux density distribution with armature
reaction, Compensation Methods of Armature Reaction.
UNIT III: CHARACTERISTICS OF DC MACHINES 10hrs
Open circuit characteristic of separately excited DC generator, voltage build-up in a shunt
generator, critical field resistance and critical speed, causes for failure to self-excited and
remedial measures. Load characteristics of DC generators, Performance characteristics of DC
Motors
UNIT-IV: PARALLEL OPERATION AND TESTING OF D.C. MACHINES 8hrs
Parallel operation of dc shunt, series and compound generators, Direct Testing - brake test
on DC Motors, load test on DC generators, Indirect testing: Swinburne‘s test-- Hopkinson‘s
test – Field’s test - Retardation test-- separation of losses - problems.
UNIT V: SINGLE PHASE TRANSFORMER AND AUTO TRANSFORMER 8hrs
Operation of single-phase transformers at different loads with phasor diagrams, testing - open
circuit and short circuit tests, polarity test, Sumpner’s test, separation of hysteresis and eddy
current losses, Efficiency and Regulation calculations. Autotransformers - construction,
principle, applications and comparison with two winding transformer, Parallel operation of
single-phase transformers
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 6
UNIT VI: POLY-PHASE TRANSFORMER 10hrs
Three-phase transformer - construction, types of connection and their comparative features,
Phase conversion – Scott connection, Tap-changing transformers - No-load and ON-load tap
changing of transformers, Three-winding transformers – Determination of Zp, Zs and Zt.
Course Outcomes:
CO1: Able to acquire the knowledge on the production of Electromagnetic force and torque in
Electrical Machines.
CO2: Able to analyze the flux distribution and commutation process in a DC Machine.
CO3: Able to determine the performance characteristics of a DC machine
CO4: Able to evaluate the performance of DC Machines.
CO5: Able to examine the performance of Transformers and analyze the magnetizing current.
CO6: Able to demonstrate the concepts of Phase conversion, Parallel operation and Tap
changing of Transformers.
CO-PO MAPPING:
TEXT BOOKS:
1. "Electric Machinery”, A. E. Fitzgerald, C. Kingsley and S. D. Umans, 6th Edition, McGraw-
Hill, 2003.
2. “Performance and Design of Direct Current machines”, A. E. Clayton and N. N. Hancock, 1st
Edition, CBS Publishers, 2004.
3. “Electric Machines”, I. J. Nagrath and D. P. Kothari, 5th Edition, McGraw Hill Education,
2010.
REFERENCE BOOKS:
1. “A Text Book of Electrical Machines”, R. K. Rajput, 4th Edition, Laxmi Publications, 2006.
2. “Electrical Machinery”, P. S. Bimbhra, 7thEdition, Khanna Publishers, 2011.
3. “Electrical Machines”, Smarajit Ghosh, 2nd Edition, Pearson, 2012.
PO’s 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2
CO2 1 2 2
CO3 1 1 2
CO4 1 1 2
CO5 1 1 1 2
CO6 1 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 7
ANALOG ELECTRONICS - I
Subject Code: UGEE3T0418 L T P C
II Year / I Semester 3 0 0 3
Prerequisites: Semiconductor Physics
Course Objective: The objective of this course is to introduce the students about the
fundamentals concepts of semiconductor diodes, Transistor and their applications. It also
introduces wave shaping concepts of both linear and non-linear circuits and design of
multivibrators. At the end of the course, the students are expected to know about the
applications of the semiconductor devices.
Syllabus
UNIT 1: DIODE CIRCUITS 10hrs
Energy Band Diagrams of insulators, semiconductors and metals, Intrinsic and extrinsic
semiconductors, Drift and diffusion charge Densities of semiconductors, P-N junction diode,
I-V characteristics of a diode, Zener diodes- Applications, Tunnel Diode
Unit II: LINEAR WAVE SHAPING 8hrs
Response of High pass and low pass RC circuits to different signals sinusoidal, step, pulse,
square, exponential and ramp), high pass RC circuit as a differentiator, low pass RC circuit as
an integrator, attenuator, its application in CRO probe.
Unit-III: NON LINEAR WAVE SHAPING 8hrs
Clipping circuits: Diode clippers, Shunt Clippers, Series clippers, clipping at two independent
levels, transfer characteristics of clippers, Comparators, Applications of Voltage comparators.
Clamping Circuits: clamping circuits using diode with different inputs, clamping circuit
theorem, Practical clamping circuits, and transfer characteristics of clampers
Unit IV: BJT and FET circuits 12hrs
BJT: Structure and configuration of BJT with input and output characteristics, BJT as a switch,
BJT as an amplifier.
FET: Types of FET, Characteristics, MOSFET as a switch and an Amplifier.
UNIT V: TRANSISTOR BIASING 8hrs
Need for Biasing, Operating point, load line analysis, BJT Biasing - Different Methods,
compensation techniques.
FET biasing – different methods, generalized analysis of transistor amplifier model using h-
parameters (frequency response)
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 8
UNIT VI: MULTIVIBRATORS: 10hrs
Bistable vibrators: Design and analysis of fixed and self-bias transistor binary.
Monostable: collector coupled mono-stable multivibrator, waveforms at bases and collectors,
Astable multivibrator: Collector coupled Astable multivibrator, Astable multivibrator as a
voltage to frequency converter
Course Outcomes:
CO1: Understand the concepts of various materials used in electronic devices
CO2: To design linear and non-linear wave shaping circuits
CO3: Analyze the operation of Transistor as an amplifier circuits
CO4: Select the Q-Point for the transistor biasing and stabilization
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 1 2
CO2 1 1 2 2 1
CO3 1 2 2 1
CO4 1 2 1
TEXT BOOKS:
1. “Electronic Devices and Circuits”, J Millman, Chritophas C Halkias, and Satyabratajit Vol 1,
4th Edition, McGraw Hill Edition, 2015.
2. “Pulse, Digital and Switching Waveforms”, Jacob Millman and Herbert Taub, Vol 1, 3rd
Edition, McGraw Hill Edition, 2011.
3. “Electronic Devices and Circuit theory”, R L Boylestad and Louis Nashelsky, Vol 1, 11th
Edition, Pearson Education, 2006.
4. “Pulse and Digital Circuits”, Venkata Rao K, Rama Sudha K and Manmadha Rao G, Vol 1,
1st Edition, 2010
REFERENCE BOOKS:
1. “ELECTRONIC PRINCIPLES”, Albert Malvino and David J Bates, Vol 1, 8th Edition, MC Graw
Hill Edition, 2015
2. “Electronic Devices”, Thomas L Floyd, Vol 1, 9th Edition, Pearson Education, 1996
3. “Electronic Devices and Circuits”, David A Bell, Vol 1, 5 Edition, Oxford University Press,
2008.
4. “Electronic Devices &Circuits”, J B Gupta, Vol 1, 6st Edition, S K Kataria & Sons, 2016
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 9
TRANSFORM CALCULUS & COMPLEX VARIABLES
Subject Code: UGBS3T0218 L T P C
II Year / I Semester 2 1 0 3
Prerequisites: Limit, Continuity and Differentiability of a Complex Function
Syllabus
Unit-I: NUMERICAL METHODS-I 8hrs
Solution of polynomial and transcendental equations – Bisection method, Newton-Raphson
method and Regula - Falsi method. Finite differences, Interpolation using Newton’s forward
and backward difference formulae.
Unit-II: NUMERICAL METHODS-II 8hrs
Ordinary differential equations: Taylor’s series, Runge - Kutta method of fourth order for
solving first order equations. Numerical integration: Trapezoidal rule and Simpson’s 1/3rd and
3/8 rules.
Unit-III: LAPLACE TRANSFORM 8hrs
Laplace transform of standard functions-Shifting Theorems, Transforms of derivatives and
integrals, multiplication by tn, division by t , Periodic functions – Unit step function –Dirac‘s
delta function- Inverse Laplace transforms–Properties- Convolution theorem (without proof).
Unit-IV: PARTIAL DIFFERENTIAL EQUATIONS 8hrs
Definition of Partial Differential Equations, Formation of partial differential equations, solutions
of first order linear and non-linear PDEs using Lagrange’s Method.
Unit-V: FUNCTIONS OF A COMPLEX VARIABLE 8hrs
Introduction –– Analyticity – Properties – Cauchy-Riemann equations in Cartesian and polar
coordinates. Harmonic and Conjugate harmonic functions – Milne – Thompson method.
Unit-VI: COMPLEX INTEGRATION AND SERIES EXPANSIONS 8hrs
Complex integration: Line integral – Cauchy‘s integral theorem – Cauchy‘s integral formula –
Generalized integral formula (all without proofs) - Radius of convergence – Expansion of a
function in Taylor‘s series, Maclaurin‘s series and Laurent series
Course Outcomes:
CO1: To provide students with techniques to solve differential equations by Laplace transform
method and apply them to engineering problems.
CO2: To train students to solve real time engineering problems using partial differential
equations.
CO3: To make students understand the importance of approximate solutions essential in
various complex problems.
CO4: To prepare to understand basic principles of complex analytic functions.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 10
CO5: To train the students to solve engineering problems involving complex integrals
CO-PO MAPPING:
Text Books:
1. B.S. Grewal, Higher Engineering Mathematics, Khanna Publishers
2. Ramana B.V., Higher Engineering Mathematics, Tata McGraw Hill New Delhi, 11th Reprint,
2010.
3. N. P. Bali and Manish Goyal, A text book of Engineering Mathematics, Laxmi Publications,
Reprint, 2008.
PO’s 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1
CO2 1 2 1
CO3 1 2 1
CO4 1 2 1
CO5 1 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 11
ELECTRICAL CIRCUTS AND SIMULATION LAB
Subject Code: UGEE3P0518 L T P C
II Year / I Semester 0 0 3 1.5
List of Experiments
Any 10 of the following experiments are to be conducted
1. Verification of Thevenin’s and Norton’s Theorems.
2. Verification of Superposition theorem and Maximum Power Transfer Theorem.
3. Verification of Compensation Theorem.
4. Verification of Reciprocity, Millman’s Theorems.
5. Locus Diagrams of RL and RC Series Circuits.
6. Series and Parallel Resonance
7. Determination of Self, Mutual Inductances and Coefficient of coupling.
8. Z and Y Parameters
9. Transmission and hybrid parameters
10. Measurement of Active Power for Star and Delta connected balanced loads.
11. Measurement of Reactive Power for Star and Delta connected balanced loads.
12. Measurement of 3-phase Power by two Wattmeter Method for unbalanced loads.
13. Simulation of DC Circuits using Nodal Analysis
14. Simulation of DC Circuits using Mesh Analysis
15. Simulation of network theorems
Course Outcomes:
CO1: Having knowledge on circuit theorems, two port networks, resonance and R, L, C circuits
CO2: Develop technical writing skills important for effective communication.
CO3: Acquire teamwork skills for working effectively in groups
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1 2 2
CO2 2 1
CO3 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 12
ANALOG ELECTRONICS -I LAB
Subject Code: UGEE3P0618 L T P C
II Year / I Semester 0 0 3 1.5
List of Experiments
PART A: ELECTRONIC WORKSHOP PRACTICE
1. Identification, Specifications, Testing of R, L, C Components (Color Codes), Potentiometers,
Switches (SPDT, DPDT, and DIP), Coils, Gang Condensers, Relays, Bread Boards.
2. Identification, Specifications and Testing of Active Devices, Diodes, BJTs, JFETs, MOSFETs,
Power Transistors, LEDs, LCDs, Optoelectronic Devices.
3. Soldering Practice – Simple Circuits using active and passive components.
4. Single layer and Multi-layer PCBs (Identification and Utility).5.
5. Study and operation of Ammeters, Voltmeters, Transformers, Analog and Digital Multi-
meters, Function Generator, Regulated Power Supplies and CRO.
PART B:
1. PN Junction diode characteristics (Static and Dynamic Resistance and Cut-in Voltage)
2. Zener diode Reverse Bias characteristics and Zener Diode as a regulator
3. Half wave Rectifier (with & without filters)
4. Center Tap Full wave Rectifier with filters (with & without filters)
5. Bridge Rectifier with filters (with & without filters)
6. Transistor CB characteristics (Input and Output) & h Parameter calculations
7. Transistor CE characteristics (Input and Output) & h Parameter calculations
8. FET characteristics (Drain, Transfer characteristics) and calculate Drain Resistance (rd),
Trans Conductance (gm), Amplification factor (µ).
9. Emitter Characteristics of UJT
10. Design and verify Self Bias Circuit. (Q - Point)
11. Frequency response of CE Amplifier (With and without Emitter bypass capacitor and
calculate Bandwidth, input and output impedances).
12. Frequency response of CC Amplifier (Emitter Follower) and calculate Bandwidth, input
and output impedances.
Course Outcomes:
CO1: Having knowledge on characteristics of various diodes, applications, characteristics of
Transistors and amplifier circuits.
CO2: Develop technical writing skills important for effective communication.
CO3: Acquire teamwork skills for working effectively in groups
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1 1
CO2 2 1
CO3 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 13
ELECTRICAL MACHINES- I LAB
Subject Code: UGEE3P0718 L T P C
II Year / I Semester 0 0 3 1.5
List of Experiments
Any ten of the experiments from the following are to be conducted.
1. Magnetization characteristics of DC Shunt Generator. Determination of critical field
resistance and critical speed.
2. Load test on DC Shunt Generator. Determination of Characteristics.
3. Load test on DC Series Generator. Determination of Characteristics.
4. Load test on DC compound Generator. Determination of Characteristics.
5. Hopkinson‘s test on DC shunt machines. Predetermination of efficiency.
6. Field‘s test on DC series machines. Determination of efficiency.
7. Swinburne‘s Test. Predetermination of DC Generator and DC Motor Efficiency.
8. Brake Test on DC compound motor. Determination of performance curves.
9. Brake Test on DC shunt motor. Determination of Performance curves.
10. Separation of losses in DC shunt motor.
11. Speed Control of DC shunt Motor by Field and Armature control Methods.
12. Retardation Test on DC shunt machine.
Course Outcomes:
CO1: Provide practical hands on experience of DC Machines.
CO2: Acquire teamwork skills for working effectively in groups.
CO3: Develop technical writing skills important for effective communication.
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1
CO2 2 1
CO3 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 14
Effective Technical Communication
(Mandatory course)
Subject Code: UGBS3X0418 L T P C
II Year / I Semester 2 0 0 0
COURSE OBJECTIVES:
To expose students to different contexts through right vocabulary
To inculcate the habit of reading and understanding any text
To enable students to acquire the ability of writing for business purposes
To enable students to acquire interview skills and group discussion dynamics
Syllabus
UNIT – I: 2 sessions
Selected High GRE Words, Idioms & Phrases – Discourse Skills – using visuals – Synonyms
and antonyms, word roots, one word substitutes, prefixes and suffixes, study of word origin,
business vocabulary, analogy, idioms and phrases, collocations & usage of vocabulary.
UNIT – II: 2 sessions
Reading Comprehension – General Vs Local Comprehension, reading for facts, guessing
meanings from context, scanning, skimming, inferring meaning.
UNIT – III: 2 sessions
Writing Skills – Structure of Resume writing – Portfolio writing –Short Report Writing
(Business/Technical)
UNIT – IV: Presentations (Technical)
UNIT – V: 2 sessions
Group Discussion – Dynamics of Group Discussion, Intervention, summarizing, modulation of
voice, body language, relevance, fluency and organization of ideas and rubrics for evaluation.
UNIT – VI: 3 sessions
Interview Skills – Concept and process – pre-interview planning, opening strategies, answering
strategies, interview through teleconference & video-conference and mock interviews.
SUGGESTED SOFTWARE:
1. K-Van solutions Software with CD
2. Oxford advanced learner’s compass, 7th Edition
SUGGESTED READING:
1. Technical Communication by Meenakshi Raman & Sangeeta Sharma, Oxford
University Press, 2009.
2. Business and Professional Communiction: Keys for Workplace Excellence. Kelly M.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 15
Quintanilla & Shawn T. Wahl. Sage South Asia Edition. Sage Publications. 2011.
3. English Vocabulary in Use Series, Cambridge University Press 2008.
4. Communication Skills by Leena Sen, PHI Learning Pvt. Ltd., New Delhi, 2009.
5. A Course Book of Advanced Communication Skills Lab published by University Press,
Hyderabad.
COURSE OUTCOMES:
Upon the completion of the course, the student will be able to:
CO1: Choose vocabulary contextually.
CO2: Comprehend, analyze and interpret the text in a definite time frame.
CO3: Write resumes cohesively and coherently.
CO4: Construct and elaborate on a given topic.
CO5: Comprehend and practice the dynamics of group discussion.
CO6: Comprehend the concept and process of interview; answering through mock
interviews.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 16
ELECTRICAL MACHINES-II
Subject Code: UGEE4T0118 L T P C
II Year / II Semester 2 2 0 4
Prerequisites: Fundamental Laws in Electromagnetism, Basic Electrical Engineering
Course Objective: To understand the concepts of Induction and Synchronous Machines.
Syllabus
UNIT I: AC Machine Windings and Revolving Magnetic Fields 8hrs
Armature windings- Distributed and concentrated windings - distribution - pitch and winding
factors, Windings spatially shifted by 90 degrees, Three windings spatially shifted by 120
degrees, Concept of revolving magnetic field and pulsating.
UNIT II: Induction Machines 8hrs
Types (squirrel cage and slip-ring), EMF equation, slip, rotor current, starting torque, running
torque, maximum torque, relationship between rotor input, rotor copper loss, and mechanical
power developed. Equivalent circuit. Phasor Diagram, Effect of parameter variation on torque
speed characteristics (variation of stator resistances, stator voltage, frequency), Power stages,
losses and efficiency.
UNIT III: Circle Diagram and speed control of Induction Motor 10hrs
No load and blocked rotor tests - Circle diagram – predetermination of performance. Methods
of starting - DOL, Resistance Control, Star-Delta & Auto-transformer and Speed Control -
Injecting EMF method & Cascaded Method, Induction Generator operation - Doubly-Fed
Induction Machines.
UNIT IV: Single-phase induction motors 8hrs
Overview Double revolving field theory and Cross field theory, equivalent circuit, and
determination of parameters. Split-phase starting methods and applications
UNIT V: Synchronous Generators 12hrs
E.M.F equation, effect of Harmonics - armature reaction, synchronous impedance, equivalent
circuit and phasor diagram, characteristics of synchronous machines, voltage regulation
methods by EMF, MMF and ZPF. Salient pole machine - two reaction analysis of salient pole
machines and phasor diagram, Parallel operation of alternators - synchronization and load
sharing.
UNIT VI: Synchronous Motors 8hrs
Principle of operation - methods of starting - phasor diagram, V and inverted V curves,
mathematical analysis for power developed - excitation and power circles – hunting and its
suppression, Losses & Efficiency.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 17
Course Outcomes:
CO1: Able to understand the arrangement of windings in AC Machines.
CO2: Able to acquire knowledge on working and types of induction motors.
CO3: Able to analyze characteristics of 3-phase induction motor.
CO4: Able to pre-determine the parameters of single phase induction motor and to compare
various split phase motors
CO5: Able to acquire knowledge on voltage regulation of alternators
CO6: Able to explain the importance and analysis of synchronous motors.
CO-PO MAPPING:
PO’s 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 2 2 1 1
CO2 1 2
CO3 2 1 1
CO4 1 2 2
CO5 1 1 2
CO6 1 1 2 2
TEXT BOOKS:
1. "Electric Machinery”, A. E. Fitzgerald, C. Kingsley and S. D. Umans, 6thEducation McGraw-
Hill, 2003.
2. “Performance and Design of Alternating Current Machines”, M. G. Say, 3rdEdition, CBS
Publishers, 2002.
3. “Electrical Machinery”, P. S. Bimbhra, 7thEdition, Khanna Publishers, 2011.
REFERENCE BOOKS:
1. “Electric Machines”, I. J. Nagrath and D. P. Kothari, 5thEdition, McGraw Hill Education,
2010.
2. “Theory of Alternating Current Machinery”, A. S. Langsdorf, 2ndEdition Tata-McGraw-Hill
Education, 1990.
3. “Principles of Electric Machines and Power Electronics”, P. C. Sen, 3rdEdition, John Wiley &
Sons, 2014.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 18
ANALOG ELECTRONICS - II
Subject Code: UGEE4T0218 L T P C
II Year / II Semester 3 0 0 3
Prerequisites: Electrical circuits, Analog Electronics - I
Course Objective: The objective of this course is to introduce the basic building blocks of
the Linear Integrated circuits, and applications on Linear & Non-linear Op-amps. To study the
specials functions of PLL, Linear IC’s and Digital IC’s and theory about the ADC and DAC.
Syllabus
UNIT 1: INTRODUCTION TO OPERATIONAL AMPLIFIER 10hrs Introduction To Operational Amplifier Block diagram of Typical Op–Amp With Various Stages– BJT Differential Amplifier With RE DC Analysis– AC Analysis –BJT differential amplifier with constant current source – Analysis Different input/output configurations dual input balanced output–Dual input unbalanced output–Signal input balanced output–Signal input unbalanced output–AC analysis with r– parameters –Current repeater circuits–Current mirror circuits–Analysis– Level translator – Cascade differential amplifier– FET differential amplifier Unit II: OP-AMP PARAMETER 10hrs OP–AMP Parameter Input offset voltage – Input off–set current–Input bias current–Differential input resistance–Common mode rejection ratio–Slew ratio–PSRR–Large signal voltage gain–Output voltage swing transient’s response–definitions and explanations. Measurement of bias current–Measurement of offset currents– Measurement of offset voltage –Measurement of slew rate – Output offset voltage balancing circuits–Bias current compensations circuit–Dual power suppliers with shunt capacitance filter–Fix voltages Regulators 78XX–79XX series and as currents sources– Dual power supply using 78XX and 79XX series. Unit-III: IDEAL OPERATIONAL AMPLIFIER THEORY AND BASIC CIRCUITS 12hrs Ideal Operational Amplifier Theory and Basic Circuits Ideal operational amplifier properties–Ideal assumptions–Basic circuits such as non-inverting type comparator–Inverting type comparator–Voltage follower– Inverting amplifier–Non–inverting amplifier–Summing amplifier– Non–inverting summing amplifier–sub-tractor– Differentiator–Integrator– Scale changer–Instrumentation amplifier– V to I and I to V convertors–Log and Anti–log amplifiers–Zero crossing detector–Schmitt-trigger peak detector– Half-wave and full-wave rectifiers– Precision diode– Non-ideal operational amplifier non–inverting amplifier– inverting amplifier– closed loop gain–Input and output resistance equivalent circuits. Unit IV: WAVEFORM GENERATORS USING OP-AMPS AND PLL 10hrs Wave form generator in angular waveform generator using op–amps and PLL, Design of Astable multi vibrator – Monostable multi vibrator using signal op-amp–Triggering waveform generator 555 timer: Introduction– Pin diagram–Functional diagram for 8pin DIP–Design of Astable and mono stable multi– Astable application–Monostable applications– PLL: Introduction, basic block diagram– Functions of each block–566 VC0– 565 PLL block diagram –Function of each block–Applications of PLL–Frequency multiplier role of each pin frequency translation– AM–FM and FSK demodulators.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 19
UNIT V: ACTIVE FILTERS 8hrs Active filters Introduction– Merits and demerits of active filters–Over passive filters– First order low pass Butter–Worth filter –Design and frequency response–Second order LPF design and frequency response – First order HPF design and frequency response– Second order HPF design and frequency response– Higher-order filters– BPF wide band–pass and narrow band–pass filter–Wide band reject filter–Notch filter–All-pass filter UNIT VI: D TO A AND A TO D CONVERTERS 10hrs D to A and A to D Convertors Digital to Analog Convertors(D to A) – Introduction–Specifications–Basic DAC techniques– Weighted resistor DAC– R–2R ladder DAC–Invested R– 2R –Output expression for each type. Analog to Digital Convertors Introduction–Specifications–Parallel comparator type–Counter type–Dual slope–Successive approximation type ADCs– Merits and demerits of each type, Comparison of different types Course Outcomes: Upon the completion of the course, students will be able to: CO1: Understand the terminal characteristics of Op-amp and design/analyze the fundamental circuits based on op-amps CO2: Learn the various applications of the Integrated circuits CO3: Design and analysis of various applications using op-amps and various IC’s CO4: Apply theory and realize analog filter circuits, D to A and A to D Convertor’s. CO5: Know the differences between Linear and Digital Integrated circuits
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 2
CO2 1 2 3 2
CO3 1 2 3 3 1
CO4 1 2 3 3 1
CO5 1 2 3 3 2
TEXT BOOKS: 1. “Op-Amps and Linear Integrated Circuits”, Ramakanth A Gayakwad, Vol 1, 4th Edition,
Pearson Education, 2000. 2. “Linear Integrated Circuits”, D Roy Chowdary, Vol 1, 2nd Edition, New Age International,
2003. 3. “Microelectronics”, Arvin Gabriel & Jacob Millman, Vol 1, 2nd Edition, Tata McGraw Hill
Education Pvt Ltd, 2001. REFERENCE BOOKS: 1. “Op-Amps and Linear Integrated Circuits”, Dr Sanjay Sharma, Vol 1, 4th Edition, S K Kataria
& Son’s, 2017. 2. “Analog Electronics”, L K Maheswari& M M S Anand, Vol 1, 1st Edition, Prentice Hall India
Pvt Ltd, 2006 3. “Linear Integrated Circuits”, S Salivahan& V S Kanhana Bhasskaran, Vol 1, 1st Edition, Tata
McGraw Hill Publishing Company Ltd, 2008 4. “Electronic Principles”, Albert Malvino and David J Bates, Vol 1, 8th Edition, Mc Graw Hill
Edition, 2015
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 20
DIGITAL ELECTRONICS
Subject Code: UGEE4T0318 L T P C
II Year / II Semester 3 0 0 3
Prerequisites: Number systems
Course Objective: To acquire the basic knowledge of digital logic levels and application of
digital electronics circuits and to prepare the students to perform the analysis and design of
various digital electronic circuits.
Syllabus
UNIT I: Review of Number System and Codes 10hrs
Overview of the subject, Representation of numbers of different radix, conversion of numbers
from one radix to another radix, r-1’s complement and r’s complement of unsigned numbers,
problem solving, 4-bit codes: BCD, EXCESS 3, 9’s complement, 2421, 8421, Gray code, error
detection and error correction codes, parity checking even parity, odd parity, Hamming code.
UNIT II: Boolean Functions and Minimization Techniques 10hrs
Boolean theorems, Principle of Complementation and Duality, De-Morgan theorems,
Minimization of logic functions using Boolean theorems, Basic logic operations NOT, OR, AND,
Universal Building Blocks, EX-OR, EX-NOR Gates, Standard SOP and POS, NAND-NAND and
NOR-NOR realizations, Minimization of switching functions using K-Map up to 4-variables,
Tabular minimization, Realization of AND, OR, NOT, NAND, NOR Gates by using Diodes, RTL,
DTL.
UNIT III: Combinational Logic Circuits Design 10hrs
Design of Half adder, full adder, half subtractor, full subtractor, Applications of full adder:4-
bit binary adder, 4-bit binary subtractor, adder-subtractor circuit, Excess3 adder circuit, Look-
a-head adder circuit, Design of decoder,7-segment decoder, encoder, multiplexer, De
multiplexer, higher order Demultiplexing, Realization of Boolean functions using decoders,
decoder multiplexers, Priority encoder, 4-bit digital comparator
UNIT IV: Introduction to PLD’s 8hrs
PROM, PLA, PAL, realization of Boolean functions using PLD’s, Programming tables of PLD’s,
merits & demerits of PROM, comparison of PLA and PAL
UNIT V: Sequential Circuits - I 10hrs
Classification of sequential circuits (synchronous and asynchronous): basic flip-flops, truth
tables and excitation tables (NAND RS latch, nor RS latch, RS flip-flop. JK flip-flop, T flip-flop,
D flip-flop with reset and clear terminals). Conversion of flip-flop to flip-flop. Design of ripple
counters, design of synchronous counters, Johnson counters, ring counters. Design of
registers, Buffer register, control buffer register, shift register, bi-directional shift register,
universal shift register.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 21
UNIT VI: Sequential Circuits - II 10hrs
Finite state machine, capabilities and limitations, analysis of clocked sequential circuits, design
procedures, reduction of state tables and state assignment. Realization of circuits using
various flip-flops. Meelay to Moore conversion and vice-versa.
Course Outcomes: Students are Able to
CO1: Have a thorough understanding of the fundamental concepts and techniques used in
digital electronics
CO2: Understand and examine the structure of various number systems, Logic gates in digital
design
CO3: Acquire knowledge on various memories and its design
CO4: Analyze and design various combinational circuits.
CO5: Analyze and design various sequential circuits
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2
CO2 1 2 3
CO3 1 3 2 3 1
CO4 1 3 2 3 1
CO5 1 3 2 3 1
TEXT BOOKS:
1. Switching & Finite Automata theory – Zvi Kohavi, TMH, 2nd Edition
2. Digital Design – Morris Mano, PHI, 3rd Edition, 2006.
3. Digital Electronics and Logic Design, Dr. Sanjay Sarma, Katson Books, Fourth Edition, 2016.
REFERENCE BOOKS:
1. An Engineering Approach to Digital Design – Fletcher, PHI. Digital Logic – Application and
Design –John M. Yarbrough, Thomson
2. Fundamentals of Logic Design – Charles H. Roth, Thomson Publications, 5th Edition, 2004.
3. Ajit Pal, ―Microcontrollers – Principles and Applications‖, PHI Learning Pvt Ltd, 2011
4. Digital Logic Applications and Design – John M. Yarbrough, Thomson Publications, 2006.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 22
ELECTRICAL MEASUREMENTS
Subject Code: UGEE4T0418 L T P C
II Year / II Semester 2 2 0 4
Prerequisites: Electrical Circuits, Vector Algebra
Course Objective: This course introduces principle of operation of basic analog and digital
measuring instruments for measurement of current, voltage, power, energy etc. Measurement
of resistance, inductance and capacitance by using bridge circuits will be discussed in detail.
It is expected that student will be thorough with various measuring techniques that are
required for an electrical engineer.
Syllabus
UNIT I: MEASURING INSTRUMENTS 10hrs
Classification of measuring Instruments, Deflecting, control and damping torques – Ammeters
and Voltmeters – PMMC, moving iron type, dynamometer and electrostatic instruments –
Expression for the deflecting torque and control torque – Errors and compensations–
Extension of range using shunts and series resistance –CT and PT: Ratio and phase angle
errors – Numerical problems.
UNIT II: MEASUREMENT OF POWER 8hrs
Single phase and three phase dynamometer wattmeter – LPF and UPF – Expression for
deflecting and control torques – Extension of range of wattmeter using instrument
transformers – Measurement of active and reactive powers in balanced and unbalanced
systems – Type of P.F. Meters
UNIT III: MEASUREMENT OF ENERGY 8hrs
Single phase and three phase dynamometer and moving iron type Single phase induction type
energy meter – Driving and braking torques – errors and compensations –Testing by phantom
loading using R.S.S. meter– Three phase energy meter – Maximum demand meters– Electrical
resonance type frequency meter and Weston type synchro-scope.
UNIT IV: POTENTIOMETERS 8hrs
Principle and operation of D.C. Crompton’s potentiometer – Standardization – Measurement
of unknown resistance – Current – Voltage.AC Potentiometers: polar and coordinate types –
Standardization – Applications.
UNIT V: MEASUREMENTS OF PARAMETERS 10hrs
Method of measuring low, medium and high resistance – Sensitivity of Wheat stone’s bridge
– Carey Foster’s bridge– Kelvin’s double bridge for measuring low resistance– Loss of charge
method for measurement of high resistance – Megger– Measurement of earth resistance –
Measurement of inductance – Quality Factor – Maxwell’s bridge–Hay’s bridge – Anderson’s
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 23
bridge–Measurement of capacitance and loss angle – Desauty Bridge – Schering Bridge–
Wagner’s Earthing device–Wien’s bridge.
UNIT VI: MAGNETIC MEASUREMENTS 10hrs
Ballistic galvanometer – Equation of motion – Flux meter – Constructional details–
Determination of B–H Loop methods of reversals six point method – AC testing – Iron loss of
bar samples– Core loss measurements by bridges and potentiometers.
Course Outcomes:
CO1: Able to choose right type of instrument for measurement of voltage and current for AC
and DC.
CO2: Demonstrate the knowledge of instruments that is useful for the measurement of power.
CO3: Demonstrate the knowledge of instruments that is useful for the measurement of
energy.
CO4: Understand the Principle, operation of D.C. Crompton’s potentiometer
CO5: Select suitable bridge for measurement of electrical parameters
CO6: Determine magnetic measurements including B-H curve, hysteresis loop and core losses
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2
CO2 1
CO3 1
CO4 1
CO5 1 2
CO6 1
TEXT BOOKS:
1. “Electrical & Electronic Measurement & Instruments” by A. K. Sawhney, Dhanpat Rai & Co.
Publications, 2015.
2. “Electrical Measurements and measuring Instruments” by E. W. Golding and F. C. Widdis,
5thEdition, Wheeler Publishing. 1998
3. “Modern Electronic Instrumentation and Measurement Techniques” A.D. Helfrick and W.D.
Cooper, 5th Edition, PHI Learning Private Ltd., 2002.
REFERENCE BOOKS:
1. “Electrical and Electronic Measurements” by Banerjee, Gopal Krishna, 2nd edition, PHI
Learning Private Ltd., 2016.
2. “Electrical and Electronic Measurements” by G. K. Banerjee, PHI Learning Private Ltd., New
Delhi, 2012.
3. “Electrical Measurements: Fundamentals, Concepts, Applications” by Reissland, M.U, New
Age International (P) Limited, 2006.
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 24
ELECTRICAL MEASUREMENTS LAB
Subject Code: UGEE4P0518 L T P C
II Year / II Semester 0 0 3 1.5
List of Experiments
Any 10 of the following experiments are to be conducted
1. Calibration and Testing of single phase energy Meter.
2. Crompton D.C. Potentiometer – Calibration of PMMC ammeter and PMMC voltmeter.
3. Kelvin’s double Bridge – Measurement of resistance – Determination of Tolerance.
4. Capacitance Measurement using Schering Bridge.
5. Inductance Measurement using Anderson Bridge.
6. Measurement of 3 phase reactive power with single–phase wattmeter for balanced loading.
7. Calibration of LPF wattmeter – by direct loading.
8. Measurement of 3 phase power with single watt meter and 2 No’s of C.T.
9. C.T. testing using mutual Inductor – Measurement of % ratio error and phase angle of
given C.T. by Null method.
10. LVDT and capacitance pickup – characteristics and Calibration
11. Measurement of Power by 3 Voltmeter and 3 Ammeter methods.
12. Parameters of choke coil.
13. Determination of Time Constant for RC & RL Circuits
Course Outcomes:
CO1: Having knowledge to calibrate various meters, working on different bridges and
measuring unknown R, L, C and determine parameters of choke coil.
CO2: Develop technical writing skills important for effective communication.
CO3: Acquire teamwork skills for working effectively in groups
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1 2 2
CO2 2 1
CO3 2 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 25
DIGITAL ELECTRONICS LAB
Subject Code: UGEE4P0618 L T P C
II Year / II Semester 0 0 3 1.5
Course Objective: To provide hand-on experience in designing and implementing
digital/logic circuits. The laboratory exercises are designed to give students ability to design,
build, and implement digital circuits and systems. Laboratory exercise progress from
investigation of the properties of basic logic gates and flip-flops to the design of combinational
and sequential circuits.
List of Experiments
1. Verify
(a) Basic Logic gates
(b) Demorgan’s Theorem for 2 variables.
2. Design and implementation of code converters using logic gates
(a) BCD to excess-3 code and vice versa
(b) Binary to gray and vice-versa
3. Design and implementation of 16 bit odd/even parity checker generator using IC74180.
4. Design and implementation of Adders and Subtractor using logic gates.
5. Design and implementation of 4 bit binary Adder/ subtractor and BCD adder using IC 7483
6. Design and implementation of Encoder and Decoder using logic gates and study of IC7445
and IC74147
7. Design and implementation of Multiplexer and De-multiplexer using logic gates and study
of IC74150 and IC 74154
8. Design and Implementation of 8-bit Magnitude Comparator using IC 7485.
9. Verification of state tables of RS, JK, T and D flip-flops with minimum NAND & NOR gates.
10. Design and implementation of n-bit synchronous up/down counter
11. Implementation of Uni/Bidirectional shift register.
Course Outcomes:
CO1: Having knowledge on number systems, logic gates and to design and implement basic
combinational and sequential logic circuits
CO2: Develop technical writing skills important for effective communication.
CO3: Acquire teamwork skills for working effectively in groups
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 1
CO2 1
CO3 1
R18
DEPARTMENT OF EEE, SVECW (AUTONOMOUS) 26
ANALOG ELECTRONICS– II LAB
Subject Code: UGEE4P0718 L T P C
II Year / II Semester 0 0 3 1.5
List of Experiments
Section A: Linear IC Applications (Any 10 Experiments to be conducted)
1. Op-Amp Applications
a. Adder
b. Subtractor
c. Comparator
d. Schmitt Trigger
2. Integrator & Differentiator Circuits using IC741.
3. Active Filter Applications: LPF and HPF (first order)
4. IC741 Oscillator Circuits
a. RC Phase Shift Oscillator
b. Wein Bridge Oscillator
5. IC 555 Timer
a. Monostable Operation Circuit
b. Astable Operation Circuit
6. 4 bit DAC using OP-AMP
Section B: Pulse And Digital Circuits (All 4 Experiments from Section B are Compulsory)
1. Linear wave shaping (Diff. Time Constants, Differentiator, Integrator)
2. Non Linear Wave Shaping – Clippers, Clampers
3. Astable Multivibrators (Voltage – Frequency Converter)
4. Monostable Multivibrator.
Course Outcomes:
CO1: Having knowledge to design and analyze OP-AMP circuits, Pulse and Digital circuits, A-
D conversion & D-A conversion
CO2: Develop technical writing skills important for effective communication.
CO3: Acquire teamwork skills for working effectively in groups
CO-PO MAPPING:
POs 1 2 3 4 5 6 7 8 9 10 11 12 PSO1 PSO2
CO1 1 2 1 1 1
CO2 2 1
CO3 2 1