ECE-1
CENTURION UNIVERSITY OF TECHNOLOGY & MANAGEMENT
ODISHA-761211, INDIA,
Web Site: -www.cutm.ac.in
B.Tech Programme in Engineering & Technology – New Regulation
(2012 – 13 Admitted Batch onwards)
Branch: Electronics & Communication Engineering
ECE-2
CENTURION UNIVERSITY OF TECHNOLOGY &MANAGEMENT:ODISHA
B.TECH PROGRAMME IN ENGINEERING & TECHNOLOGY –New Regulations
(2012-13 Admitted Batch onwards)
ELECTRONICS & COMUNICATION ENGINEERING:: B.TECH II YEAR
3rd Semester 4th Semester
Theory Theory
Code Subject L-T-P Credits Code Subject L-T-P Credits
BTMA 2201
Mathematics-III
(Common to all
branches)
3-1-0 4 BTCH 2101
Environmental Science
(Common to all
branches)
3-1-0 4
BTEC2102 Networks and Systems 3-1-0 4 PCEE 3202
Control System
Engineering(Common
with EE & EEE)
3-1-0 4
PCEC 2103
Analog Electronic
Circuit (Common with
EEE)
3-1-0 4 PCEC 2203
Digital Electronic
Circuits (Common with
EEE)
3-1-0 4
BTEE 2202
Electromagnetic Theory
(Common with EE &
EEEE)
3-1-0 4 PCEC 2204 Analog Communication 3-1-0 4
Management Core - I 3-1-0 4 Management Core - II 3-1-0 4
Total Theory 15-5-0 20 Total Theory 15-5-0 20
Practical/Sessional Practical/Sessional
PLEC 2106
Analog Electronic
Circuit lab(Common
with EEE)
0-0-3 2 PLEC2206
Digital Electronic
Circuit Lab(Common
with EEE)
0-0-3 2
PLEC 2107 Networks and Systems
Lab 0-0-3 2 PLEC 2207
Analog Communication
Lab 0-0-3 2
PLEC 2108 /
BLHU 2109
Java Lab / Corporate
Readiness Lab 1-0-2 2 PLEC 2208
Advanced Simulation
Lab 0-0-3 2
PLEC 2109 Design and Simulation
Lab 0-0-3 2
BLHU2109 /
PLEC 2108
Corporate Readiness
lab/ Java Lab 0-0-3 2
BLHU 2110 Life Skills Development* 0-0-2 1* BLHU 2210 Life Skills
Development* 0-0-2 1*
Total Practical/Sessional 1-0-13 8 Total Practical/Sessional 1-0-14 8
TOTAL SEMESTER CREDITS 28 TOTAL SEMESTER CREDITS 28
TOTAL CUMULATIVE CREDITS 84 TOTAL CUMULATIVE CREDITS 112
Total Contact Hours. 34 Total Contact Hours. 34
* Not to be counted for CGPA computations
ECE-3
3rd SEMESTER
BTMA 2201 MATHEMATICS-III (3-1-0) CREDITS: 4
(Common to all branches)
MODULE-I (18 Hrs)
Partial Differential Equation of First Order, Linear and Non-linear Partial Differential Equations, Charpit’s
Method, Homogeneous and Non-homogeneous Linear Partial Differential Equations with Constant
Coefficients, Cauchy Type Differential Equation, Solution of Second Order Partial Differential Equation.
MODULE-II (16 Hrs)
Complex Analysis: Analytic Function , Cauchy-Riemann Equations, Laplace Equation, Harmonic Function,
Linear Fractional Transformation , Line Integral in the Complex plane, Cauchy’s Integral Theorem, Cauchy’s
Integral Formula, Derivatives of Analytic Function.
MODULE-III (14 Hrs)
Power Series,Taylor’s Series, Maclaurin Series, Laurent’s Series, Singularities and Zeroes, Residue Theorem,
Residue Integration Method, Evaluation of Real Integrals.
Text Books:
1) Higher Engineering Mathematics by B.V. Raman Publisher: TMH Chapters : 18(18.1 to 18.8, 18.10)
2) Advanced Engineering Mathematics by E. Kreyszig Publisher: Johnwilley& Sons Inc-8th Edition
Chapters : 12 (12.1 to 12.4, 12.9) ; 13, 14 (14.2,14.4) & 15.
Reference Books:
1) Advanced Engineering Mathematics by P.V. O’Neil Publisher: Thomson
2) Fundamentals of Complex Analysis (with Applications to Engineering and Science) by E.B. Saff& A.D.
Snider Publisher: Pearson
BTEC 2102 NETWORKS AND SYSTEMS (3-1-0) CREDITS:4
MODULE- I (16 Hrs)
SIGNALS & ITS PROPERTIES: Some Elementary continuous-time & discrete-time signals, Classifications
and manipulations.
Linear Time-Invariant (LTI) Systems: definitions and properties; causality, stability, impulse response, time
variance, convolution, poles and zeros. Sampling theorem(Definition Only)
CONTINUOUS TIME FOURIER ANALYSIS & ITS APPLICATION: Fourier series, Fourier analysis and
evaluation of coefficients, Steady state response of network to periodic signals, Continues time Fourier
transform and convergence, Fourier transform of some functions, Brief idea about network filters (Low pass,
High pass, Band pass and Band reject) and their frequency response.
NETWORK TOPOLOGY : Network graphs: matrices associated with graphs; incidence, fundamental cut set
and fundamental circuit matrices.
MODULE- II (16Hrs)
Network Theorems & Coupled Circuits: Solution methods: nodal and mesh analysis. Network theorems:
superposition, Thevenin and Norton's, Maximum power transfer theorem, Wye-Delta transformation, Coupled
Circuits, Dot Convention for representing coupled circuits, Coefficient of coupling, Band Width and Q-factor
for series and parallel resonant circuits.
ECE-4
Two Port Network Functions & Responses: 2-port network parameters: z, y, ABCD and h-parameters,
driving point and transfer functions. State equations for networks.
MODULE- III (18 Hrs)
Laplace Transform & Its Application: Introduction to Laplace Transform, Laplace transform of some basic
functions, Laplace transform of periodic functions, Inverse Laplace transform
Ac-Transients : Steady state sinusoidal analysis using phasors. Linear constant coefficient differential
equations; time domain analysis of simple RLC circuits, Solution of network equations using Laplace transform:
frequency domain analysis of RLC circuits.
The Z-Transform and Its Application to the Analysis of LTI Systems:
The Z-Transform: The Direct Z-Transform, Properties of the Z-Transform; Solution of Difference Equations by
Z-transform, The Inversion of the Z-Transform by Power Series Expansion, The Inversion of the Z-Transform
by Partial-Fraction Expansion;
Text Books:
1. Network Theory –A K Chakraborty –Dhanpat Rai Publication.
2. Digital Signal Processing – Principles, Algorithms and Applications by J. G. Proakis and D. G.
Manolakis, 4th Edition, Pearson.
Reference Books:
3. Network Analysis – M E Van Valkenburg – Pearson Education.
4. Engineering circuit analysis William Hart Hayt, Jack Ellsworth Kemmerly, Steven M. Durbin
McGraw-Hill Higher Education, 2007 – 856
5. Circuits and Networks –Analysis and Synthesis by A.Sudhakar, ShyamMohan S Palli,TMH,3rd Edition
6. Fundamentals of Signals and Systems - M. J. Roberts, TMH
7. Signals and Systems by Alan V. Oppenheim, Alan S. Willsky , S. Hamid Nawab
PCEC 2103 ANALOG ELECTRONIC CIRCUIT (3-1-0) CREDITS: 4
(Common with EEE)
MODULE- I (16 Hrs)
Small Signal Modeling of BJT and Analysis : The re transistor model, hybrid model, graphical determination
of h-parameters. Low frequency small signal analysis of CE, CC and CB configurations without feedback.
Small Signal Modeling and Analysis of FETs : Small Signal Model, Analysis of JFET C-S and C-D
configuration. Analysis of E-MOSFET and D-MOSFET configurations.
System Approach - Effects of RS and RL : Two-port system, Individual and combined effects of RS and RL on
CE, Emitter follower and C-S networks.
MODULE- II (18 Hrs)
BJT and JFET Frequency Response: General frequency considerations. Low-frequency analysis of R-C
combination in single stage BJT or FET amplifier - Bode Plot. Lower Cut Off frequency for the system. Low
frequency response of BJT and FET amplifiers. Miller Effect Capacitance. High - frequency modeling of BJT
and FET. High frequency analysis of BJT and FET amplifiers - Bode plot.
Compound Configurations : Cascade, Cascode and Darlington connections, C-MOS Circuit, Current Source
Circuits, Current mirror ckt, Differential amplifier circuit.
Feedback and Oscillator Circuit : Feedback concept, Type of feedback circuits, Practical feedback circuit.
Analysis of only voltage-series feedback type amplifier. Effects of negative feedback. Positive feedback,
Barkhausen Criterion of Oscillation. Oscillator Operation. R-C phase shift oscillator. Crystal Oscillator.
ECE-5
MODULE- III (16 Hrs)
Ideal Operational Amplifiers : Differential and Common mode operation, OP-AMP basics. Equivalent Circuit
Analysis of Inverting and Non - inverting OP - AMP circuits. Input impedance.
Practical OP-AMPS : OP-AMP Specifications, DC offset parameters, frequency parameters, gain - bandwidth.
OP-AMP applications on constant gain multiplier, Voltage summing, Integrator, Differentiator and Controlled
sources. Instrumentation Amplifier and Active Filters-low, high and band pass.
Power Amplifiers : Definition of A, B and C types. Conversion efficiency, Distortion analysis. Push - pull
configuration.
Text Book
1) Electronic Devices and Circuit Theory By - Robert L. Boylestad and Lewis Nashelsky.
8th Edition Pearson Publication.
Reference Books
1. Electronic Design - By Martin S. Roden etl. Fourth Edition, SPD Publication.
2. Integrated Electronics - By Millman & Halkias, Mcgraw Hill Internation students Edition.
3. Electronic Devices and Circuits By David A. Bell, 4th Edition, PHI.
BTEE 2202 ELECTROMAGNETIC THEORY (3-1-0) CREDITS: 4
(Common with EE & EEE)
MODULE- I (16 Hrs)
The Co-ordinate Systems; Rectangular, Cylindrical, and Spherical Co-ordinate System. Co-ordinate
transformation. Gradient of a Scalar field, Divergence of a Vector field and Curl of a Vector field. Their
Physical interpretation. The Laplacian. Divergence Theorem, Stokes’ Theorem. Useful Vector identifies .
Electrostatics:-
The experimental law of Coulomb, Electric field intensity. Field due to a line charge, Sheet Charge and
Continuous Volume Charge distribution. Electric Flux and Flux Density; Gauss’s law. Application of Gauss’s
law. Energy and Potential . The Potential Gradient. The Electric dipole. The Equipotential surfaces. Energy
stored in an electrostatic field. Boundary Conditions. Capacitors and Capacitances. Poisson’s and Laplace’s
equations. Solutions of Simple Boundary value problems. Method of Images.
MODULE- II (17 Hrs)
Steady Electric Currents: Current densities , Resistance of a Conductor; The Equation of Continuity . Joules
law. Boundary Conditions for Current densities. The EMF.
Magnetostatics:
The Biot-Savart law. Amperes’ Force Law . Torque exerted on a current carrying loop by a magnetic field.
Gauss’s law for magnetic fields. Magnetic Vector Potential . Magnetic Field Intensity and Ampere’s Circuital
law. Boundary conditions. Magnetic Materials . Energy in magnetic field . Magnetic circuits. Application to
cathode Ray Oscilloscope.
ECE-6
MODULE- III (17 Hrs)
Faraday’s Law of Induction; Self and Mutual inductance . Maxwell’s Equations from Ampere’s and Gauss’s
Laws. Maxwell’s Equations in Differential and Integral forms; Equation of Continuity. Inconsistency of
Amperes law, Concept of Displacement Current. Electromagnetic Boundary Conditions. Poynting’s Theorem ,
Time – Harmonic EM Fields . Application to Transformer.
Plane wave Propagation :
Helmholtz wave Equation. Plane wave solution. Plane wave propagation in lossless and lossy dielectric medium
and conducting medium . Plane wave in good conductor, surface resistance , depth of penetration. Polarization
of EM wave - Linear, Circular and Elliptical polarization. Normal and Oblique incidence of linearly Polarized
wave at the plane boundary of a perfect conductor, Dielectric – Dielectric Interface . Reflection and
Transmission Co-efficient for parallel and perpendicular polarizations , Brewstr angle.
Text Books:
1) Electromagnetic Field Theory, Fundamental by B. S. Guru & Huseyn R. Hiziroglu. Publication Thomson
Asia Pte. Ltd. Singapore. Vikas Publishing Home Pvt. Ltd. New Delhi. 21 Chapter 2 ( 2.4 and 2.8 to 2.13
), Chapter 3 ( 3. 1 to 3.12 ), Chapter 4 ( 4.1 to 4.4 , 4.6 , 4.8 to 4.10 ), Chapter 5 ( 5.1 to 5.12 ), chapter 6 (
6.3 ) , Chapter 7 (7.1 to 7.6 & 7.9 to 7.14 ) , Chapter 8 (8.1 to 8.10),
Reference :
1. Electromagnetic waves and Radiating Systems E. C. Jordan & K. G. Balmain, 2nd Edition. PHI Pvt.
Ltd. Chapter 1 ( 1.01 to 1.05 ), Chapter 2 ( 2.01 to 2.11 ), Chapter 3 ( 3.01 to 3.08 & 3.10 to 3.11 ) ,
Chapter 4 ( 4.01 to 4.04 ) , Chapter 6 ( 6.01)
2. Elements of Electromagnetic by Mathew N. O. Sadiku, Publisher : Oxford University Press.
3. Fields and Wave Electromagnetics, By David K. Cheng, 2nd Edition , Publisher : Pearson Education .
MANAGEMENT CORE -I (3-1-0) CREDITS: 4
Common to all Branches. Syllabus as prescribed by School of Management. Refer Annexure -I
for list of subjects and syllabus
PLEC 2106 ANALOG ELECTRONIC CIRCUIT LABORATORY (0-0-3) CREDITS: 2
(Common with EEE)
(At least 6 experiments should be done with software and 6 with hardware)
1. BJT bias circuit – Design, assemble and test.
2. JEET/MOSFET bias circuits – Design, assemble and test.
3. Design, assemble and test of BJT common-emitter circuit – D.C and A.C performance: Voltage gain,
input impedance and output impedance with bypassed and un-bypassed emitter resistor.
4. Design, assemble and test of BJT emitter-follower – D.C and A.C performance: A.C. voltage gain, input
impedance and output impedance.
a. Design, assemble and Test of JFET/MOSFET common-source– D.C and A.C performance: Voltage
gain, input impedance and output impedance.
b. Design, assemble and Test of JFET/MOSFET common-drain– D.C and A.C performance: Voltage gain,
input impedance and output impedance.
5. Frequency response of a common-emitter amplifier: low frequency, high frequency and mid frequency
response.
6. Study of Darlington connection and current mirror circuits.
7. OP-Amp Frequency Response and Compensation.
8. Application of Op-Amp as differentiator, integrator, square wave generator.
ECE-7
9. Square wave testing of an amplifier.
10. R.C phase shift oscillator/Wien-Bridge Oscillator using OPAMP.
11. Class A & Class B power amplifier.
PLEC 2107 NETWORKS AND SYSTEMS LABORATORY (1-0-2) CREDITS: 2
[All the experiments will be conducted through MATLAB]
1. Generation of different signals with different frequency like 25 Hz,50Hz etc.
2. Plot unit step, unit ramp, unit impulse without using Matlab command.
3. Analysis of Fourier series and Transforms.
4. Design of RC-low pass and high pass filter and its frequency response.
5. Analysis of Maximum Power Transfer Theorem for AC circuit.
6. Plot instantaneous voltage, current & power for R, L ,C and mixed. Loads. Calculate real power and
power factor for single phase and Phasors.
7. Calculation of resonance frequency for series RLC resonant circuit and Plot the response curves for
Impedance, reactance and current.
8. Analysis of Poly phase Systems using MATLAB.
9. Apply Laplace transform using MATLAB. Understanding Pole zero constellation and understanding s-
plane.Magnitude and Phase Response of discrete signals.
10. Find pole-zero diagram, bode diagram, step response from system function.
11. Locus of roots of a polynomial
12. Response of an LTI system to an input.
PLEC 2108 JAVA LABORATORY (1-0-2) / CORPORATE READINESS LAB@ (0-0-3) CREDITS: 2
PLEC 2108 JAVA LABORATORY
[Any 12 have to be one]
1) JDK Installation Procedure and Simple Java Programs.
2) Java Programs with control statements and using Arrays.
3) Write java programs using concept of Constructors.
4) Write java programs using concept of Inheritance.
5) Write java programs using concept of Interfaces.
6) Write java programs using concept of String handling.
7) Write java programs using concept of Package.
8) Write java programs using concept of Exception Handling.
9) Write java programs using concept of Multithreading.
10) Write a java program using concept of Networking.
11) Write a java program using concept of RMI.
12) Write java programs using concept of Applets.
13) Write java programs using concept of AWT & Event Handling.
Note: @ Particulars of Corporate Readiness Lab given in 4th Semester.
PLEC 2109 DESIGN AND SIMULATION LABORATORY (0-0-3) CREDITS: 2
Students will design any circuit which they have read in Electronics Devices and Analog Electronic Circuit. At
least 12 experiments they will perform.
1) Design and simulation of Diode clipper and clamper circuit.
2) Design and simulation of Half wave and Full wave rectifier circuit.
ECE-8
3) Design and simulation of Different biasing circuit of BJT.
4) Design and simulation of Different biasing circuit of FET.
5) Design and simulation of Different config of Op-Amp.
6) Design and simulation of Op-Amp as a differentiator.
7) Design and simulation of Op-Amp as an Integrator.
8) Design and simulation of Different types of comparator circuit.
9) Design and simulation of Schmitt Trigger Circuit.
10) Design and simulation of Different Voltage limiter circuit.
11) Design and simulation of Push pull configuration
12) Design and simulation of Current mirror, current source, Darlington pair circuits.
BLHU 2110 LIFE SKILLS DEVELOPMENT LABORATORY (0-0-3) CREDITS:0
Common to all Branches. Will be conducted from 1st to 6th Semesters for all branches. No credits added
but the students are required to get qualified as prescribed by the T & P cell for being able to and
considered for placement. The exercises to be carried out shall be decided as per the industry’s
requirements from time to time.
ECE-9
4th SEMESTER
BTCH 2101 ENVIRONMENTAL SCIENCE (3-1-0) CREDITS: 4
(Common to all branches)
MODULE- I (15Hrs)
Environment and its multidisciplinary nature; Need for public awareness; Renewable and non-renewable
resources – forest, water, mineral, land, food and energy resources; Structure and function of ecosystems of
forest, grass land, desert and aquatic types;
MODULE -II (16Hrs)
Biodiversity and its conservation; Biodiversity at global, national and local levels; Threats to biodiversity-
Habitat loss; wild life poaching and man-wildlife conflicts; Endangered and endemic species; conservation
measures.
Causes, effects and control measures of pollution, air, water, marine thermal and noise pollution;
Nuclear hazards; solid-waste management – Causes, effects and control measures; Management of disasters due
to natural causes of floods, earthquakes, cyclones and landslides.
MODULE -III(16Hrs)
Social issues and the environment; Sustainable environment, Water conservation measures; Rain water
harvesting; Resettlement and rehabilitation of people; Climate change and global warming; Acid rain; Ozone
layer depletion; water land reclamation; Consumerism and waste products;
Features of Environment Protection Act, Air pollution and Control of Pollution Acts; Water Pollution and its
Control Act. Effects of Pollution explosion on environment and public health; Need for value education to
Protect environment and resources.
Text Book:
Anubhav Kaushik & C.P. Kaushik : Environmental Studies - New age International Publishers
Reference Books:
1. Benny Joseph : Environmental Studies - Tata Mac Graw Hill
2. E. Bharucha : Text book of Environmental Studies for Under graduate courses – Universities Press.
(Book prepared by UGC Committee.
PCEE 3202 CONTROL SYSTEM ENGINEERING (3-1-0) CREDITS: 4
(Common with EE & EEE)
MODULE - I: (17 Hrs)
Introduction to Control Systems : Basic Concepts of Control Systems, Open loop and closed loop systems,
Elements of Servo Mechanism and types of servo mechanism, Mathematical Models of Physical Systems:
Differential Equations of Physical Systems: Mechanical Translational Systems, Mechanical Acceloroments,
Rotational systems, Electrical Systems, Analogy between Mechanical and electrical quantises, Derivation of
Transfer functions, Block Diagram Algebra, Signal flow Graphs, Mason’s Gain Formula. Feedback
characteristics of Control Systems: Effect of negative feedback on sensitivity, bandwidth, Disturbance,
linearizing effect of feedback, Regenerative feedback. Control Components: D.C. Servomotors, A.C.
Servomotors, A.C. Tachometer, Synchros, Stepper Motors.
ECE-10
MODULE - II: (17 Hrs)
Time response Analysis: Standard Test Signals : Time response of first order systems to unit step and unit ramp
inputs. Time Response of Second order systems to unit step input, Time Response specifications, Steady State
Errors and Static Error Constants of different types of systems. Stability and Algebraic Criteria, concept of
stability, Necessary conditions of stability, Hurwitz stability criterion, Routh stability criterion, Application of
the Routh stability criterion to linear feedback system, Relative stability by shifting the origin in s-plane. Root
locus Technique: Root locus concepts, Rules of Construction of Root locus, Determination of Roots from Root
locus for a specified open loop gain, Root contours, Systems with transportation lag. Effect of adding open loop
poles and zeros on Root locus.
MODULE - III: (16 Hrs)
Frequency Response Analysis: Frequency domain specifications, correlation between Time and Frequency
Response with respect to second order system, Polar plots, Bode plot. Determination of Gain Margin and Phase
Margin from Bode plot.
Stability in frequency domain: Principle of argument, Nyquist stability criterion, Application of Nyquist
stability criterion for linear feedback system.
Controllers: Concept of Proportional, Derivative and Integral Control actions, P, PD, PI, PID controllers.
Text Books :
1. Modern Control Engineering by K. Ogata, 5th edition PHI.
2. Control Systems Engg. by I.J. Nagrath and M.Gopal, 5th Edition, New Age International Publishers (2010).
3. Modern Control Systems by Richard C.Dorf and Robert H. Bishop, 11th Ed (2009), Pearson
Reference Books :
1. Design of Feedback Control Systems by R.T. Stefani, B. Shahian, C.J. Savator, G.H. Hostetter, Fourth
Edition (2009), Oxford University Press.
2. Control Systems (Principles and Design) by M.Gopal 3rd edition (2008), TMH.
3. Analysis of Linear Control Systems by R.L. Narasimham, I.K. International Publications
4. Control Systems Engineering by S.P. Eugene Xavier and J. Josheph Cyril Babu, 1st Ed (2004), S. Chand Co.
5. Problems and solutions in Control System Engineering by S.N. Sivanandam and S.N. Deepa, Jaico Pub.
PCEC 2203 DIGITAL ELECTRONIC CIRCUIT (3-1-0) CREDITS: 4
(Common with EEE)
MODULE - I: (16 Hrs)
Number System and Codes:-
Binary Number base Conversations, Octal and Hexadecimal numbers, Complements, Signed Binary Numbers,
Binary Codes- BCD Codes, Gray Code, ASCII Character Code, Codes for serial data transmission and storage.
Boolean Algebra and Logic Gates
Axiomatic definition of Boolean algebra. Basic theorems and properties of Boolean algebra, Boolean functions;
Canonical and Standard forms; minterms and maxterms standard forms; minterms and maxterms, standard
forms Digital Logic Gates, multiple inputs.
ECE-11
Gate Level Minimization:-
The Map Method, K Maps, input five variables, Product of Sums Simplification, Don’t care conditions. Nand
and NOR implementation. AND –OR invent, OR-AND invent implementation, Ex-OR function, Parity
generation and checking, Hardware Description Language (HDL).
MODULE - II: (17 Hrs)
Combinational Logic:-
Combinational Circuits, Analysis and Design Procedure; Binary Adder-Sub tractor, Decimal Adder, Binary
Multiplier, Magnitude Comparator, Decoders, Encoders, Multipliers, HDL for Combinational Circuits.
Synchronous Sequential Logic:-
Sequential Circuit, Latches, Flip-flop, Analysis of Clocked sequential Circuits, HDL for Sequential Circuits,
State Reduction and Assignment. Design Procedure.
MODULE - III: (17 Hrs)
Registers and Counters:-
Shift Register, Ripple Counters, Synchronous Counters Asynchronous Counter, Ring Counters, Modulo-N
Counters, HDL for Registers and Counters.
Memory and Programmable Logic:-
Random Access Memory (RAM), Memory Decoding, Error detection and Correction, Read only Memory,
Programmable Array Logic, Sequential Programmable Devices.
Text Book
1. Digital Design, 3rd Edition by M. Morries Mano, Pearson Edu. India (Ch: 1, 2, 3, 4, 5, 6, 7, 8)
Reference Books:
1. Digital Principles and Applications, 6th Edition, Donald P. Leach, Albert Paul Malvino and Goutam
Saha, Tata McGraw Hill Publishing Company Ltd., New Delhi.
2. Digital Fundamentals, 5th Edition, T.L. Floyd and R.P. Jain, Pearson Education, New Delhi.
3. Digital Electronics, Principles and Integrated Circuit, Anil K. Jain, Wiley India Edition
4. Digital Design – Principle & Practice, 3rd Edition by John F. Wokerly, Pub. Pearson Education.
PCEC 2204 ANALOG COMMUNICATION (3-1-0) CREDITS: 4
MODULE-I (17 Hrs)
SIGNALS AND SPECTRA: An Overview of Electronic Communication Systems, Fourier series, Response of
a linear system, Normalized power in a Fourier expansion, Power spectral density. The Fourier transform,
Convolution, Parseval's theorem, Power and energy transfer through a network, Auto and Cross correlations.
ECE-12
RANDOM VARIABLES AND PROCESSES: Probability, Mutually exclusive events, Joint probability,
Statistical independence, Random variables, Probability density function, Average and variance. The Gaussian
probability density. The error function, Mean and Variance of sum of random variables, Probability density of
Z = X+Y. The Central limit theorem, correlation between random variables, auto correlation, power spectral
density.
AMPLITUDE MODULATION SYSTEMS: Frequency translation, Recovery of base band signal, Amplitude
Modulation, Maximum Allowable Modulation. The square Law demodulator, Spectrum of AM signal, Balanced
Modulator, SSB modulation and generation, VSB, FDM.
MODULE-II: (16 Hrs)
ANGLE MODULATION: Phase and frequency modulation and their relationship, Frequency deviation,
spectrum of FM Signal, BW of FM signal, Effect of modulation on BW, constant BW, FM phasor diagram,
Narrow band FM, Armstrong and Parameter Variation methods of FM generation. FM Demodulators.
MATHEMATICAL REPRESENTATION OF Noise: Sources and Types of Noise, Noise figure and noise
temperature – Noise in cascaded systems, Frequency Domain Representation of Noise, Power Spectral Density,
Spectral Components of Noise, Response of a Narrow band filter to noise, Effect of a Filter on the Power
spectral density of noise, Superposition of Noises, Noise Bandwidth, Narrow band representation of noise and
its PSD.
MODULE-III: (17 Hrs)
Noise in AM Systems: Calculation of Signal Power and Noise Power in SSB, DSB-SC and DSB FC. Figure of
Merit
Noise in FM System: Mathematical Representation of the operation of the Limiter Discriminator, Calculation
of output SNR, Comparison of FM and AM. SNR Improvement using pre-emphasis 37
Communication Receivers: Receiver Types - Tuned radio frequency receiver, Superhetrodyne receiver, RF
section and Characteristics – Frequency conversion, Intermediate frequency, AGC, FM Receiver.
Text Books:
1. H. Taub, D. L Schilling, G. Saha; Principles of Communication System, 3rd Edition; 2008, Tata McGraw
Hill, India; ISBN: 0070648115. (Selected portions from chapters: 1, 2, 3, 4, 5, 7, 8 and 9)
2. Electronic Communication Systems, George Kennedy and Bernard Davis, Fourth Edition (1999), Tata
McGraw Hill Publishing Company Ltd.
Reference Books:
1. B.P. Lathi, 3rd Edition, Modern Digital and Analogue Communication Systems, Oxford University Press
2. Louis E. Frenzel, Principles of Electronic communication Systems,3rd Edition, Tata McGraw Hil
3. Communication System Engineering,Second Edition by Masoud Salehi, John G. Proakis, ISBN:
0130950076 (paperback)
4. Communication Systems by Simon Haykin, 4th Edition, Inc. John Wiley & Sons
MANAGEMENT CORE - II (3-1-0) CREDITS:4
Common to all Branches. Syllabus as prescribed by School of Management. Refer Annexure -I for list of
subjects and syllabus
ECE-13
PLEC 2206 DIGITAL ELECTRONIC CIRCUIT LABORATORY (0-0-3) CREDITS: 2
(Common with EEE)
[Minimum 12 experiments have to be done with 5 minimum using software]
1. Digital Logic Gates: Investigate logic behavior of AND, OR, NAND, NOR, EX-OR, EX-
a. NOR, Invert and Buffer gates, use of Universal NAND Gate.
2. Gate-level minimization: Two level and multi level implementation of Boolean functions.
3. Combinational Circuits: design, assemble and test: adders and subtractors, code converters,
a. gray code to binary and 7 segment display.
4. Design, implement and test a given design example with (i) NAND Gates only (ii) NOR
a. Gates only and (iii) using minimum number of Gates.
5. Design with multiplexers and de-multiplexers.
6. Flip-Flop: assemble, test and investigate operation of SR, D & J-K flip-flops.
7. Shift Registers: Design and investigate the operation of all types of shift registers with
a. parallel load.
8. Counters: Design, assemble and test various ripple and synchronous counters - decimal
a. counter, Binary counter with parallel load.
9. Clock-pulse generator: design, implement and test.
10. Binary Multiplier: design and implement a circuit that multiplies 4-bit unsigned numbers
a. to produce a 8-bit product.
Using VHDL:-
11. Verilog/VHDL simulation and implementation of Experiments listed at Sl. No. 3 to 11.
Using Pspice:-
12. Design and simulation of Digital Adder circuit.
13. Design and simulation of Multiplexer, Demultiplexer, Encoder and Decoder.
14. Design and simulation of Digital Multiplier and Comparator.
15. Design and simulation of different types of Flip-Flop(S-R, J-K,D & T).
16. Design and simulation of different types of Counter circuits (Synchronous Counter, Asynchronous
Counter and Up-down Counter).
PLEC 2207 ANALOG COMMUNICATION LABORATORY [0-0-3]
{Minimum 12 experiment should be conducted}
1. Analyze and plot the spectrum of following signals with aid of spectrum analyzer: Sine wave, square
wave, triangle wave, saw-tooth wave of frequencies 150Khz, 200Khz ,1 MHz onwards.
2. Study and design of AM (DSB with carrier) modulator and demodulator. Calculation of the modulation
index (m) and plot the signals for m>1,m=1 & m<1.
3. AM generation and demodulation using OP-AMPs and IC multipliers
4. Generation and demodulation of DSB-SC, SSB Signal. SSB generation and demodulation using
integrated circuits
5. Implementation of intermediate frequency amplifier- Frequency response
6. Design and Study of FM modulation and Demodulation Techniques.
7. (Frequency modulation using FET and VCO - Frequency deviation)
8. Study of Pre emphasis & De-emphasis in FM.
9. Analyze the process of frequency division multiplexing and frequency division de-multiplexing.
10. Design and study of active Low Pass, high pass, Band pass and Band reject filters.
ECE-14
11. Using MATLAB/SCILAB generate a carrier and a modulating signal. Modulate the carrier using AM.
Show the waveform in time domain and analyze its frequency spectrum. Repeat the simulation for
modulating signal being square, triangular and other forms waveform.
12. Using MATLAB/SCILAB generate a carrier and a modulating signal Modulate the carrier using FM.
Show the waveform in time domain and analyze its frequency spectrum. Repeat the simulation for
modulating signal being square, triangular and other forms waveform.
13. Generation of Gaussian Noise, study on PSD of noise.
14. Study on SNR of AM, FM by MAT LAB. Simulation.
15. Generation and study of Sampling and Quantization of Sinusoidal signal and Signal Reconstruction.
16. Observer the process of quantization and determination of quantization noise
17. Study AGC Characteristics
PLEC 2208 ADVANCED SIMULATION LABORATORY [0-0-3]
{Minimum 12 experiment should be conducted. All the experiments are to be conducted with
Lab View only }
1. Introduction to Lab VIEW:- Introduce LabVIEW basics that are relevant for developing
experiments and exercises related to communication systems.
2. Amplitude Modulation:- Review the basic concepts of amplitude modulation and demodulation.
Demonstrate and analyze the behavior of various amplitude modulation and demodulation schemes.
3. Frequency Modulation:- Review the basic concepts of frequency mo
4. dulation and demodulation. Build and analyze the behavior of an FM modulator and demodulator.
Perform demodulation of an FM signal from a circuit and study the effect of additive noise on the
demodulated output.
5. Sampling and Quantization :- Understand the basic concepts of sampling and quantization.
Demonstrate and analyze the process of sampling with emphasis on the sampling conditions that
enable regeneration of an original signal. Demonstrate and analyze uniform and non-uniform
quantization algorithms taking into account the pros and cons of each approach.
6. Pulse Coded Modulation (PCM):- Understand the basic concepts of pulse-code modulation
(PCM). Demonstrate and analyze the behavior of uniform and non-uniform PCM systems.
Demonstrate and analyze the A-law and the µ –law companders. Demonstrate and analyze encoding
schemes for PCM systems.
7. Digital Modulation:- Understand the basic concepts of MPSK and MQAM digital modulation
techniques. Demonstrate and analyze MPSK and MQAM modulation techniques. Evaluate the
performance of MPSK and MQAM modulation techniques.
8. Digital Modulation:- Understand the basic concepts of MFSK and MSK digital modulation
techniques. Demonstrate and analyze MFSK, MSK, and GMSK modulation techniques. Evaluate
the performance of MFSK, MSK, and GMSK modulation techniques.
9. Demodulation and Performance:- Understand the basic concepts of demodulation of digitally
modulated signals. Demonstrate and analyze MPSK, MQAM and MFSK demodulators. Evaluate
the BER performance of MPSK, MQAM, and MFSK modulation schemes. Analyze basic
properties of channel coding for communication systems.
10. PAM over Inter-Symbol Interference (ISI) Channels:- Understand the basic concepts of PAM
modulation over inter-symbol interference channels. Demonstrate and analyze PAM modulation
over linear Gaussian channels. Understand the effect of pulse shaping filters on inter-symbol
interference.
11. PAM over Inter-Symbol Interference (ISI) Channels:- Understand the building blocks of the
receiver structure for PAM over ISI channels. Demonstrate and analyze demodulation using
matched filters. Investigate various equalization techniques to combat ISI.
ECE-15
12. Digital Communication System Setup
13. Simulating different Communication Channels
14. Analog Communication System Setup
BLHU 2109 CORPORATE READINESS LABORATORY / PLEC 2108 JAVA LABORATORY@
(0-0-3) CREDITS:2
Common to all Branches. Students to conduct projects offered / identified which are oriented towards
corporate awareness and requirements. The list of exercises are dynamic and shall be changed by the
instructors incharge taking into consideration regional / national / global changes and requirements.
@ Syllabus of JAVA laboratory given in 3rd semester.
BLHU 2110 LIFE SKILLS DEVELOPMENT LABORATORY (0-0-3) CREDITS:0
Common to all Branches. Will be conducted from 1st to 6th Semesters for all branches. No credits added
but the students are required to get qualified as prescribed by the T & P cell for being able to and
considered for placement. The exercises to be carried out shall be decided as per the industry’s
requirements from time to time.
ECE-16
CENTURION UNIVERSITY OF TECHNOLOGY &MANAGEMENT:ODISHA
B.TECH PROGRAMME IN ENGINEERING & TECHNOLOGY –New Regulations
(2012-13 Admitted Batch onwards)
ELECTRONICS & COMUNICATION ENGINEERING:: B.TECH III YEAR
5th Semester 6th Semester
Theory Theory
Code Subject L-T-P Credits Code Subject L-T-P Credits
PCEC 3109
Microprocessors
(Common with EE &
EEE)
3-1-0 4 PCEC 3201 Digital Signal Processing
(Common with EE) 3-1-0 4
PCEC 3110 Digital Communication 3-1-0 4 PCEC 3202 VLSI Design 3-1-0 4
PCEC 3103 Antenna and Wave
Propagation 3-1-0 4 PCEC 3203 Embedded C 3-1-0 4
Free Elective - I 3-1-0 4 Free Elective - II 3-1-0 4
Management Core - III 3-1-0 4 Management Core - IV 3-1-0 4
Total Theory 15-5-0 20 Total Theory 15-5-0 20
Practical/Sessional Practical/Sessional
PLEC 3106 Microprocessor Lab
(Common with EE & EEE) 0-0-3 2 PLEC 3206
Digital Signal Processing
Lab (Common with EE) 0-0-3 2
PLEC 3107 Digital Communication Lab 0-0-3 2 PLEC 3207 VLSI Design Lab 0-0-3 2
PLEC 3108 Advanced Communication
Lab 0-0-3 2 PLEC 3208 Embedded C Lab 0-0-3 2
BLHU 3109 Life Skills Development* 0-0-2 1* PLEC 3209 Project -1 0-0-3** 2
BLHU 3210 Life Skills Development* 0-0-2 1*
Total Practical/Sessional 0-0-11 6 Total Practical/Sessional 0-0-11 8
TOTAL SEMESTER CREDITS 26 TOTAL SEMESTER CREDITS 28
TOTAL CUMULATIVE CREDITS 138 TOTAL CUMULATIVE CREDITS 166
Total Contact Hours. 31 Total Contact Hours. 31
* Not to be counted for CGPA computations
Free Electives- 3rd Year
5th Semester 6th Semester
Signals and Systems Microprocessors
ECE-17
5th SEMESTER
PCEC 3109 MICROPROCESSORS (3-1-0) CREDITS: 4
(Common with EE & EEE)
MODULE-I : (16 Hrs)
Organization of Microprocessor
Introduction to the general concept of microprocessor organization, I/O sub-systems, programming the system,
ALU, instruction execution, instruction word format, addressing modes, address/data/control bus, tristate bus,
interfacing I/O devices, data transfer schemes, architectural advancements of microprocessor, evolution of
microprocessors.
Microprocessor Architecture: Microcomputer and 8085 Microprocessor Architecture, Pins & Signals,
Register Organization, Timing & Control Module, 8085 Instruction Timing & Execution.
Assembly Language Programming of 8085: Instruction set of 8085, Memory & I/O Addressing, Assembly
language programming, Stack & Subroutines.
Interfacing EPROM & RAM Memories: 2764 & 6264, 8085 Interrupts
MODULE-III: (16 Hrs)
Intel 8086- Hardware Architecture:
Introduction, Bus interface unit(BIU), Execution unit(EU), pin description, register organization, instruction
pointer, data register, pointer and index registers, status register, stack, external memory addressing, bus cycle
(minimum mode):memory or I/O read/write for minimum mode, clock generator Intel- 8284A, bidirectional bus
trans-receiver 8286/8287, bus controller 8288, bus cycle memory read/write for minimum mode, 8086 system
configuration (minimum mode as well as maximum mode), memory interfacing, interrupt processing; software
interrupts, single step interrupt, non-maskable interrupt, maskable interrupt, interrupt priority, DMA, Halt State,
Wait for Test state, comparison between 8086 an 8088.
MODULE-III: (16 Hrs)
Instruction set and programming:
Programmer’s model of Intel 8086, operand type, addressing modes 8086 assembler directives, instruction set,
programming examples on data transfer group, arithmetic-logical groups, control transfer groups (loop and loop
handling instruction), conditional and unconditional group, procedures and stack operations, string instructions.
branch program structure like IF-THEN-ELSE REPEAT-UNTIL and WHILE-DO,
I/O Interfacing ;
8-bit input- output port 8255 PPI, memory mapped i/o ports,8254 programmable Interval Timer, 8257
Programmable Direct Memory Access Controller, 8251 USART, 8279 Programmable Keyboard/Display
Controller.
Text Books:
1. Ghosh& Sridhar,0000 to 8085–Introduction to Microprocessor for Scientists & Engineers, PHI
2. Microprocessors and Interfacing; by Douglas V Hall ; McGraw Hill.
ECE-18
Reference Book:
1. Microprocessors and Micro controllers Architecture, programming and system Design 8085, 8086, 8051,
8096: by Krishna Kant; PHI.
2. The 8086 Microprocessor: Programming & Interfacing the PC- Kenneth J. Ayala, Delmar Cengage Learning,
Indian Ed.
3. Fundamentals of Microprocessors and Microcontrollers by B.Ram. DhanpatRai Publications.
4. The 8088 and 8086 Microprocessors Programming, Interfacing, Softw, Hardware and Application; by Walter
A. Triebel&AvtarSingh ; Pearson India.
PCEC 3110 DIGITAL COMMUNICATION (3-1-0) CREDITS: 4
MODULE - I (15 Hrs)
Sampling Theorem, Signal Reconstruction from uniform samples, Practical issues in signal sampling and
reconstruction, Maximum Information Rate, Non-ideal practical sampling analysis, Some applications of
sampling theorem (Ref Text Book 2: Chapter 6.1) Digital Representation of Analog Signal - Quantization of
Signals, Quantization error, PCM, Electrical representation of binary digits, PCM System, Companding, Certain
issues in Digital transmission: Line coding, scrambling, T1Digital System, Multiplexing T1 lines – The T2, T3
and T4 lines. Differential PCM: Linear predicted design, Delta Modulation, Adaptive Delta Modulation (Ref
Text Book 1: Chapter 5.4, 5.5 and 5.6)
MODULE - II (15 Hrs)
Digital Modulation Technique: Generation, Transmission, Reception, Spectrum and Geometrical
Representation in the Signal Space of BPSK, DPSK, QPSK, QASK, M-ary PSK, BFSK, M-ary FSK, and
Minimum Shifting Keying (MSK). (Ref Text Book 1: Chapter 6) Noise in PCM and DM: Calculation of
Quantization Noise, Output Signal Power, and the Thermal Noise. Output SNR in PCM, Quantization noise in
Delta Modulation, output signal power, output SNR, Comparison with PCM and DM (Ref Text Book 1:
Chapter 12.1 -12.3)
MODULE - III (20 Hrs)
Principle of Digital Data Transmission: Digital Communication Systems – Source, Line coder, Multiplexer,
Regenerative repeater;Line Coding: PSD of various line codes, polar signaling, constructing a DC Null in PSD
by pulse shaping, On Off signaling, Bipolar signaling; Pulse shaping – ISI and effect, Nyquist first criterion for
zero ISI;, Digital receiver and regenerative repeaters; Equalizers, Timing extraction, Detection error, Eye
Diagram (Ref Text Book 2: Chapter 7.1, 7.2, 7.3.1, 7.3.2, 7.4, 7.5, 7.6)
A base band signal Receiver, Peak signal to RMS noise output voltage ratio, probability of error, optimum
threshold, optimum receiver for both base band and pass band: calculation of optimum filter transfer function,
optimum filter realization using Matched filter, Probability error of the matched filter, optimum filter realization
using correlator. (Ref Text Book 1: Chapter 11.1 – 11.3)
Discrete Messages and information content: The Concept of amount of Information, Average Information,
Entropy; Information rate, source coding to increase average information per bit; Shanon-Fano coding, Huffman
Coding,Lempel-Zivcoding,Shanon'sTheoerm- Channel Capacity, Capacity of Gaussian channel, Bandwidth –
S/N Trade off. Use of Orthogonal Signals to attain Shannon's limit. Matched Filter Reception, calculation of
error probability, Efficiency of orthogonal Signal transmission.(Ref Text Book 1: Chapter 13.1 – 13.4)
Coding: Parity Checkbit Coding for error Detection, Hamming distance.Upper Bounds of probability of error
with coding. Block codes - Coding and Decoding Algebraic Codes: Hadamard Code, Hamming Code,
Convolutional Coding: Code generation. Decoding of Convolutional Codes.
ECE-19
Text Books:
1. Taub’s Principles of Communication Systems by H Taub, D L Schilling and G Saha, 3rd Edition 2008, TMH
Education Pvt Ltd, New Delhi.
2. Communication Systems by SimanHaykin, 4th Edition, John Wiley & Sons, Inc.
Additional Readings:.
1. Digital Communication by Amitabha Bhattacharya, TMH Publishing Company Ltd, 2006.
2. Modern Digital and Analogue Communication Systems by B.P. Lathi and Z Ding, 4th Edition 2010, Oxford
University Press, New Delhi.
3. Digital and Analogue Communication System, Leon W. Couch-II, 6th Edition, Pearson.
PCEC 3103ANTENNA & WAVE PROPAGATION (3-1-0) CREDITS: 4
MODULE -I (17 Hrs)
Review of Maxwell’s wave equation in free space, Wave Polarization– Linear, Circular and Elliptical
Polarization, Antenna Basics, Radiation mechanism.
Wave equation in terms of potential functions; Vector potential A for an electric current source J & Vector
potential F for a magnetic current source M
Fundamental parameters of Antenna:
Radiation Pattern – Isotropic, Directional and omni directional patterns; Principle Patterns and Secondary lobes:
Field regions: radiation field and Steradian.
Radiation Power Density; Radiation Intensity, Directivity, Gain, Antenna Efficiency, HPBW, Beam efficiency,
Bandwidth, Polarization.Noise Figure and Noise Temperature.Effects of antenna height and effect of ground on
performance of antenna.Antenna effective length.
MODULE -II (17 Hrs)
Short Dipole(Hertzian) and half wavelength Dipole ,Small Loop Antenna– Current distribution, Radiated Fields,
Power density and Radiation resistance; radiating near field (Fresenel) and reactive near field region,
intermediate field and far field (Fraunhofer) region, Ground effects – vertical and horizontal electric dipole,
earth curvature.
Antenna Arrays: Uniform linear arrays of isotropic elements, array factor and directivity. Broadside &Endfire
array, principle of pattern multiplication. Binomial array.
Ground Wave, Sky Wave, Space Wave & Scatter Propagation with general application: Propagation with
general applications: Propagation Equations in Ground Waves: Attenuation Factor, Transmission Coverage,
Receiving Antenna for ground wave. Sky Wave Propagation: Attenuation, Refractive Index, Conductivity and
Permittivity, Electron Collision Frequency, D, E & F Layers, Critical Frequency & MUF, skip distance, Curved
Ionosphere, Propagation Equation, Antennas for Sky Wave reception. Space Wave Propagation in the
Troposphere: LOS Range, Flat Earth Reflection with variable wavelengths and heights, Inverse Distance
Equation, Point of reflection on curved Earth, Curvature of space Waves in the Troposphere, Diffraction of
space waves, Duct Propagation, Fading of Space Waves. Antennas for Space wave Propagations.
ECE-20
MODULE -III (16 Hrs)
Loop Antenna and Horn Antenna (basics). Frequency independent Antennas: Log periodic Dipole antenna
and helical antenna (basics).
Microstrip Antenna – Basic Characteristics, Rectangular Patch, Circular Patch, Quality factor bandwidth and
efficiency, Feed to microstrip antenna: probe feed, microstrip line feed, aperture feed (basic ideas).
Text Books:
1. Antenna Theory – Analysis and Design By C Balanis, 2nd Edition, John Willey & Sons.
2. Antenna by J.D. Kraus, 2nd Edition, TATA McGraw Hill.
3. Radio Wave Propagation and Antennas,An Introduction –John Griffiths, PHI International
Reference Books:
1.Antenna& Wave Propagation by R.LYadava, PHI Publication.
2. Electromagnetic Wave and Radiating Systems by E.C. Jordan and K.G. Balmain,2nd Ed. PHI
3. Antenna Engineering by W. L. Weeks
4. Antennas and Wave Propagation by G.S.N. Raju, Person Education.
5. Antenna & Wave Propagation by R. E. Collins.
6. Antenna & wave Propagation by K.D Prasad, Satyaprakasan publishing House.
FREE ELECTIVE - I (3-1-0) CREDITS:4
Refer Annexure - II for list of Free Electives and the syllabus
MANAGEMENT CORE – III (3-1-0) CREDITS: 4
Common to all Branches. Syllabus as prescribed by School of Management. Refer Annexure -I for list
of subjects and syllabus
PLEC 3106 MICROPROCESSOR LABORATORY (0-0-3) CREDITS:2
(Common with EE & EEE)
(TOTAL 10 (Ten) experiments to be completed. Two from Group A, Two from Group B, Two from Group
C, Two from Group D and another two experiments to be conducted as projects in design, development
and application of microprocessor system.,
A) 8085
1. Addition, Subtraction, Multiplication, Division two 8 bit numbers resulting 8/16 bit numbers.
2. Smallest /Largest number between two & among n number in a given data array. Arrange a set of
numbers in ascending & descending order.
3. Binary to Gray Code, Gray to binary code / Hexadecimal to decimal conversion.
B) INTERFACING COMPULSORY
1. Generate square waves on all lines of 8255 with different frequencies (concept of delay program)
OPTIONAL
1. Study of Traffic Light controller
2. Study of stepper Motor and its operations (Clockwise, anticlockwise, angular movement, rotate in
various speeds)
ECE-21
3. Generation of Square , triangular and saw tooth wave using Digital to Analog Converter
4. Study of 8253 and its operation (Mode 0, Mode 2, Mode 3)
5. Study of Mode 0, Mode 1, and BSR Mode operation of 8255.
6. Study of 8259 Programmable Interrupt controller.
C) 8086 COMPULSORY
1. Addition, subtraction, Multiplication, Division of 16 bit numbers + 2’s complement of a 16 bit numbers.
OPTIONAL
1. Finding a particular data element in a given data array.
2. Marking of specific bit of a number using look-up table.
3. Largest /Smallest number of a given data array.
4. To separate the Odd and Even numbers from a given data array.
5. Sorting an array of numbers in ascending/descending order.
D) Application of microprocessor system(any two)
1. Traffic light controller
2. Water level controller.
3. Automatic door opening system with application of stepper motor.
4. Study of Elevator Simulator
PLEC 3107 DIGITAL COMMUNICATION LABORATORY (0-0-3) CREDITS:2
1. Obtain the characteristics & Study pulse modulation schemes PAM, PWM and PPM.
2. Study the functioning of PCM,DPCM.
3. Implement Delta modulator and demodulator.
4. Obtain the characteristics of the Amplitude Shift Keying (ASK) Modulator and demodulate
5. Obtain the characteristics of the Phase Shift Keying (PSK) Modulator and demodulate.
6. Obtain the characteristics of the Frequency Shift Keying (FSK) Modulator and demodulate
7. Study the functioning of Time division multiplexer.
8. To study the different channel coding and decoding technique.
9. Experimentally compare different forms of BPSK, QPSK, and OQPSK,
10. Generation and detection of QAM using IC multipliers
11. To transmit and receive three separate signal audio, video, tone simultaneously through satellite link.
12. Measurement of Refractive Index profile, Numerical Aperture attenuation and dispersion in a
multimode optical fiber.
ECE-22
PLEC 3108 ADVANCED COMMUNICATION LABORATORY (0-0-3) CREDITS:2
(Experiments from 1-11 using MATLAB)
1. Generation of square wave, Sgn function and frequency content of square wave and rectangular wave
using FFT. and Generation of poission distribution, Gaussian distribution with different values of alpha
and find relationship between autocorrelation and PSD.
2. Implementation of oversampling, under sampling using Nyquist rate.
3. Implementation of PWM modulation and demodulation, Delta Modulation.
4. Implementation of power spectrum of random noise that has dc component and power spectrum of
white Gaussian noise across different load.
5. Demonstrate the effect of AWGN noise in DSB-SC and SSB transmission and reception.
6. Design And Implement Simulink Model Of Amplitude Modulation, and frequency modulation, ASK.
7. Design And Implement Simulink Model Of BPSK,FSK, PLL,and PLL as frequency synthesizer.
8. Simulation of probability of error for different types of modulation contaminated by white Gaussian
noise.
9. Implementation of noise cancellation using adaptive filters .
10. Simulation of adaptive channel equalization using LMS algorithm and RLS algorithm.
11. Simulation of white and colored uniformly distributed Gaussian noise.
12. Measurement of losses in a given optical fiber ( propagation loss, bending loss) and numerical aperture
Analog and Digital (with TDM) communication link using optical fiber.
REFERENCE BOOK:
1. Principles Of Communication Systems ,Herbert TAUB , Donald L Schilling,Gautam Saha.
2. Fundamentals of Digital Signal Processing using MATLAB – Robert J. Schilling and Sandra L. Harris,
Cengage Learning.
3. Tools to be used: MATLAB/SCILAB
BLHU 3109 LIFE SKILLS DEVELOPMENT LABORATORY (0-0-3) CREDITS:0
Common to all Branches. Will be conducted from 1st to 6th Semesters for all branches. No credits added
but the students are required to get qualified as prescribed by the T & P cell for being able to and
considered for placement. The exercises to be carried out shall be decided as per the industry’s
requirements from time to time.
ECE-23
6th SEMESTER
PLEC 3201 DIGITAL SIGNAL PROCESSING (3-1-0) CREDITS: 4
(Common with EE)
MODULE - I (16 Hrs)
Discrete time fouriertransform(DTFT) :
The discrete time fourier transform of Aperiodic signal, Convergence of fouriertransform,thefourier transform
of signal with poles on unit circle,frequency domain and time domain signal properties, prorerties of DTFT.
The Discrete Fourier Transform: Its Properties and Applications
Frequency Domain Sampling: Frequency-Domain Sampling and Reconstruction of Discrete-Time Signals, The
Discrete Fourier Transform, The DFT as a Linear Transformation, Relationship of the DFT to other Transforms;
Properties of the DFT: Periodicity, Linearity, and Symmetry Properties, Multiplication of Two DFTs and
Circular Convolution, Additional DFT Properties; Linear Filtering Methods Based on the DFT: Use of the DFT
in Linear Filtering, Overlap add method, Overlap save method, Frequency Analysis of Signals using the DFT;
Efficient Computation of the DFT: Fast Fourier Transform Algorithms
Efficient Computation of the DFT: FFT Algorithms: Direct Computation of the DFT, Radix-2 FFT Algorithms:
Decimation-In-Time (DIT), Decimation-In-Time (DIF).
Textbook – I Chapter 8 (8.1.1, 8.1.3, 8.2.1, 8.2.2, 8.2.3)
MODULE - II (18 Hrs)
Implementation of Discrete-Time Systems:
Structure for the Realization of Discrete-Time Systems, Structure for FIR Systems: Direct-Form Structure,
Cascade-Form Structures, Frequency-Sampling Structures; Structure for IIR Systems: Direct-Form Structures,
Signal Flow Graphs and Transposed Structures, Cascade-Form Structures, Parallel-Form Structures.
Textbook – I Chapter 9 (9.1, 9.2.1, 9.2.2, 9.2.3, 9.3.1, 9.3.2, 9.3.3, 9.3.4)
Design of Digital Filters:
General Considerations: Causality and Its Implications, Characteristics of Practical Frequency-Selective Filters;
Design of FIR Filters: Symmetric and Ant symmetric FIR Filters, Design of Linear-Phase FIR Filters by using
Windows, Design of Linear-Phase FIR Filters by the Frequency-Sampling Method; Design of IIR Filters from
Analog Filters: IIR Filter Design by Impulse Invariance, IIR Filter Design by the Bilinear Transformation.
Textbook – I Chapter 10 (10.1.1, 10.1.2, 10.2.1, 10.2.2, 10.2.3, 10.2.4, 10.3.2, 10.3.3) 54
MODULE -III (16 Hrs)
Digital signal processor
Introduction, DSP processor memory architecture, some examples of DSP processor, pipelining, overview of
TMS320c family DSP processors, First generation TMS320c1x processors, second generation TMS320c2x
processors, third generation TMS320c3x processors, fourth generation TMS320c4x processors, fifth generation
TMS320c5x processors, sixth generation TMS320c1x processors.
Textbook – 2 Chapter 15 (15.1, 15.2, 15.3, 15.4, 15.5, 15.6, 15.7, 15.8, 15.9, 15.10, 15.11, 15.12)
ECE-24
Text Books :
1. Digital Signal Processing – Principles, Algorithms and Applications by J. G. Proakis and D. G. Manolakis,
4th Edition, Pearson.
Reference Book :
1. Digital Signal Processing –SanjitK.Mitra, TMH.
2. Digital Signal Processing – Manson H. Hayes (Schaum’s Outlines) Adapted by Subrata Bhattacharya, TMH.
3. Modern Digital Signal Processing – Roberto Cristi, Cengage Learning.
4. Digital Signal Processing: S.Salibhanaan, A. Vallavaraj, C.Gnanapriya, TMH
5 Digital Signal Processing ,Alan V. Oppenheim, Ronald W. Schafer
6. Adaptive signal processing: Bernard Widrow,SamuuelD.Sterns, Pearson Education
PLEC 3202 VLSI DESIGN (3-1-0) CREDITS: 4
MODULE - I (17Hrs )
Introduction: Historical Perspective, Moore’s law, VLSI Design and Packaging Methodologies, VLSI Design
Flow Hierarchy, VLSI Design Styles, Computer-Aided Design Technology.
Fabrication of MOSFETs: Introduction, Fabrication Processes Flow – Basic Concepts, The CMOS n-Well
Process, Layout Design Rules, Stick Diagrams, Full-Customs Mask Layout Design.
MOS Transistor: The Metal Oxide Semiconductor (MOS) Structure, The MOS System under External Bias,
Structure and Operation of MOS Transistor (MOSFET), MOSFET Current-Voltage Characteristics, MOSFET
Scaling and Small-Geometry Effects, MOSFET Capacitance.
(Chapter 1 to 3 of Text Book 1 and for Stick Diagram Text Book 2)
MODULE - II (17 Hrs )
MOS Inverters – Static Characteristics: Introduction, Resistive-Load Inverters, Inverters with n-Type
Depletion and Enhancement MOSFET Load, CMOS Inverter.
MOS Inverters – Switching Characteristics and Interconnect Effects: Introduction, Delay-Time Definitions,
Calculation of Delay-Times, Inverter Design with Delay
Constraints, Estimation of Interconnect Parasitics, Calculation of Interconnect Delay, Switching Power
Dissipation of CMOS Inverters.
Combinational MOS Logic Circuits: Introduction, MOS Logic Circuits with Depletion
nMOS Loads, CMOS Logic Circuits, Complex Logic Circuits, CMOS Transmission Gates (Pass Gates).
(Chapter 5 to 7 of Text Book 1)
MODULE - III (16Hrs )
Sequential MOS Logic Circuits: Introduction, Bi-stable circuit elements, SR & JK Latch Circuits, Clocked
Latch and Flip-Flop Circuits, CMOS D-Latch and Edge-Triggered Flip-Flop.
Dynamic Logic Circuits: Introduction, Basic Principles of TG and Pass Transistor Circuits,
ECE-25
Voltage Bootstrapping, Charge sharing, Synchronous Dynamic Circuit Techniques, Dynamic CMOS Circuit
Techniques, Cascading dynamic gates, High Performance Dynamic CMOS Circuits, Domino logic, np-CMOS
domino logic.
Semiconductor Memories: Introduction, Dynamic Random Access Memory (DRAM), Static Random Access
Memory (SRAM), Non-volatile Memory, Flash Memory, PLA and PAL.
Design for Testability: Introduction, Fault Types and Models, Ad Hoc Testable Design Techniques, Scan-
Based Techniques, Built-In Self-Test (BIST) Techniques, Current Monitoring IDDQ Test.
(Chapter 8 to 10 and chapter 15 of Text Book 1)
Text Books:
1. Sung-Mo Kang and Yusuf Leblebici, CMOS Digital Integrated Circuits: Analysis and
Design, 3rd Edn., Tata McGraw-Hill Publishing Company Limited, 2003.
Reference Books:
1. Jan M. Rabaey, AnanthaChandrakasan, BorivojeNikolic, Digital Integrated Circuits
– A Design Perspective, 2nd Edn., PHI.
2. Wayne Wolf, Modern VLSI Design System – on – Chip Design, 3rd Edn., PHI
3. Debaprasad Das, VLSI Design, Oxford University Press, New Delhi, 2010.
4. John P. Uyemura, CMOS Logic Circuit Design, Springer (Kluwer Academic
Publishers), 2001.
5. Ken Martin, Digital Integrated Circuit Design, Oxford University Press, 2000
6. K. Eshraghian and N.H.E. Weste, Principles of CMOS VLSI Design – a Systems
Perspective, 2nd Edn., Addison Wesley, 1993.
PLEC 3203 EMBEDDED C (3-1-0) CREDITS: 4
MODULE-I: (16 Hrs)
Programming embedded system in c: Introduction,What is an embedded system, which processor should you
uses, which programming language should you use, which operating system should you use, how to develop the
embedded software.
Introduction to Keil C: Introduction to Keil C programming. List of various keywords and data types specific
to Keil Micro vision.
Pointers In Keil: Different types of pointers in Keil, with examples on how to define them and use them.
Functions in Keil C: Learn to define function in Keil C. Various types of function definitions available.
MODULE-II: (16 Hrs)
Writing First C program: Learn basics of C program as per embedded rules and learn Basics of hardware
specific code.
Writing C and Assembly together:Learn to interface your C programs with assembly codes and different
segment naming conventions used in Keil C
Advanced C programming: Advanced techniques of writing assembly code to interface them to C programs.
Introducing the 8051 microcontroller family: Introduction, external interface of the standard 8051, reset
requirements, clock frequency and performance, memory issues, I/O pins, timers, interrupts, serial interface,
power consumption.
ECE-26
MODULE-III: (16 Hrs)
8051 programming in C: Time delay and I/O operations, I/O bit manipulations, Logic and arithmetic
operations, ASCII and BCD data conversion, binary to decimal conversion program to use code space, data
serialization.
Text Book:-
1. Embedded C by Michael J. Point.
Reference :
2. http://www.8051projects.net/keil-c-programming-tutorial/pointers.php
3. The 8051 microcontroller and embedded system using assembly and c – M Ali Mazidi ,J G Mazidi .
FREE ELECTIVE - II (3-1-0) CREDITS:4
Refer Annexure – II for list of Free Electives and the syllabus
MANAGEMENT CORE - IV (3-1-0) CREDITS:4
Common to all Branches. Syllabus as prescribed by School of Management. Refer Annexure -I for list of
subjects and syllabus
PLEC 3206 DIGITAL SIGNAL PROCESSING LABORATORY (0-0-3) CREDITS:2
(Common with EE)
(All experiments shall have be performed through MATLAB only)
1. Linear Convolution of sequences.
2. Correlation of two sequences (Auto correlation and Cross Correlation)
3. Simulation of DTFT, DFT and IDFT of sequences.
4. Circular Convolution of sequences using DFT and IDFT method.
5. Implementation of FFT algorithm by decimation in time and decimation in frequency.
6. Design and simulation of different FIR and IIR Filter structures.
7. To design digital IIR filters (Low-Pass, High Pass, Band-Pass, and Band-Stop).
8. To design FIR filters using windows technique.
9. Implementation of signals, mixed signals using DSP kit.
10. Design and study of convolution(linear and circular) using DSP kit.
11. Implementation of linear phase FIR (Lowpass And Highpass) Filters using DSP kit.
12. Implementation of IIR (Lowpass And Highpass) Filters DSP kit.
Reference Books:
1. Digital Signal Processing: A MATLAB-Based Approach – Vinay K. Ingle and John G. Proakis, Cengage
Learning.
2. Fundamentals of Digital Signal Processing using MATLAB – Robert J. Schilling and Sandra L. Harris,
Cengage Learning.
Tools to be used: MATLAB/SCILAB
DSP kit: Preferably TMS 320C6XXX
ECE-27
PLEC 3207 VLSI DESIGN LABORATORY (0-0-3) CREDITS:2
1. Layout design and characteristic study of PMOS and NMOS device.
2. Design of schematic and simple layout for CMOS inverter, parasitic extraction and simulation.
3. Design of schematic and simple layout for CMOS NAND gate, parasitic extraction and simulation.
4. Design of schematic and simple layout for CMOS NOR gate, parasitic extraction and simulation.
5. Design of schematic and simple layout for CMOS adder, parasitic extraction and simulation.
6. Design of 4 bit adder circuit using VHDL.
7. Design of multiplexer, de-multiplexer, encoder and decoder circuit using VHDL.
8. Design of comparator circuit using VHDL.
9. Design of Latch, S-R flip-flop, J-K FF, T-FF and D flip-flop using VHDL
10. Design of counter circuit using VHDL.
11. Design of memory circuit using VHDL.
12. Design of ALU circuit using VHDL.
Required Software:
1. Xilinx ISE Tool
2. Tanner Tool
3. Cadence/ Microwind Tool.
PLEC 3208 EMBEDDED C LABORATORY (0-0-3) CREDITS:2
1. Introduction to Keil micro vision software.
2. C Program to print hello world.
3. C program to store the data in the accumulator.
4. C Program to send values 00-ff to Port 1.
5. C Program to send hex values for ASCII characters 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, a, b, c, d, e, f to port 1.
6. C program to toggle all the bits of P1 continuously.
7. C program to toggle bit D0 of port 1 50,000 times.
8. C program to generate a square wave for 1ms delay.
9. C program to send the data serially.
10. C program to receive the data serially
11. C program to convert packed BCD 0x29 to ASCII and Display the bytes on P1and P2.
12. C program to convert the hex to decimal and display the digits on P0, P1, and P2.
PLEC 3209 PROJECT - 1 (0-0-3) CREDITS:2
BLHU 3210 LIFE SKILLS DEVELOPMENT LABORATORY (0-0-3) CREDITS:0
Common to all Branches. Will be conducted from 1st to 6th Semesters for all branches. No credits added
but the students are required to get qualified as prescribed by the T & P cell for being able to and
considered for placement. The exercises to be carried out shall be decided as per the industry’s
requirements from time to time.
ECE-28
ANNEXURE - I MANAGEMENT CORE (3-1-0) CREDITS:4
List of Management Core subjects
(Students are required to choose one subject out of the four in 3rd, 4th, 5th and 6th semesters.)
Sl. No. Semester Course Code Course Title
1
3rd /4th /
5th / 6th
MGGM1104 Essential Economics for Management
2 MGFM1101 Accounting for Managers
3 MGGM1206 Organizational Behavior
4 MGOM1201 Production & Operations Management
SYLLABUS OF MANAGEMENT CORE SUBJECTS
MGGM1104 ESSENTIAL ECONOMICS FOR MANAGEMENT (3-1-0)
Course Objective:
In today's dynamic economic environment, effective managerial decision making requires timely and
efficient use of information. The basic purpose of this course is to provide students with a basic
understanding of the economic principles, methodologies and analytical tools that can be used in business
decision making problems. It provides an understanding of the economic environment and its impact on
strategy formulation. The course also focuses on the impact of economic policies on managerial decision-
making by providing an understanding of fiscal policy, and national and global economic issues affecting
business.
The language of science (and all analytical thinking) is mathematics. Since economics is a social science,
use of some mathematical tools, basically the constrained and un-constrained optimization techniques will
help in measuring and solving the basic economic problems and thus improves decision-making. It becomes
difficult and totally un-practicable to solve business (economic) problems logically and systematically
without use of mathematics. The basic objective is to solve problems mathematically and interpret the
results economically.
Module-1: Introduction & Micro Economics .
Introduction to economics- Scarcity, Choice and Efficiency, Circular Flow of Economic Activity,
Fundamental issues of what, how and for whom to produce to make the best use of economics, Economic
Role of Government.
Basic Concepts: Marginalism and Incrementalism, Functional Relationships: Total, Average and
Marginal. General and partial equilibrium, Opportunity cost
Demand for a commodity: Law of demand, Demand schedule and demand curve, Individual and market
demand, Change in demand
Consumer behavior: Analysing law of demand through Marshalian utility analysis and
Indifference curve technique. Consumer Surplus
Elasticity of Demand
Price Elasticity of demand : Estimation, Types, Elasticity and revenue, Factors affecting price elasticity of
demand
Income elasticity , Cross elasticity, Uses of different concepts elasticity in business decisions.
ECE-29
Analysis of Supply: Law of Supply, Supply schedule and supply curve, Change in supply, Price elasticity of
supply,
Equilibrium of demand and supply: Equilibrium with demand and supply curves, Effect of a shift of
demand and supply curves, Rationing of prices, Impact of tax on prices and quantity, Prices fixed by law
(Minimum floors and Maximum ceilings)
Demand Estimation: Approaches to demand estimation, Demand Estimation by Regression Analysis.
Demand Forecasting: Sources of Data (Expert opinion, Surveys, Market experiments), Timeseries Analysis
(trend projection and Exponential smoothening), Barometric Forecasting, Forecasting with input and output
model.
Production Function: Production function with one variable input, Production function with two variable inputs,
optimal combination of inputs, Returns to scale
Cost Theory: Types of costs, Production and cost, Short-run cost functions, Long-run cost functions,
Economies of scale and scope, Learning curve, Cost-Volume-profit Analysis
Perfect Competition: Characteristics, Equilibrium price determination under both short run and long run,
Evaluation of perfect competition
Monopoly: Characteristics, Profit maximizing price determination under both short run and long run,
Allocative efficiency and income redistribution, Relevance of perfect competition and monopoly
Monopolistic Competition: Characteristics, Profit maximizing price determination under both short run and
long run, Evaluation of Monopolistic competition
Oligopoly: Characteristics, Price Rigidity(Kinked demand curve model), Interdependence (The
Cournot model) and Cartels and Collusion, Price Leadership, Cost-plus Pricing, Multiple Product
Pricing, Price Skimming, Penetration Pricing, Transfer Pricing and Price Discrimination
Module-2: Macro Economics .
National Income Accounting: Concept, Eight variants of national product aggregates, Measurement
(Income, Value Added and Expenditure), Real and Nominal GNP, Difficulties in measuring the national
income, Uses of National income statistics
Environmental Income Accounting, Green GDP, Sustainable Development, National income and social welfare
Consumption and Investment functions: Concept, Determinants, Multiplier and Accelerator
Demand for Money: Classical and Keynesian theories on demand for money
Supply of Money: Components of money supply, The process of Deposit Creation, Balance Sheet of the
Central Bank.
Aggregate Demand: The Goods Market and the IS Curve, The Money Market and the LM Curve, Form IS-LM
model to the Aggregate Demand.
Aggregate Supply
Explaining macro-economic equilibrium through Aggregate Demand and Aggregate Supply,
Monetary Policy: Objectives, Instruments, Monetary Policy in The AD- AS Framework,
Crowding-Out Controversy, Monetary policy in an open economy
Fiscal Policy: Objectives, Instruments, Impact of Structural Deficits, Government Debt and Economic Growth.
Interaction between monetary and Fiscal Policy
Features of The Business Cycle, Definition Of Inflation, Price Indices, Prices in the AD-AS
Framework, The Economic Impacts of Inflation, The Phillips Curve, Anti-Inflationary Policy
Unemployment: Types, Okun’s Law, Impact of Unemployment, Economic Interpretation Of
Unemployment
International Trade: Economic Basis For International Trade, Gains from International Trade Balance of
Payment (BoP): Meaning, BoP Account, Disequilibrium in BoP, Measures to correct disequilibrium in BoP
Foreign Exchange: The Determination of Foreign Exchange Rates, Floating Exchange Rate and Fixed
Exchange Rates, Mundell-Fleming Model,
Books & Reference:
ECE-30
1. Managerial Economics in a Global Economy, by D. Salvatore, Sixth Edition, OUP, 2008
2. Managerial Economics, Truett&Truett, Wiley Publication.
3. Managerial Economics, by Petersen Craig H. Cris Lewis and S.K. Jain, Pearson, 2007
4. Modern Micro Economics, , Koutsoyiannis, (1975) , A, Macmillan Press
5. Managerial Economics, Mehta, P. L (1999), Sultan Chand & Sons
6. Principles of Microeconomics, Mankiw, N. G (2006), Cengage Learning
7. Macroeconomics, Mankiw, N. G, (2009), Worth Publishers
8. Macroeconomics, Theory and Policy, Dwivedy, D.N (2007), Tata McGraw Hill
9. Macroeconomics, D’Souza, E (2008), Pearson Education
10. Macroeconomic Analysis, Shapiro, E (2003), Galgotia Publications
11. Environmental Economics in Theory and Practice – Hankey N, Shogren J F, and White B – 1999 –
Macmillan Indian Limited
12. Indian Economy, Mishra &Puri (2011), Himalaya Publishing House
MGFM1101 ACCOUNTING FOR MANAGERS (3-1-0)
Course Objective:
This course ‘Accounting for Managers’ has been designed to enable the students to acquire the skills
necessary to prepare, use, interpret and analyze financial information.
Module 1 (12)
Accounting Environment of business, Corporate Entities: Salient Features, GAAP: Concepts,
Conventions, Assumptions, Accounting Equation: Tool to understand business decisions, Financing
Decisions/Investment Decisions/Operating Decisions, Accounting Equation Financial Statements,
Balance Sheet/Income Statement/Cash Flow Statement, Financing Decisions and Financial
Statement,
Module 2 (12)
Equity Instruments: Equity and Preference Capital, Debt Instruments: Debentures/ Bonds/ Loans,
Dividend and Interest payment, Investment Decision and Financial Statements, Fixed
Assets:/Inventory Valuation/Investment , Operating Decisions and Financial Statements, Revenue
Recognition, Expenses, Profit: Gross Profit/PBDITA/PBIT/PBT/PAT, Interrelationship between Financial
statements
Module 3 (12)
Financial Statement Analysis: common size statements, ratio analysis, Du pont analysis, Inter-firm and
intra-firm comparison, reading CFS
Module 4 (12)
Cost Concepts and decision making, Overheads, CVP analysis. Preparation of Cost Sheets using excels,
Budgeting and Budgetary Control, Variance analysis, Activity based costing (ABC), cost & pricing A group
project work will be given to students to analyse an industry and track market price movement.
Books & Reference:
1. Financial Accounting -- A managerial Perspective, R. Narayanswamy, PHI
2. Cost Accounting- A managerial Emphasis by Horn green, Dater and Foster.
3. Khan & Jain – Management Accounting, TMH.
4. Horngren ,Datar, Foster- Cost Accounting, Pearson.
5. Financial Accounting, Jain/Narang/Agrawal, Kalyani.
6. Basic Financial Accounting for Management, Shah, Oxford.
ECE-31
MGGM1206 ORGANIZATIONAL BEHAVIOUR (3-1-0)
Introduction to the Course :
Organizational Behavior (OB) is a field of study that investigates the impact that individuals, groups, and
structure have on behavior within an organization. Then it applies that knowledge to make organizations work
more effectively.
Course Objective :
This course will expose students to gain knowledge on the diversified behavioral science theories and its
applications in organizations.
Pedagogy
Class room lectures will be substantiated by Case Analysis, assignment and viva-voce,
Demo Exercises, Movie Analysis, Games, role playing Comprehensive Course Outline :
Module – 1 (12)
Concept and models of OB, OB Systems- The Synergy
Module - 2(Individual System)(12)
Perception, Learning and Behaviour Modification, motivation, attitude and Values, personality,
emotion and stress.
Module – 3(Social System) (12)
Communication, Group Dynamics, Conflict , Leadership
Module - 4(Organizational systems) (12)
Organizational power and politics, Organizational culture and climate, Organizational Change and
development, International Dimensions of OB, Managing Diversity.
Recommended Text :
• Robins &Sanghii, Organisational Behaviour, Pearson
• Aswathappa, Organization Behavior,HimalayaReference Books :
• Luthans ,F. Organisational Behaviour - TMH
• UdaiPareek , Understanding Organisational Behaviour, Oxford
• Prasad,L.M. Organization Behavior,S.Chand.
• Greenberg and Baron, Behavior in organization, Prentice hall.
MGOM1201 PRODUCTION AND OPERATIONS MANAGEMENT (3-1-0)
Course Objective:
The course is designed to acquaint the students with decision making in planning, scheduling
and control of production and operation functions in both manufacturing and services.
Course Content:
Module:1 (12)
Operations Management- An Introduction Primary topics in Operations Management, Operations Function, and
Transformation process and Competitiveness.
Operations Strategy
9Strategic Decisions in Operations, Strategy Deployment, and Vertical Integration, Service
Operation, Service strategy, Manufacturing Strategy and Mass customization;
Product Development and Service Design
New Product design, Product life cycle, Process design, Process life cycle, Form design,
Functional design, Production design, Concurrent design, Technological design and Service
design process.
ECE-32
Module:2 (14)
Facilities Location & Layout Planning
Location - Principles and Factors; Location Analysis techniques- Factor Rating, Centre of
Gravity Technique, Brown & Gibson Model. Layout – Concept & Basic Principles, Process
Layout (Block Diagramming,
Relationship Diagram, Computerized Layout Solutions, Service Layout); Product Layout – Process
Layout; Fixed Position Layout. Hybrid Layouts – Cellular, FMS (Flexible Manufacturing System)
Project Management and Scheduling
Project planning, , project control, project scheduling Models Project Network, Critical path Method
(CPM), Programme Evaluation Review Technique( PERT) , Project crashing and Time cost Trade-Off;
Objective of Scheduling, Sequencing, Gantt charts, Advanced Planning and Scheduling System. Strategies
for Managing Demand, Strategies for Managing Supply Production planning control, Aggregate planning
costs and strategies. Gantt chart, Sequencing model. "n" jobs 1 machine, "n" jobs 2 machines, "n" jobs “m”
machine
Module:3 (12)
Inventory Management
Concept of inventory with independent demand: Inventory cost structure Deterministic inventory
model - EOQ models, instantaneous receipt, Inventory model with discounts, delivery over a period
of time, Periodic review and continuous review inventory model; Selective Inventory Control -
ABC and VED.
Quality Management
Concept of quality; Quality of design, Conformance & performance; Cost of poor process
performance and quality. Statistical Quality Control - Process Control (X, R & P chart), Product
control-acceptance sampling and OC curve. Concept of TQM.
Module:4 (10)
Just in Time and Lean Production
Basic element in JIT, Pull system, Push system, Kanban production control system ,
Benefits of JIT, Jit implementation in Learning Organization, JIT in Services. topics.
Books
1. Chase, Jacobs, Aquilano, Agarwal, - “Operations Management”, TMH
2. Aswathappa& Sridhar Bhat, - “Production and Operations Management”, HPH Reference:
1. Krajewski,Ritzman,Kansal, - “Operations Management”, Pearson
2. Everette. Adam Jr., Ronald J. Ebert, - “Production and Operations Management”, PHI
3. Roberta S. Russell & Bernard W. Taylor III, - “Operations Management”, Pearson/ PHI
4. Gaither, Frazier- Operations Management