TY BTech (Electrical) 1/23

PROGRAMME: 103: B.TECH (ELECTRICAL ENGINEERING)

Sr.

No.

Course Code Course Title L P/T T

O

T

A

L

Cr Evaluation

weightage

ESE

(Theory)

Hours

TWA MST ESE

Semester Five

1 200040 Engineering Statistics 3 1 4 7 10 15 75 3

2 303080 Integrated circuits 3 2 5 8 20 20 60 3

3 303090 Signal processing 3 2 5 8 20 20 60 3

4 303101 Control system I 3 2 5 8 20 20 60 3

5 303110 Electromagnetic field 3 2 5 8 20 20 60 3

6 303120 Applied power electronics 3 2 5 8 20 20 60 3

TOTAL 18 11 29 47

Semester Six

1 303131 Electrical power system I 4 2 6 10 20 20 60 3

2 303140 Microprocessor 3 2 5 8 20 20 60 3

3 303102 Control system II 3 2 5 8 20 20 60 3

4 303150 Wave theory and radiating systems 3 2 5 8 20 20 60 3

5 200050 Industrial Economics & Management 2 2 4 6 20 20 60 3

6 303160 Principles of communication

Engineering 3 2 5 8 20 20 60 3

TOTAL 18 12 30 48

TY BTech (Electrical) 2/23

200040: Engineering Statistics

1)Review of probability. Baye’s theorem. Discrete and continuous random variables.

Probability mass function and density function. Expected value. (Expectation)

Moments and moments generating functions. Relation between Raw moments and

Central moments.

2) Probability, distribution : Binomal, Poisson, Normal, Student’s distribution, x2

(Chisquare), F distribution.

3) Sampling theory : Sampling distribution. Test of hypothesis. Level of

significance. Critical region. One- tailed and two-tailed tests. Degree of freedom.

Estimation of population parameters. Central limit theorem.

Large and Small samples :

A) Test of significance for large samples.

i) Test of significance of the difference between sample proportion

and population proportion.

ii) Test of significance of the difference between the sample

proportions.

iii) Test of significance of the difference between sample mean and

population means.

iv) Test of significance of the difference between the means of two

samples.

B) Test of significance for small samples :

i) Test of significance of the difference between sample mean and

population mean.

ii) Test of significance of the difference between means to two small

samples drawn from the same normal population

iii) Paired- t test.

C) F-test of significance of the difference between population variances.

D) Test of the Goodness of fit and independence of attribute. Contingency table.

Yate’s correction.

4) Fitting of curves : Least square method. Fitting of the straight line and

parabolic

curve. Bivariate frequency distribution. Co-relation, Co-variance. Karl

Pearson’s Coefficient and Spearman’s Rank Co-relation coefficients, Regression

coefficients and lines of regression.

5) Analysis of variance: one way and two way classification

6) Statistical quality control and control charts.

Text Books:

1. S G Gupta, V K Kapur, Fundamentals of Mathematical Statistics, S Chand &

Co

2. T Veerrajan, Probability, Statistics and Random Processes, Tata McGraw Hill

3. R P Hooda, Statistics for Business and Economics, Macmillan

TY BTech (Electrical) 3/23

303050: Integrated Circuits

(1) Logic Families

RTL, DTL, TTL, Schottky clamped TTL. Tristate gate ECL, I2L, NMOS

and CMOS gates. Comparison of logic families. Interfacing different

families e.g. TTL with CMOS, NMOS, ECL & TTL, I2L and TTL etc.

(2) All methods of conversion of analog to digital, DAC 0808 and ADC 9809.

IC

7107 functional diagram and description.

(3) Memories. RAM, ROM. The basic cell. IC bipolar. CMOS, RAM, AND

dynamic RAM cell. Magnetic core memory, NVRAM, bubble Memory.

CCD,

PAL and PLA.

(4) OPAMP linear application. Voltage follower. Inverting non-inverting amp.

Adder Substractor. V to I and I to V converter, with floating load and

ground

load. Howland current source. 3 mode integrator. Frequency response of

differentiatior and compensated differentiator, gyrator (simulation of

inductance).

(5) Nonlinear applications of OPAMPS

Precision rectifier, Half wave and full wave. Clipping clamping circuits.

Sample and Hold circuit (performance parameters); Peak detectors, log

amplifiers, temp. Compensated log Amp. Antilog amplifier, multiplier

divider. Instrumentation amplifier. Comparator. Threshold detector zero

crossing detector. Schmitt trigger. Free running multivibrator, weinbridge

oscillator. Phase shift oscillator.

(6) Voltage Regulator

Series, Shunt, break down protection, thermal shutdown. 78XX series.

Negative 75XX series. Adjustable IC regulator 723 & its applications.

Switch mode IC regulator.

(7) 555 Timer

Astable and monostable multivibrator using 555 with one application of

each.

(8) Power control ICs like SL 440, CA 3059 & CA 3095. Miscellaneous ICs

like.

LM335, LM336 Function generator ICs like 8038,566.

(9) Active Filters. First and second order LP, HP, BP & band reject filters.

Switched filters.

TY BTech (Electrical) 4/23

REFERENCES:

(1) Design with OPAMP analog ICs by Sergio Franco. McGraw Hill 1998 2nd

edition.

(2) OPAMP and Linear ICs by Ramakant Gaykwad-1998 2nd

edition

(3) Linear ICs by Roy Choudhary Wiley Eastern – 1987

(4) Analog / Linear ICs by N.K. Jog Technical publications – 1997

(5) SCR Manual – General Electric – Prentice Hall, 1979

Suggested List of experiments:

(1) Study of TTL and CMOS Characteristics.

(2) a) V to I and I to V Converter with grounded load & floating load

b) Adder Substractor.

(3) Differentiator and Integrator using & 741 IC.

(4) a) Clipping clamping circuits using

b) Log amp.

(5) a) Schmitt trigger. Free running multivibrator using IC 555

b) Wien bridge oscillator.

(6) Astable and monostable multivibrator using IC 555

(7) Butterworth and chebychev filter. Frequency response.

(8) Adjustable voltage regulator using IC 723.

(9) Application of any one of the miscellaneous ICs.

TY BTech (Electrical) 5/23

303060: Signal Processing

Preprocessing in analog domain- Concept of tyransducer, Preprocessing of

signal & sampling theory

2. Introduction to signals & Systems ( CT and DT domain )

Definition of Signal

Signal classification

Signal manipulations

Periodicity in CT ( Continuous Time) & DT( Discrete Time) domain

Concept of a system

System representations & classification

Concept of Impulse Response

Convolution in CT domain

3. Review of Fourier Series (FS) & Fourier Transform (FT) for CT systems

4. Fourier Series & Fourier Transform for DT systems( DTFS & DTFT):

Concept, properties and uses

Amplitude & phase spectra

Energy Spectral Density

Power Spectral Density

5. Review of the Laplace Transform

Definition & properties of Two-sided & one-sided Laplace Transform

Region of Convergence (ROC)

System transfer function

Relationship with Fourier Transform & mapping

Zero state & zero input responses

6. Z Transform

Definition & properties of Two-sided & one-sided Z Transform

Region of Convergence (ROC)

Relationship with Fourier and Laplace Transform , & mapping

Inverse Z Transform

7. Introduction to DT Systems

Difference equation

FIR & IIR systems

System transfer function

System realization: Direct forms, Cascade & parallel forms

Linear and circular Convolution

BIBO stabillity

8. Time Domain Analysis of DT Systems

System Transfer function & Impulse response

Solution of a difference equation

zero input & zero state response calculations

9. Discrete Fourier Transform (DFT)

DTFT & DFT

DFT Properties

Fast Fourier Transform (FFT)

TY BTech (Electrical) 6/23

DITFFT and DIFFFT Algorithms

Divide and Conquer Algorithms

DFT analysis of Sinusoidal signals

Limitations of DFT

Text- Books

Signal & Systems by Haykin , Wiley Publication

Digital Signal Processing: Principles, Algorithms and applications by J.G.

Proakis, D. G. Manolakis, PHI publications (1995)

Analog and Digital Signal Processing: by Ashok Ambardar, Thomson Learning

Publication, second edition, (2001)

Discrete- Time Signal Processing by Oppenheim and Schafer with Buck, PHI

publications (2000)

Additional Reading :

Signal Processing & Linear Systems by Lathi , Oxford University Press, First

Indian Impression 2000

TY BTech (Electrical) 7/23

303071: Control System –I

Modeling in frequency domain

Laplace Transform review

The transfer function

Electric network transfer function

Translational mechanical system transfer function

Rotational mechanical system transfer function

Electromechanical system transfer function

Electrical circuit analogs

2. Modeling in the time domain

The general state-space representation

Applying the state-space representation

Converting the transfer function to state-space

Converting from state-space to transfer function

3. Time response

Poles, Zeros, & System response

First order system

Second order system : Introduction

The general second order system

Under damped second order system

System response with additional poles

System response with zeros

Laplace transform solution of state equations

Time domain solution of state equations

4. Reduction of multiple systems

Block diagrams

Analysis and design of feedback system

Signal flow graphs

Mason's rule

Signal flow graphs of state equations

5. Stability

Routh Hurwitz criterion

Routh Hurwitz criterion : special cases

Routh Hurwitz criterion :Additional examples

Stability in state space

6. Steady state error

Steady state error for unity feedback systems

Static error constants and system type

Steady state error specification

Steady state error for disturbances

Steady state error for non unity feedback systems

Sensitivity

TY BTech (Electrical) 8/23

Steady state error for systems in state space

7. Root locus techniques

Defining the root-locus

Properties of root-locus

Sketching the root-locus

Pole sensitivity

8. Frequency response techniques

Asymptotic Approximations: Bode plots

Introduction to the Nyquist criterion

Sketching the Nyquist diagram

Stability via the Nyquist diagram

Gain margin and phase margin via the Nyquist diagram

Stability Gain margin and phase margin via the Bode-plots

Relation between closed loop transient and closed loop frequency response

Relation between closed loop and open loop frequency response

Relation between closed loop transient and open loop frequency response

Steady state error characteristic from frequency response

Term work:

Term work shall consists of at least six assignments and at least 3 computer

programs/simulation carrying weightage of 15 marks and a test covering center

syllabus carrying weightage of 10 marks

Text Books:

1. Norman S. Nise,"Control system engineering",3rd

edition, John Wiley and sons

(Asia) Pvt. Ltd.2001

2. K.Ogata: Modern Control Engineering, 4th edition (LPE),Pearson

Education Asia,2000

Reference Books:

1. R. Bishop and R. Dorf," Modern Control system ", 8 th

edition (LPE) Addison

Wesley,1998

2. G. Franklin, J. D. Powell & Abbas Emami- Naeni," Feedback control of Dynamic

system, 4 th

edition(LPE) Pearson Education asia, 2000.

3. Erononi Umez-Erononi: System dynamics and control, 1st

edition, Thomson

Asia

TY BTech (Electrical) 9/23

303080: Electromagnetic Field

Electrostatics

Coloumb’s Law,The Electric Field, Gauss’s Law, Divergence Theorem,

Electric Potential, Relationship between Electric field intensity and

potential gradient.

The electric dipole, Electrostatic energy density.

Dielectrics,Polarisation,the polarized electric field, relative and effective

permitivity,Boundary conditions between two dielectrics, Boundary

conditions between conductor and dielectric, Dielectric strength.

The analysis of parallel plate capacity with single and multiple dielectrics.

Coaxial cable and energy stored in capacitor, Poisson’s and Laplace

equatons,The method of electric images, point plane and sphere-sphere

problem.

Energy and mechanical forces in electric field.

2. Current

The electric current in metallic conductor, conduction,convection and

displacement current.

Equation of continuity.

3. Magnetic Fields

Forces in moving electric fields, The Gauss’s law of magnetic

fields,character of B lines, line integral of magnetic field vector, self and

mutual inductance.

The automatic model and magnetism inside a material medium,

magnetic field intensity H, Boundary conditions at magnetic surfaces.

Magnetic dipole and magnetic polarization, the various magnetic

materials, domain theory and magnetization curve.

Magnetic circuit of transformer,toroid etc, permanent Magnets.

Magnetic scalar and vector potential, application of vector potential,

the energy and forces in magnetic fields.

4. Time dependent electric and magnetic fields

Maxwell’s Equations in point form, in integral form, for static

harmonic etc fields, physical significance of Maxwell’s Equations, wave

equation.

Plane electromagnetic waves in space in pure and glossy dielectric

media, importance of characteristic impedance and propagation constant, the

wave travel, concept of phase velocity and group velocity in wave travel,

voltage standing wave ratio, current standing wave ratio.

Travelling waves in transmission lines, concept of power transmission in the

form of study of Poynting theorem and Poynting vector.

TestBooks:

1. W.Hayt, “Engg Electromagnetics”,Mcgraw Hill,4th

edition,1987.

2. Edminister, “Schaum’s Series in electromagnetic”, McGraw Hill Pub, 3rd

Edition,1986.

TY BTech (Electrical) 10/23

3. N.Narayan Rao, “Elements of Engg. Electromagnetics ”,PHI Pub,4th

edition,2001.

Refernce Books:

1. Feynmann,”Lectures of Physics”,Vol-2,Addition Wesley,1965

2. S.Seely,”Introduction to Electromagnetics”,McGraw Hill,1958

3. David K.Chen,”Fields and wave Electromagnetics”, Addition Wesley,2nd

edition,1999

Corson and Brain,”Electromagnetics”,CBS Pub,2nd

TY BTech (Electrical) 11/23

303090: Applied Power Electronics

1. Controlled Rectifier

Principle of Phase-Controlled Converter Operation

Single Phase Full Converters, with RL load

Single Phase Dual Converters

Principle of Three-Phase Half- Wave Converters

Three Phase Full Converters

Three Phase Full Converters with RL load

Three Phase Dual Converter

Power Factor Improvements

Extinction Angle Control

Symmetric Angle Control

PWM control

Single-Phase Sinusoidal PWM

Three Phase PWM Rectifier

Single Phase Semi-Converters with RL load

Three Phase Semi-Converters with RL load

2. AC Voltage Controllers

Introduction

Principle of On-Off Control

Principle of Phase Control

Single Phase Bidirectional Controllers with Resistive Loads

Single Phase Controllers with Inductive Loads

Cycloconverters

1) Single Phase Cycloconverters

2) Three Phase Cycloconverters

3) Reduction of Output Harmonics

AC voltage Controller with PWM Control

3. Inverters

Principle of Operation

Performance parameters

Typical Inverters : series Inverters, Self commutated Inverters. Parallel

Inverters, Bridge Inverters, Three Phase Inverters, Current Source

Inverters

Static Frequency Conversion

Voltage Control of Inverters

Harmonic neutralization of Inverters

PWM Inverters

Simple Application of Inverters with Motor load, etc

4. Chopper

Principle of Chopper operation

Step-up Chopper, Step-down Chopper, Step-up/ Step-down Chopper

Chopper Commutation

Jone’s Chopper

TY BTech (Electrical) 12/23

Morgan’s Chopper

Switch mode regulators-Buck, Boost, Buck-Boost & Cuck Regulator

5. AC Regulators

Single Phase AC Regulator

Sequence control of AC Regulator

Three Phase AC Regulator

AC Regulator to feed Transformers

6. Power Supplies

DC Power Supplies

Switched-Mode DC Power Supplies

Flyback Converter

Forward Converter

Push-Pull Converter

Half Bridge Converter

Full Bridge Converter

Resonant DC Power Supplies

Bidirectional Power Supplies

AC Power Supplies

Switched Mode AC Power Supplies

Resonant AC Power Supplies

Bidirectional AC Power Supplies

Text Books:

1) Rashid M. H., “ Power Electronics-Circuits, Devices and Application”,

PHI Publication, second edition ,2001

2) Mohan, Undeland Robbias,” Power Electronics-Converters, application

design ,” John Wily & Sons, second edition,1995

3) Vedam Subrahmanyam,” Power Electronics,” New Age International Pvt.Ltd

1997

Reference Book:

Bose B.K. ,” Modern Power Electronics and AC drives”,Pearson Education

Asia.

TY BTech (Electrical) 13/23

303101: Electrical Power System I

1. Basic structure of power system

Conventional & non- conventional sources of energy Thermal, hydro,

nuclear power plant, solar, wind, geothermal, tidal power plant

Influence of working voltage on size of feeders & distributors in DC

system

Choice of working voltage for transmission.

Factors affecting cost of generation.

Choice of generation unit.

2. Mechanical design of overhead transmission line

Introduction to Main components of overhead lines

Introduction to Line supports, towers, single circuit, double circuit

lines& types of conductors used

Sag calculation for supports at equal levels

Sag calculation for supports at different levels

Effect of wind & ice on sag

3. Transmission line parameters

Inductance

Definition of Inductance

Inductance of a single phase two wire line

Conductor type & bundle conductors

Inductance of composite conductor line, three phase line & double

circuit three phase line

Capacitance

Potential difference between two conductors of a group of parallel

conductors

Capacitance of two wire line, three phase line with equilateral

spacing, three phase line with unsymmetrical spacing

Earth effect on transmission line capacitance

Bundled conductors, method of GMD

Resistance

Resistance

Skin effect & proximity effect

4. Representation of power system components

Introduction

1-ph solution of balanced three phase networks, one line diagram,

impedance and reactance diagram

Per unit (p.u.) system, per unit impedance diagram of a power system.

Representation of loads

TY BTech (Electrical) 14/23

5. Transmission line model & performance

Short line model

Medium line model

(i) nominal T method

(ii) nominal method

Long line model

(i) Interpretation of long line equation

(ii) Ferranti effect, tuned power lines

(iii) Equivalent circuit of a long line

Surge impedance loading

Power flow through transmission lines, power transmission capability

Method of voltage control

6. Overhead insulators

Types of insulators

Potential difference over a string of suspension insulators

Method of equalizing potential

7. Insulated cables

Insulation, Extra high voltage cables , grading of cables

Insulation resistance of a cable, capacitance of single core able

Heating of cables, current rating

Overhead lines versus underground cables

8. 8.1 Neutral grounding

Underground system, effectively grounded system, resonant grounding

Method of neutral grounding , grounding practices

8.2 Earthing & safety Techniques

Objective and definitions

Soil resistivity , earth resistance

Tolerable limit of body currents, tolerable step and touch voltage, actuial

step and touch voltage

Design of earthing grid, concrete encased electrodes and tower footing.

Measurement of earth resistance, soil resistivity

Impulse behavior of earthing system

Text Books:

1. Nagrath I.J. and Kothari D.P., “Modern Power System Analysis,” TMH

Publication third edition 2003

2. Wadhawa C.L.,’Electrical Power System,” Wiley Eastern Ltd. Second

edition 1991

3. Gupta B.R.,”Power System Analysis and design,” Wheeler Publication,3rd

edition,1998

4. Saadat Hadi,” Power System Analysis,” TMH Publication,1st edition

2002

5. S.N.Singh,” Electrical Power Generation, Transmission, and

distribution,” PHI Publication,2003

6. Sony, Gupta ,Bhatnagar & Chakrabharti,” Electrical Power System,

Dhanpat Rai & Son’s

7. J. B. Gupta,” Electrical Power System,” S K Kataria Publication

8. B. M. weedy,” Electrical Power System”.

TY BTech (Electrical) 15/23

303110: Microprocessor

1. Introduction

Introduction to Microprocessors, Microcomputers, and Assembly Language

2. Microprocessor Architecture and Microcomputers Systems

Microprocessor Architecture and its operation

Input and output (I/O) devices.

3. 8085 Microprocessor Architecture and Memory Interfacing

The 8085 architecture

Instruction cycle, machine cycles and T-sate, concept of wait states.

Minimum system design

Memory interfacing with timing considerations. Clock reset and buffering

circuits.

4. 8085 Assembly Language Programming

The 8085 programming model

Instruction classification, Instruction and Data format

Process of writing, assembly and execution of assembly language programs.

5. 8085 Instructions

Data transfer operations

Arithmetic & Logic operations

Branch operations

Writing assembly language programs

Debugging a program

6. Programming Techniques

Looping

Counting and indexing, counters and timers

Code conversion, BCD arithmetic and 16 bit data operations

7. Stack & subroutines

Concept of stack and subroutines

Parameter passing techniques

Re-entrant and recursive subroutines.

8. I/O data transfer techniques

Basic interfacing concepts

Interfacing input and output devices with examples.

Memory mapped I/O and I/O Mapped I/O.

Testing and troubleshooting I/O interfacing circuits.

I/O data transfer classification.

Programmable I/O , Interrupt driven program controller I/O, Hardware I/O

(Direct Memory Access)

9. Interrupts

Requirements

Single level interrupt. Multi level interrupt, Vectored interrupt.

8085 interrupt structure and operation

8259A programmable interrupt controller features and operations.

10. Programmable Interface Devices

Features and operating modes of working of 8155 multipication device

TY BTech (Electrical) 16/23

8255A programmable peripheral interface

8254 programmable interval timer

Direct Memory Access(DMA) and DMA controller 8237

8279 programmable keyboard/display interface.

11. Serial I/O and Data Communication

Basic concept in serial I/O

8085 serial I/O lines

12. Microprocessor Applications

Microprocessor based

a) Over Current relay operation

b) D.C. Motor speed Control

c) Temperature Control

d) Traffic Light Control

e) Stepper Motor control

Text Books:

1. Gaonkar R.S.,” Microprocessor architecture, Programming & application with

8085 “, Penram International (India), 4th

edition, 2000.

2. Pal Ajit – Microprocessor- Principle & application, TMH Publication, 1990.

3. Leventhal L.A.-,”Introduction to microprocessor-Software, Hardware &

Programming, PHI Publication, 1983.

TY BTech (Electrical) 17/23

303072: Control System II

1. Design specifications

a. Relative stability

b. Steady state accuracy (error)

c. Transient response

d. Frequency response characteristics

2. Control configurations

a. Series (cascade compensation

b. Feedback compensation

c. State feedback compensation

d. Series feedback compensation

e. Feed forward compensation

3. Design via root locus techniques

a. Transient response design via gain adjustment

b. Improving steady state error via cascade compensation

c. Improving transient response via cascade compensation

d. Improving steady state and transient response

e. Feedback compensation

4. Design via frequency response

a. Transient response via gain adjustment

b. Lag compensation

c. Lead compensation

d. Lag-lead compensation

5. Design via state space

a. Advantages of state space

b. Analysis of the state equations

c. Control law design for full-state feedback

d. Selection of pole locations for good design

e. Estimator design

f. Compensator design: combined control law and estimator

g. Introduction to the reference input with the estimator

h. Integral control and robust tracking

6. Digital control

a. Digitization

b. Dynamic analysis of discrete systems

c. Design by emulation

d. Discrete design

e. State space design methods

7. Hardware characteristics

a. Analog to Digital (A/D) converters

b. Digital to analog (D/A) converters

TY BTech (Electrical) 18/23

c. Anti-alias prefilters

d.

e. The computer

8. Word size effects

a. Random effects

b. Systematic effects

9. Sample rate selection

a. Tracking effectiveness

b. Disturbance rejection

c. Effect of anti alias prefilters

d. Asynchronous sampling

Text Books:

1. G. Franklin, J.D.Powell & Abbas Emami-Naeini : Feedback control of

Dynamic systems, 4th

edition (LPE), Pearson Education Asia.

2. J. Wilkie, M.Johnson, & R. Katebi: Control engineering : an introductory

course, 1st edition, Palgrave

3. Norman S.Nise: Control system engineering, 3rd

edition, John wiley and sons,

Inc

4. B.Kuo & F.Golnaraghi: Automatic control systems, 8th

edition, john Wiley

and sons, Inc

5. K. Ogata: Modern Control Engineering, Prentice-Hall, 3rd

edition, 1996.

TY BTech (Electrical) 19/23

303120: Wave Theory & Radiating System

1. Maxwell’s equation

Introduction

Faraday’s law

Transformer and Motional EMFs

Displacement Current

Maxwell’s Equations in Final Forms

Time-Harmonic Fields

2. Electromagnetic Wave Propagation

Introduction

Wave Propagation in Lossy Dielectrics

Plane Waves in Lossless Dielectrics

Plane Waves in Free Space

Plane Waves in Good Conductors

Power & the Poynting Vector

Reflection of Plane Wave at Normal Incidence

3. Transmission Lines

Introduction

Transmission Line Parameters

Transmission Line Equations

Input Impedance, SWR and Power

The Smith Chart

Some applications of Transmission Line

4. Waveguides

Introduction

Rectangular Waveguides

Transverse Magnetic(TM) Modes

Transverse Electric (EM) Modes

Wave Propagation in the Guide

Power Transmission and Attenuation

Waveguide Resonator

5. Antennas

Introduction

Hertzian Dipole

Half-Wave Dipole Antenna

Quarter-Wave Monopole Antenna

Small Loop Antenna

Antenna Characteristics

Antenna Arrays

TY BTech (Electrical) 20/23

Text Book:

1) Matthew N. O. Sadiku,”Elements of Electromagnetics,” second edition

1995, Oxford University Press

2) Engineering Electromagnetics by John. D. Krons

3) Engineering Electromagnetics by Jordans & Balmoin.

TY BTech (Electrical) 21/23

200050: Industrial Economics & Management

Basic economic problems. Resource constraints and welfare maximization. Nature

of economics. Positive and normative economics, micro and macroeconomics. The

role of the state in economic activity; market and government failures. Theories of

demand, supply and market equilibrium. Market structures, perfect and imperfect

competition commercial and central banking. International trade. Foreign exchange

and balance of payments.

Management : Definition process. The functions of a manager. Planning – its nature,

objectives, types of plans. Decision – making. Organising – departmentalization,

delegation decentralization, span of management. Staffing – selection and

recruitment, appraisal, management development. Leadership motivation and

communication. Controlling – its nature techniques.

Books recommended

1) Economics : Samuelson & Nordhaus

2) Principles of Economics : Mankiw

3) Essential of Management : Koontz & O’donnell

4) Management : David R. Hampton

TY BTech (Electrical) 22/23

303130: - Principles of Communication Engineering

1. Signal Representation

Types of signal

Signal Spectrum

Orthogonality

Mean Square Wave

Lagendre Polynomial

Complex Fourier Spectrum

Properties of Fourier Transform

Convolution Theorem

IEEE frequency Spectrum

2. Modulation Techniques

Amplitude Modulation and circuits

Sideband transmission

Frequency modulation and circuits

Phase Modulation and circuits

Pulse Modulation techniques

Delta Modulation and adaptive delta modulation

Companding

3. Demodulation Techniques

AM detection and circuit

VSB detection and circuits

FM detection and circuits

PM demodulation and circuits

4. Radio receivers

TRF and Superhetrodyne receivers

AGC methods

Communication receivers and features

FM receivers

5. Propagation of Waves

Reflection and refraction of Radio Waves

Groundwave, line of sight waves. Sky waves

Fading and echo scattering

6. Aerials

Radiation pattern form short Dipole

Radiation Pattern form short ground aerial

Shortwave and medium wave aerials

Reference:

1. Simon Hykin –Communication System, John Wiley & Sons Inc 2001 4th

edition

2. Lathi B.P.- Modern Digital and Analog Communication Systems, Oxford

University Press 1998 3rd

edition

3. Dennis Roddy and John Coolen –Electronic Communication, Prentice Hall

of India 1992 3rd

edition

TY BTech (Electrical) 23/23

Term Work:

The term work should consist of consist of at least 8 experiment properly

recorded and graded which will carry a weightage of 15 marks and test will

carry a weightage of 10 marks

List of Experiments:

1) To understand the AM demodulation principle using Diode detector circuit

2) To learn the principle of FM generation(any one method)

3) To learn the principle of AM generation

4) To generate the pulse amplitude modulation waveforms

5) To generate the pulse position modulation waveforms

6) To generate PWM waveforms

7) Study of radio receivers characteristics like sensitivity, selectivity, image

rejection

8) To plot the radiation Pattern of Antenna