## Thursday, 10 May 2012

## Shivaji University, Kolhapur. Revised Syllabus & Structure of S.E. Part-I & II (Electronics Engineering / Electronics and Telecommunication Engineering) Semester –III and IV (w.e.f. Academic Year 2008-09)

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester -III*

*ENGINEERING MATHEMATICS – III*

*Teaching Scheme Examination Scheme*

*Lectures : 3 hours/week Theory : 100 marks*

*Tutorial : --- Term work : --*

*SECTION – I*
UNIT-I:
Linear Differential Equations: (6 Hrs)

Linear
Differential Equations with constant coefficients, Homogenous Linear
differential

equations,
method of variation of parameters, Applications of LDE with constant
coefficients

to
Electrical systems.

UNIT-II:
Partial Differential Equation: (4 Hrs)

Four
standard forms of partial differential equation of first order

UNIT-III:
Fourier Series: (5 Hrs)

Definition,
Euler’s formulae, Conditions for a Fourier expansion, Functions having points
of

discontinuity,
change of interval, expansions of odd and even periodic functions, Half range

series.

UNIT-IV:
Fourier Transforms: (5 Hrs)

Fourier
transforms, Fourier sine and cosine transforms, complex form of Fourier
integral,

Finite
Fourier sine and cosine transforms.

**SECTION – II**

UNIT–V:
Laplace Transform: (5 Hrs)

Definition,
properties of Laplace transforms, transforms of derivatives, transforms of
integral,

Inverse
Laplace transforms, Convolution theorem. Applications to initial value boundary

problems,
Heaviside Unit step function, Dirac-delta function, Periodic function.

UNIT- VI:
Z Transform: ( 5 Hrs)

Definition,
properties of z transform , Z Transform of basic sequences , Z transform of
some

standard
discrete function inverse Z transform

UNIT-
VII:Probability: (5Hrs)

Definitions
of Random variable, Discrete and continuous random variable, Expected value of

random
variable, Variance, Moments and moment generating functions. Probability mass

function
and probability density function, Probability distribution for random variables
,

Binomial,
Poisson and Normal distributions

UNIT
-VIII: Vector Differentiation: (5
Hrs)

Differentiation
of vectors, Gradient of scalar point function, Directional derivative,

Divergence
of vector point function, Curl of a vector point function. Irrotational and
solenoidal

vector
field.

**Reference Books:**

1. A text
book of Applied Mathematics: Vol. I, II and III by J. N. Wartikar & P. N.
Wartikar,

Vidyarthi
Griha Prakashan, Pune.

2. Higher
Engineering Mathematics by Dr. B. S. Grewal.

3.
Advanced Engineering Mathematics by Erwin Kreyszig.

4. A
textbook of Engineering Mathematics by N. P. Bali, Ashok Saxena and N. Ch. S.
N.

Iyengar-
Laxmi Publication, Delhi.

5.
Fundamental of Statistics by S. C. Gupta.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester- III*

*Electrical Machines and Measurements*

*Teaching Scheme: Examination Scheme:*

*Lectures: 3 hr/week Theory : 100 Marks*

*Practical: 2 hr/week Term Work: 25 Marks*

*Section -I*
UNIT-I:
D.C. Motors: (6Hrs)

Speed
control of shunt & series motors , armature voltage control , flux control
, series – parallel

control,
Electrical braking –Dynamic, Plugging , regenerative for shunt and series
motors , starters for

DC motors
– three point , four point starters , face plate type controller, electronic
starter, numerical

on speed
control.

UNIT-II:
Induction Motor : (6 Hrs)

Construction
, types , working principle , torque equation – relation among starting maximum
&

running
torque , torque slip characterstics, effect of rotor resistance on maximum
torque , speed

control
methods – frequency control , pole changing methods , voltage control , rotor
resistance

control ,
constant V/F & constant voltage – variable frequency , modes of operation ,
starters for

three
phase induction motor- D.O.L, Star/delta , autotransformer, rotor resistance
starter.

Numericals
on power stages & torque equations. Equivalent circuit, linear induction
motor.

UNIT-III:
Electrical Devices – Instruments (6Hrs )

Servo
& Stepper Motors: Working principle, construction, types, and
applications.

Electromagnetic
relay , induction relay contactors , Potential transformer, current transformer
, auto

–
transformer , miniature Circuit Breaker (MCB), Earth Leakage Circuit
Breaker(ELCB)

,Dynamometer
type wattmeter ,.

**Section-II**

UNIT-IV:
Transducers : (6Hrs)

Definition,
classification, transducer selection, different types of transducers, strain
gauges, RTD,

thermistor,
thermocouple, LVDT, capacitive transducers, piezoelectric transducer,
photovoltaic cell,

LDR,
pressure transducer speed measurement using magnetic and photoelectric pickup,
IC based

Sensor-LM35

UNIT- V:
Introduction to Measurements :

(6Hrs)

Measurements,
significance of measurements, methods of measurements- Direct & indirect
method,

elements
of generalized measurement system, measurement system performance, Performance

characteristics-
static and dynamic characteristic, Errors- Types & source of error.

Digital
voltmeters- Introduction, Dual Slope Integrating type DVM, Integrating type DVM
&

successive
approximation principles, general specifications of DVM, digital multimeter,
digital

measurements
of time, digital frequency meter , Q meter,

UNIT VI :
Measuring Devices : (6Hrs)

CRO: Dual
Beam, Dual Trace, sampling, Digital storage, measurement of phase and frequency
using

Lissajous
pattern, CRO probes: active, passive, current, attenuators

display
devices & principle: LED,LCD,graphics display .

Signal
generators, Function generators. Spectrum analyzer, logic analyzer

**Text Books**

1. H .S.
Kalsi ‘Elecronic Instrumentation’ – 2nd edition
--Tata McGraw Hill Publication

2. A. D.
Helfrick , W. D. Cooper ‘ Modern Electronic Instrumentation and Measurement

Techniques’--
Pearson Education

**Reference Book:**

1.
A.K.Sawhney ‘A Course in Electrical & Electronics Measurement &
Instrumentation.’

--11th
Edition, 1996 --Dhanpat Rai & sons

2. C.S.
Rangan ,G.R. Sharma , V.S.V. Mani ‘Instrumentation devices and system’—

2nd
edition --Tata McGraw Hill Publication

3.
B.C.Nakra, K.K.Choudhary ‘Instrumentation, Measurement and Analysis’

2nd
edition -- Tata McGraw Hill Publication l

4.
E.O.Doebeline.’Measurement systems application and design ‘Tata McGraw Hill
Publication

5. Oliver
Cage ‘Electronic measurement and instrumentation ‘Tata McGraw Hill Publication

**Term Work:**

**List of Experiments (Minimum 8)**

1. Study
of temperature transducers: (Any two)

a) RTD

b)
Thermocouple

c)
Thermistor

2. Study
of displacement transducers: (Any two)

a)
Inductive

b)
Capacitive

c)
Resistive

3. Study
of weight measurement using strain gauge:

4. Study
of speed measurement using : (Any one)

a)
Magnetic pick up

b)
Photoelectric pick up

5. Study
of AC and DC bridges: (Any two)

a)
Wheastones’ bridge

b) Maxwell’s
bridge

c) Wein
bridge

6.
Measurement of frequency and phase using Lissageous patterns

7. Study
of digital storage oscilloscope

8. Study
of spectrum analyzer / Wobbuloscope.

9. Study
of pressure measurement using bourdan tube

10. Speed
control of DC shunt Motor using:

a) Flux
control and b) Armature voltage control

11. Load
test on three phase Induction Motor

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester- III*

*ANALOG ELECTRONIC CIRCUITS AND DESIGN – I*

*Teaching Scheme*

*:*

*Examination Scheme*

*:*

*Lecturers : 4 hr/week Theory : 100 marks*

*Practical : 2 hr/week Term Work : 25 marks*

*Tutorial : - hr/week POE : 50 marks*

*Section-I*
UNIT-I:
Unregulated Power Supplies: (8 Hrs)

Specification
and ratings of diodes (P-N junction, Zener and power diode) and transistor (low
power,

high power
& switching) .

Rectifiers:
Half wave, full wave: center tap and bridge type, analysis for different
parameters: PIV,

TUF,
efficiency, ripple factor, regulation, etc.

Filters:
Need of filters, Types: capacitor, inductor, LC, CLC, Analysis for ripple
factor and regulation.

Design of
unregulated power supply with and without filter.

UNIT-II:
Voltage Regulators : (8Hrs)

Need of
voltage regulator, Stabilization factors, Analysis & Design of

Shunt
regulator (using Zener diode & BJT), series voltage regulator (using BJT)

Series
voltage regulator with Pre- regulator & Overload protection circuit.

UNIT-III:
Transistor Biasing : (8Hrs)

Need of
biasing, DC load line analysis, operating point, thermal runaway. Different
biasing circuits:

fixed
bias, collector to base bias & voltage divider bias. Stability factor,
General expression for

stability
factor, stability factor for all biasing circuits. Design of biasing circuits,
Compensation

techniques:
Thermistor and diode compensation

**Section-II**

UNIT-IV:
Voltage Amplifiers:- (10 Hrs)

H-Parameters,
Hybrid model for transistor (CE, CB& CC configuration), Generalized
H-parameter

analysis
of transistor amplifier for Voltage Gain, Current gain, Input resistance &
Output resistance

taking Rs
into account, approximate H-parameter model for CE,CB & CC. Classification
of voltage

amplifiers,
Detailed study of Single stage RC coupled amplifier & Emitter follower.
Analysis for

voltage
gain, current gain, input resistance & Output resistance. Design of single
stage RC coupled

amplifier
& Emitter follower.

UNIT-V:
Frequency Response of Single Stage RC Coupled Amplifier: (8Hrs)

Low
frequency response: Effect of emitter bypass capacitor(CE
) & Coupling capacitor(CC),
Amplifier

response
to square wave, percentage Sag calculation, (Numerical are expected)

High
frequency response: Hybrid M model , Derivation for CE short circuit &
resistive current gain, N

cutoff, O
cutoff frequency, approximate amplifier high freq. response to square wave
,gain bandwidth

product,
(Numerical are expected)

UNIT-VI:
Feedback Amplifiers : (6Hrs)

General
theory of feedback, reasons for negative feedback.

Types of
negative feedback in transistor circuits: Voltage series, Current series,
Voltage shunt, Current

shunt
feedback amplifiers, Darlington pair, Darlington amplifier using bootstrapping
principle,.

(Numerical
are expected)

Design of
Voltage series feedback amplifier

**Text Books:**

1. Allen
Mottershed –‘Electronic devices & circuits’-Prentice- Hall India

2. J.
Millman & C.Halkias -‘Electronic devices & circuits’-IInd
Edition- Tata McGraw Hill

Publication

3. N.C.
Goyal & R.K. Khetan-‘ A Monograph on Electronics Design Principles’-Vth
Edition-

Khanna
Publishers

**References Books**

**:**

1. David
A. Bell –‘Electronic devices & circuits’- IVth Edition-
Prentice- Hall India

2. Robert
L. Boylsted, Louis Nashelsky- ‘Electronic devices & circuit theory’-

(IXth
edition)- Pearson Education

3 National
Semiconductor Data Manual.

**List of Experiments (Minimum 10)**

1. Study
of ratings of Electronic components and lab. Equipments.

2. Design
& analysis of Half wave rectifier(HWR) with & without filter by
calculating

performance
parameters

3. Design
& analysis of Full wave rectifier(FWR) with & without filter by
calculating

performance
parameters

4. Design
& analysis of Bridge rectifier with & without filter by calculating
performance

parameters

5. Design
& analysis of Zener shunt regulator.

6. Design
& analysis of Transistorized shunt regulator.

7. Design
& analysis of series pass regulator with & without pre- regulator.

8. Design
& analysis of Voltage divider biasing circuit.

9.
Determination of H-parameters from transistor CE characteristics.

10.
Calculation of performance parameters (Av, Ai, Ri, Ro) for single stage RC
coupled amplifier.

11. Study
of Frequency response of single stage stage RC coupled amplifier.

12. Study
of square wave response of RC coupled amplifier & calculation of Sag &
rise time (tr).

13.
Comparative study of voltage amplifiers (with & without feedback).

14. Design
& analysis of voltage series feedback amplifier.

**Note for paper setter**

**:**

• Question
paper shall consist of approximately 60% analysis & design based problems

and
approximately 40% theory type questions.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester-III*

*LINEAR CIRCUITS*

*Teaching Scheme: Examination Scheme*

*:*

*Lecturers: 3 hr/week Theory : 100 Marks*

*Practical: 2 hr/week Term Work: 25 Marks*

*Tutorial : 1 hr/ week*

*Section -I*
UNIT-I:
Network Fundamentals : (6 Hrs)

Basic
Definitions: Passive Network, Active Network, Linear Element, non-linear
elements,

Unilateral,
bilateral, lumped & distributed elements.

Representation
of voltage & current sources.(Ideal & practical) , source
transformation, series &

parallel
connection of passive elements(R,L,C), graph of network & its parts, loops
& trees, linear

graphs
& incidence matrix, cutsets, planner & non-planner graph loop matrix.

Star-
Delta transformation, reduction of networks: Mesh analysis, Node analysis.

UNIT-II:
Network Theorems: (4 Hrs)

Superposition
Theorem, Millman’s Theorem, Compensation Theorem,

Norton’s
Theorem, Thevenin’s Theorem, Maximum Power Transfer Theorem,

Reciprocity
Theorem.

UNIT-III :
Two Port Network & Network Functions: (8 Hrs)

Two port
network: Open circuit
impedance ( Z ) parameters, Short circuit admittance ( Y )

parameters
, Hybrid ( H ) parameter, Transmission parameters(ABCD), Interrelation of

different
parameters, Interconnections of two port network (Series, Parallel, Cascaded,
Series-

Parallel)
T & R representation .

Network
Functions : Network functions for one port & two port networks, Driving
point

impedance
and admittance of one port network, Driving point impedance, admittance &
different

transfer
function of two port network (Z,Y,G & D
parameters). Concept of complex frequency,

significance
of poles & zeros. Restrictions on poles & zeros for transfer &
drawing points

function
,stability concept in passive circuit using Routh-Harwitz criterion , pole zero
diagram.

**Section –II**

UNIT-IV :
Resonance : (6 Hrs)

Defination
, Types: series & parallel resonance.

Series
resonance- resonant frequency, variation of impedance, admittance, current
& voltage

across L
& C w.r.t. frequency, Effect of resistance on frequency response,
Selectivity , B.W.&

Quality
factor.

Parallel
resonance – Anti resonance frequency, variation of impedance & admittance
with

frequency,
. Selectivity & B.W.

UNIT-V:
Filters & Attenuators: (8 Hrs)

Definitions,
classification & characteristics of different filters, filter fundamental
such as

attenuation
constant ( O ) , phase shift
(N) propagation constant (S) characteristic impedance ( Zo) , decibel ,neper. Design
& analysis of constant K , M derived & composite filters (low pass,
high pass, band pass & band stop filters): T & R sections.

Attenuators
- Definitions, classification , relation between neper & decibel . Analysis
& design of T type, R type , O Lattice , bridged- T & L types
attenuators

UNIT-VI :
Transient Response: (4 Hrs)

Steady
state & transient response (Voltage & Current)

DC
response of RL circuit

DC
response of RC circuit

DC
response of RLC circuit

Sinusoidal
response of RL, RC & RLC circuit

**Term Work: (Minimum 10 tutorials):**

**Minimum 10 tutorials based on above syllabus covering all units.**

**Practials :**

**Minimum 08 experiments based on above syllabus covering all units.**

**Text book :**

1 .A.
Sudhakar ,Shyammohan S.Palli ‘Circuit & Network – Analysis & Synthesis’
IIIrd Edition –

Tata
McGraw Hill Publication

2. D. Roy
Choudhury ‘Networks & Systems’ - New Age International Publisher

Reference
books:

1.
A.Chakrabarti ‘Circuit Theory (Analysis & Synthesis)’ - IIIrd
Edition

Dhanpat
Rai & co

2. M.E.Van
Valkenburg ‘ Network Analysis’ - IIIrd Edition
, Pearson Education / PHI

3. Josheph
Edministrar ‘Theory & Problems of Electronic Circuit (Schaum’s series) –
Tata Mc

Graw Hill,
Publication.

4. Soni
Gupta ‘Electrical Circuit Analysis’ Dhanpat Rai & Co.

5.
Boylestad ‘Introductory Circuit Analysis – Universal book stall, New Delhi.

Note for
paper setter:

• Question
paper shall consist of approximately 60% Numerical problems &

approximately
40% theory should be covered.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. ( Electronics and Telecommunication Engineering)*

*Semester-III*

*DIGITAL DESIGN*

*Teaching Scheme: Examination Scheme*

*:*

*Lectures: 3hr/week Theory: : 100 marks*

*Practical : 2hr/week Term Work : 25 marks*

*Tutorial : 1 hr/week POE : 50 marks*

*Section-I*
UNIT-I:
Binary Arithmetic & Codes: (4Hrs)

Binary
arithmetic operations: addition, Subtraction, multiplication, Division of
binary numbers,

Subtraction
using 2’s complement method.

Binary
codes: weighted and non weighted codes, self complementary codes, BCD,
Excesses-3, Gray

codes,
error detecting and correcting codes, hamming codes, alphanumeric codes, ASCII
Codes.

UNIT- II:
Boolean Algebra: (4Hrs)

Boolean
Laws and Expression using Logic Gates, Realization of different gates using
Universal gates,

De-Morgan’s
Theorem, Duality Theorems.

Standard
forms: SOP, POS, Simplification of Switching function & representation
(Maxterm &

Minterm),
Boolean expression & representation using logic gates, Propagation delay in
logic gate.

UNIT- III:
Boolean Function Reduction Techniques : (6Hrs) Karnaugh
map: Kmap

Format up
to 4 variables, mapping and minimization of SOP and POS expression, Don’t care

condition,
conversion from SOP to POS and POS to SOP form using K-map, minimization of
multiple

output
circuits,

UNIT- IV:
Logic Families: (4 Hrs)

Digital IC
specification terminology, Logic families: TTL, CMOS, ECL families, Interfacing
of TTLCMOS

&
CMOS-TTL.

**Section-II**

UNIT- V
:Combinational Circuits Design : (6Hrs)

Adder
& Subtractor(Half and Full), Parallel Binary adder, BCD Adder, Binary
multipliers, Code Converters, parity bit generator, Comparators, , Decoder, BCD
to 7-segment Decoder ,Encoders, Priority encoders, Multiplexers, De-
Multiplexers

UNIT VI:
Sequential Circuits Elements: (6Hrs)

Flip-flop
& Timing Circuits: SR latch, Gated latch, Edge triggered flip-plop:- D, JK,
T Flip-flop, flipflop

asynchronous
inputs ,characteristic table of Flip-flop, excitation table of Flip-flop, ,
master slave JK flip flop, inter conversion of Flip-flop.

Study of
timing parameters of flip-flop: clock to Q, setup time, hold time, timing
parameters of flipflop asynchronous input.

UNIT-VII:
Applications of Sequential circuits. (6Hrs)

Shit
resistor: buffer register, controlled buffer register.

Data
transmission in shift resistor SISO, SIPO, PISO, PIPO, Bidirectional shift resistor
universal shift resistor.

Counter:
Classification, Ripple or asynchronous counter, Effect of propagation delay in
ripple counters, up-down counter, Mod-n counter, synchronous counter, Ring
counter, Johnson counter.

**Text Books:**

1. A.
Anand Kumar ‘Fundamentals of Digital Circuits’--. PHI

2. M.
Morris Mano ‘Digital Design’-- (Third Edition),. PHI

Reference
Books:

1. Willim
I. Fletcher.’An Engineering Approach to Digital Design’—PHI/ Pearson

2. Norman
Balabanian Bradle Carlson. ‘Digital Logic Design Principals,.’ Wiley
Publication.

3.
Rajkamal ‘Digital Systems Principals and Design’—Pearson

4. A.P.
Malvino, D.P. Leach ‘Digital Principles & Applicatios’ -VIth
Edition-Tata Mc Graw Hill,Publication.

5. R.P.
Jain-‘Modern Digital Electronics’ IIIrd Edition-
Tata Mc Graw Hill, Publication.

**Term Work:**

**List of Experiments: [Minimum 10]**

1. Study
of basic gates using TTL, CMOS: 7432, 4011,4050, 4070,4071,40106

2. Study
of Static I/O and transfer Characteristic of TTL.

3. Study
of Static I/O and transfer Characteristic of CMOS.

4. Study
of Universal gates ( NAND, NOR )

5. K map
based implementation of combinational logic

6. Half
and Full Adder, Half and Full Subtractor

7. 4 bit
Adder subtracor using IC 7483

8. Code
Converters ( Binary to Gray, Excess 3 to Binary )

9.
Comparator using IC 7485

10.
Implementation of combinational logic using MUX

11. Study
of Decoder and DEMUX (IC 74138)

12. Study
of 7 segment decoder driver. (IC 7447)

13. Study
of Flip Flops ( SR FF, D FF, JK FF, T FF)

14. Design
Built and test MOD N counter

15. Design
Built and test Shift Register

**Tutorials: (minimum 10)**

1)
Tutorial based on comparative study of various types of TTL Circuits

2)
Tutorial based on Characteristics of of TTL family

3) Based
on datasheets of following TTL & CMOS ICs

7400,7402,7404,7408,7432,7486,7446/47,7474,7476,7490,7493,7495,7483,7485,74154,74150

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*SE (Electronics and Telecommunication Engineering)*

*Semester-III*

*PROGRAMMING TECHNIQUES*

*Teaching Scheme: Examination Scheme:*

*Lectures: 2hr/week POE : 50 marks*

*Practical: 2hr/week Term Work: 50 marks*
UNIT-I:
Introduction: (3 Hrs)

Object
oriented programming [C++], applications of OOP & C++, dynamic
initialization of variables, storage classes. Functions in C++, function
prototype, call & return by reference, inline function, Default & Const
argument.

UNIT-II:
Classes & Objects: (4 Hrs)

Introduction
,structures,classes, defining member function, making an outside function
inline, Nesting member function, private member function, Arrays within a
class, memory allocation for objects, Array of objects, pointer to members.
Pointers to objects this Pointer.

UNIT-III:
Constructors and Destructors: (4 Hrs)

Constructors,
parameterized and multiple, constructors with default arguments, Dynamic
initialization of objects (new, delete)
copy constructor, dynamic constructors and destructors.

UNIT-IV:
Polymorphism & Inheritance: (6 Hrs)

Function
overloading, Unary & binary operator overloading, manipulation of strings
using operators. Friend function & friend class.

Single,
multiple, multilevel, Hybrid, Hierarchical inheritance, virtual base classes,
Abstract classes. Templates,exception handling.

UNIT-V:
File Handling : (3 Hr)

Classes
for file stream operations, opening and closing of files, file modes, file
pointer & their manipulations, sequential I/O operations.

UNIT-VII:
Graphics : (4 Hr)

Introduction
to graphics.

Text mode
graphics function ,The window function,text mode functions cputs,ctrscro
,Graphics mode graphics function,integraph,circle, closegraph setting
colours,lines & rectangle ,polygon

**Text Book**

:

1. E
Balgurusamy –‘Object oriented programming with C++’ -, IIIrd
Edition- Tata Mc- Graw Hill Publication

**Reference Book:**

1. Herbert
Schildt –‘The Complete Reference C++’ - IIIrd Edition
- Tata McGraw Hill Publication

2.
Ravichandran D.-‘Programming with C++ ‘-IInd Edition-
Tata McGraw Hill Publication

3. Robert
Lafore –‘C++ Programming’ –. IV th Edition –Techmedia, New Delhi.

4. Object
oriented programming in Turbo C++ - Robert Lafore

- Galgotia
pub.

**Term Work :-**

A] 10
programmes based on above syllabus.

B] Mini
project based on data structures, file handling, graphics and it should be
carried out by a group of two students
only.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester-IV*

*ANALOG ELECTRONIC CIRCUITS & DESIGN--II*

*Teaching Scheme: Examination Scheme:*

*Lectures: 4 hr/week Theory : 100 marks*

*Practical: 2 hr/week Term Work : 25 marks*

*POE : 50 marks*

*Section – I*
UNIT –I:
Wave Shaping Circuits: (7Hrs)

Low pass
& high pass RC circuits (square & step response), High pass RC circuit
as a

differentiator,
Low pass RC circuit as integrator. Clipping circuits: Classification, diode
clippers, transistor clippers, Transfer characteristics, Design & analysis
of clipper circuits. Clamping circuits: Classification, clamping operations,
Clamping circuit theorem, practical clamping circuits, Voltage multipliers: Doubbler, Trippler &
Qudrappler circuits.

UNIT –II:
Multi Stage Amplifiers : (6Hrs)

Need of
cascading, Parameter evaluation such as Ri , Ro, Av, Ai & Bandwidth for
general multi stage amplifier ,Analysis & design at low frequency & mid
frequency of RC coupled, direct coupled & voltage series feed back (Two
stage) amplifier.

UNIT –III:
Power Amplifiers : (7Hrs)

Need of
Power amplifier, classification of power amplifier, Power considerations,

Distortion
in power amplifiers: Phase, Frequency, amplitude/ harmonic / non linear
distortion, amplitude distortion using Three point method. Class A single ended
transformer coupled amplifier& class A Push pull amplifiers analysis and
design, Class B amplifier & class B push pull amplifier analysis &
design, crossover distortion, class AB Push pull amplifiers analysis and design
Complementary symmetry power amplifier.

UNIT–IV:
FET & MOSFET: (6Hrs)

Biasing of
JFET, Common source FET amplifier at low and high frequency- analysis and
design. MOSFET-construction, characteristics and comparative study of
Enhancement and Depletion MOSFET (P-channel & N-channel),Handling
precautions of MOS devices, ratings and specifications of MOS,CMOS inverter.

**Section – II**

UNIT –V:
Oscillators: (8Hrs)

Barkhausen’s
criteria , Frequency and amplitude stability, Classification,

RC
oscillators : RC phase shift & Wein bridge oscillator analysis & design
using BJT & FET , LC oscillators: Colpit’s & Hartely’s oscillators
analysis and design

using BJT,
Crystal oscillator.

UNIT –VI:
Multivibrators : (9Hrs)

Transistor
as a switch, Different transistor switching parameters, classification of
multivibrators, Analysis and design of Astable, Monostable, Bistable
multivibrator and Schmitt trigger using BJT. Design of triggering circuits for
Multivibrators

UNIT –VII
: IC Regulators : (5Hrs)

Study and
design of regulators using IC’s :78XX,79XX,723,LM317,

Switching
regulator: Introduction, study of LM3524.

**Text Books:**

1. J.
Millman & C.Halkias -‘Electronic devices & circuits’-IInd
Edition- Tata McGraw Hill

Publication

2. Allen
Mottershed –‘Electronic devices & circuits’-Prentice- Hall India

3. N.C.
Goyal & R.K. Khetan-‘ A Monograph on Electronics Design Principles’-Vth
Edition-

Khanna
Publishers

4. J.
Milman & H. Taub ‘ Pulse Digital & Switching Waveforms’

- IInd
Edition- Tata McGraw Hill Publication

**References Books**

**:**

1. David
A. Bell –‘Electronic devices & circuits’- IVth Edition-
Prentice- Hall India

2. J
Millman & A. Grabel-‘ Microelectronics’- IInd Edition-
McGraw Hill International

Editions

3 National
Semiconductor Data Manual.

4 M.S.
Roden, G.L. Carpenter ‘ Electronic Design- From Concept to reality’-IV th
Edition-

Shroff
publisher & Distributors

**Term Work:**

**List of experiments (Minimum 10)**

1. a Study
of RC low pass filter as an integrator

b. Study
of frequency response of low pass filter

2 a. Study
of RC high pass filter as an differentiator

b. Study
of frequency response of high pass filter

3. Design
of different clipper circuits

4. Study
of different clamper circuits: positive, negative & bias

5. Design
& study of Frequency response of two stage RC coupled amplifiers

6. Study
of power amplifiers

7. Design
of astable multivibrators

8. Design
of monostable multivibrators

9. Design
of bistable multivibrators

10. Design
of Schmitt trigger

11. Design
of Wein bridge oscillator using BJT.

12. Design
of RC phase shift oscillators using BJT/ FET.

13. Design
of Collpitt’s oscillators using BJT

14. Design
of Hartly oscillators using BJT

15. Study
of Frequency response of Common Source(CS) amplifier

**Note for paper setter**

**:**

• Question
paper shall consist of approximately 60% analysis & design based problems

and
approximately 40% theory should be covered.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester- IV*

*ELECTRONICS COMMUNICATION SYSTEMS*

*Teaching Scheme: Examination Scheme*

*:*

*Lectures : 4 hr/week Theory : 100 Marks*

*Practical : 2 hr/week Term Work : 25 Marks*

*POE : 50 Marks*

*Section-I*
UNIT-I:
Introduction : (5 Hrs)

Block
schematic of communication system, base band signals, RF bands, Necessity of
modulation, types of modulation – AM, FM, PM and Pulse Modulation. Noise types,
Noise figure. Introduction to radio wave propagation, ground wave, space wave
and sky wave.

UNIT-II:
Amplitude Modulation : (7 Hrs)

Amplitude
Modulation principles, AM envelope, frequency spectrum & BW, phase
representation of AM wave, Modulation index, % modulation (Numericals expected)

AM
modulating circuits: Low level AM modulation, medium power AM modulation,

AM
transmitters: Block of low level DSBFC, High level DSBFC, Trapezoidal patterns

Evolution
and descriptions of SSB, Suppression of carrier using balanced modulator,
Suppression of unwanted sideband, Methods: Filter system, phase shift &
third method Vestigial sideband(VSB)

UNIT-III:
Angle Modulation: (10 Hrs)

Theory of
frequency and phase modulation, mathematical analysis, deviation sensitivity,
FM and PM waveforms, phase deviation and modulation index, frequency deviation
and percentage modulation, angle modulation circuits using varactor diode
,using frequency analysis of angle modulated wave- Bessel function, BW
requirements, deviation ratio, Noise and angle modulation, pre-emphasis and
deemphasis.

*Section-II*
UNIT-IV:
Pulse Modulation : ( 8 Hrs)

Pulse
amplitude modulation, Sampling theorem & type:Natural & flat top, PAM
modulation circuit, PAM demodulation circuit, TDM and FDM, Crosstalk in TDM,
pulse time modulation, generation of PTM signals ( direct-indirect method), PWM
modulator, PPM modulators, demodulation of PTM.

UNIT-V: AM
Receiver: (7 Hrs)

Simplified
block diagram of AM receiver, receiver parameters: Sensitivity, Selectivity,

BW,
dynamic range, Tracking, fidelity, Types of AM receiver: TRF and superhetrodyne
(block diagram), AM detection types: using diode, practical diode detector,
distortion in diode detector. Negative peak clipping & diagonal clipping,
Demodulation of SSB

using :
product demodulator & diode balanced modulator, Automatic Gain Control
(AGC).

UNIT-VI:
FM Receiver : (6 Hrs)

Double
conversion FM receivers, block diagram, FM demodulator, tuned circuit frequency
discriminators, slope detectors, fosters seeley discriminator, ratio detectors,
PLL-FM demodulators, FM noise suppression , Antenna: basic consideration
radiation, Radiation mechanism, Elementary doublet.

UNIT-VII:
Telephone System : ( 5 Hrs)

Introduction
,public switched telephone network , local loop signals and noise in the
telephone system , digital transmission telephone network signaling , digital
local loops.

**Text Books:**

1. George
Kennedy ‘Electronics Communication System’- IVth Edition-Tata
McGraw Hill

Publication.

2. Wayne
Tomasi ‘Electronics Communication System’ -Fundamentals through Advanced.- Vth

Edition-
Pearson Education.

**Reference Books:**

1. R P
Singh, S D Sapre ‘Communication System-Analog & Digital’

IInd
Edition –Tata Mc Graw Hill Publication

2. Dennis
Roddy, John Coolen.‘Electronics Communications ‘IVth
Edition-

Pearson
Education

3. Louis
E. Frenzel ‘Principles of Electronic Communication System’-

IIIrd
edition - Tata McGraw Hill Publication

**Term Work:**

**List of Experiments (Minimum 10):**

1. Study
Of Amplitude Modulation (A.M.)

2. Study
Of AM Detection.

3. Study
Of AM Receiver Characteristics.( Sensitivity, Selectivity & Fidelity)

4. Study
Of Frequency Modulation.(F.M.)

5. Study
Of FM Demodulation.

6.
Sampling And Reconstruction.

7. Study
Of Pulse Amplitude Modulation (PAM.)

8. Study
Of Pulse Width Modulation.(PWM)

9. Study
Of Pulse Position Modulation.(PPM)

10. Study
Of PAM-TDM.

11. Study
Of Antenna Parameters.

12. Study
Of SSB Modulation & Demodulation.

13. Study
Of DSB Modulation & Demodulation.

14. Visit
To AIR (AM/FM).

**Note:**

1.Visit to
AIR station/telephone exchange is compulsory. Students are supposed to attach
report of visit to journal.

2. minimum
two experiment based on simulation software (comsim)

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester –IV*

*MICROPROCESSOR AND PERIPHERALS*

*Teaching Scheme: Examination Scheme:*

*Lectures: 3hr/week Theory : 100 Marks*

*Practicals: 2hrs/week Term Work : 25 marks*

*POE : 50 marks*

*Section-I*
UNIT-I:
Introduction & Overview: (6
Hrs)

Review of
number System: Binary, Decimal, Hex, Negative Number representation. Basic
Structure of Computer system. Introduction to general purpose CPU,
Architecture.

UNIT- II:
Semiconductor Memories (4 Hrs)

Memory
Capacity, Memory Organization, Speed, Memory Types-RAM, ROM, PROM, EPROM,
EEPROM, Memory Address Decoding. Battery Backup.

UNIT- III:
Interfacing Devices: (15 Hrs)

8205,
74138, 74373. Introduction to 8085, CPU Architecture, Register Organization,
8085 Instruction Set, Addressing modes. Stack & Subroutines, Instruction
Cycle, machine Cycle, Timing Diagrams (Graphical representation), Wait, Hold
& Halt States, and Interrupts of 8085( Hardware and software)

**Section-II**

UNIT- IV:
Interfacing I/Os: (5 Hrs)

Concept of
I/O ports, Memory mapped I/O and I/O mapped I/O schemes, I/O instructions, data
Transfer Techniques, interrupt Driven I/O

UNIT V:
Real World Interfacing: (5 Hrs)

Interfacing
of Memory, keyboard, seven segment display, Relay, stepper motor,

Conversion
techniques such as ADC Techniques: Dual Slope & Successive Approximation
and DAC Techniques: Weighted resistor & R-2R Ladder

UNIT VI:
Peripherals (15 Hrs)

a. Programmable
I/O- 8255

b. Timer-8155

c. Keyboard/Display
Controller-8279

d. ADC
-0809/7109

e. DAC-
0808

**Reference Books:**

1. Kenneth
L Short –‘Microprocessors and Programmed logic‘

2. Douglas
V Hall- ‘Microprocessors and Digital Systems”

3. Ramesh
S Gaonkar- ‘Microprocessors Architecture, Programming and applications with
8085A.

**Note to Paper setter:**

• Question
paper shall consist of approximately 80 % theory type questions( Hardware &

design
based problems) and approximately 20% Assembly language programs type

questions
( Algorithms/ Software’s).

**Term work: (minimum 12 experiment )**

• 50%
Assembly language programs based on Assembler & Simulator software’s.

• 25%
Assembly language programs based on Hardware ( kit system )

• 25%
Assembly language programs based on Interfacing ( kit + Interfacing cards )

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester –IV***DATA STRUCTURES**

**Teaching Scheme: Examination Scheme:**

**Lectures: 3hr/week Theory : 100 Marks**

**Tutorial: 1hr/week Term Work : 25 marks**

**Practical: 2hrs/week**

**Section-I**

UNIT-I:
Introduction & Overview: (1
Hrs)

Introduction
to theory of data structures & its data types,

Algorithms:
complexity, time space trade-off with example.

UNIT- II:
Arrays, Records & Pointers: (6 Hrs)

Introduction,
linear arrays, representation of linear array in memory, traversing linear
arrays, inserting & deleting,

Sorting:
bubble sort, searching: linear search, binary search,

Multidimensional
arrays, Pointers: pointer arrays, Records: Record structures, representation of
records in memory, parallel arrays, matrices, space matrices.

UNIT III:
Linked Lists: (6 Hrs)

Introduction,
linked lists & its representation, Traversing & searching a linked
list, memory allocation, Garbage collection, insertion & deletion of nodes
of linked list, header linked list, two-way lists, programming problems.

UNIT IV :
Stacks & Queues: (6 Hrs)

Introduction
to stacks, stack as an Abstract Data type , representation through Arrays &
linked lists , Applications of stacks , stacks & recursion, Queue as an
abstract data type representation, cicular, double ended, priority, application
of queues

**Section-II**

UNIT V:
Trees : (8 Hrs)

Binary
Tree: introduction, types, definition, properties, representations, operations,
binary tree traversal reconstruction, counting number of binary trees,
applications.

Advanced
trees : AVL trees or height balanced trees, representation operation, Threaded
binary trees, Expression trees. Multiway trees: trees , multiway search trees,
B+ trees, Heaps, construction of a Heap.

UNIT VI:
Graphs: (6 Hrs)

Introduction,
Graph theory terminology, sequential representation of graphs: Adjacency
Matrix, Path matrix, Warshall’s Algorithm, shortest paths, linked
representation. Operations, Traversing, Posets, Topological sorting

.

UNIT-VII:
Hashing: (3 Hrs)

Hashing,
Hash functions, collision, chaining

**Text Books:**

1. ISRD
group –‘Data structure using C ‘–- Tata McGraw Hill

2. Seymour
Lipschautz –‘Data structures’ - Shaum’s outlines -Tata McGraw Hill

Reference
Books:

4.
Langsam, Rubenstein, Tenenbaun –‘Data structure using C & C++ ‘ - PHI

5. Mark
Allen Weiss- ‘Data structure & algorithm analysis in C’- 2nd
edition –Pearson Education (LPE)

6. M.T.
Goodrich, R. Tamassia, D. Mount- Data Structures & Algorithms in C++- Wiley
Publication

7. A.N.
Kathie-“ Introduction to Data structures in C"- Pearson Education (LPE)

__Term Work: Tutorial (Minimum 12 tutorials based on following)__
Unit I 01
tutorial

Unit II 02
tutorials

Unit III
03 tutorials

Unit IV 03
tutorials

Unit V 02
tutorials

Unit VI 01
tutorial

Note:
Tutorial should consist only algorithms.

*Shivaji University, Kolhapur*

*.*

*Revised Syllabus w.e.f. Academic Year 2008-09*

*S.E. (Electronics and Telecommunication Engineering)*

*Semester- IV*
Electromagnetic
Fields

*Teaching Scheme: Examination Scheme*

*:*

*Lectures: 3 hr/week Theory : 100 Marks*

*Tutorial: 1 hr/week Term Work: 25 Marks*
Section-I

UNIT-I: Vector
Analysis :- Vector Algebra, Co-ordinate systems, line, Surface & Volume

Integral,
Curl, Divergence & Gradient, Electric Charge, Coulomb’s law, Charge
distribution, Electric Field Intensity, field due to distributed charges. (6)

UNIT-II: Electric
Flux & Potential: Flux density, Gauss’s law, Gauss’s law in point form,

Applications
of Gauss’s law, Divergence Theorem, Energy of a moving charge in Electric
Field, Potential & potential Difference , Potential field of a point
charge, potential Gradient, Dipole, Energy density in Electrostatic field. (8)

UNIT-III: Dielectrics&
Boundary conditions: Dielectrics, polarization, Boundary condition in perfect
dielectrics, Method of Images, Point charge near an Infinite Grounded
conducting plane, Laplace’s Equations. (6)

Section-II

UNIT-IV: Steady
magnetic fields: Current & current Density piot savart law, stoke’s

Theorem,
Ampere’s Law , Magnetic flux & flux density, vector magnetic potential,
Derivation of

steady
magnetic field laws, faraday’s law (6)

UNIT-V: Electromagnetic
waves: Maxwell’s Equations in point form & Integral form for

various
fields, Retarded potential, Wave equation in free space, wave propagation
through different

medium,
skin depth, poynting vector, Reflection of plane wave & standing wave
ratio. (6)

UNIT-VI: Transmission
Lines: Field Theory & circuit Theory, Transmission Line equations,

Line
parameters, Input impedance , The terminated uniform Transmission Line &
VSWR, smith chart

and
applications. (8)

**Text Books:**

1)
Engineering Electromagnetic _ W.H. Hyte

2)
Elements of Electromagnetic fields - Surinder P.Seth

(Dhanpat
Rai Publications)

**Reference Books:**

1)
Electromagnetic with applications - J.D. Kraus.

(MGHpbs)-4th
Edition.

2) Field
& Wave Electromagnetics - David K. Cheng

( pearon
Education)

2 Minimum
10 Tutorials based on above Topics

2 Note
for Paper setter: 50% Theory & 50% Problems are expected

**Shivaji University, Kolhapur**

**.**

**Revised Syllabus w.e.f. Academic year 2008-09**

**S.E. (Electronics and Telecommunication Engineering)**

**Semester –IV**

Circuit
Simulation

*Teaching Scheme: Examination Scheme:*

*Lectures:*

*1hr/week*

*Term Work: 25 Marks*

*Practical: 02hr/week*
UNIT-I:
Schematic Design: ( 4 Hrs )

Introduction,
Description of P-Spice, Types of analysis, Description of simulation software
tools (like

OrCAD /
Proteus)

Schematic
Description: Introduction, Input files, element values, Nodes, circuit
elements, sources,

output
variables, format of circuit and output files, drawing the schematic, Design
rule Check (DRC ),

Netlist
details.

UNIT-II:
Simulation: ( 4 Hrs )

Types of
Analysis: Bias point, Time domain, AC Sweep, DC Sweep, Parametric, Monte Carlo,
Noise

analysis.

UNIT-III:
PCB Design: ( 4 Hrs )

IC
packages, Types of Connectors, Netlist for layout, Types of PCB’s, Description
of layout design

tool,
foot- print creation, Setting board parameter ( board template, layer
strategies), Component

placement
considerations, Routing strategies, Design Rule check, back annotation, post
processing reports.

**Text book:**

1. M. H.
Rashid ‘Introduction to P-spice using OrCAD for circuits and Electronics’
–Pearson Education

**Reference Books:**

1 . User
manuals of PROTEUS, OrCAD, Multisim

2.. W.C.
Bosshart ‘Printed Circuit Boards-Design & Technology’–Tata McGraw-Hill
Publication.

**List of Experiments: (Minimum 8)**

Sr. No.
Title of the Experiment

1
Schematic drawing & component symbol creation

2
Hierarchical schematic drawing

3
Simulation and analysis (bias point analysis, time domain, AC sweep, DC

sweep,
parametric) of :RLC Circuit

4
Simulation and analysis (bias point analysis, time domain, AC sweep, DC

sweep,
parametric) of : Transistorized Circuit

5
Simulation and analysis (bias point analysis, time domain, AC sweep, DC

sweep,
parametric) of : Two Stage Amplifier

6
Simulation and analysis IC Based Circuits

7,8,9 Experiments
based on PCB design which would include component

placement,
setting design rules, auto routing and interactive routing.

10
Experiments based on noise analysis and Monte-carlo analysis

Note:
Experiments may be based on the software’s like OrCAD / PROTEL/ PROTEUS /
MULTISIM

etc.

Equivalence
of Subject S.E. Part-I & II under the

Faculty of
Engineering & Technology

w.e.f.
Academic Year 2008-09

Part-I
(Semester-III)

Sr. No.
S.E. Part-I Pre-revised S.E. Part-I Revised

1 Engineering.
Mathematics - III Engineering. Mathematics - III

2 Electrical
Machines and component Electrical Machines and measurements

3 Electronics
devices and circuits Analog Electronic circuits & Design - I

4 Circuits
and networks Linear circuits

5 Digital
techniques Digital Design

6 Transducers
and measurements Electrical Machines and measurements

Part-II
(Semester-IV)

Sr. No.
S.E. Part-II Pre-revised S.E. Part-II Revised

1 Discrete
circuit design Analog Electronic circuits & Design - II

2 Principal
of communication Electronics Communication systems

3 Linear
integrated circuits Microprocessor and peripherals

4 Control
systems Data Structures

5 Electromagnetic
Engineering. Electromagnetic Fields.

E:\eback\Syllabi
2008-09\Engineering\S.E Syllabus\E&TC\E&TC Structure.doc