LAN · 7 Numericals based on range equation ... 20 Bridge rectifier 21 Clipping and clamping...

Lesson Plan

Discipline ECE

Semester 6th

Subject Computer Networks

Lesson Plan Duration 15 weeks(jan,2018 to april,2018)

**Work

Load(Lecture/Practical)

Per Week(in hours) 3 hours /week(lecture) & 2 hours/week for practical

Lecture Day Topic(including assignment/ test) Practical Day Topic

1 Introduction to computer networks

2 Various Network topologies

3 Bus,Star,Ring topology

4 Hybrid,Tree

5 Introduction to types of networks:

6 LAN(Local area Network)

7 Assignment-1: computer networks basics

8 MAN(Metropolitan area network)WAN(Wide Area Network)

9 Layering architecture of networks

10 OSI Model

11 Functions & services of each layer

12 Protocols of each layer

13 Intro. Of TCP/IP

14 History of TCP/IP

15 Layers of TCP/IP

16 Assignment-2: OSI Model

17 Internet protocols:Transmission control protocol

18 User datagram protocol

19 IP Addressing

20 IP address classes

21 Subnet addressing

22 Internet control protocols:ARP

23 RARP,ICMP

24 Application layer

25 DNS

26 Assignment-3: TCP/IP model

27 Intro. To LAN,Features & components of LAN

28 IEEE 802 standards

29 Various channel access methods

30 ALOHA

10th 10th To implement distance vector routing protocol.

8th 8th How to use remote desktop connection for

connecting to a window device.

9th 9th Study of Dijkestra algorithm.

6th 6th Study of various network topologies used in

LAN

7th 7th To share data between two computers

4th 4th Connect the computers in LAN

5th 5th Study of basic network commands

2nd 2nd To implement cross wired cable & straight

through cable using clamping tool.

3rd 3rd Study of network IP : subnetting & supernetting

Week Theory Practical

1st 1st Study of different types of network cables.

31 CSMA/CD

32 Ethernet

33 Token Ring

34 LAN interconnecting devices:Hubs,switches

35 Routers & Gateways

36 Intro. To WAN:Routing

37 Assignment 4 :Congestion control technologies

38 DQDB

39 SDH,SONET

40 Asynchronous transfer mode

41 Intro. To network management

42 Remote monitoring techniques

43 Firewalls

44 Network operating systems:Client-Server architecture

45 Windows NT/2000

14th 14th Study of various networking devices:

Router,Bridge,gateway

15th 15th Study of basic network configuration commands

12th 12th To study performance of Token ring protocol

through simulation & Kit

13th 13th Study of various networking devices:

Repeater,Hub,Switch

11th 11th To study performance of ethernet LAN protocol

through simulation & kit

Lesson Plan

Discipline ECE

Semester 6th

Subject Microprocessor & interfacing


**Work


Per Week(in hours) 3 hours /week(lecture) & 2 hours/week for practical

Lecture Day Topic(including assignment/ test) Practical Day Topic

1 Introduction to microprocessor

2 8085 microprocessor organisation

3 8085-block diagram with complete details

4 Instruction set of 8085 microprocessor :started

5 Data transfer instructions

6 Arithmatic instructions

7 Assignment-1:8085 architecture

8 Logical instructions

9 Branch instructions

10 Writing ALP for 8085 up



13 Interrupt structure

14 8086 microprecessor block diagram:

15 Assignment-2 : 8086 architecture

16 PSW,Queue,Pointer & index registers

17 Memory segmentation

18 physical address calculation

19 Program relocation

20 Addressing modes

21 Instruction formats

22 8086 pin diagram

23 Description of various signals

24 Instruction set of 8086 microprocessor

25 Assignment-3 : 8086 pin diagram

26 Data transfer instructions

27 Arithmatic instructions

28 Branch instructions

29 NOP & HLT instructions

30 Flag manipulation instructions

31 Logical instructions

32 Shift & rotate instructions

33 String instructions

34 Assembler directives

35 Operators

36 Assignment-4 : 8086 programming

12th 12th Write a Program using 8086 for arranging array

in ascending order

10th 10th Write a Program using 8086 for finding square

root of a number

11th 11th Write a Program using 8086 for copying 12

bytes of data from source to destination

8th 8th Write a Program using 8085 for division of two

8-bit numbers by repeated subtraction method

9th 9th To study 8086 kit used in practicals

6th 6th Write a Program using 8085 for multiplication

of two 8-bit numbers by bit rotation method

7th 7th Write a Program using 8085 for multiplication

of two 8-bit numbers by repeated addition

method

4th 4th Write a Program using 8085 for subtraction of

two 8-bit numbers

5th 5th Write a Program using 8085 for subtraction of

two 16-bit numbers

2nd 2nd Write a Program using 8085 for addition of two

8-bit numbers(including with carry)

3rd 3rd Write a Program using 8085 for addition of two

16-bit numbers


1st 1st To study 8085 kit used in practicals





41 8255 detail:Block Diagram

42 8255 Control words,modes,examples

43 8237 DMA controller

44 Intel 8259 Block diagram

45 Programmable interval timer chips

14th 14th Write a Program using 8086 for division of

double word by another word

15th 15th Write a program to control operation of stepper

motor using microprocessor & PPI.

13th 13th Write a Program using 8086 for arranging array

in descending order

Lesson Plan

Discipline ECE

Semester 8th

Subject RADAR & SONAR ENGG.


**Work


Per Week(in hours) 4 hours /week(lecture)

Lecture Day Topic(including assignment/ test)

1 Introduction to RADAR

2 Radar block diagram & operation

3 RADAR frequencies

4 RADAR development

5 Applications of radar

6 RADAR range equation

7 Numericals based on range equation

8 Numericals based on range equation9 Assignment-1: Radar Basics & range equation10 Prediction of range performance

11 Minimum detectable signal

12 Receiver Noise

13 S/N ratio14 Transmitter power 15 prf & range ambiguities 16 Numericals based on above topics

17 Numericals based on above topics18 Assignment-2: Receiver noise & concept of S/N ratio19 System losses

20 propagation effect

21 Doppler effect22 CW radar23 Concept of FM CW radar24 Block diagram of FMCW radar25 Multiple frequency CW radar 26 Introduction to MTI & pulse doppler RADAR27 Assignment-3 : CW & FMCW RADAR28 Delay line cancellers 29 Double cancellation concept30 multiple/Staggered prf31 Pulse repetition frequencies32 Range gated doppler filter33 Assignment-4: MTI RADAR34 Non Coherent MTI 35 pulse doppler radar36 Block diagram of pulse doppler RADAR37 MTI from moving plateform 38 Tracking with radar39 sequential Lobbing40 Conical scan41 Monopulse tracking RADAR42 Tracking in range 43 Acquisition 44 Radar receivers45 Noise figure46 Mixer 47 Various types of mixers48 low noise front end49 Display50 Various types of displays51 Duplexer52 Types of duplexers53 Receiver protector54 Introduction to SONAR55 Basic Principle of SONAR

56 Types of SONAR57 Active & Passive SONAR

58 Applications of SONAR59 Explanation of particular application

60 Remaining topic(if any)

14th

15th

12th

13th

10th

11th

8th

9th

6th

7th

4th

5th

2nd

3rd

Week Theory

1st

Lesson Plan

Discipline B.Tech.(Applied Science department)

Semester 2nd

Subject Basics of Electronics Engg.

Lesson Plan Duration 15 Weeks ( from January 2018, April 2018)

**Work


Per Week(in hours) Lecture-03


1 Introduction of Subject ,

2 Energy band in solids.

3 semiconductor materials4 classification of Semiconductor materials

5 Energy distribution of electrons,Mass action law

6 Effect of temp. on semiconductors

7 Assignment 1 -semiconductors

8 Charge densities

9 Total current density,conductivity

10 Pn junction diode & application--Pn junction theory

11 V-I characterstics &equation

12 Resistance levels,Piecewise linear characteristics

13 Transition & diffusion capacitance14 Reverse recovery time

15 Varactor diode,

16 Assignment 2 -zener diode

17 LED,Photodiode

18 Load line analysis of a diode circuit

19 Rectifier circuits(half wave and full wave rectifier)

20 Bridge rectifier

21 Clipping and clamping circuits

22 Voltage multiplier

23 Zener voltage regulator

24 BJT:I/P and o/p charc of NPN transistor

25 Active region operation of transistor,

26 Transistor as an amplifier,BJT Amplifier configuration

27 CB,CE,CC Amplifiers

28 BJT Biasing:Fixed bias,Emitter feedback bias,

29 Collector feedback bias,voltage divider bias

30 Assignment 3 -FETS

31 Types of FETS

32 Construction,governing equations of FETS.

33 Charac. Of JFET

34 MOSFET characterictics

35 Test and revision

36 Revision of important Question

37 Amplifier configuration using FET

38 Comparison of BJT,JFET & MOSFET

39 Introduction to thermistor,optocoupler.




43 Assignment 4 -optocoupler.



15th

10th

11th

12th

13th

14th

9th

Week Theory

1st

2nd

3rd

4th

5th

6th

7th

8th

Lesson Plan

Discipline B.Tech.(Electrical & Electronics Engineering)

Semester 8th

Subject Television Engg. (TV)


**Work




1 Introduction of TV ,

2 Picture transmission, sound transmission

3 picture reception ,sound reception,

4 synchronization, receiver controls

5 Analysis and Synthesis of Television Pictures

6 Assignment 1 -Composite Video signal,

7 channel B.W. TV standards

8 Vestigial side band transmission

9 Vestigial side band reception

10 Revision of 1st

unit

11 Monochrome picture tube, Test

12 Beam deflection, screen phosphor, faces plat.

13 picture tube characteristics

14 picture tube circuit controls

15 Television Camera Tubes: Basic principal orthicon

16 Vidicon, plumbicon

17 Block diagram of Monochrome Signal Receiver


19 Transmitting and receiving antennas

20 Revision of 2nd

unit,

21 composite color signal

22 comparison of NTSC, PAL and SECAM Systems

23 Assignment 2 Color television display tubes :-Delta gun

24 CT display tube:- PIL, Trinitron Test

25 Color signal transmission

26 Interleaving process

27 compatibility considerations

28 Three color theory,

29 Assignment 3 -Chrominance Signal ,

30 BW for color signal transmission

31 Camcorders.

32 Cable television, CCTV

33 picture phone & facsimile,Test

34 Television via satellite

35 Remote Control ( Electronic control system )

36 bandwidth for color signal transmission

37 Digital TV,


39 Projector TV

40 3D-TV,

41 Digital TV

42 Technology and their merits

43 Assignment 4 -HDTV,



14th

15th

12th

13th

10th

11th

8th

9th

6th

7th

4th

5th

2nd

3rd

Week Theory

1st

Lesson Plan

Discipline B.Tech.(Electronics & Communication Engineering)

Semester 6th

Subject Television Engg. (TV)


**Work




1 Introduction of TV ,

2 Picture transmission, sound transmission

3 picture reception ,sound reception,

4 synchronization, receiver controls

5 Analysis and Synthesis of Television Pictures

6 Assignment 1 -Composite Video signal,

7 channel B.W. TV standards

8 Vestigial side band transmission

9 Vestigial side band reception10 Revision of 1

st unit

11 Monochrome picture tube, Test

12 Beam deflection, screen phosphor, faces plat.

13 picture tube characteristics 14 picture tube circuit controls

15 Television Camera Tubes: Basic principal orthicon

16 Vidicon, plumbicon



19 Transmitting and receiving antennas

20 Revision of 2nd

unit,

21 composite color signal

22 comparison of NTSC, PAL and SECAM Systems

23 Assignment 2 Color television display tubes :-Delta gun

24 CT display tube:- PIL, Trinitron Test

25 Color signal transmission

26 Interleaving process

27 compatibility considerations28 Three color theory,

29 Assignment 3 -Chrominance Signal ,

30 BW for color signal transmission

31 Camcorders.

32 Cable television, CCTV

33 picture phone & facsimile,Test

34 Television via satellite

35 Remote Control ( Electronic control system )


37 Digital TV,


39 Projector TV

40 3D-TV,

41 Digital TV

42 Technology and their merits

43 Assignment 4 -HDTV,



14th

15th

12th

13th

10th

11th

8th

9th

6th

7th

4th

5th

2nd

3rd

Week Theory

1st

Lesson Plan


Semester 8th

Subject SIMULATION LAB


**Work



Practical Day Topic

14th File checking and complete the experiment

15th Internal VIVA voice.

12th To develop a program for Cramer’s Rule

13th To develop a program for Tower of Hanoi.

10th Draw a straight-line use graphics.

11th Find Eigen value for given Matrix.

8th Check stability by Jury Test.

9th Draw a circle for given radius use graphics.

6th Find Inverse of Matrix.

7th Check stability by Routh Hurwitz Criteria.

4th Add two Matrix.

5th Multiplication of two Matrix

2nd To Study The different Commands of MATLAB.

3rd To develop a Program for Matrix n*n.

Practical

1st Inroduction of MATLAB


Semester 8th

Subject Laser Technology (PHY-452-E)


**Work




1 Conditions for Producing Laser



4 Concept of coherence

5 Special coherence

6 temporal coherence

7 Population Inversions

8 Population Inversions

9 Einstein coefficient

10 Gain

11

Gain saturation

Assignment 1- Concept of Laser

12 Saturation intensity

13 Development and Growth of a Laser Beam

14 Development and Growth of a Laser Beam

15 Exponential Growth factor

16 Threshold Requirement for a Laser

17

Threshold Requirement for a Laser

Assignment 2- Threshold

18 Inversions and two-level systems

19 steady-state inversions

20 three -level systems

21 four-level systems

22 Transient Population Inversions

23 Factors effecting population inversion



26 Laser Amplifiers

27

Laser Amplifiers

Assignment 3- Inversions

28 Excitation or Pumping Threshold Requirements

29 Pumping Pathways

30 Pumping Pathways

31 Specific Excitation Parameters

32 Parameters Associated with Optical Pumping

33 Parameters Associated with Optical Pumping

34 Parameters Associated with Partical Pumping

35 Parameters Associated with Partical Pumping

36 Gas lasers

37 Helium-Neon Laser

38 Helium-Neon Laser

39 Co2 Laser

40 Co2 Laser

41 Ruby Laser

42 Ruby Laser

43 Semiconductor Diode Laser

44

Semiconductor Diode Laser

Assignment 4- Types of Laser

45 Numerical Problems

15th

4th

5th

6th

7th

8th

9th

10th

11th

12th

13th

14th

3rd

Lesson Plan

Week Theory

1st

2nd


Semester 6th

Subject Linear & IC Application (EEE-306-E)


**Work

Load(Lecture/Practic

al) Per Week(in

hours) Lecture-03, Practical- 02

Lecture Day Topic(including assignment/ test) Practical Day Topic1 Balanced and unbalanced output differential amplifier

2 FET differential amplifier

3 current mirrors4 level translators

5 cascade or CB-CE configuration of amplifier

6 operational amplifier7 block diagram representation of op-amp

8 introduction to idea op-amp, characteristics

9

parameters, interpretation of data sheets,

data specification of op-amp

10 main parameter like CMMR, thermal drift11 data specification of op-amp & , offset voltage12 current practical op-amp and its equivalent circuit

13 op-amp circuit configurations

14

Frequency response compensating network

Assignment 1- Amplifiers

15

frequency response of internally compensated

and non-compensated op-amp16 High frequency op-amp equivalent circuit

17 open loop and closed loop frequency response

18 circuit stability19 slew rate

20 Block diagram representation of feedback amplifier

21 voltage series feedback22 voltages shunt feedback

23

differential amplifier

Assignment 2- Feedback

24 DC and AC amplifier, peaking amplifier25 peaking amplifier, summing

26 scaling, averaging and instrumentation amplifier

27

differential input and output amplifier

voltage to current converter

28

current to voltage converter, very high input impedance

circuit,

29 integrator, diffentitor, voltage limiters,

30 voltage regulator, voltage to frequency converter

31

frequency to voltage converter

Introduction to active filters

32 Butter worth and Chebyshev approximation to low pass filter

33

high pass, band pass filters

Assignment 3- Filters

34 Oscillators, criterion for oscillation

35 phase shift, wein bridge

36 quadrature, square wave, saw tooth

37 voltage controlled oscillator

38 Introduction to basic comparator, zero crossing detector

39

Schmitt trigger

comparator characteristics

40 analog to digital & digital to analog converters

41 analog to digital & digital to analog converters

42

sample & hold circuit, peak detector

Assignment 4- Converters

43 Universal active filters, switched capacitor filter

44 the 555 & 556 timers and their applications

45 Phase locked loop and voltage regulators

14th 14th To construct the astable multivibrator

using IC 555

15th 15th To study the phase shift wein bridge

oscillator

12th 12th To study the notch filter

13th 13th To study the operation of the Schmitt

trigger using the IC 741

10th 10th To demonstrate the operation of

high pass active filter

11th 11th To study the frequency response of

band pass filter

8th 8th To demonstrate the operation of low

pass filter

9th 9th Design the second order low pass

filter

6th 6th To study the OPAMP as integrator

7th 7th To study the OPAMP as summer

4th 4th To study FET amplifier

5th 5th To study the OPAMP as

differentiator

2nd 2nd To study the OPAMP as non-

inverting amplifier

3rd 3rd To study CE configuration of

amplifier with negative feedback

Lesson Plan


1st 1st To study the OPAMP as inverting

amplifier


Semester 6th

Subject MOS IC's & Technology (EE-306-E)

Lesson Plan Duration 15 Weeks ( from January 2018, April 2018)**Work

Load(Lecture/Practic

al) Per Week(in

hours) Lecture-03

Lecture Day Topic(including assignment/ test)1 Introduction to IC technology

2

MOS Transistor enhancement mode

depletion mode operations

3 NMOS Fabrication Process sequence

4 CMOS Fabrication Process Sequence

5

Equivalent circuit for MOSFET

Equivalent circuit for CMOS.

6

MOS transistor

Evaluation aspects of MOS transistor

7 MOS device design equations

8

MOS transistor transconductance

output conductance

9 figure of merit

10

determination of pull-up to pull-down ratio for an n-MOS

inverter driven by another n-MOS inverter

11 by one or more pass transistor

12 alternative forms of pull-up

13 CMOS -inverters

14 CMOS -inverters

15 BiCMOS-inverters

16 Latch up in CMOS circuitry

17

BiCMOS Latch up susceptibility

Assignment 1- Mos Transistor

18 Basic physical design of NOT logic gates using n-MOS

19 Basic physical design of OR logic gates using n-MOS

20 Basic physical design of AND logic gates using n-MOS

21 Basic physical design of NOT logic gates using C-MOS

22 Basic physical design of OR logic gates using C-MOS

23 Basic physical design of AND logic gates using C-MOS

24 CMOS logic gate design considerations

25 CMOS logic structures

26 CMOS logic structures

27 clocking strategies

28

clocking strategies

Assignment 2- Gates Design

29 Resistance estimation

30 capacitance estimation

31 inductance estimation

32 switching characteristics

33 CMOS gate transistor sizing

34 power dissipation

35 Crystal growth, wafer preparation, epitaxy

36 oxidation, lithography, etching

37 diffusion

38 dielectric and poly-silicon film deposition

39 ion implantation

40

yield and reliability,metalization

Assignment 3- VLSI Fabrication

41 Incrementer / decrementer, left/right serial/parallel register

42 comparator for two n-bit number

43

a two-phase non-overlapping clock generator with

buffered output on both phases

44 design of an event driven element for EDL system

45

Two phase non-overlapping clock generator

Assignment 4- Design Examples

15th

4th

5th

6th

7th

8th

9th

10th

11th

12th

13th

14th

3rd

Lesson Plan

Week Theory

1st

2nd

Month Class UNIT Topic/Chapter Covered Academic Activity Test/Assisgnment

Radar Block diagram and operation

Radar frequencies

Radar Development

Application of Radar

Radar Range Equation

Detection of signal in noise

Radar Cross-section of targets

Cross-section Fluctuations, Transmitter power

PRF and Range ambiguities

System losses, Propagation Effects

Pulse Doppler Radar

CW Radar

FMCW Radar

MFCW Radar

Delay line cancellers

Pulse Repetition Frequency

Range Gate Doppler

Other MTI delay line, Limitation of MTI

performance

Noncoherent MTI, Pulse Doppler Radar

MTI from a moving platform.

Tracking with Radar

Sequential Lobbing

Conical Scan, Monopulse Tracking Radar,

Tracking in range, Acquisition

Radar Receivers

Noise Figure, Mixer

Low-noise Front ends

Displays, Duplexer

Receiver protectors

VII INTRODUCTION TO SONAR ●Quiz of U it -VII ●Assisg e t-

Department Electronics and Communication Engineering

Lesson Planning For the semester started wef JAN/FEB 2018

Name of institute OITM, Hisar

Name ofTeacher with Designation Mr. Deepak Sharma, Assistant Professor

Semester 8

Subject with Subject Code RADAR AND SONAR ENGINEERING EE-454-E

II

●Quiz of U it-II ● Nu e ical Sessio of Rada Ra ge Equation

●Assisg e t- , ●Test of u it-II

March

III

●Quiz of U it-III, ● Nu e ical Sessio of Rada ●P ese tatio o "Pulse Dopple Radar"

●Assisg e t- , ●Test of u it-III

IV

●Quiz of U it -IV ●Nu e ical Sessio ●P ese tatio o "MTI, Pulse Dopple Radar"

●Assisg e t- , ●Test of u it-IV

FEB

B.TECH Electronics

and

Communication

Engineering 8th

SEMESTER

I●Quiz of U it-I, ● P ese tatio o Rada Develop e t

●Assisg e t- , ●Test of u it-I

Signature Of Concerned Teacher

April

V

●Quiz of U it -V ●P ese tatio o "T acki g i a ge, Acquisition",

●Assisg e t- , ●Test of u it-V

VI

●Quiz of U it -VI ●Nu e ical Sessio ●P ese tatio o "Rada Receive s"

●Assisg e t- , ●Test of u it-VI


Evolution of Mobile Radio Communications :

Introduction,

First Generation (1G), Second Generation (2G), Genera

Paging, Cordless telephone system

Comparison of various wireless system

Second Generation (2G), Generation (2.5G) ,Third G

Evolution from 2G To 3G,

Fourth Generation (4G), Examples of Wireless Comm

Wireless Local Loop [WLL]

Wireless Local Area Networks (WLAN)

Personal Area Network(PAN)

Bluetooth

Spectrum Allocation

Cellular System Performance Criteria

Operation of Cellular system

Analog Cellular System

Digital Cellular System

Frequency Reuse

Channel Assignment Strategies

Hand-Off Strategies

Interference and System Capacity

Trunking and Grade of Service

Improving Coverage and Capacity in Cellular

Systems

Introduction, Frequency Division Multiple Access

(FDMA)

Time Division Multiple Access (TDMA )

Spread Spectrum Multiple Access

Space Division Multiple Access (SDMA), Capacity

of Cellular System

Difference Between Fixed Telephone Network

and Wireless Telephone Network

Development of Wireless Telephone Network

Fixed Telephone Network Trans Mission

Hierarchy

Traffic Routing in Wireless Networks

Wireless Data Services, Common Channel

Signaling

Integrated Services Digital Network (ISDN)

Intelligent cell concept

Application of Intelligent cell Micro-cell system

In-Building Communication

CDMA cellular Radio Network




Name ofTeacher with Designation Mr. Deepak Sharma, Assistant Professor

Semester 8

Subject with Subject Code Wireless Communication EE-402E

II ●Quiz of U it-II ● P ese tatio o G & G

●Assisg e t- , ●Test of u it-II

March

III

●Quiz of U it-III, ● Nu e ical Sessio of Pe fo a ce Criteria

●P ese tatio o "Cellula syste "

●Assisg e t- , ●Test of u it-III

IV

●Quiz of U it -IV ●Nu e ical Sessio ●P ese tatio o "F e ue cy Reuse"

●Assisg e t- , ●Test of u it-

FEB

B.TECH Electronics

and

Communication

Engineering 8th

SEMESTER

I ●Quiz of U it-I, ●Assisg e t- , ●Test of u it-I


V ●Quiz of U it -V ●P ese tatio o "TDMA & FDMA",

●Assisg e t- , ●Test of u it-V

April

VI

●Quiz of U it -VI ●Nu e ical Sessio ●P ese tatio o "CCS", ●P ese tatio o "ISDN".


VII ●Quiz of U it -VII ●Assisg e t- , ●Test of u it-VII


PRINCIPLES OF SATELLITE

COMMUNICATION: Evolution & growth of

communication satellite

Synchronous satellite, Satellite frequency allocation

& Band spectrum

Advantages of satellite communication, Active &

Passive satellite, Modem & Codec

Applications of satellite communication

COMMUNICATION SATELLITE LINK

DESIGN: Introduction, General link design

equations

System noise temperature, C/N & G/T ratio

Atmospheric & Ionospheric effects on link design

Complete link design

Earth station parametersANALOG SATELLITE COMMUNICATION:

Introduction, Baseband analog(Voice) signal

FDM techniques, S/N & C/N ratio in frequency

modulation in satellite link

S/N ratio in FM with multiplexed telephone signal

in satellite link, Analog FM/FDM TV satellite link

Single channel per carrier(SCPC) systems

Companded single sideband (CSSB) systems

Intermodulation products & their effects in

FM/FDM systems, Energy disposal in FM/FDM

DIGITAL SATELLITE COMMUNICATION:

Advantages of digital communication

Elements of digital satellite communication

systems, Digital baseband signals

Digital modulation techniques,Time Division

Multiplexing.

Satellite digital link design,

MULTIPLE ACCESS TECHNIQUES:

Introduction

TDMA, TDMA-Frame structure, TDMA-Burst

structure, TDMA-Frame efficiency, TDMA-

superframe, TDMA-Frame acquisition &

Synchronization

TDMA compared to FDMA, TDMA Burst Time

Plan, Multiple Beam ( Satellite switched) TDMA

satellite system,

Beam Hopping(Transponder Hopping) TDMA,

CDMA & hybrid access techniques.

SATELLITE ORBITS: Introduction,

Synchronous orbit

Orbital parameters, Satellite location with respect to

earth, Look angles

Earth coverage & slant range, Eclipse effect,

Satellite placement in geostationary orbit,

station keeping, Satellite stabilization.

SPECIAL PURPOSE COMMUNICATION

SATELLITES: BDS, INMARSAT, INTELSAT,

VSAT

MSAT, Sarsat, LEOs

Satellite communication with respect to Fiber

Optic Communication, LANDSAT, Defense

satellite.

LASER SATELLITE COMMUNICATION:

Introduction, Link analysis

Optical satellite link transmitter, Optical satellite

link receiver,

Satellite Beam Acquisition, Tracking & Positioning,

Deep Space Optical Communication Link

Department Electronics & communication Engineering



Name ofTeacher with Designation Mrs.Seema wadhwa, Assistant Professor

Semester 8

Subject with Subject Code SATELLITE COMMUNICATION ENGG (EE-404-E)

II

● Quiz of U it -II &III ● P ese tatio o the topic "C/N

& G/T ratio"

●Assisg e t- , ●Test of u it-II &III

III

March

●Quiz of U it - IV & V ● P ese tatio o the topic "Digital

modulation techniques"

●Assisg e t- , ●Test of u it-IV & V

IV

V

● Quiz of U it - VI ● P ese tatio o the topic "station keeping, Satellite

stabilization."

FEB

B.TECH

ELECTRICAL

ENGINEERING

SIX SEMESTER

I ● Quiz of U it -I ● P ese tatio o the topic "Active & Passive satellite, Modem &

Codec"

●Assisgnment-1,

●Test of u it-I



April

VI

VII

Presentation on the topic "TDMA

compared to FDMA"

●Assisg e t- , ●Test of u it- VII & VIII

VIII


Conditions for Producing Laser

Concept of coherence – Special and temporalEinstein coefficient, Threshold Requirement for a Laser

Gain and Gain saturation,Development and Growth of

a Laser Beam,

Inversions and two-level systems

steady-state inversions and three and four-level systems

Transient Population Inversions

Factors effecting population inversion

Laser Amplifiers

Exponential Growth factor

Excitation or Pumping Threshold Requirements

Pumping Pathways

Specific Excitation

Parameters Associated with Optical and particle Pumping.

Helium-Neon Laser

Co2 Laser

Ruby Laser

Semiconductor Diode Laser




Name ofTeacher with Designation Ms. Nisha, Assistant Professor

Semester 8

Subject with Subject Code LASER TECHNOLOGY (PHY-452)

II ●Quiz of Unit-II ● Presentation on Laser Amplifier

●Assisgnment-2, ●Test of unit-II

March III

●Quiz of Unit-III, ● Numerical Session of Performance Criteria

●Presentation on "Specific Excitation"

●Assisgnment-3, ●Test of unit-III

FEB

B.TECH Electronics

and

Communication

Engineering 8th

SEMESTER

I ●Quiz of Unit-I, ●Assisgnment-1, ●Test of unit-I

Aprial IV

●Quiz of Unit -IV ●Numerical Session ●Presentation on "Ruby laser"

●Assisgnment-4, ●Test of unit-4


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LAN · 7 Numericals based on range equation ... 20 Bridge rectifier 21 Clipping and clamping...

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