Lesson PlanLesson Plan Duration: 15 Week (January, 2018 to April, 2018 Work Load (Lecture/Practical)...

Lesson Plan

Name of the Faculty: RINKI

Discipline: ECE

Semester: 4TH

Subject: Communication System

Lesson Plan Duration: 15 Week (January, 2018 to April, 2018

Work Load (Lecture/Practical) per week (in hours): Lectures-03, Practical-02

Week

Theory Practical

Lecture Day

Topic (including assignment /test )

Practical Day

Topic

1st week

1

(UNIT1) INTRODUCTION TO COMMUNICATION SYSTEM: Modulation, Demodulation, Radio

Frequency Spectrum

1

To study and waveform analysis of amplitude modulation and determine the modulation index of amplitude modulation.

2 Signals & their classification

3

Limitations & Advantages of a

Communication System , Comparison

of Analog & Digital Communication Systems

2nd week

4 Historical Perspective, Modes & Medias

of Communication

2 To study and waveform analysis of amplitude demodulation by any method.

5 (UNIT1) NOISE: Sources of Noise,

External & Internal Noise

6 Noise Calculations, Noise Figure, Noise

Figure Calculation, Noise Temperature

3rd week

7 Noise in Communication Systems,

Band Pass Noise Model, Cascaded States & its Noise Figure Calculation

3

To study and waveform analysis of frequency modulation and determine the modulation index of frequency modulation.

8 Signal in presence of Noise, Pre-

Emphasis & De-Emphasis

9 Noise Quieting Effect, Capture Effect, Noise in Modulation Systems.

Lesson Plan


Discipline: ECE

Semester: 4TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10

(UNIT2) LINEAR MODULATION: (AM) Basic definition & derivation for Modulation & Modulation Index

4 To study and waveform analysis of frequency demodulation by any

method. 11 Modulation & Demodulation of AM,

Suppressed Carrier Modulation

12 SSB-SC, DSB-SC,

5th week

13

VSB Modulation & Demodulation , Comparison of various AM Systems, Generation of AM waves.

5 To study Amplitude Shift Keying (ASK) modulation.

14

(UNIT2) ANGLE MODULATION: Basic definition & derivation for Modulation & Modulation Index

15 Generation of FM waves, Comparison

between PM & FM

6th week

16 Frequency Spectrum of FM, B.W. &

required spectra, Types of FM

6 To study Frequency Shift Keying (FSK) modulation.

17 vector representation of FM, Universal Curve

18 Multiple FM , Demodulation of FM

waves

Lesson Plan


Discipline: ECE

Semester: 4TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19

(Cont.) (UNIT 2) ANGLE MODULATION Demodulation of PM waves, Comparison between AM & FM.

7 To study Phase Shift Keying (PSK) modulation.

20

(UNIT3) TRANSMITTERS & RECEIVERS: Classification of Radio Transmitters, Basic Block Diagram of Radio Transmitter

21

Effect of Feedback on operation of Transmitter, Radio Telephone Transmitters, Privacy Device in Radio Telephony

8th week

22 FM Transmitter using Reactance Modulator, Armstrong FM Transmitter

8 To study and waveform analysis of phase modulation.

23 Radio Receivers, Classification, TRF

Receiver

24 Super Heterodyne Receiver, Image

Rejection & Double Spotting, Choice of IF

9th week

25 Tracking & Alignment of Receivers, AGC.

9 To study Phase demodulation.

26

(UNIT 3) PROBABILITY THEORY & RANDOM PROCESSES: Probability, Properties, Conditional Probability

27 Random Variables, CDF, PDF

Lesson Plan


Discipline: ECE

Semester: 4TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28

(Cont.) (UNIT 3) PROBABILITY THEORY & RANDOM PROCESSES: Uniform Distribution, Random or Stochastic Process

10 To study Pulse code modulation. 29 Ergodic Process

30 PSD, Properties of PSD,

11th week

31 Correlation Function

11 To study Pulse amplitude modulation and demodulation.

32 (UNIT4) PULSE ANALOG

MODULATION: Sampling theory,

33 TDM , FDM

12th week

34 Modulation and Demodulation of PAM

12 To study Pulse width modulation.

35 Modulation and Demodulation of PWM

36 Modulation and Demodulation of PPM

Lesson Plan


Discipline: ECE

Semester: 4TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 (UNIT4) PULSE DIGITAL

MODULATION: Elements of

Pulse Code Modulation

13 To study Pulse position modulation 38 Noise in PCM Systems

39 Bandwidth of PCM Systems, Measure

of Information

14th week

40 Channel Capacity,

14 41 Channel Capacity of PCM

System,

42 Differential Pulse Code

Modulation (DPCM)

15th

43 Delta Modulation (DM)

15 44 Revision

45 Revision

Lesson Plan

Name of the Faculty: Ms. RITIKA

Discipline: B.Tech_ECE

Semester: 4th

Subject: Digital Circuits and System



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1 Number System

1 Study & design basic gates. 2 Binary Codes

3 Boolean Algebra

2nd week

4 Sets

2 Study & minimize K-Map. 5 Relation

6 Lattice

3rd week

7 Minimization of Switching

Functions

3 Study & minimize K-Map

using Quine Mc cluskey

Method. 8 Five variable K-map

9 Six variable K-map

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 Quine Mcluskey

4 Study of Flip Flop conversion

from S-R to J-K. 11 VEM Methods of

Simplifications

12 Logical Design

5th week

13 Design with Basic logical

Gates


from J-K to T. 14 Logic Design with Integrated

Circuits

15 NAND Circuits

6th week

16 NOR Circuits


from D to T. 17 Design of High- Speed

Adders

18 Symmetric Functions

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19 Functional Decomposition

7 Design and implement a ckt

to detect a Count Sequence. 20 Symmetric Networks

21 Identification of Symmetric

Functions

8th week

22 Introduction to Threshold

logic

8 Design and implement a

Asynchronous sequential ckt. 23 Synthesis of Threshold

Networks

24 Sequential Circuits

9th week

25 Capabilities of Sequential

Machines

9 Design and implement

Synchronous counter with

count sequence. 26

Minimization of Sequential

Machines

27 Transformation of Sequential

Machines

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 The Finite State Model-Basic

Definitions

10 Design an Asynchronus

Counter for a Count

Sequence. 29 Memory Elements

30 Excitations Functions of

Memory Elements

11th week

31 The Finite State Model-

Further Definitions

11

Study the conversion of state

digram to the state table and

implement it using logical ckt.

32 Capabilities

33 Limitations of Finite State

Machines

12th week

34 State Equivalence


Melay Machine. 35 Machine Minimization

36 Simplification of

Incompletely Specified

Machines

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 Asynchronous Sequential

Circuits


Moorey Machine. 38 Fundamental- Mode Circuits

39 Synthesis

14th week

40 State Assignment in

Asynchronous Sequential

Circuits

14 41 Structures of Sequential

Circuits Introduction

42 State Assignments

15th week

43 State Assignments using

Partitions

15 44 The Lattice of Closed

Partitions

45 Reduction of the output

Dependency

Lesson Plan



Semester: 4th

Subject: Field and Wave


Work Load (Lecture/Practical) per week (in hours): Lectures-03

Week

Theory

Lecture Day


1st week

1 Coulomb’s Law of Electrostatic Force, Electric Field Intensity

2 Electric Potential, Electric Charge Density

3 Field Potential of A Finite Line Of Charge, Field Potential of an Infinite

Line Of Charge

2nd week

4 Electric Potential Difference, Electric Dipole, Electric Flux Density

5 Gauss Law, Application of Gauss Law

6 Laplace Equation, Solution of Laplace Equation in Rectangular And

Cartesian Coordinates

3rd week

7 Uniqueness Theorem of Electrostatic Field Solutions

8 Methods of Electrostatic Images, Electrostatic Energy, Capacitance

9 Introduction, Faraday Induction Law

Lesson Plan



Semester: 4th




Week

Theory

Lecture Day


4th week

10 Magnetic Effect on Current Carrying Conductor

11 Magnetic Flux

12 Magnetic Flux Density

5th week

13 Biot-Savart’s Law

14 Ampere’s Law of Force

15 Magnetic Field of A Solenoid

6th week

16 Magnetic Field In Vector Notations

17 Magnetic Field Intensity

18 Magnetic Flux Density in an Infinitely Long Cylinder Containing

Uniform Current Density

Lesson Plan



Semester: 4th




Week

Theory

Lecture Day


7th week

19 Magnetic Vector Potential

20 Energy Stored In A Magnetic Field

21 Energy Density In A Magnetic Field

8th week

22 Displacement Current Mawell’s Equations in Free space

23 Displacement Current Mawell’s Equations in Differential Form

24 Displacement Current Mawell’s Equations in Integra Form

9th week

25 Physical Interpretations Of Maxwell’s Field Equations

26 Boundary Conditions

27 Electromagnetic Wave In Homogeneous Medium

Lesson Plan



Semester: 4th




Week

Theory

Lecture Day


10th week

28 Wave Equation

29 Plane Wave And Uniform Plane Wave

30 Electromagnetic Wave Equations

11th week

31 Wave Propagation In Conducting Medium

32 Polarization

33 Introduction Of Transmission Lines

12th week

34 Principles Of Transmission Lines

35 Equivalent Circuit Representation

36 General Transmission Line Equation

Lesson Plan



Semester: 4th




Week

Theory

Lecture Day


13th week

37 Wave Characteristics on Finite Transmission Lines

38 Transients on Transmission lines

39 Primary Constant

14th week

40 Voltage And Current Calculations

41 Characteristic Impedance

42 Open And Short Circuit Lines

15th week

43 Reflection Coefficient

44 VSWR

45 Smith’s Chart And Its Applications

Lesson Plan

Name of the Faculty: Sonia Dahiya

Discipline: B.Tech , ECE

Semester: 4th

Subject: POWER ELECTRONICS (ECE208B)



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1 Characteristics of Power Diodes, Types of Power Diodes, Power Transistors

1

To study Steady-state characteristics of SCR by plotting graph between voltage and current of Thyristers

2

Power MOSFET, Insulated Gate Bipolar Transistors (IGBT), MOS Controlled Thyristors.

3 Terminal Characteristics of Thyristors, Thyristor Turn ON Methods

2nd week

4 Switching Characteristics of Thyristors, Characteristics, Two Transistor Model of a Thyristor,

2

To Study R and RC Triggering Circuit for SCR.

5 Protection, Heating Cooling and Mounting of Thyristors

6 Series and Parallel Operation of Thyristors, Programmable Unijunction Transistors(PUT)

3rd week

7 Silicon Unilateral Switch(SUS), Silicon Controlled Switch(SCS

3 To study UJT as Relaxation Oscillator

8 ,Light Activated Thyristors, Static Induction

9 Thyristors, Diac, Triac

Lesson Plan


Discipline: B.Tech , ECE

Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 Asymmetric Thyristors, Reverse Conducting Thyristors

4 To study SCR Half Wave and Full Wave Bridge Controlled Rectifier-Output characteristics

11 Firing Circuits for Thyristors, Pulse Transformer in Firing Circuits, Triac Firing Circuit

12 Doubt class of unit 1

5th week

13 Class A Commutation (Load), Class B Commutation (report )

5

To study 1-Phase Full Wave Bridge Controlled Rectifier using SCR and UJT with R and R-L Load and observe its input/output characteristics with and without freewheeling (commutating ) diode.

14 Class C Commutation , Class D Commutation (Impulse )

15 Class E Commutation (External Pulse Commutation),

6th week

16 Class F Commutation (Line Commutation)

6

To study three Phase Full-Wave

Uncontrolled Rectifier Operation

with R and R-L Load and Observe

its input/output Characteristics

17 Principle of Phase Control ,Full Wave Controlled Converters

18 Single Phase Full Wave Converter

Lesson Plan


Discipline: B.tech , ECE

Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19 Single Phase Two Pulse Converter with Discontinuous Load Current

7

To study single Phase Cycloconvener output characteristics.

20 Three Phase Converter Systems Using Diodes

21 Three Phase Thyristor Converter Circuits

8th week

22 Effect of Source Impedance on Performance of Converter

8 To study Series operation of SCR’s

23 Dual Converters.

24 Doubt class of unit 2

9th week

25 Principle of Chopper Operation, Control Strategies

9 To study Parallel operation of SCR’s.

26 Step Up Choppers, Types of Chopper Circuits

27 Steady State Time Domain Analysis of Type A Choppe

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 Thyristor Chopper Circuits,

Multiphase Choppers

10 To study Speed Control of DC

motor using SCR’s.

29

Single Phase Voltage Source

Inverter

30 Operating Principle ,Force

Commutated Thyristor Inverters

11th week

31 Three Phase Bride Inverter, Voltage

Control in Single Phase Inverter,

Pulse Width Modulated Inverter

11 To study Lamp-Dimmer Using Diac

& Triac With Lamp Load 32 Reduction of Harmonics in the

Inverter Output Voltage

33 Single Phase Parallel Inverter

Doubt class of unit 3

12th week

34 Types of AC Voltage Controller,

Integral Cycle Control

12 35 , Single Phase Voltage Controllers,

Sequence Control of AC Voltage

Controller.

36 Principle of Cycloconverter

Operation, Three Phase Half Wave

Cycloconverter,

Lesson Plan



Semester: 4th




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 Output Voltage Equation for Cycloconverter,

13 38 Load Commutated Cycloconverter.

39 Switched Mode Power Supply

14th week

40 Uninterruptible Power Supplies, High

14 41 Voltage DC Transmission, Static Switches

42 Static Circuit Breakers

15th

43 Solid State Relays. Doubt class from unit 4

15 44 Doubt class from entire syllabus

45 Doubt class from entire syllabus

Lesson Plan


Discipline: ECE

Semester: 6TH

Subject: Control System Engineering



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1

(UNIT1) INPUT / OUTPUT RELATIONSHIP: System / Plant model, illustrative examples of plants & their inputs and outputs, open loop & closed loop control system & their illustrative examples

1 To study A.C. servo motor and to plot its torque-speed characteristics. 2

Mathematical modeling and representation of physical systems

3 Concept of transfer function, relationship between transfer function and impulse response

2nd week

4 order of a system, block diagram algebra

2 To study D.C. servo motor and to plot its torque speed characteristics.

5 signal flow graphs: Mason’s gain formula & its application

6 (Cont.)signal flow graphs: Mason’s gain formula & its application

3rd week

7 (Cont.)signal flow graphs: Mason’s gain formula & its application

3

To study the magnetic amplifier and to plot its load current v/s control current characteristics for:

(a) series connected mode (b) parallel connected mode.

8 characteristic equation

9 derivation of transfer functions of electrical and electromechanical systems

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 (Cont.)derivation of transfer functions of electrical and electromechanical systems

4

To plot the load current v/s control current characteristics for self exited mode of the magnetic amplifier.



5th week

13 (UNIT2) TIME DOMAIN ANALYSIS:

Typical test signals

5 To study the lead, lag, lead-lag compensators and to draw their magnitude and phase plots.

14 time response of first order systems to various standard inputs

15 (Cont.) time response of first order systems to various standard inputs

6th week

16 time response of 2nd order system to step input

6

To study a stepper motor & to execute

microprocessor or computer-based

control of the same by changing number

of steps, direction of rotation & speed.

17 time domain specifications

18 steady state error and error constants

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19 concept of stability, pole-zero configuration and stability

7 To implement a PID controller for level control of a pilot plant.

20 necessary and sufficient conditions for stability

21 Hurwitz stability criterion

8th week

22 Routh stability criterion and relative stability

8 To implement a PID controller for temperature control of a pilot plant 23 Root locus concept

24 development of root loci for various systems

9th week

25 stability considerations

9

To study the synchro & to: (a). Use the synchro pair (synchro transmitter & control transformer) as an error detector. (b). Plot stator voltage v/s rotor angle for synchro transmitter i.e. to use the synchro transmitter as position transducer.

26

(UNIT3) FREQUENCY DOMAIN

ANALYSIS: Relationship between frequency response and time-response for 2nd order system

27 Nyquist

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 (Cont) Nyquist Plot

10 29 Bode plots

30 (Cont) Bode plots

11th week

31 stability

11 32 Gain-margin and Phase Margin

33 Relative stability, frequency response specifications.

12th week

34 (UNIT4) COMPENSATION: Necessity of compensation

12 35 compensation networks

36 application of lag and lead

compensation

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 Basic modes of feedback control

13

38 Proportional controllers.

39 Integral controllers.

14th week

40 Derivative controllers.

14 41 (UNIT4) CONTROL COMPONENTS: Synchros

42 servomotors

15th

43 stepper motors

15 44 magnetic amplifier

45 REVISION

Lesson Plan

Name of the Faculty:Mr.Pintu

Discipline:B.Tech-ECE

Semester: 6th

Subject: Microelectronics



Week

Theory

Lecture Day


1st week

1 CRYSTAL GROWTH AND WAFER PREPARATION: Clean room concept, safety requirements, crystal growth techniques: czochralski and gradient freeze techniques,

2 physics involved in CZ growth, Energy flow balance,

3 pull rate- considerations, problems and solutions

2nd week

4 defects involved in CZ method, effects due to carbon and oxygen impurities

5 modeling of dopant incorporation, float zone growth for high purity silicon,.

6 liquid encapsulated growth for GaAs, material characterization- wafer shaping, crystal characterization, wafer cleaning

3rd week

7 CURRENT ELEMENT CHARACTERISTICS: Growth mechanism and kinetic oxidation, thin oxides, ,

8 oxidation techniques and systems, oxide properties

9 characterization of oxide films

Lesson Plan



Semester: 6th




Week

Theory

Lecture Day


4th week

10 growth and properties of dry and wet oxidation

11 charge distribution during oxidation, oxide characterization,

12 Anomalies with thin oxide regime.

5th week

13 DIFFUSION:

The nature of diffusion, diffusion mechanisms – interstitial, substitution,

14 interstitial-substitution combined, interstitially and grain boundary,

15 Fick’s law of diffusion, limited and constant source diffusion

6th week

16 ,models of diffusion in solid, diffusion equation,

17 atomic diffusion mechanisms, diffusion system for silicon and

18 gallium arsenide. Measurement techniques, experimental analysis of diffused profiles

Lesson Plan



Semester: 6th




Week

Theory

Lecture Day


7th week

19 ION IMPLANTATION: Introduction, physics of implantation, range theory, projected range,

20 ion stopping mechanisms- channeling, nuclear stopping, electronic stopping,

21 implantation damage, implantation equipment,

8th week

22 annealing, shallow junction

23 Application to silicon and gallium arsenide, RTA mechanism.

24 Test

9th week

25 LITHOGRAPHY: Pattern generation and mask making, exposure sources, photolithography,

26 photo resists, optical lithography, electron lithography, X-ray lithography,

27 ion lithography, mask defects

Lesson Plan



Semester: 6th




Week

Theory

Lecture Day


10th week

28 atomic force microscopy based lithography system,

29 dip pen lithography system.

30 Assignment

11th week

31 DEPOSITION: Need for film deposition, film deposition methods- physical and chemical,

32 deposition processes, CVD techniques for deposition of polysilicon,

33 slicon dioxide, silicon nitride and metal films

12th week

34 sputter deposition, sputter unit

35 Epitaxy –types, techniques,

36 advantages, vapor phase epitaxy, molecular beam epitaxy.

Lesson Plan



Semester: 6th




Week

Theory

Lecture Day


13th week

37 ETCHING: Directionality and selectivity issues, wet chemical etching, wet etchants, dry physical etching,

38 dry etchants, plasma etching, advantages and disadvantages, issues involved,

39 dry etching systems, dry chemical etching, reactive ion etching,

14th week

40 Etching induced damage, cleaning. .

41 METALLIZATION: Introduction, metallization applications, ,

42 metallization choices,

15th

43 physical vapor deposition, patterning

44 metallization problems

45 Test

Lesson Plan



Semester: 6th

Subject: HDL Based System Design



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1 System: Definition,

Introduction to digital system

1 Design all Basic gates using

HDL 2

Design issues of digital

system

3 Computer-aided design tools

for designing of digital

systems

2nd week

4 Hardware description

languages

2 Design Universal gates using

HDL 5 Simulation and synthesis.

6 PLA, PAL, ROM

3rd week

7 CPLDs and FPGA

3

VHDL programs for half

adder and full adder circuits,

check the wave forms and the

hardware generated

8 Introduction to VHDL, entity

and architecture declaration

9 Data objects, classes and data

types

Lesson Plan



Semester: 6th




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 Operators, overloading,

logical operators

4

VHDL programs for

multiplexer & demultiplexer

circuits, check the wave forms

and the hardware generated

11 Types of delays

12 Behavioural, Dataflow and

structural models.

5th week

13 Assignment statements

5

VHDL programs for encoder

and decoder, check the wave

forms and the hardware

generated

14 Sequential statements and

process

15 conditional statements,

Generate statement, case

statement

6th week

16 Array and loops, resolution

functions

6

VHDL program for a

comparator and check the

wave forms and the hardware

generated

17 Concurrent Statements

18 Packages and libraries,

subprograms

Lesson Plan



Semester: 6th




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19 Application of functions and

procedures

7

VHDL program for a code

converter and check the wave


generated

20 Structural modeling

21 component declaration

8th week

22 Structural layout and

generics

8

VHDL program for a FLIP-

FLOP and check the wave


generated

23 configuration statement

24 Test Benches

9th week

25 ALIAS

9 VHDL program for a counter

and check the wave forms and

the hardware generated

26 Generate statement

27 VHDL models and

simulation of combinational

circuits such as multiplexers

Lesson Plan



Semester: 6th




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 Demultiplexers

10

VHDL programs for Register,

Shift register,check the wave


generated

29 Encoders

30 Decoders

11th week

31 Code converters

11 Implement any three (given

above) on FPGA kit 32 Comparators

33 Implementation of boolean

functions

12th week

34 VHDL models and

simulation of sequential

circuits flip flops

12

Implement any three (given

above) on CPLD kit.

35 Shift registers

36 Counters

Lesson Plan



Semester: 6th




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 Introduction to FSM

13 38 VHDL models and

simulation of FSM

39 Basic components of a

computer

14th week

40 Specifications

14 41 Architecture of a simple

computer system

42 Design of ALU

15th week

43 Memory unit

15 44 design implementation using

CPLDs

45 Design implementation using

FPGA

s

Lesson Plan


Discipline: B.tech ,ECE

Semester: 6th

Subject: ANTENNA AND WAVE PROPAGATION (ECE304B)



Week

Theory

Lecture Day


1st week

1 Introduction, Electromagnetic Wave Equations,

2 Poynting Theorem , Electromagnetic Power,

3 Short Electric Dipoles Retarded Vector Potential,

2nd week

4 Radiation from a Small Current Element

5 CURRENT ELEMENT CHARACTERISTICS:

6 Power Radiated by a Current Element and Its Radiation Resistance

3rd week

7 Radiation from a Half Wave Dipole

8 Radiation Patterns

9 , Radiation Power Density, Radiation Intensity

Lesson Plan

Name of the Faculty:

Discipline:

Semester:

Subject:



Week

Theory

Lecture Day


4th week

10 Doubt class from unit 1

11 Doubt class from unit 1

12 Antenna Pattern, Antenna Parameters

5th week

13 Front To Back Ratio, Gain,

14 Directivity, Radiation Resistance

15 Efficiency, Aperture Area, Impedence,

6th week

16 Effective Length and Beam width

17 Reciprocity Theorem for Antenna and Its Applications

18 Impedance Measurements,

Lesson Plan


Discipline:

Semester:

Subject:



Week

Theory

Lecture Day


7th week

19 Radiation Pattern Measurement, Beam width Measurement

20 Phase And Current, Radiation Resistance

21 , Directivity And Polarisation Measurement

8th week

22 Doubt class of 2unit

23 Introduction,Isotropic,Yagi-Uda,Biconical

24 ,Helical,Horn,Slot,Parabolic Feeds, Conical,

9th week

25 Log Periodic, Microwave and Patch Antenna.

26 Types of Antenna Array

27 Broadside Array, End Fire Array, Collinear Array

Lesson Plan


Discipline:

Semester:

Subject:



Week

Theory

Lecture Day


10th week

28 Parasitic Array, array of point sources, pattern multiplication

29 Linear Array, Phased Array

30 Tapering of Arrays, Binomials Arrays,

11th week

31

32

33

12th week

34

35

36

Lesson Plan


Discipline:

Semester:

Subject:



Week

Theory

Lecture Day


13th week

37

38

39

14th week

40

41

42

15th

43

44

45

Lesson Plan

Name of the Faculty:Mukesh Kumari

Discipline:B.Tech -ECE

Semester: 6TH

Subject: MWRE



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1 Characteristic features- advantages and applications

1 To study of Wave guide Components 2 Waveguides- Basic concepts and properties

3 Comparison of Waveguide with transmission lines

2nd week

4 Propagation in TE & TM mode,

2 Generation of Microwave Power & Basic set-up.

5

Rectangular waveguide, TEM mode in rectangular waveguide

6 Introduction to circular waveguides and planar transmission lines.

3rd week

7 Test

3 To Study the characteristic of reflex

klystron 8 Directional Couplers, Tees, Hybrid Ring, Attenuators

9 Cavity resonators, Mixers & detectors, ,

Lesson Plan



Semester: 6TH

Subject: MWRE



Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 Matched load, Phase shifter,

4

To measure frequency of Microwave

source and demonstrate relationship

among frequency, free space

wavelength and guide wave length.

11 Isolators, Circulators.

12 Limitations of conventional tubes, Construction, operation

5th week

13 properties and applications of Klystron amplifier, Reflex Klystron

5 To measure VSWR of an unknown load.

14 , Reflex Klystron

15

6th week

16 Magnetron, TWT, BWO

6 To measure large standing wave ratio of

a unmatched load 17 Crossed field amplifiers

18 Assignment

Lesson Plan



Semester: 6TH

Subject: MWRE



Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19 Principle of operation and applications

of Varactor diode

7 To match impedance for maximum power transfer using slide screw tuner 20

Tunnel diode, Schottky diode, GUNN diode

21 TRAPATT and PIN diodes.

8th week

22 MASER, Parametric amplifiers.

8 To measure VSWR, insertion loss and attenuation of a fixed and variable attenuator

23 Test

24 Measurement of Frequency

9th week

25 Power, VSWR

9 To measure coupling factor and directivity of Directional coupler.

26

Wavelength & Impedance.

27 . Introduction, RADAR principles, development, frequencies

Lesson Plan



Semester: 6TH

Subject: MWRE



Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 block diagram and operation and

applications

10 To determine the insertion loss, isolation

of three port circulator 29 Test

30 Simple form of RADAR equation

11th week

31 Prediction of Range Performance

11 To determine the insertion loss, isolation of a isolator.

32 Minimum detectable signal

33 Pulse repletion frequency & range ambiguities

12th week

34 system losses, propagation effects.

12 To study the characteristics of Gunn Diode.

35 Assignment

36 . Block Diagram and operation of

CW

Lesson Plan



Semester: 6TH

Subject: MWRE



Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 MTI & Pulsed Doppler RADAR

13 38 Frequency Modulated RADAR

39 The Doppler effect

14th week

40 blind speed, Applications.

14 41 Test

42 Test

15th

43 Test

15 44 Test

45 Test

Lesson Plan


Discipline: ECE

Semester: 6TH

Subject: MICROCONTROLLER BASED SYSTEM DESIGN



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1

(UNIT1) INTRODUCTION OF EMBEDDED SYSTEMS: Definition, ingredients of embedded system

1 Study Architecture of 8051 Microcontroller & Power on reset circuit. 2

requirements & challenges of embedded system design

3 different types of microcontrollers: Embedded microcontrollers, external memory microcontrollers etc.

2nd week

4 processor architectures: Harvard V/S Princeton

2

(a) Write an assembly language program to add eight 8-bit numbers. (b)Write an assembly language program to find average of eight 8-bit numbers.

5 CISC V/S RISC

6 microcontrollers memory types

3rd week

7 microcontrollers features: clocking, i/o pins

3

(a) Write an assembly language program to find a maximum number from a given 8-bit ten numbers. (b) Write an assembly language program to find a minimum number from a given 8-bit ten numbers.

8 microcontrollers features: interrupts, timers, and peripherals.

9 (Cont.)microcontrollers features: interrupts, timers, and peripherals.

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10

(UNIT1) SOFTWARE FOR EMBEDDED SYSTEM DESIGN: Development tools/ environments,

Assembly language programming style

4 Arrange the given ten 8-bit numbers in ascending order.

11 Interpreters, High level languages

12 Intel hex format object files, Debugging.

5th week

13 (UNIT2) 8051 MICROCONTROLLER: Pin diagram explanation

5 Generate a square wave of 10kHz at P1.0 Crystal frequency is XXXX.

14 internal diagram 8051

15 Instruction Set

6th week

16 Addressing mode

6 Write a program to transfer data from given memory block B1 to block B2.

17 data transfer instruction, logical

18 arithmetic instruction, bit instruction, branching instruction.

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19

(UNIT2) TIMERS, SERIAL INTERFACE & INTERRUPTS OF 8051 MICROCONTROLLER: Timer: Control Word

7 Interface LED and switch with microcontroller 8051 or PIC.

20 mode of timers.

21 simple programming, generation of square wave

8th week

22 Serial interface: Introduction, Control Word

8 Interface seven segment display with microcontroller 8051 or PIC.

23 mode of serial interface, simple programming

24 Interrupts: Introduction, Control word Simple Programming

9th week

25 generation of waveforms using interrupt

9 Interface LCD with microcontroller 8051 or PIC

26 serial interface using interrupt

27

(UNIT3) PIC MICROCONTROLLER: Introduction to PIC microcontrollers.

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 features of PIC family microcontrollers

10 Interface DC motor with microcontroller 8051 or PIC and control speed using PWM.

29 architecture and pipelining

30 program memory considerations, addressing modes

11th week

31 CPU registers

11 32 Instruction set, and simple operations

33 (UNIT3) FEATURES OF PIC

MICROCONTROLLER: Timer: Control

Word,

12th week

34 mode of timers,

12 35

simple programming, generation of square

wave,

36 Watch-dog timer, Serial interface:

Introduction, Control Word, mode of serial

interface, simple programming,

Lesson Plan


Discipline: ECE

Semester: 6TH




Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37 Interrupts: Introduction, Control word

Simple Programming

13

38 generation of waveforms using

interrupt, serial interface using interrupt.

39

(UNIT4) APPLICATIONS BASED ON 8051 MICROCONTROLLER: Interfacing of memory

14th week

40 intelligent LCD, 8255

14 41 ADC, DAC, LED display

42 Memory Card, Bio-metric system

15th

43

(UNIT4) APPLICATION BASED ON

PIC MICROCONTROLLERS:

Interfacing of Graphical Display,

Memory Card

15 44

Bio-metric system Music box,

Applications like Mouse wheel turning,

PWM motor control, ultra sonic distance

measuring

45 Temperature Sensor, Pressure

Sensor, Magnetic Field Sensor

Lesson Plan


Discipline: ECE

Semester: 8TH

Subject: EMBEDDED SYSTEM DESIGN



Week

Theory

Lecture Day


1st week

1 (UNIT1 ) INTRODUCTION OF EMBEDDED SYSTEMS DESIGN: Embedded Systems Design: Definition, Issues

2 Challenges and Trends, Current events and emerging technologies

3 (UNIT1 ) AVR MICROCONTROLLER: Introduction to AVR microcontroller, features of AVR family microcontrollers

2nd week

4 different types of AVR microcontroller

5 architecture

6 memory access and instruction execution

3rd week

7 pipelining, program memory considerations

8 addressing modes, CPU registers

9 Instruction set, and simple operations

Lesson Plan


Discipline: ECE

Semester: 8TH




Week

Theory

Lecture Day


4th week

10 (UNIT2 ) FEATURES OF AVR MICROCONTROLLER: Timer: Control Word, mode of timers

11 simple programming, generation of square wave

12 Interrupts: Introduction, Control word Simple Programming

5th week

13 generation of waveforms using interrupt

14 serial interface using interrupt

15 (UNIT2 ) SPECIAL FEATURES OF AVR MICROCONTROLLER: Watch-dog timer

6th week

16 Power-down modes of AVR microcontroller

17 UART

18 SRAM

Lesson Plan


Discipline: ECE

Semester: 8TH




Week

Theory

Lecture Day


7th week

19 (UNIT3 ) APPLICATIONS BASED ON AVR MICROCONTROLLER: Applications based on RF Card

20 Graphical LCD, Color LCD, Zigbee

21 DTMF, GSM

8th week

22 GPS, Smart Card

23 RF ID, Touch Screen, Bluetooth

24 (UNIT3 ) COMMUNICATION INTERFACE WITH AVR MICROCONTROLLER: RS-232, RS-485,

9th week

25 SPI, IIC

26 ISA

27 CAN

Lesson Plan


Discipline: ECE

Semester: 8TH




Week

Theory

Lecture Day


10th week

28 (UNIT4 ) SOFTWARE REQUIREMENTS FOR EMBEDDED SYSTEMS DESIGN: Assemblers, Compilers,

29 Linkers, Loaders

30 Debuggers

11th week

31 Profilers

32 Test Coverage Tools Utilities like make, ranlib, obj copy and obj dump,

33 Test Coverage Tools Utilities like make, ranlib, obj copy and obj dump,

12th week

34 Configuring GNU Cross-Tool chain Building RTOS / EOS Image for Target Hardware.

35 Building GNU Cross-Tool chain Building RTOS / EOS Image for Target Hardware.

36 Building GNU Cross-Tool chain Building EOS Image for Target Hardware.

Lesson Plan


Discipline: ECE

Semester: 8TH




Week

Theory

Lecture Day


13th week

37 (UNIT4 ) OPERATING SYSTEM FOR EMBEDDED SYSTEM: Embedded Operating Systems

38 Real Time Operating System (RTOS)

39 Writing Time and Space Sensitive Programs

14th week

40 ,Writing Device Drivers

41 Interrupt Handling in C

42 Combining C with Assembly

15th

43 Revision

44 Revision

45 Revision

Lesson Plan

Name of the Faculty:Mukesh kumari


Semester:8th

Subject:Wireless communication system



Week

Theory

Lecture Day


1st week

1 Evolution of Mobile Radio Communications : Introduction, First Generation (1G), Second Generation (2G), Generation (2.5G)

2 Second Generation (2G), Generation (2.5G) ,Third Generation (3G),

3 Evolution from 2G To 3G, Fourth Generation (4G), Examples of Wireless Communication Systems

2nd week

4 Difference Between Fixed Telephone Network and Wireless Telephone Network

5 Wireless Local Loop [WLL], Wireless Local Area Networks (WLAN) , Personal Area Network(PAN), Bluetooth.

6 Test

3rd week

7 Introduction, Frequency Reuse, Channel Assignment Strategies

8 , Hand-Off Strategies, Interference and System Capacity

9 Trunking and Grade of Service, Improving Coverage and Capacity in Cellular Systems.

Lesson Plan



Semester:8th




Week

Theory

Lecture Day


4th week

10 Introduction to Radio Wave Propagation

11 Free Space Propagation Model

12 Assignment

5th week

13 Practical Link Budget Design Using Path Loss Models, Outdoor Propagation Models,

14 Indoor Propagation Models, Signal Penetration into Buildings

15 Small Scale Multipath Propagation, Impulse Response Model of a Multipath Channel

6th week

16 Small Scale Multipath Measurements,

17 Parameters of Mobile Multipath Channels

18 Types of Small Scale Fading, Rayleigh and Ricean Distributions.

Lesson Plan



Semester:8th




Week

Theory

Lecture Day


7th week

19 Fundamentals of Equalization, Equalizer in a Communication Receiver

20 Linear Equalizer, Non Linear Equalization

21 Diversity Techniques, Rake Receiver, Interleaving

8th week

22 Test

23 Introduction, Frequency Division Multiple Access (FDMA).

24 Time Division Multiple Access (TDMA )

9th week

25 Spread Spectrum Multiple Access

26 Space Division Multiple Access (SDMA), Capacity of Cellular System.

27 Introduction to Wireless Networks, Development of Wireless Networks

Lesson Plan



Semester:8th




Week

Theory

Lecture Day


10th week

28 Traffic Routing in Wireless Networks

29 Wireless Data Services, Common Channel Signaling

30 Assignment

11th week

31 Integrated Services Digital Network (ISDN), Signalling System No.7(SS 7),

32 Personal Communication Services/Networks.(PCS/PCN)

33 Test

12th week

34 Test

35 Test

36 Test

Lesson Plan



Semester:8th




Week

Theory

Lecture Day Topic (including

assignment /test )

13th week

37 Global System for Mobile (GSM)

38 Cdma Digital Cellular Standard(IS-95),

39 GPRS,EDGE,W-Cdma,Cdma2000

14th week

40 Test

41 Test

42 Test

15th

43 Test

44 Test

45 Test

Lesson Plan

Name of the Faculty: Mr.Pintu

Discipline:B.Tech –ECE

Semester: 8th

Subject: DCN



Week

Theory Practical

Lecture Day


Practical Day

Topic

1st week

1

Data Communication and Networks: Components,DataRepresentation,DataFlow,

Guided and Unguided

1 To study different types of transmission media

2 Media

3 DistributedProcessing,NetworkCriteria

2nd week

4 PhysicalStructure,NetworkModels,

2 To study Quadrature Phase Shift Keying Modulation

5 Category of Networks

6 Data and Signals: Analog and Digital Data,Analog and

Digital Signals

3rd week

7 ,Periodic and Non Periodic Signals,Transmission

3 To study Quadrature Amplitude Modulation

8 Impairments- Attenuation,Distortion,Noise,Performancebandwidth,

9

Throughput,Latency,Bandwidth-Delay Product,Jitter

Lesson Plan



Semester: 8th

Subject: DCN



Week

Theory Practical

Lecture Day


Practical Day

Topic

4th week

10 Latency,Bandwidth-Delay Product,Jitter

4 To Study 16 Quadrature Amplitude Multiplexing 11 Bandwidth-Delay Product,Jitter

12 Test

5th week

13 Digital Transmission: Digital to digital Conversion-Line Coding,

5

To Study Serial Interface RS-232 and its applications. .

14 Line Coding

Schemes,BlockCoding

15 Scrambling,

6th week

16 Transmission modes-

6 To study the Parallel Interface Centronics and its applications

17 Parallel Transmission

18 Serial Transmission

Lesson Plan



Semester: 8th

Subject: DCN



Week

Theory Practical

Lecture Day


Practical Day

Topic

7th week

19

Multiplexing Frequency Division

Multiplexing,

7

To configure the modem of a

computer.

20 Assignment

21 Wavelength division Multiplexing,

8th week

22 Synchronous Time division multiplexing,

8

To make inter-connections in

cables for data communication in LAN.

23 Statistical Time Division multiplexing

24 Test

9th week

25

Switching: Circuit Switched Networks-

Three Phases,EfficiencyDelay,

9 To install LAN using Tree

topology. 26

Datagram Networks-Routing table,

27 Efficiencydelay,

Lesson Plan



Semester: 8th

Subject: DCN



Week

Theory Practical

Lecture Day


Practical Day

Topic

10th week

28 Virtual Circuit Networks-Addressing ,

10

To install LAN using STAR topology.

29 Three Phases,Efficiency,,

30 Delay in Virtual Circuit Networks

11th week

31

Data Link Control Framing-Fixed Size Framing,Variable Sized framing,

11

To install LAN using Bus topology.

32 Error Control-Flow Control,,

33 Flow and errorcontrol,Protocols

12th week

34 ;Noiseless Channels-Simplest

protocol,stop and Wait Protocol,Noisy Channels-,

12 To install LAN using Token-Ring topology

35

Stop and Wait Automatic Repeat Request,Go Back n

Automatic Repeat request,

36 Selective Repeat Automatic Repeat request,PiggyBacking

Lesson Plan


Discipline: M.Tech –ECE

Semester: 2nd

Subject: Advance Optical Communication



Week

Theory Practical

Lecture Day


Practical Day

Topic

13th week

37

Network Models: Layered Tasks -Sender,receiver and Carier,The OSI Model-Layered,

13

To install WIN NT

. 38

Architecture,Peer to peer processes,Encapsulation,

39 Layers in the OSI Model-Physical Layer,data Link layer,Networklayer,transportlayer

14th week

40 Sessionlayer,Presentationlayer,applicationlayer,Summary of layers,

14

To cofigure a HUB/Switch.

41 Introduction to TCP-IP and Internetworking

42 Wired Lans-Ethernet: IEEE Standards-Data Link Layer,Physicallayer,

15th

43 Standard Ethernet -Mac Sublayer,

44 Physicallayer,Changes in the standard bridged Ethernet,

45 SwitchedEthernet,full duplex Ethernet,fast

Ethernet-Mac sublayer,Physical layer

Lesson Plan


Discipline:B.Tech- ECE

Semester: 8th

Subject: RADAR & SONAR



Week

Theory

Lecture Day


1st week

1 Radar Block Diagram & operation

2 Radar Frequencies

3 Radar development

2nd week

4 Application of Radar

5 Test

6 Simple form of Radar Equation, Prediction of Range performance.

3rd week

7 Minimum detectable signal, Receiver noise

8 Signal to Noise ratio, Transmitter Power

9 Pulse repetition frequency & range ambiguities, System losses

Lesson Plan



Semester: 8th




Week

Theory

Lecture Day


4th week

10 Propagation effects.

11 Test

12 The Doppler effect, CW Radar

5th week

13 Frequency-modulated CW Radar,

14 Multiple Frequency CW Radar

15 Assignment

6th week

16 Introduction, Delay Line Cancellors, Multiple or staggered

17 Pulse repetition frequencies, range-Gated Doppler Filters

18 Digital Signal Processing, Other MTI delay line, Limitation of MTI performance

Lesson Plan



Semester: 8th




Week

Theory

Lecture Day


7th week

19 Noncoherent MTI, Pulse Doppler Radar

20 MTI from a moving platform.

21 Test

8th week

22 Tracking with Radar

23 Sequential Lobbing, Conical Scan

24 Monopulse Tracking Radar

9th week

25 Tracking in range, Acquisition

26 Assignment

27 Radar Receivers, Noise Figure

Lesson Plan



Semester: 8th




Week

Theory

Lecture Day


10th week

28 Low-noise Front ends

29 Displays, Duplexer

30 Receiver protectors

11th week

31 History of sonar,underwaterpropagation

32 sound velocity profile

33 propagationmode,multipaths

12th week

34 Types of sonar system:activ

35 generic active and passive.

36 Test

Lesson Plan



Semester: 8th




Week

Theory

Lecture Day


13th week

37 Basic Types of noise in sonar system

38 Detection of acoustic energy using sonar:detectioncriterion,.

39 Test

14th week

40 sonar system performance,figure of merit;Sonar transducers.

41 Test

42 Test

15th

43 Test

44 Test

45 Test

Lesson PlanLesson Plan Duration: 15 Week (January, 2018 to April, 2018 Work Load (Lecture/Practical)...

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Transcript of Lesson PlanLesson Plan Duration: 15 Week (January, 2018 to April, 2018 Work Load (Lecture/Practical)...