Lesson Plan Name of Faculty : Suresh Kumar Discipline : Electronics & Comm. Engg. Semester : 3rd Subject : ELECTRONIC INSTRUMENTS AND MEASUREMENT Lesson Plan Duration : 16 weeks

Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week Theory Practical Lecture Day

Topic (Including Assignment/ Test) Practical

Day Topic

1st

1 Measurement, method of measurement, types of instruments

1st

Measurement of voltage, resistance, frequency using digital multimeter

2 Specifications of instruments Accuracy, precision

3 Specifications of instruments sensitivity, resolution, range, errors in measurement

2nd

4 sources of errors, limiting errors,

2nd

Measurement of voltage, resistance, frequency using digital multimeter

5 loading effect, importance and applications of standards and calibration

6 Assignment / test

3rd

7 Principles of measurement of DC voltage

3rd

Measurement of voltage, frequency, time period and phase using CRO

8 Principles of measurement of DC current

9 Principles of measurement of AC voltage

4th

10 Principles of measurement of AC current

4th

Measurement of voltage, frequency, time period and phase using CRO

11 Principles of operation and construction of permanent magnet moving coil (PMMC) instruments

12 Moving iron type instruments

5th

13 Assignment

5th Practical file Checking and viva-voice

14 Revision / test

15 Construction and working of Cathode Ray Tube(CRT)

6th 16

Block diagram description of a basic CRO and triggered sweep oscilloscope

6th

Measurement of voltage, frequency, time and phase using DSO

17 Front panel controls 18 Specifications of CRO and their explanation

7th

19 Measurement of current, voltage, frequency

7th

Measurement of voltage, frequency, time and phase using DSO

20 Measurement of current time period and phase using CRO

21 Digital storage oscilloscope (DSO) block diagram and working principle

8th 22 Assignment / Problem Taking

8th Measurement of Q of a coil

23 Class test 24 Wheat stone bridge

9th 25 AC bridges: Maxwell’s induction bridge

9th Measurement of Q of a coil

26 Hay’s bridge, De-Sauty’s bridge, 27 Schering bridge and Anderson bridge

10th 28 Bock diagram description of laboratory type RLC bridge, specifications of RLC bridge

10th

29 Block diagram and working principle of Q meter

Practical file Checking and viva-voice 30 Assignment

11th

31 Problem Taking

11th

Measurement of resistance and inductance of coil using RLC Bridge

32 Class test

33 Explanation of block diagram specifications of low frequency, RF generators

12th

34 pulse generator, function generator

12th

Measurement of impedance using Maxwell Induction Bridge

35 Distortion factor meter

36 Instrumentation amplifier: its characteristics, need and working

13th

37 Instrumentation amplifier need and working

13th

To find the value of unknown resistance using Wheat Stone Bridge

38 Assignment

39 Comparison of analog and digital instruments

14th

40 Working principle of ramp, dual slope

14th

Measurement of distortion using Distortion Factor Meter

41 Working principle of integration type digital voltmeter

42 Block diagram and working of a digital multi-meter

15th

43 Specifications of digital multi-meter and their applications

15th Use of logic pulser and logic pobe

44 Limitations of digital multi-meters

45 Working principle of logic probe, logic pulser analyzer

16th 46

Working principle of logic analyzer and signature analyzer

16th Revision 47 Revision 48 Revision

Lesson Plan Name of Faculty : Arshad Jamal Discipline : Electronics & Comm. Eng. Semester : 3rd Subject : PRINCIPLES OF COMMUNICATION ENGINEERING Lesson Plan Duration : 16 weeks

Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

week 1st

Lecture Day

Topic (Including Assignment/ Test Practical

Day Topic

1 Introduction of Subject and Need for modulation

1st General idea’s for lab Equipment’s

2 frequency translation and demodulation in communication systems

3 Basic scheme of a modern communication system

2nd

4 Derivation of expression for an amplitude modulated wave Carrier and side band components

2nd

To observe an AM wave on CRO produced by a standard signal generator using internal and external modulation

To measure the modulation index of the wave obtained in above practical

5 Modulation index. Spectrum and BW of AM Wave. Relative power distribution in carrier and side bands

6 Elementary idea of DSB-SC modulations and its application

3rd

7 Elementary idea of SSB-SC modulations and its application

3rd

To observe an AM wave on CRO produced by a standard signal generator using internal and external modulation

To measure the modulation index of the wave obtained in above practical

8 Elementary idea of ISB and VSB modulations and its application

9 Comparison of DSB- SC ,SSB- SC, ISB, and VSB modulation

4th

10 Expression for frequency modulated wave and its frequency spectrum (without Proof and analysis of Bassel function)

4th

To obtain an AM wave from a square law modulator circuit and observe waveforms b) To measure the modulation index of the obtained wave form

11 Modulation index, maximum frequency deviation and deviation ratio, BW of FM signals, Carson’s rule

12 Effect of noise on FM carrier. Noise triangle

5th 13 Role of limiter, Need for pre-emphasis and de-emphasis, capture effect.

5th To obtain an AM wave from a square law

14 Comparison of FM and AM in communication systems

modulator circuit and observe waveforms To measure the modulation index of the obtained wave form

15 Assignment / Revision

6th

16 Test

6th

To obtain an FM wave and measure the frequency deviation for different modulating signals.

17 Derivation of expression for phase modulated wave modulation index

18 Derivation of expression for phase modulated wave modulation index

7th

19 Comparison with frequency modulation.

7th

To obtain an FM wave and measure the frequency deviation for different modulating signals.

20 Assignment /Quiz

21 Circuit Diagram and working operation of Collector Modulator

8th

22 Circuit Diagram and working operation of Base Modulator

8th To obtain modulating signal from FM detector

23 Circuit Diagram and working operation of Square Low Modulator

24 Circuit Diagram and working operation of Balanced Modulator

9th

25 Revision

9th Revision 26

Working principles and applications of reactance modulator

27 Working principles and applications of varactor diode modulator

10th

28 Working principles and applications of VCO modulator

10th

To observe the sampled signal and compare it with the analog input signal. Note the effect of varying the sampling pulse width and frequency on the sampled output

29 Working principles and applications of Armstrong phase modulator

30 Stabilization of carrier using AFC (Block diagram approach)

11th

31 Assignment / Test

11th

To observe and note the pulse amplitude modulated signal (PAM) and compare them with the corresponding analog input signal

32 Principles of demodulation of AM wave using diode detector circuit

33 concept of Clipping

12th 34 formula for RC time constant for minimum distortion (no derivation)

12th Revision

35 Assignment 36 Expert Lecture

13th

37 Basic principles of FM detection using slope detector

13th

To observe PPM and PWM ignal and compre it with the analo input signal

38 Principle of working of the Foster-Seeley discriminator FM demodulator (No Derivation)

39 Principle of working of the Ratio detector FM demodulator (No Derivation)

14th

40 Block diagram of Phase locked Loop (PLL) FM demodulator (No Derivation)

14th Revision 41 Revision / Assignment

42 Statement of sampling theorem and elementary idea of sampling frequency for pulse modulation

15th 43

Basic concepts of time division multiplexing (TDM)

15th Revision/ viva 44 frequency division multiplexing (FDM) 45 Pulse Amplitude Modulation (PAM)

16th 46 Pulse Position Modulation (PPM)

16th Revision/ viva 47 Pulse Width Modulation (PWM) 48 Revision

Lesson Plan Name of Faculty : Smt. Bharti Verma Discipline : ECE Semester : 3rd Subject : Digital Electronics Lesson Plan Duration : 16 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week

Theory Practical Lecture

Day Topic (Including Assignment/ Test

Practical Day

Topic

1st

1 Introduction

1st

Verification and interpretation of truth

tables for AND, OR, NOT NAND, NOR and Exclusive OR (EXOR)

and Exclusive NOR (EXNOR) gates

2 Distinction between analog and digital signal.

3 Applications and advantages of digital signals

2nd

4 Assignment

2nd

Verification and interpretation of truth

tables for AND, OR, NOT NAND, NOR and Exclusive OR (EXOR)

and Exclusive NOR (EXNOR) gates

5 Binary

6 octal and hexadecimal number system

3rd

7 conversion from decimal and hexadecimal to binary and vice-versa

3rd Realisation of logic

functions with the help of NAND or NOR gates

8

Binary addition and subtraction including binary points. 1’s and 2’s complement method of addition/subtraction.

9 Assignment

4th

10 Concept of code, weighted and non-weighted codes

4th

To design a half adder using XOR and NAND gates and verification

of its operation

11 examples of 8421, BCD, excess-3 and Gray code

12 Concept of parity, single and double parity and error detection

5th

13 Assignment

5th

Construction of a full adder circuit using

XOR and NAND gates and verify

its operation

14 Concept of negative and positive logic

15 Definition, symbols and truth tables of NOT, AND, OR, NAND, NOR, EXOR Gates

6th 16 NAND and NOR as universal gates

6th Revision of

Experiments 17 Introduction to TTL and CMOS logic families 18 Assignment

7th 19 Logic Simplification

7th Revision of

Experiments 20 Postulates of Boolean algebra, De Morgan’s Theorems

21 Implementation of Boolean (logic) equation with gates

8th

22 Assignment

8th

Verification of truth table for positive edge

triggered, negative edge triggered, level triggered IC flip-flops

(At least one IC each of D latch, D flip-flop, JK

flip-flops).

23 Half adder and Full adder circuit

24 design and implementation

9th

25 Decoders, Multiplexers, Multiplexers and Encoder

9th

Verification of truth table for positive edge

triggered, negative edge triggered, level

triggered IC flip-flops (At least one IC each of D latch, D flip-flop, JK

flip-flops).

26 Four bit decoder circuits for 7 segment display and decoder/driver ICs

27 Basic functions and block diagram of MUX and DEMUX with different ICs

10th

28 Basic functions and block diagram of Encoder

10th Revision of

Experiments 29 Assignment

30 Concept and types of latch with their working and applications

11th

31 Operation using waveforms and truth tables of RS, T, D, Master/Slave JK flip flops

11th

Verification of truth table for encoder and decoder ICs, Mux and

DeMux

32 Difference between a latch and a flip flop

33 Introduction to Asynchronous and Synchronous counters

12th

34 Binary counters

12th

To design a 4 bit SISO, SIPO, PISO, PIPO shift registers using JK/D

flip flops and verification of their

operation

35 Divide by N ripple counters

36 Decade counter

13th

37 Ring counter

13th Revision of

Experiments 38 Assignment

39 Introduction and basic concepts including shift left and shift right

14th

40 serial in serial out, parallel in serial out parallel in parallel out parallel in parallel out Universal shift register

14th To design a 4 bit ring counter and verify its

operation. 41 Working principle of A/D and D/A converters

42 Stair step Ramp A/D converter, Dual Slope A/D converter

15th

43 Successive Approximation A/D Converter

15th Use of Asynchronous Counter ICs (7490 or

7493)

44 Binary Weighted D/A converter

45 R/2R ladder D/A converter, Applications of A/D and D/A converter

16th 46 Memory organization, classification of semiconductor memories (RAM, ROM, PROM, EPROM, and EEPROM)

16th Revision of

Experiments

47 static and dynamic RAM 48 introduction to 74181 ALU IC

LESSON PLAN

Name of Faculty : Rajesh Kumar Gautam Discipline : Electronics & Communication Engg. Semester : 3rd Subject : Electronic Devices & Circuits Lesson Plan Duration : 16 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week

Theory Practical Lecture Day

Topic (Including Assignment/ Test Practical

Day Topic

1st

1 Review of Amplifiers

1 Review of Lab/ Practicals.

2 Need for multistage amplifier & Gain of multistage amplifier

3 RC coupled multistage amplifier, its frequency response and bandwidth

2nd

4 Transformer coupled Multistage Amplifier, its frequency response and bandwidth.

2

Plot the frequency response of two stage RC coupled amplifier and calculate the bandwidth and compare it with single stage amplifier.

5 Direct coupled multistage amplifier, its frequency response and bandwidth.

6 Difference between voltage and power amplifiers, Importance of impedance matching in amplifiers.

3rd

7 Class A & Class B amplifiers,

3 To measure the gain

of push-pull amplifier at 1 KHz.

8 Class AB and Class C amplifiers, collector Efficiency & Distortion in Class A, B, C amplifiers.

9

Single ended Power amplifiers, Graphical method of calculation (without derivation) of output power, heat dissipation curve and importance of heat sinks.

4th 10 Push Pull Amplifier

4 Revision / File

Assessment 11 Complementary Symmetry Push-Pull amplifier. 12 Assignment topic/Test/Quiz.

5th

13 Basic principal and types of feedback, derivation of expression for gain of an amplifier employing feedback

5

To measure the voltage gain of emitter follower circuit and plot its frequency.

14 Effect of feedback (negative) on gain, stability, distortion and bandwidth of and amplifier.

15 RC coupled amplifier with emitter bypass capacitor.

6th

16 Emitter follower amplifier and its application.

6 Revision 17 Assignment –Topic & Class work Checking

18 Expert lecture

7th 19 Sessional Test 7

20 Use of positive feedback, Bark-hausen criterion for oscillations.

Plot the frequency response curve of

Hartley and Colpitt’s Oscillator

21 Working principle of Tunned Collector Oscillator

8th

22 Working principle of Hartley and Colpitt’s Oscillator Circuits.

8

Plot the frequency response curve of phase shift and Wein bridge Oscillator.

23 Working principle of Phase shift and wein- bridge Oscillator Circuits.

24 Working principle of crystal Oscillator Circuit.

9th

25 Revision

9 Revision 26

Series and parallel resonant circuit and bandwidth of resonant circuits.

27 Single tuned voltage amplifier & its frequency response.

10th

28 Double tuned voltage amplifier & its frequency response.

10

Use of IC 555 as monostable multivibrator and observe the output for different values

29 Expert Lecture

30 Working principle of transistor as switch.

11th

31 Concept of multi-vibrator: a stable, mono-stable, and bistable and their applications.

11

Use of IC as a stable multivibrator and observe the output at different duty cycles.

32 Concept of multi-vibrator: a stable, mono-stable, and bistable and their applications.

33 Concept of multi-vibrator: a stable, mono-stable, and bistable and their applications.

12th

34 Block diagram of IC555 and its working and applications.

12 Revision

35 IC555 as monostable and astable multi-vibrator and bistable multivibrator.

36 Assignment topic/sessional.

13th

37 Characteristics of an ideal operational amplifier and its block diagram.

13

To use IC 741 (op-amp) as 1.Inverter 2. Adder 3.Subtractor 4.Integrator

38 IC-741 and its pin configuration

39 Definition of differential voltage gain, CMRR, PSRR, slew rate and input offset current.

14th

40 Operational amplifier as an inverter, scale change, adder Subtractor, differentiator, and integrator.

14

To realize positive and negative fixed voltage DC power supply using three terminal voltage

regulator IC (7805, 7812

41 Operational amplifier as an inverter, scale change, adder Subtractor, differentiator, and integrator

42 Operational amplifier as an inverter, scale change, adder Subtractor, differentiator, and integrator.

15th 43 Concept of DC power supply, line and load regulation

15 Prototype making/ practice

44 Concept of fixed voltage, IC regulators 9like 7805, 7905), and variable

45 Voltage regulator like (IC 723)

16th 46 Revision/ seminar

16 Viva Voice 47 Revision/ Seminar 48 Sessional

Lesson Plan Name of Faculty : Ajay Kumar Discipline : Electronics & Comm. Eng. Semester : 3rd Subject : Electrical Machine Lesson Plan Duration : 15 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week Theory Practical

Lecture Day

Topic (Including Assignment/ Test Practical

Day Topic

1st

1 Advantage of three-phase system over single-phase system. Star Delta connection

1 Introduction to

Electrical Machine Lab 2

Relation between phase and line voltage and current in a three phase system

3 Power and power factor in three-phase system

2nd

4 Measurements of Power by one, two and three wattmeter methods.

2

To measure power and power factors in 3 Phase load by two wattmeter method

5 Assignment / Problem Taking

6 Principle of operation and constructional details of single phase transformer

3rd

7 Voltage Regulation of a transformer (No Derivation) Losses in a transformer

3

To measure power and power factors in 3 Phase load by two wattmeter method

8 Efficiency, condition for maximum efficiency and all day efficiency

9 CTs and PTs (Current transformer and potential transformer)

4th

10 CVT (Constant Voltage Transformer )

4

To measure power and power factor of a

single phase induction motor.

11 Assignment / Problem Taking

12 E.M.F induced in a coil rotating in a magnetic field.

5th

13 Definition of motor and generator

5

To measure power and power factor of a

single phase induction motor.

14 Basic principle of a generator and a motor

15 Torque due to alignment of two magnetic fields and the concept of Torque angle

6th

16 Basic Electromagnetic laws (Faraday’s laws of Electromagnetic Induction)

6

To determine the efficiency of a single phase transformer

from the data obtained through open circuit and short circuit test

17 Assignment

18 Class Test

7th

19 Introduction to DC Machines

7

To determine the efficiency of a single phase transformer

from the data obtained through

20 Principle of working of d.c motors and

21 D.c generator, their constructional details

open circuit and short circuit test

8th

22 Function of the commutator for motoring and generating action

8

To run a synchronous motor with a.c supply and to measure speed to verify the relation

N=12O f/ P

23 Factors determining the speed of a DC motor

24 Different types of excitation

9th

25 Characteristics of different types of DC machines

9

To run a synchronous motor with a.c supply and to measure speed to verify the relation

N=12O f/ P

26 Starting of DC motors and starters

27 Application of DC machines

10th

28 Assignment

10

To make connections of starting and running

winding of a single phase capacitor motor and to run it with the

help a DOL starter and to measure its speed

29 Class Test

30 Revolving magnetic field produced by poly phase supply

11th

31 Brief introduction about three phase induction motors, its principle of operation

11

To make connections of starting and running

winding of a single phase capacitor motor and to run it with the

help a DOL starter and to measure its speed

32 Principle and working of Synchronous Machines

33 Application of Synchronous Machines

12th

34 Assignment

12

Study construction of a stepper and

servomotor and to write their complete

specifications.

35 Class Test

36 Problem Taking

13th

37 Single Phase Fractional Kilowatt Motors Introduction

13

Study construction of a stepper and

servomotor and to write their complete

specifications.

38 Principle of operation of single phase motors

39 Types of single phase induction motors and their constructional details

14th

40 Single phase synchronous motors – reluctance motor ( hysteresis motor)

14 Repeat if any Required 41

Introduction to Commutator type single-phase motors

42 Introduction to servo- motors

15th 43 Introduction to stepper motors

15 Viva-Vice 44 Concept of micro-motors 45 Assignment

16th 46 Class Test

16 47 Problem Taking 48 Test

Lesson Plan

Name of Faculty : Ajay Kumar

Discipline : Electronics & Comm. Egg.

Semester : 3rd

Subject : Computer Programming using C

Lesson Plan Duration : 15 weeks

Work load (Lecture /Practical) per week (in hours): Lectures—04, Practical—03

Week Theory Practical

Lecture Day

Topic (Including Assignment/ Test Practical

Day Topic

1st

1 Introduction to Algorithm

1

Programming exercises on

executing and editing a C program

2 Introduction to Programming Development 3 Steps in development of a program 4 Flow charts

2nd

5 Algorithm development

2

Programming exercises on

defining variables and assigning values

to variables.

6 Programme Debugging 7 Assignment / Problem Taking

8 Introduction to Program Structure

3rd

9 I/O statements,

3

Programming exercises on

arithmetic and relational operators.

10 Assign statements 11 Constants, variables

12 Data types

4th

13 Operators and Expressions

4

Programming exercises on arithmetic

expressions and their evaluation.

14 Standards and Formatted IOS 15 Data Type Casting

16 Assignment

5th

17 Problem Solving

5

Programming exercises on formatting

input/output using printf and scanf and

their return type values.

18 Control Structures Introduction 19 Decision making with IF – statement

20 IF – Else a

6th

21 Nested IF

6 Programming

exercises using if statement

22 While

23 do-while

24 for loop

7th

25 Break. Continue Statement

7 Programming

exercises using if – Else

26 Got and switch statements 27 Assignment 28 Class Test

8th 29 Problem Taking

8 30 Introduction to Pointers

31 Address operator and pointers Programming exercises on switch

statement 32 Declaring Pointers

9th

33 Initializing pointers

9 Programming

exercises on do – while, statement.

34 Single pointer 35 Assignment 36 Class Test

10th

37 Problem Taking

10 Programming

exercises on for – statement.

38 Introduction to functions 39 Global and Local Variables 40 Function Declaration

11th

41 Standard functions

11 Programs on one-dimensional array.

42 Parameters and Parameter Passing 43 Call - by value 44 Call - by Reference

12th

45 Assignment

12 Programs on two-dimensional array

46 Class Test 47 Problem Taking

48 Introduction to Arrays

13th

49 Array Declaration, Length of array

13

i) Programs for putting two strings

together.

50 Single Array 51 Multidimensional Array 52 Arrays of characters

14th

53 Passing an array to function

14

(ii) Programs for comparing two

strings.

54 Pointers to an array 55 Assignment 56 Class Test

15th

57 Problem Taking

15 Simple programs using structures.

58 Revision of Chapter 1 59 Revision of Chapter 2 60 Revision of Chapter 3

16th

61 Revision of Chapter 4

16 Repeat if any

required

62 Revision of Chapter 5

63 Revision of Any Topic if required

64 Test

LESSON PLAN

NAME OF FACULTY : Suresh Kumar DISCIPLINE : Electronics & Communication Engg SEMESTER : 5th SUBJECT : EMPLOYABILITY SKILLS –I LESSON PLAN DURATION : 15 WEEKS WORK LOAD (LECTURE/PRACTICAL) PER WEEK : (2 Practical’s)

WEEK

PRACTICAL

PRACTICAL DAY

TOPIC

1st 1 1. Writing skills Official and business correspondence

2nd 2 Job application - covering letter and resume (Cont.)

3rd 3 Job application - covering letter and resume.

4th 4 Report writing - key features and kinds.

5th 5 2. Oral Communication Skills Giving advice

6th 6 Making comparisons

7th 7 Agreeing and disagreeing

8th 8 Taking turns in conversation

9th 9 Fixing and cancelling appointments (Cont.)

10th 10 Fixing and cancelling appointments

11th 11 3. Generic Skills Stress management

12th 12 Time management

13th 13 Negotiations and conflict resolution

14th 14 Team work and leadership qualities

15th 15 Viva voce and evaluation

Lesson Plan Name of Faculty : Himanshu Asija Discipline : Electronics & Comm. Engg. Semester : 5th Subject : CONSUMER ELECTRONICS Lesson Plan Duration : 16 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week Theory Practical Lecture Day

Practical

Day Topic

1st 1 Audio Systems:

1st To plot the frequency response of a Microphone

2 Microphones and Loudspeakers 3 Carbon, moving coil, cordless microphone

2nd 4 Direct radiating and horn loudspeaker

2nd To plot the frequency response of a Microphone

5 Multi-speaker system 6 Assignment

3rd 7 Problem Taking

3rd To plot the frequency response of a Loud Speaker

8 Class Test 9 Sound Recording

4th 10 Magnetic Recording

4th To plot the frequency response of a Loud Speaker

11 Digital Recording 12 Optical Recording ( CD system and DVD)

5th 13 Television

5th Trouble shooting of CD/DVD Player

14 Monochrome TV 15 Elements of TV communication system

6th

16 Scanning and its need

6th Trouble shooting of CD/DVD Player

17 Need of synchronizing and blanking pulses, VSB

18 Composite Video Signal

7th

19 Picture Tube

7th Practical file Checking and viva-voice

20 Camera Tube : Vidicon and Plumbicon

21 TV Receiver: Block diagram, function of each block,

8th

22 waveform at input and output of each block

8th

To observe the wave forms and measure voltage of B/W TV Receiver at different points

23 Assignment

24 Problem Taking

9th

25 Class Test

9th

To observe the wave forms and measure voltage of B/W TV Receiver at different points

26 Colour Television

27 Primary, secondary colours

10th

28 Concept of Mixing, Colour Triangle

10th

To observe the waveforms and measure voltages of colour TV Receiver at different points

29 Camera tube

30 PAL TV Receiver

11th

31 Concept of Compatibility with Monochrome Receiver

11th

To observe the waveforms and measure voltages of colour TV Receiver at different points

32 NTSC, PAL, SECAM system ( brief comparison)

33 Assignment

12th

34 Problem Taking

12th Fault finding of colour T.V

35 Class Test

36 LCD and LED Television: Basic principle and working of LCD and LED TV

13th 37

LCD and LED Television: Basic principle and working of LCD and LED TV

13th Fault finding of colour T.V 38 Assignment

39 Problem Taking

14th

40 Class Test

14th DTH System 41

Cable Television: Working of Cable TV, DTH, HDTV

42 Cable Television: Working of Cable TV, DTH, HDTV

15th 43 Assignment

15th Scanner 44 Problem Taking 45 Class Test

16th 46 Scanner

Revision 47 Digital Camera 48 VCD/DVD

Lesson Plan Name of Faculty : Bharti Verma Discipline : ECE Semester : 5th Subject : Optical Fiber Communication Lesson Plan Duration : 15 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week

Theory Practical Lecture Day

Topic (Including Assignment/ Test Practical Day

Topic

1st

1 Historical perspective, basic communication systems

1st To set up fiber analog link 2

optical frequency range, advantages of optical fiber communication

3 application of fiber optic communication

2nd 4

Electromagnetic spectrum used, Advantages of OFC

2nd To set up fiber analog link 5 Principle of light penetration

6 reflection, critical angle

3rd 7 Assignment

3rd To set up optic digital link

8 Problem Analysis 9 Fiber types construction

4th

10 multimode and mono-mode fibers

4th To set up optic digital link

11 step index and graded index fibers

12 acceptance angle and types of optical fiber cables

5th

13 Optical Fibers cable connectors

5th

To measure bending losses in optical fibers

14 splicing techniques (Mechanical, fusion)

15 Assignment

6th 16 Problem Analysis

6th To observe and measure the splice or connector loss

17 Absorption Losses 18 Scattering Losses

7th 19 Radiation losses

7th To observe and measure the splice or connector loss

20 Connector losses, Bending loses 21 Dispersion: Types and its effect on data rate

8th 22

Testing of losses using OTDR (Optical Time Domain Reflectometer). 8th

To measure and calculate numerical aperture of optical fiber 23 Assignment

24 Problem Analysis

9th

25 Characteristics of light source used in optical communication,

9th

To measure and calculate numerical aperture of optical fiber

26 Characteristics of light source used in optical communication, principle of operation of LED

27 different type of LED structures used and their brief description

10th 28 LED driving circuitry 10th

29 Injection Laser diode, principle of operation To observe characteristics of optical source

30 different injection laser diodes, comparison of LED and ILD, non-semiconductor laser

11th 31

Characteristics of photo detectors used in optical communication; PIN diode and avalanche photo diode (APD), their brief description

11th

To observe characteristics of optical detector

32 Assignment 33 Class test

12th 34 Problem Analysis

12th To connect a fiber with connector at both ends

35 Fiber alignment and joint losses 36 splicing, types of splices

13th 37 types of connectors used

13th To connect a fiber with connector at both ends

38 couplers, three and four port coupler, 39 Stare coupler, fiber optic switch.

14th

40 Optical transmitter circuit, optical receiver

circuit, optical power budgeting 14th

To identify and use various components and tools used in optical fiber communication

41 Multiplexing Methods used. Modulation methods used

42 Introduction to SDH, SONET

15th 43 Assignment

15th Revision of Experiments

44 Class test 45 Problem Analysis

Lesson Plan

Name of Faculty : Arshad Jamal

Discipline : Electronics & Comm. Eng.

Semester : 5th

Subject : MICROWAVE AND RADAR ENGINEERING

Lesson Plan Duration : 16 weeks

Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

week

1st

Lecture Day

Topic (Including Assignment/ Test Practical

Day Topic

1 Introduction to microwaves and its applications,

1st General idea’s for lab

Equipment’s 2

Classification on the basis of its frequency bands (HF, VHF, UHF, L, S, C, X, KU, KA, mm, SUB, mm)

3 Rectangular and circular wave guides and their applications

2nd

4 Mode of wave Guide

2nd

To measure the electronics and mechanical tuning range of a reflex klystron

5 Propagation constant of a rectangular wave guide

6

cut off wavelength, guide wavelength and their relationship with free space wavelength (no mathematical derivation)

3rd

7 Impossibility of TEM mode in a wave guide

3rd

To measure the electronics and mechanical tuning range of a reflex klystron

8 REVISON /Assignment

9 Constructional features, characteristics and application of tees, bends

4th

10 Constructional features, characteristics and application of matched termination & twists

4th To measure VSWR of a given load.

11 Constructional features, characteristics and application of detector, mount, slotted section

12 Constructional features, characteristics and application of directional coupler

5th

13 Constructional features, characteristics and application of fixed and variable attenuator

5th To measure VSWR of a given load.

14 Constructional features, characteristics and application of isolator, circulator

15 Constructional features, characteristics and application of duplex, coaxial to wave guide adapter

6th

16 Assignment/ Test

6th

To measure the Klystron frequency by slotted section method

17 Basic concepts of thermionic emission and vacuum tubes

18

Effects of interelectrode capacitance, Lead Inductance and Transit time on the high frequency performance of conventional vacuum tubes

7th

19 steps to extend their high frequency operations

7th

To measure the Klystron frequency by slotted section method

20 Construction, characteristics, operating principles and typical applications of Multi cavity klystron

21 Construction, characteristics, operating principles and typical applications of Reflex klystron

8th

22 Construction, characteristics, operating principles and typical applications of Multi-cavity magnetron

8th Revision 23 Construction, characteristics, operating principles and typical applications of Traveling wave tube

24 Construction, characteristics, operating principles and typical applications of Gunn diode and Impatt diode

9th

25 Revision

9th

To measure the directivity and coupling of a directional coupler.

26 Expert Lecture/ Quiz

27 General Trams and views for microwayse antennas

10th

28 Structure characteristics and typical applications of Horn antennas

10th

To measure the directivity and coupling of a directional coupler.

29 Structure characteristics and typical applications of Dish antennas

30 Revision / Quiz /expert Lecture

11th

31 Block diagram and working principles of microwave communication link.

11th

To plot radiation pattern of a horn antenna in horizontal and vertical planes.

32 Troposcatter Communication Troposphere and its properties

33 Troposcatter Communication Troposphere and its properties

12th

34 Tropospheric duct formation and propagation

12th

To plot radiation pattern of a horn antenna in horizontal and vertical planes.

35 Tropospheric duct formation and propagation

36 Roposcatter propagation.

13th 37 Assignment

13th To verify the properties of magic tee.

38 Revision 39 Introduction to radar, its various applications

14th

40 radar range equation (no derivation) and its applications

14th

To verify the properties of magic tee.

41 Block diagram and operating principles of basic pulse radar

42 Concepts of ambiguous range, radar area of cross-section and its dependence on frequency

15th

43 Block diagram and operating principles with application of CW (Doppler radar )

15th Revision/ viva 44 Block diagram and operating principles with application of FMCW radar

45 Block diagram and operating principles of MTI radar.

16th

46 Radar display- PPI

16th Revision/ viva 47 Introduction to VSAT transponders multiple access techniques

48 VSAT and its features

Lesson Plan

Name of the faculty : SURESH KUMAR Discipline : Electronics & Comm. Engineering Semester : 5th Subject : Environmental Education Lesson Plan Duration : 15 weeks (July-18 to Nov-18) Work Load : (3 Periods/Week)

Theory Week Lecture Day Topics

1st

1st 1. Definition and Scope of Environmental Education

2nd Importance of Environmental Education

3rd 2. Basics of ecology, biodiversity

2nd

4th Eco system

5th Sustainable development

6th 3. Sources of pollution - natural and manmade

3rd

7th Causes, effects of air pollution

8th Control measures of air pollution

9th Causes, effects of noise pollution

4th

10th Control measures of noise pollution

11th Causes, effects of soil pollution poll pollution

12th Control measures of soil pollution

5th

13th Causes, effects of radioactive pollution poll pollution

14th Control measures of radioactive pollution

15th Causes, effects of nuclear pollution poll pollution

6th

16th Control measures of nuclear pollution

17th Units of measurement of pollution

18th 4. Solid waste management- Causes and effects of urban waste

7th

19th SESSIONAL I

20th Control measures of urban waste

21th Causes and effects of industrial waste

8th

22nd Control measures of industrial waste

23rd 5. Mining and deforestation – Causes, effects of mining

24th Control measures of mining

9th

25th Causes, effects of deforestation

26th Control measures of deforestation

27th 6. Environmental Legislation - Water (prevention and control of pollution) Act 1974

10th 28th Air (Prevention and Control of Pollution) Act 1981 29th Environmental Protection Act 1986 30th Role and Function of State Pollution Control Board

11th 31st Environmental Impact Assessment (EIA)

32nd SESSIONAL II

33rd 7. Role of Non-conventional Energy Resources Solar Energy

12th

34th Wind Energy

35th Bio Energy

36th Hydro Energy

13th

37th 8. Current Issues in Environmental Pollution – Global Warming, Green House Effect

38th Depletion of Ozone Layer, Recycling of Material

39th Environmental Ethics

14th

40th Rain Water Harvesting

41th Maintenance of Groundwater

42nd Acid Rain

15th 43th Carbon Credits 44th Revision 45th SESSIONAL III

LESSON PLAN

NAME OF FACULTY : Himanshu Asija DISCIPLINE : Electronics & Communication Engg SEMESTER : 5th SUBJECT : Trouble Shooting of Electronics Equipment’s LESSON PLAN DURATION : 15 WEEKS WORK LOAD (LECTURE/PRACTICAL) PER WEEK : (6 Practical’s)

Practical Week Day Topics

1st 1 Repair, Servicing and Maintenance Concepts 2 Demonstration and practice of fault finding and repair of CRO

2nd 3 Demonstration and practice of fault finding and repair of CRO 4 Fundamental Trouble Shooting Procedures

3rd 5 Demonstration and practice of fault finding and repair of Function Generator 6 Demonstration and practice of fault finding and repair of Function Generator

4th 7 Trouble Shooting Techniques 8 Demonstration and practice of fault finding and repair of Power Supplies

5th 9 Demonstration and practice of fault finding and repair of Power Supplies

10 Mobile Phones

6th 11 Demonstration and practice of fault finding and repair of Digital Multimeter 12 Demonstration and practice of fault finding and repair of Digital Multimeter

7th 13 SESSIONAL I 14 Trouble shooting and maintenance of testing equipment like C.R.O , function generator,

power supplies and other measuring devices, detailed discussion about trouble shooting of medical, electronic equipment like, ECG, EEG, Ultra sound. Repair and maintenance and exposure of medical electronics equipment through industrial visits.

8th 15

16

9th 17

Demonstration, practice of fault finding and repair of any one equipment from group-I i.e. Communication

18 Demonstration, practice of fault finding and repair of any one equipment from group-I i.e. Communication

10th 19 Troubleshooting Digital Systems

20 Demonstration and practical’s to be performed on following groups of Electronic equipment, with compulsory visit to low service center.

11th 21

Demonstration, practice of fault finding and repair of any one equipment from group-II i.e. Consumer

22 SESSIONAL II

12th 23

Demonstration, practice of fault finding and repair of any one equipment from group-III i.e. Audio/Video systems

24 Demonstration, practice of fault finding and repair of any one equipment from group IV i.e. Computer

13th 25

Demonstration, practice of fault finding and repair of any one equipment from group IV i.e. Computer

26 Testing of Integrated Circuits (ICs)

14th 27 Testing of Integrated Circuits (ICs) 28 Use of digital tools for troubleshooting digital equipment’s

15th 29 Use of digital tools for troubleshooting digital equipment’s 30 SESSIONAL III

Lesson Plan Name of Faculty : Ashok Kumar Choudhary Discipline : Electronics & Comm. Engg. Semester : 5th Subject : POWER ELECTRONICS Lesson Plan Duration : 16 weeks Work load (Lecture /Practical) per week (in hours): Lectures—03, Practical—03

Week

Theory Practical Lecture

Day Topic

Practical Day

Topic

1st 1 Construction, Working principle of SCR

1st To plot V-I

characteristic of an SCR

2 two transistor analogy of SCR, 3 V-I characteristics of SCR

2nd 4 SCR specifications and ratings

2nd To plot V-I

characteristics of TRIAC.

5 Different methods of SCR triggering 6 Different commutation circuits for SCR

3rd

7 Series and parallel operation of SCR

3rd To plot V-I

characteristics of UJT

8 Revision / Assignment

9 Construction and working principle of DIAC, TRIAC and their V-I characteristics

4th

10 Construction, working principle of UJT, V-I characteristics of UJT. UJT as relaxation Oscillator.

4th To plot V-I

characteristics of DIAC

11 Brief introduction to Gate Turn off thyristor (GTO), Programmable Uni-junction Transistor (PUT), MOSFET.

12 Basic idea about the selection of Heat sink for thyristor

5th

13 Applications such as light intensity control, speed control of universal motors, fan regulator, battery charger

5th Revision 14

Single phase half controlled full wave rectifier with load (R, R-L)

15 Fully controlled full wave bridge rectifier

6th

16 Assignment/Test

6th

Study of UJT relaxation oscillator. And observe I/P and

O/P wave forms

17 Single phase full wave center tap rectifier

18

Principle of operation of basic inverter circuits, concepts of duty cycle, series and parallel Inverters and their applications

7th

19 Choppers: Introduction, types of choppers (Class A, Class B, Class C and Class D).

7th

Observation of wave shape of voltage at relevant point of single-phase half wave controlled

Rectifier and effect of change of firing

angle.

20 Step up and step down choppers.

21 Dual Converters and cyclo converters: Introduction

8th

22 types and basic working principle of dual converters

8th

Observation of wave shape of voltage at relevant point of single-phase half wave controlled

23 types and basic working principle of dual converters

24 Revision

Rectifier and effect of change of firing

angle.

9th

25 Revision

9th

Observation of wave shapes of voltage at

relevant point of single phase full wave controlled

rectifier and effect of change of firing

angle

26 Expert Lecture/Quiz

27 Cyclo converters and their applications.

10th

28 Cyclo converters and their applications.

10th

Observation of wave shapes of voltage at

relevant point of single phase full wave controlled

rectifier and effect of change of firing

angle

29 Thyristorised Control of Electric drives

30 Thyristorised Control of Electric drives

11th 31 DC drive control

11th Revision 32 Half wave drives 33 Full wave drives

12th

34 Chopper drives (Speed control of DC motor using choppers)

12th

Observation of wave shapes and

measurement of voltage at relevant

points in TRIAC based

AC phase control circuit for Varying lamp intensity and

AC fan speed control

35 Chopper drives (Speed control of DC motor using choppers)

36 Revision

13th

37 Revision

13th

Observation of wave shapes and

measurement of voltage at relevant

points in TRIAC based

AC phase control circuit for Varying lamp intensity and

AC fan speed control

38 Assignment

39 AC drive control

14th

40 AC drive control

14th

Installation of UPS system and routine

maintenance of batteries

41 Phase control

42 Constant V/F operation

15th

43 Cycloconverter/Inverter drives

15th

Installation of UPS system and routine

maintenance of batteries

44 Cycloconverter/Inverter drives

45 Un interrupted Power Supply (UPS)

16th 46

UPS: Block Diagram & specifications of on-line, off line and Smart UPS

16th Revision 47 Concept of high voltage DC transmission 48 Concept of high voltage DC transmission