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Specimen of lesson Plan Name of the Faculty : Smt. Suchet Kumari Discipline : Electronics and Communication Engg. Semester : 3rd Subject : PRINCIPLES OF COMMUNICATION ENGINEERING
Lesson Plan Duration : July-Nov-2018 Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture) 03 Hours per Group (PRACTICAL)
Week
Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction about subject,- Need for modulation To observe an AM wave on
CRO produced by a standard signal generator using
internal and external modulation
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.
To measure the modulation
index of the wave obtained in above practical
5 Carrier and side band components. Modulation index
6
Spectrum and BW of AM Wave. Relative power distribution in carrier and side bands.
3rd
7 Elementary idea of DSB-SC
To obtain an AM wave from
a square law modulator circuit and observe
waveforms
8 SSB-SC, ISB
9 VSB modulations, their comparison, and areas of applications
4th
10 Expression for frequency modulated wave and its frequency
spectrum (without Proof and analysis of Bassel function)
To measure the modulation
index of the obtained wave form.
11
Modulation index, maximum frequency deviation and
deviation ratio, BW of FM signals
12 Carson’s rule.
5th
13 Effect of noise on FM carrier, Noise triangle, Role of limiter
To obtain an FM wave and
measure the frequency deviation for different
modulating signals.
14 Need for pre-emphasis and de-emphasis, capture effect.
15 Comparison of FM and AM in communication systems
6th
16 1st Sessional To obtain modulating signal from an AM detector circuit
and observe the pattern for different RC time constants
and obtain its optimum value
for least distortion.
17
Derivation of expression for phase modulated wave, modulation index, comparison with frequency modulation
18 Collector and Base Modulator
7th
19 Collector and Base Modulator To obtain modulating signal
from an AM detector circuit and observe the pattern for
different RC time constants and obtain its optimum value
for least distortion.
20 Square Low Modulator
21 Balanced Modulator
8th
22 Working principles and applications of reactance modulator
To obtain modulating signal from FM detector.
23 varactor diode modulator
24 VCO and Armstrong phase modulator
9th
25 Stabilization of carrier using AFC (Block diagram approach).
To obtain modulating signal
from FM detector.
26 Stabilization of carrier using AFC (Block diagram approach).
27 Principles of demodulation of AM wave using diode
10th
28 detector circuit; concept of Clipping 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
Clipping and formula for RC time constant for minimum distortion (no derivation
30 Revision
11th
31 Revision To observe and note the
pulse amplitude modulated
signal (PAM) and compare them with the corresponding
analog input signal
32 2nd Sessional Test
33 Basic principles of FM detection using slope detector
12th
34 Foster-Seeley discriminator
To observe PPM and PWM
signal and compare it with
the analog input signal
35 Foster-Seeley discriminator
36 Ratio detector
13th
37 Block diagram of Phase locked Loop (PLL) FM demodulators (No Derivation)
Revision & Viva
38 Block diagram of Phase locked Loop (PLL) FM demodulators (No Derivation)
39
Statement of sampling theorem and elementary idea of
sampling frequency for pulse modulation
14th
40 Basic concepts of time division multiplexing (TDM)
Revision & Viva
41 frequency division multiplexing (FDM)
42 Pulse Amplitude Modulation (PAM)
15th
43 Pulse Position Modulation (PPM),
Revision & Viva
44 Pulse Width Modulation (PWM).
45 3rd Sessional Test
Specimen of lesson Plan Name of the Faculty : Sh. Inderjeet Singh Dhindsa Discipline : Electronics and Communication Engg. Semester : 3rd Subject : COMPUTER PROGRAMMING USING C
Lesson Plan Duration : Jan-Apr-2018 Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Week Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction to Algorithm 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 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, Programming exercises on
arithmetic and relational
operators. 10
Assign statements
11
Constants, variables
12
Data types
4th
13 Operators and Expressions Programming exercises on
arithmetic expressions and their evaluation.
14 Standards and Formatted IOS
15
Data Type Casting
16
Assignment
5th 17
Problem Solving 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 Programming exercises using if
statement
22
While
23
do-while
24
for loop
7th
25 Break. Continue Statement Programming exercises using if –
Else
26
Got and switch statements
27
Assignment
28
Class Test
8th
29 Problem Taking
Programming exercises on
switch statement
30
Introduction to Pointers
31
Address operator and pointers
32
Declaring Pointers
9th
33 Initializing pointers
Programming exercises on do – while, statement.
34
Single pointer
35
Assignment
36
Class Test
10th
37 Problem Taking
Programming exercises on for –
statement.
38
Introduction to functions
39
Global and Local Variables
40
Function Declaration
11th
41 Standard functions
Programs on one- dimensional
array.
42
Parameters and Parameter Passing
43
Call - by value
44 Call - by Reference
12th
45 Assignment
Programs on two- dimensional array
46
Class Test
47
Problem Taking
48
Introduction to Arrays
13th
49 Array Declaration, Length of array
i) Programs for putting two strings together.
50
Single Array
51
Multidimensional Array
52
Arrays of characters
14th
53 Passing an array to function
(ii) Programs for comparing two strings.
54
Pointers to an array
55
Assignment
56
Class Test
15th
57 Problem Taking
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
Repeat if any required
62
Revision of Chapter 5
63
Revision of Any Topic if required
64
Test
Specimen of lesson Plan Name of the Faculty : Sh. Rajiv Sapra Discipline : Electronics and Communication Engg. Semester : 3rd Subject : DIGITAL ELECTRONICS Lesson Plan Duration : July- Nov-2018 Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Week Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction about subject 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 Number System Verification and interpretation of truth tables for AND, OR, NOT
NAND, NOR and Exclusive OR
(EXOR) and Exclusive NOR(EXNOR) gates
5 Binary, octal and hexadecimal number system:
6
conversion from decimal and hexadecimal to binary and vice-versa.
3rd
7 Binary addition and subtraction including binary points
Realisation of logic functions with
the help of NAND or NOR gates
8 1’s and 2’s complement method of addition/subtraction.
9
Codes and Parity Concept of code, weighted and non-
weighted codes, examples of 8421
4th
10 BCD, excess-3 and Gray code.
To design a half adder using XOR and NAND gates and verification
of its operation
11
Concept of parity, single and double parity and error
detection
12
Logic Gates and Families, Concept of negative and
positive logic
5th
13 Definition, symbols and truth tables of NOT, AND
Construction of a full adder circuit
using XOR and NAND gates and verify its operation
14
OR, NAND, NOR, EXOR Gates, NAND and NOR as
universal gates.
15 Introduction to TTL and CMOS logic families
6th 16 1st Sessional Test
Verification of truth table for positive edge triggered, negative
17 Logic Simplification Postulates of Boolean algebra, De Morgan’s Theorems
edge triggered, level triggered IC
flip-flops (At least one IC each of D latch , D flip-flop, JK flip-flops).
18 Implementation of Boolean (logic) equation with gates
7th
19 Karnaugh map (upto 4 variables) 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).
20 and simple application in developing
21 combinational logic circuits
8th
22 Arithmetic circuits Half adder and Full adder circuit, design
and implementation
Verification of truth table for
encoder and decoder ICs, Mux
and DeMux
23 4 bit adder circuit
24
Decoders, Multiplexeres, Multiplexeres and Encoder Four bit decoder circuits for 7 segment display and
decoder/driver ICs
9th
25 Basic functions and block diagram of MUX
Verification of truth table for
encoder and decoder ICs, Mux and DeMux
26 DEMUX with different ICs
27 Basic functions and block diagram of Encoder
10th
28 Latches and flip flops Concept and types of latch with their working and applications To design a 4 bit SISO, SIPO,
PISO, PIPO shift registers using JK/D flip flops and verification of
their operation
29 Operation using waveforms and truth tables of RS,
30 T, D, Master/Slave JK flip flops.
11th
31 Difference between a latch and a flip flop
To design a 4 bit ring counter
and verify its operation
32 2nd Sessional Test
33
Counters Introduction to Asynchronous and Synchronous
counters
12th
34 Binary counters
Use of Asynchronous Counter ICs
(7490 or 7493)
35 Divide by N ripple counters,
36 Decade counter, Ring counter
13th
37 Shift Register Introduction and basic concepts including
shift left and shift right Revision
38
Serial in parallel out, serial in serial out, parallel in serial
out, parallel in parallel out.
39 Universal shift register
14th
40 A/D and D/A Converters
Revision
41 Stair step Ramp A/D converter, Dual Slope A/D
converter
42 Successive Approximation A/D Converter
15th
43 Detail study of : Binary Weighted D/A converter
Revision & Viva
44 R/2R ladder D/A converter
45 Applications of A/D and D/A converter
16th
46 Semiconductor Memories, Memory organization, classification of semiconductor memories (RAM, ROM,
PROM, EPROM, EEPROM),
Revision & Viva 47 static and dynamic RAM, introduction to 74181 ALU IC
48 3rd Sessional Test
Specimen of lesson Plan
Name of the Faculty : Sh.Pankaj Oberoi
Discipline : Electronics and Communication Engg.
Semester : 3rd
Subject : ELECTRONIC INSTRUMENTS AND MEASUREMENT
Lesson Plan Duration : July- Nov-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Week Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction about subject
Measurement of voltage,
resistance, frequency using
digital multimeter 2
ch-1. Measurement, method of measurement, types of instruments
3 Specifications of instruments Accuracy, precision
2nd
4 Specifications of instruments sensitivity, resolution, range, errors in measurement
Measurement of voltage, resistance, frequency using
digital multimeter 5 sources of errors, limiting errors,
6 loading effect, importance and applications of standards and
calibration
3rd
7 Class work/Assignment and revision.
Measurement of voltage, frequency, time period and
phase using CRO 8 Ch-2 . Principles of measurement of DC voltage
9 Principles of measurement of DC current
4th
10 Principles of measurement of AC voltage
Measurement of voltage,
frequency, time period and phase using CRO
11 Principles of measurement of AC current
12 Principles of operation and construction of permanent magnet moving coil (PMMC) instruments
5th
13 Moving iron type instruments
Practical file Checking and viva-voice
14 Class work and revision.
15 Class work and revision.
6th
16 1st Sessional Test Measurement of voltage,
frequency, time and phase using DSO 17 Ch-3. Construction and working of Cathode Ray Tube(CRT)
18 Block diagram description of a basic CRO and triggered sweep oscilloscope
7th
19 Front panel controls
Measurement of voltage, frequency, time and phase
using DSO 20 Specifications of CRO and their explanation
21 Measurement of current, voltage, frequency
8th
22 Measurement of current time period and phase using CRO
Measurement of Q of a coil 23 Digital storage oscilloscope (DSO) block diagram and
working principle
24 Class work/Assignment and revision.
9th
25 Class work/Assignment and revision.
Measurement of Q of a coil 26 Ch-4. Wheat stone bridge
27 AC bridges: Maxwell’s induction bridge
10th
28 Hay’s bridge, De-Sauty’s bridge,
Practical file Checking and viva-voice
29 Schering bridge and Anderson bridge
30 Bock diagram description of laboratory type RLC bridge, specifications of RLC bridge
11th
31 Block diagram and working principle of Q meter and revision
Measurement of resistance and inductance of coil using RLC
Bridge 32 2nd Sessional Test
33 Ch-5. Explanation of block diagram specifications of low
frequency, RF generators
12th
34 pulse generator, function generator
Measurement of impedance
using Maxwell Induction Bridge 35 Distortion factor meter
36 Instrumentation amplifier: its characteristics, need and
working
13th
37 Class work/Assignment and revision.
To find the value of unknown
resistance using Wheat Stone Bridge
38 Class work/Assignment and revision.
39 Ch-6. Comparison of analog and digital instruments
14th
40 Working principle of ramp, dual slope digital voltmeter.
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
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
Practical file Checking and viva-
voice 47 Class work/ Revision.
48 3rd Sessional Test
Specimen of lesson Plan
Name of the Faculty : Sh.Pankaj Oberoi
Discipline : Electronics and Communication Engg.
Semester : 3rd
Subject : ELECTRICAL MACHINES
Lesson Plan Duration : July- Nov-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Week Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction about Three Phase Supply Demonstrate various instruments
use viz Ammeter, Voltmeter,
Wattmeter, p.f meter etc for their identification and and connecting
procedure in a circuit.
2 Advantage of three-phase system over single-phase
system.
3 Star Delta connections
2nd
4 Relation between phase and line voltage and current in a three phase system
To measure power and power factors in 3 Phase load by two
wattmeter method 5 Power and power factor in three-phase system
6 their measurements by one, two and three wattmeter
methods.
3rd
7 Introduction about Transformers
To determine the efficiency of a single phase transformer from the
data obtained through open circuit
and short circuit test
8 Principle of operation and constructional details of
single phase transformer
9 Voltage Regulation of a transformer (No Derivation)
4th
10 Losses in a transformer
To determine the efficiency of a
single phase transformer from the data obtained through open circuit
and short circuit test
11 Efficiency, condition for maximum efficiency and all day efficiency
12 CTs and PTs (Current transformer and potential
transformer)
5th
13 CVT (Constant Voltage Transformer)
To measure power and power
factor of a single phase induction motor.
14 1st Sessional Test
15 Introduction to Rotating Electrical Machines
6th 16 Definition of motor and generator To run a synchronous motor with a.c supply and to measure speed to
17 Basic principle of a generator and a motor verify the relation N=12O f/ P
18 Torque due to alignment of two magnetic fields
7th
19 concept of Torque angle 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
20 Basic Electromagnetic laws (Faraday’s laws of
Electromagnetic Induction)
21 Introduction to DC Machines
8th
22 Principle of working of d.c motors and d.c generator
Study construction of a stepper and
servomotor and to write their complete specifications.
23 their constructional details
24 Function of the commutator for motoring and generating action
9th
25 Factors determining the speed of a DC motor
Study construction of a stepper and servomotor and to write their
complete specifications. 26 Different types of excitation
27 Characteristics of different types of DC machines
10th
28 Characteristics of different types of DC machines
Revision 29 Starting of DC motors and starters
30 Application of DC machines
11th
31 Application of DC machines
Revision 32 2nd Sessional Test
33 Introduction to A.C. Motors
12th
34 Revolving magnetic field produced by poly phase
supply
Revision 35 Brief introduction about three phase induction motors,
its principle of operation
36 Principle and working of Synchronous Machines
13th 37 Application of Synchronous Machines Revision
38 Introduction to Single Phase Fractional Kilowatt Motors
39 Introduction - Principle of operation of single phase motors
14th
40 Types of single phase induction motors
Revision 41 their constructional details
42 Single phase synchronous motors – reluctance motor (
hysteresis motor)
15th
43 reluctance motor ( hysteresis motor)
Revision 44 Introduction to Commutator type single-phase motor
45 Introduction to servo- motors
16th
46 stepper motors
Revision 47 Concept of micro-motors.
48 3rd Sessional Test
Specimen of lesson Plan Name of the Faculty : Sh.Sandeep Goel Discipline : Electronics and Communication Engg. Semester : 3rd Subject : ELECTRONIC DEVICES AND CIRCUITS Lesson Plan Duration : July- Nov-2018 Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Week Theory Practical
Lecture day
Topic (including assignment/ test) Topic
1st
1 Introduction about Multistage Amplifiers Plot the frequency
response of two stage
RC coupled amplifier
and calculate the
bandwidth and
compare it with single
stage amplifier
2 Need for multistage amplifier - Gain of multistage amplifier
3 Different types of multistage amplifier like RC coupled
transformer coupled, direct coupled
2nd
4 their frequency response and bandwidth, Difference between voltage and power amplifiers ,mportance of impedance matching in amplifiers To measure the gain
of push-pull amplifier at 1KHz
5
Class A, Class B
6 Class AB, and Class C amplifiers
3rd
7 collector efficiency and Distortion in class A,B,C To measure the
voltage gain of emitter follower circuit and plot its frequency
response
8 Single ended power amplifiers, Graphical method of
calculation (without derivation) of out put power
9 heat dissipation curve and importance of heat sinks
i
i) Adder,
4th
10 Push-pull amplifier, and complementary symmetry push-pull amplifier Plot the frequency
response curve of Hartley and Colpitt’s
Oscillator
11
Basic principles and types of feedback
12 Derivation of expression for gain of an amplifier employing feedback
5th
13 Effect of feedback (negative) on gain, stability, distortion and bandwidth of an amplifier
Viva
14 RC coupled amplifier with emitter bypass capacitor
15
Emitter follower amplifier and its application
6th
16 1st Sessional Test Plot the frequency response curve of
phase shift and Wein bridge Oscillator
17 Use of positive feedback, Barkhausen criterion for
oscillations
18 Different oscillator circuits-tuned collector, Hartley
7th
19 Colpitts, phase shift, Wien’s bridge, Use of IC 555 as
monostable multivibrator and
observe the output for different values of RC
20
Basic Electromagnetic laws (Faraday’s laws of Electromagnetic Induction)
21 crystal oscillator. Their working principles (no mathematical
derivation but only simple numerical problems)
8th
22 Series and parallel resonant circuits and bandwidth of resonant circuits Use of IC 555 as
astable multivibrator and observe the
output at different duty cycles
23
Single and double tuned voltage amplifiers
24 frequency response characteristics
9th
25 Working principle of transistor as switch
Viva
26 Concept of multi-vibrator: astable, monostable
27
bistable and their applications
10th
28 Block diagram of IC555 and its working and applications To use IC 741 (op-
amplifier) as i) Inverter, ii) Adder, iii) Subtractor iv) Integrator
29
IC555 as monostable
30 astable multi-vibrator
11th
31 bistable multivibrator
To realize positive
and negative fixed
voltage DC power
supply using three
terminal voltage
regulator IC (7805,
7812, 7905)
32
2nd Sessional Test
33 Characteristics of an ideal operational amplifier and its block diagram
12th
34 IC-741 and its pin configuration
Revision
35 Definition of differential voltage gain
36
CMRR, PSRR
13th
37 slew rate and input offset current
Revision
38 Operational amplifier as an inverter
39
scale changer, adder
14th
40 subtractor, differentiator
Revision
41 integrator
42
Concept of DC power supply
15th
43 Line and load regulation
Viva
44 Concept of fixed voltage
45
IC regulators (like 7805, 7905),
16th
46 variable voltage regulator like (IC 723)
Viva
47 Revision
48 3rd Sessional Test