lesson plan name of the faculty : sh. inderjeet singh...
TRANSCRIPT
Practical
Lecture
day
Topic (including assignment/ test) Topic
1 Introduction about subject
2 Networks : Two port (four terminals) network
3Basic concepts of Symmetrical and asymmetrical networks ,Balanced and
unbalanced network;
4Basic concepts of T-network,π- Network, Ladder network,Lattice network,L-
network and Bridge T-network
5Concept and significance of the terms characteristic impedance, propagation
constant,attenuation constant, phase shift constant
6 Characteristic impedance of a T- Network
7 Characteristic impedance of a π- Network
8 Propagation constant of a T- Network
9 Propagation constant of a π- Network
10 Attenuation and phase constant of a T and π- Network
11 insertion loss of T-network and π Network
12 Revision of symmetrical networks
13 Asymmetrical Network Concept and significance of iterative impedance
14 image impedance, image transfer constant and insertion loss
15 The half section (L-section); symmetrical T and Л sections into half sections
16 1st
Sessional Test
17Attenuators, Units of attenuation (Decibels and Nepers),General
characteristics of attenuators.
18 Analysis and design of Symmetrical T attenuator
19 Analysis and design of Symmetrical π attenuator
20 Analysis and design of L- type attenuator
21 Numerical problem on design of attenuators
22 Filters
23 Brief idea of the use of filter networks in different communication systems
24 concept of low pass,
25 high pass, band pass and band stop filters.
26Prototype Filter Section: Impedance characteristics vs frequency
characteristics of a low and high pass filter and their significance
27Attenuation Vs frequency; Phase shift Vs frequency, characteristics
impedance vs frequency of T and π filters and their significance
28 Simple design problems of prototype low pass filter.
29M-Derived Filter Sections Limitation of prototype filters, need of m-derived
filters
30Crystal Filters Crystal and its equivalent circuits, special properties of
piezoelectric filters and their use
31Active Filters Basic concept of active filters and their comparison with passive
filters.
32 2nd
Sessional Test
Week Theory
1st
2nd
3rd
7th
To design and measure the
attenuation of a symmetrical
T/ π type attenuator
To determine the impedance
characteristic and attenuation
characteristic of a prototype band
pass filter and plot the
5th
4th
To determine the characteristic
impedance experimentally of a
prototype high pass filter and plot
the attenuation characteristic
Lesson Plan Duration : Jan-Apr-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecturer)
To determine the impedance
characteristic and attenuation
characteristic of a m-derived
lowpass filter
To determine the impedance
characteristic and attenuation
characteristic of a m-derived
highpass filter
To observe the information of
standing waves on a transmission
line and measurement of SWR and
characteristic impedance of the
line
Introduction about Practical
To measure the characteristic
impedance of symmetrical T and
π- Network
To measure the image impedance
of a given asymmetrical T and π - Network
To determine the characteristic
impedance experimentally of a
prototype low pass filter and plot
the attenuation characteristic
11th
10th
8th
9th
6th
lesson PlanName of the Faculty : Sh. Inderjeet Singh Dhindsa
Discipline : Electronics and Communication Engg.
Semester : IVth
Subject : NETWORK FILTERS AND TRANSMISSION LINES
Draw the attenuation
characteristics of a crystal filte
33 Transmission Lines Transmission Lines, their types and applications.
34 Distributed constants, T and πrepresentation of transmission line section.
Primary constant of transmission line.35 Secondary constant of a transmission line. Transmission line equation
36 transmission line equation contd.
37 Concept of infinite line
38Condition for minimum distortion and minimum attenuation of signal on-the-
line and Introduction to loading methods.
39Concept of reflection and standing waves, definition of reflection coefficient,
SWR & VSWR and their relation (no derivation).
40 ---------------do -------------------
41 Concept of transmission lines at high frequencies.
42 Impedance matching, quarter wave transformer
43 Introduction to stubs. (single, open and short stubs).
44 revision of transmission line equation
45 3rd
Sessional Test
Repeat of any experiment12th
11th
Repeat of any experiment
Repeat of any experiment
The theory and practical part may be taken by a single faculty member or separately by 02 members as the case may be.
For instance, subject having 03 lectures per week as per curriculum will have 45 lecture days for 15 weeks of lesson plan.
Similarly, the practical days (may be of 02 hours/03 hours/ 04 hours duration) may be calculated per week and accordingly, lesson
plan is to be prepared for 15 weeks.
Draw the attenuation
characteristics of a crystal filte
Viva15th
14th
13th
Practical
Lecture
dayTopic (including assignment/ test) Topic
1Introduction about subject,AM/FM Transmitters ,Classification of
transmitters on the basis of modulation, service, frequency and power.
2 Block diagram of AM transmitters and working of each stage.
3Block diagram and working principles of reactance FET and armstrong FM
transmitters
4AM/FM Radio Receivers,Principle and working with block diagram of super
heterodyne AM receiver.
5Function of each block and typical waveforms at input and output of each
block.
6 Performance characteristics of a radio receiver.
7Sensitivity, selectivity, fidelity, S/N ratio,image rejection ratio and their
measurement procedure.
8 ISI standards on radio receivers.
9 Selection criteria for intermediate frequency (IF).
10 Concepts of simple and delayed AGC.
11 Block diagram of an FM receiver,
12Function of each block and waveforms at input and output,of different
blocks.
13 Need for limiting and de-emphasis in FM reception
14Block diagram of communication receivers, differences with respect to
broadcast receivers.
15 1st
Sessional
16 Antennas: Electromagnetic spectrum and its various ranges.
17 VLF, LF, MF, HF, VHF, UHF,Microwave.
18Physical concept of radiation of electromagnetic energy from a dipole.
Concept of Polarization of EM Waves.
19Definition and physical concepts of the terms used with antennas like point
source, gain directivity.
20Aperture, effective area, radiation pattern, beam width and radiation
resistance,loss resistance.
21Types of antennas-brief description, characteristics and typical applications
of half wave dipole, medium wave (mast) antenna.
22Types of antennas-brief description, characteristics and typical applications
of half wave dipole.
23Medium wave (mast) antenna, folded dipole, patch, loop antenna, yagi
and ferrite,rod antenna (used in transistor receivers).
24Brief description of broad-side and end fire arrays, their radiation pattern
and applications (without analysis).
Introduction about
Practical Communication
Systems
To observe the
waveforms at different
stages of a AM
transmitter
To observe the
waveforms at different
stages of a Radio
Receiver
To align AM broadcast
radio receiver
To identify and study the
various types of antennas
used in different
frequency ranges
To identify and study the
various types of antennas
used in different
frequency ranges
To plot the radiation
pattern of a directional
and omni directional
antenna
To plot the variation of
field strength of a
radiated wave, with
distance from a
transmitting antenna
Lesson Plan Duration : Jan-Apr-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture) 03 Hours per Group (PRACTICAL)
Specimen of lesson PlanName of the Faculty : Smt. Suchet Kumari
Discipline : Electronics and Communication Engg.
Semester : IVth
Subject : Communication Systems
3rd
2nd
WeekTheory
1st
7th
6th
4th
5th
8th
25 Brief idea about Rhombic antenna and dish antenna.
26 Propagation:Basic idea about different modes of wave propagation.
27 typical areas of application.Ground wave propagation.
28 characteristics of Ground wave propagation.
29 summer field equation for field strength.
30 2nd
Sessional Test
31Space wave communication – line of sight propagation, standard
atmosphere,
32concept of effective earth radius range of space wave propagation
standard atmosphere.
33 Duct propagation: sky wave propagation - ionosphere and its layers.
34 Explanation of terms -virtual height, critical frequency, skips distance.
35 maximum usable frequency, multiple hop Propagation.
36 Digital Modulation Techniques
37 Introduction of:PCM, DPCM
38 DELTA Modulation
39 Basic block diagram and principle of working of the following ASK.
40 Basic block diagram and principle of working of the following FSK.
41 Basic block diagram and principle of working of the following PSK, QPSK.
42 Spread Spectrum Techniques
43 Frequency Hopping Technique
44 Revision
45 3rd
Sessional Test
Revision & Viva
10th
11th
Revision & Viva
To plot the variation of
field strength of a
radiated wave, with
distance from a
transmitting antenna
Installation of Dish
Antenna for best
reception
To observe waveforms at
input and output of ASK
and FSK modulators
To observe waveforms at
input and output of ASK
and FSK modulators
Revision & Viva
* At least Three Assignment covering substantial portion of syllabus to be given.
13th
9th
14th
15th
12th
Practical
Lecture
day
Topic (including assignment/ test) Topic
1 Introduction about subject
2 Measurements: Importance of measurement, basic measuring systems.
3 Advantages and limitations of each measuring system.
4 Display devices
5 Theory of Transducers: construction and use of various transducers
6 Resistive transducers and wire wound potentiometer.
7 Capacitive transducers
8 Inductive transducers
9 Electromagnetic, piezo electric type transducer.
10 Measurement of Displacement and Strain: LVDT and RVDT transducer.
11 Strain gauges and Gauge factor, gauge materials and their selections.
12Use of electrical strain gauges their different types such as inductance
type resistive type, wire and foil type etc.
13 Strain gauge bridges and amplifiers.
14 Revision
15 Revision
16 1st
Sessional Test
17Force Measurement: Different types of force measuring devices and their
principles
18 Load cells
19load measurements by using elastic transducers and electrical strain
gauges.
20 Torque Measurement: Different types of torque measurement methods.
21 Measurements of torque by brake and dynamometer.
22 Speed measurements; different methods, devices.
23 Pressure Measurement
24 Bourdon pressure gauges
25Electrical pressure pickups and their principle construction and
applications.
26 Low pressure measurements and Use of pressure cells.
8th
9th
To measure linear
displacement using
LVDT
Specimen of lesson PlanName of the Faculty : Sh. Inderjeet Singh Dhindsa
Discipline : Electronics and Communication Engg.
Semester : IVth
Subject : Instrumentation
Week Theory
1st
5th
7th
4th
3rd
Lesson Plan Duration : Jan-Apr-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
To study the use of
electrical strain gauge
6th
2nd
Introduction about
Practical
Instrumentation
To measure the level of
a liquid using a
transducer
To measure
temperature using a
thermo-couple
Study and use of digital
temperature controller
Use of themistor in
ON/OFF transducer
Study of variable
capacitive transducer
Draw the characteristics
of a potentiometer
27 Revision
28 Revision
29 2nd
Sessional Test
30 Flow Measurement: Basic principles of magnetic flow meters.
31 Ultrasonic flow meters
32 Measurement of Temperature: Bimetallic thermometer.
33 Resistance thermometers
34 Thermisters
35 Thermocouple
36 Pyrometer
37 Temperature recorders
38Measurement of other non electrical quantities such as humidity
measurements.
39 pH value measurements
40 Level measurements
41 Vibrations measurements
42 Revision
43 Revision
44 Revision
45 3rd
Sessional Test
11th
12th
13th
9th
Revision & Viva
Revision & Viva
Revision & Viva
Revision & Viva14th
15th
* At least Three Assignment covering substantial portion of syllabus to be given.
To study the use of
electrical strain gauge
To study weighing
machine using load cell
To study pH meter.
10th
Practical
Lecture
day
Topic (including assignment/ test) Topic
1 Introduction about subject
2Logic Families,Logic family classification. TTL, ECL, MOS, CMOS. Types of
integration,SSI,MSI, LSI, VLSI.
3 Characteristics of TTL and CMOS and the comparison.
4Propagation delay.Speed, noise margin. Logic levels., power dissipation,
fan-in, fan-out,power supply requirements.
5Open collector and totem pole output circuits, operation of a standard
TTL.
6 Idea about CMOS, NAND, NOR gates.
7 CMOS to TTL interfacing and TTL to CMOS interfacing.
8 Introduction to tri-state devices, tri-state buffer and inverter circuits.
9A/D and D/A Converters,D/A Converters : Performance characteristics of
D/A converters.
10binary,resister network and resistance ladder network methods of D/A
converters,and applications.
11 A/D Converters
12 Performance characteristics of A/D converters.
13 Single,slope, dual slope,A/D converters.
14 Successive approximation and parallel A/D converters.
15 1st
Sessional Test
16 Basics of Memories
17 Memory organisation, classification of semi conductor memories, ROM.
18 PROM,DROM, EPROM, EEPROM.
19RAM, expansion of memory. CCD memories,content addressable memory,
programmable logic devices, PROM at PLD.
20 programmable logic array (PLA)
21 programmable array logic (PAL), field,programmable gate array (FPGA).
22 familiarization with common ICs.
23 Combinational Circuits
24 Minimization of Boolean expressions using Quine Mcclaaskey method.
25 Minimization of Boolean expressions using Quine Mcclaaskey method.
26 Minimization of Boolean expressions using Quine Mcclaaskey method.
27 Minimization of Boolean expressions using Quine Mcclaaskey method.
28 Revision
Verify the operation of
D/A converter
3rd
Week Theory
1st
4th
Verify the writing and
reading operation of RAM
IC
Introduction about
Practical of Digital
Electronics
Verify the operation of
A/D converter
Design J-K Flip-flop
counter and verify its
truth table
Familiarity with the use of
EPROM programmes and
UV index
Exercise on programming
of EPROM
8th
9th
10th
6th
7th
5th
2nd
Specimen of lesson PlanName of the Faculty : Sh. Ravinder Punia
Discipline : Electronics and Communication Engg.
Semester : IVth
Subject : DIGITAL ELECTRONICS - II
Lesson Plan Duration : Jan-Apr-2018
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecture)03 Hours per Group (PRACTICAL)
Design and implement full
adder and full subtractor
Verify the logical
operation, arithmetic
operation of binary
numbers using IC74181
Verify the logical
operation, arithmetic
operation of binary
numbers using IC74181
29 Revision
30 2nd
Sessional Test
31 Essential components of sequential circuit.
32 Synchronous and asynchronous,sequential circuits.
33 Classification of sequential circuits (Meely and Moore Machine).
34 Design of counters using J-K
35 Design of counters using R-S flip-flops.
36 Arithmetic and Logic Unit,Basic idea about arithmetic logic uni.
37 IC 74181 and applications.
38 Implementation of binary multiplication, division.
39 Implementation of binary subtraction and addition.
40 Introduction to Fuzzy logic
41 Fuzzy sets and classical sets and their operations.
42 Fuzzy relations, Properties of membership functions.
43 Fuzzification, Defuzzfication, Fuzzy control system.
44 Revision
45 3rd
Sessional Test
Revision & Viva
15th
12th
13th
10th
11th
* At least Three Assignment covering substantial portion of syllabus to be given.
Revision & Viva
Revision & Viva
Verify the logical
operation, arithmetic
operation of binary
numbers using IC74181
Revision & Viva
Revision & Viva
14th
Practical
Lecture
day Topic (including assignment/ test) Topic
1 Introduction about subject
2 Evolution of Microprocessor
3Typical organization of a microcomputer system and functions of its
various blocks
4 Microprocessor, its evolution, function and impact on modern society
5Architecture of a Microprocessor (With reference to 8085
microprocessor)
6 Concept of Bus, bus organization of 8085,
7 Functional block diagram of 8085 and function of each block,
8 Pin details of 8085 and related signals
9Demultiplexing of address/data bus,generation of read/write control
signals,
10 Steps to execute a stored programme
11 Instruction Timing and Cycles
12 Instruction cycle, machine cycle
13 T-states, Fetch and execute cycle.
14 8085 instruction
15 8085 instruction
16 8085 instruction
17 8085 instruction
18 8085 instruction
19 8085 instruction
20 1st
Sessional Test
21 8085 instruction
22 8085 instruction
23 8085 instruction
24Stack, I/O and Machine Control Group. Programming exercises in
assembly language. (Examples can be taken from the list of
experiments).25 Memories and I/O interfacing
26 Concept of memory mapping
27 partitioning of total memory space
28 Address decoding
29 concept of peripheral mapped I/O and memory mapped I/O .
30 concept of peripheral mapped I/O and memory mapped I/O .
31 Interfacing of memory mapped I/O devices
32 Interfacing of memory mapped I/O devices
33 Proogramming exercise of 8085
34 Proogramming exercise of 8085
35 Proogramming exercise of 8085
36 Proogramming exercise of 8085
37 Proogramming exercise of 8085
38 Proogramming exercise of 8085
39 Proogramming exercise of 8085
40 2nd
Sessional Test
41Interrupts, Maskable and non-maskable, Edge triggered and level
triggered interrupts,
42 Software interrupt, Restart interrupts and its use,Various hardware
interrupts of 8085
lesson PlanName of the Faculty : Sh. Rajinder Dahiya
Discipline : Electronics and Communication Engg.
Semester : Ivth
Subject : MICROPROCESSORS AND PERIPHERAL DEVICE
Lesson Plan Duration : Jan-Apr-2018
Interfacing exercise on 8253
programmable interval timer
Interfacing exercise on 8279
programmable KB/display
interface like to display the
hex code of key pressed on
display
Familiarization of different
keys of 8085 microprocessor
kit and its memory map
Familiarization of different
keys of 8085 microprocessor
kit and its memory map
7th
Writing and execution of ALP
for arranging 10 numbers in
ascending/descending order
4th
5th
Work Load (Lecture/ Practical) per week (in hours): 03 HOURS (Lecturer)
3rd
Steps to enter, modify
data/program and to execute
a programme on 8085 kit
Writing and execution of ALP
for addition and sub station
of two 8 bit numbers
6th
Writing and execution of ALP
for multiplication and division
of two 8 bit numbers
Introduction about Practical
Week
Theory
1st
2nd
8th
9th
10th
11th
Writing and execution of ALP
for 0 to 9 BCD counters
(up/down counter according
to choice stored in memory)
Interfacing exercise on 8255
like LED display control
43 Various hardware interrupts of 8085
44 RIM and SIM instruction
45 Priority interrupt controller
46 Data Transfer Techniques : sync data transfer, async data transfer
(hand shaking),
47 Interrupt driven data transfer
48 DMA, Serial output data, Serial input data
49 Peripheral devices : 8255 PPI
50 8255 PPI
51 8255 PPI
52 8253 PIT
53 8257 / 8237 DMA controller
54 8251 Communication Interface Adapter
55 8279 Programmable KB/Display Interface
56 8279 Programmable KB/Display Interface
57 Revision
58 Revision
59 Revision
60 3rd
Dessional
The theory and practical part may be taken by a single faculty member or separately by 02 members as the case may be.
For instance, subject having 03 lectures per week as per curriculum will have 45 lecture days for 15 weeks of lesson
plan. Similarly, the practical days (may be of 02 hours/03 hours/ 04 hours duration) may be calculated per week and
accordingly, lesson plan is to be prepared for 15 weeks.
Interfacing exercise on 8279
programmable KB/display
interface like to display the
hex code of key pressed on
display
Use of 8085 emulator for
hardware testing
Test & Viva
Test & Viva14th
15th
12th
Test & Viva
11th
13th