Lesson Plan Name of the Faculty - rpsinstitutions.org SEM ECE_1.pdf · Lesson Plan Name of the...
Transcript of Lesson Plan Name of the Faculty - rpsinstitutions.org SEM ECE_1.pdf · Lesson Plan Name of the...
Lesson Plan
Name of the Faculty : Mr. Sandeep Kumar (Theory)
Discipline : B.TECH (ECE )
Semester : 6th
semester
Subject : VLSI Design
Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load( lecture/Practical) Per Week(in hours): Lectures-04, Practical-00
WEEK Theory Practical
Lecture Day Topic(including
assignment/test)
Practical Day Topic
1st 1
st Introduction to VLSI
2nd
Basic Mos Transistor
3rd
Enhancement mode
4th
Depletion mode
2nd
5th
Fabrication
6th
NMOS Fabrication
7th
PMOS Fabrication
8th
CMOS Fabrication
3rd
9th
BiCMOS
Fabrication
10th
NMOS transistor
current equation
11th
Second order effects
12th
MOS Transistor
Model
4th 13
th Class test -1
14th
Introduction to
NMOS Inverter
15th
Introduction to
CMOS Inverter
16th
Introduction to Gates
5th 17
th Determination of
pull up ratio
18th
Determination of
pull down ratio
19th
Stick diagram
20th
Lamda based rules
6th 21
st Super buffers
22nd
BiCMOS logic
23rd
Steering logic
24th
Introduction to Sub
System Design
7th 25
th Layout of Sub
System Design
26th
Structured design of
combinational
circuits
27th
Dynamic CMOS
28th
Examples of Sub
System Design
8th 29
th Class Test -2
30th
Clocking
31st Introduction to Tally
circuits
32nd
NAND-NAND
Tally circuits
9th 33
rd
NOR-NOR Tally
circuits
34th
AOI logic
35th
EXOR structure
36th
Multiplexer
structures
10th 37
th Barrel shifter
38th
Introduction to
Design of
Combinational
Elements
39th
Introduction to
Regular Array Logic
40th
NMOS PLA
11th 41
st Programmable Logic
Devices
42nd
Finite State Machine
43rd
PLA
44th
Introduction to
FPGA
12th
45th
Examples of Tally
Circuits
46th
Introduction to
VHDL Programming
47th RTL Design
48th
Class test-3
13th 49
th Combinational logic
50th
Data types
51st Operators
52nd
Packages
14th 53
rd Sequential circuit
54th
Sub-programs
55th
Test benches
56th
Examples: address
15th 57
th VHDL programming
counters
58th
VHDL programming
flipflops
59th
FSM
60th
VHDL programming
of Multiplexers /
De-multiplexers
Lesson Plan
Name of the Faculty : Mr. Sandeep (Theory and Practical)
Discipline : B.TECH (ECE)
Semester : 6th
semester
Subject : Control System Engineering
Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load (Lecture/Practical) per week (in hours) : Lecture – 04, Practical-01
WEEK Theory Practical
Lecture Day Topic(including
assignment/test)
Practical Day Topic
1st 1
st System/Plant
model
1st To study speed
Torque
characteristics of
A.C. servo motor 2
nd Types of models
3rd
Illustrative
examples of
plants
4th
And their inputs
and outputs
2nd
5th
Controller servo
mechanism
2nd
To study speed
Torque
characteristics of
DC servo motor 6
th Regulating
system,
7th
Linear time-
invariant (LTI)
System
8th
Time-varying
system
3rd
9th
Causal system 3rd
To demonstrate
simple motor
driven closed
loop DC position
control
system
10th
Closed loop
control system
11th
Open loop
control system
12th
Illustrative
examples of
open-loop control
system
4th 13
th Class Test-1 4
th To study and
demonstrate
simple closed
loop speed
14th
Feedback control
systems
Continuous time
data control
systems
control system
15th
Sampled data
control
systems
16th
Effects of
feedback on
sensitivity (to
parameter
variations)
5th 17
th Stability 5
th To study the
lead, lag, lead-
lag compensators
and to draw their
magnitude and
phase plots
18th
External
disturbance
(noise)
19th
Overall gain
20th
Introductory
remarks about
non-linear control
systems
6th 21
st Concept of
transfer function
6th
To study a
stepper motor &
to execute
microprocessor
or computer-
based control
of the same by
changing number
of steps,
direction of
rotation & speed
22nd
Relationship
between transfer
function
and impulse
response
23rd
Order of a system
24th
Block diagram
algebra
7th 25
th Signal flow
graphs : Mason’s
gain formula
& its application
7th
To implement a
PID controller
for temperature
control of a pilot
plant 26th
Characteristic
equation
27th
Derivation of
transfer functions
of electrical
system
28th
Derivation of
transfer functions
of
electromechanical
systems
8th 29
th Class test -2 8
th To study
behavior of 1
order,2 order
type 0,type 1
system
30th
Transfer
functions of
cascaded and
non-loading
cascaded
elements
31st Introduction to
state variable
analysis
32nd
Introduction to
state variable
design
9th 33
rd
Typical test
signals
9th
To study control
action of light
control device 34th
Time response of
first order
systems to
various
standard inputs
35th
Time response of
2nd order system
to step input
36th
Relationship
between location
of roots of
characteristics
equation
10th 37
th Time domain
specifications of a
general an under-
damped 2nd
order
system
10th
To study water
level control
using a industrial
PLC
38th
Steady state error
and error
constants
39th
Dominant closed
loop poles
40th
Concept of
stability
11th 41
st Pole zero
configuration and
stability
11th
To study motion
control of a
conveyor belt
using a industrial
PLC 42
nd Necessary and
sufficient
conditions for
stability
43rd
Class Test-3
44th
Root locus
concept
12th 45
th
Development of
root locus for
various systems
46th
Stability
considerations
47th Hurwitz stability
criterion
48th
Routh stability
criterion
13th 49
th Relationship
between
frequency
response and
time-response for
2nd order system
50th
Polar, Nyquist
and Bode plots
51st Stability
52nd
Gain-margin and
Phase Margin
14th 53
rd Relative stability
54th
Frequency
response
specifications
55th
Necessity of
compensation and
compensation
networks
56th
Application of
lag and lead
compensation
15th 57
th Basic modes
of feedback
control,
proportional,
integral and
derivative
controllers
58th
Synchros, AC
and DC techo-
generators
59th
Servomotors,
stepper motors &
their applications
60th
Magnetic
amplifier
Lesson Plan
Name of the Faculty : Mr. Pawan Kumar (Theory and Practical)
Discipline : B.TECH (ECE)
Semester : 6th
semester
Subject : Digital System Design
Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical – 01
WEEK Theory Practical
Lecture Day Topic(including
assignment/test)
Practical Day Topic
1st 1
st Introduction to
Computer-aided
design tools for
digital systems
1st Design all gates
using VHDL
2nd
Hardware
description
Languages;
introduction to
VHDL data
objects
3rd
Data Classes
4th
data types
2nd
5th
Operators 2nd
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
a. half adder
b . full adder
6th
Overloading
7th
Types of delays
8th
Syntax of VHDL
model
3rd
9th
Entity 3rd
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
a. multiplexer
10th
Architecture
declaration
11th
Introduction to
behavioral
12th
Dataflow models
b. demultiplexer
4th
13th
Structural
models
4th
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
a. decoder
b. encoder
14th
Class test -1
15th
Assignment
statements
16th
Sequential
statements
5th
17th
Process
statement
5th
Write a VHDL
program for a
comparator and
check the wave
forms and the
hardware
generated
18th
Conditional
Statements
19th
Case statement
20th
Array
6th
21st loops 6
th Write a VHDL
program for a
code converter
and check the
wave forms and
the
hardware
generated
22nd
Packages
23rd
Libraries
24th
Concurrent
instantaneous
7th
25th
Concurrent
Statements
7th
Write a VHDL
program for a
FLIP-FLOP and
check the wave
forms and the
hardware
generated
26th
Functions
27th
Resolution
functions
28th
Example of
subprogram
8th
29th
Procedures 8th
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
a. register
b. shift register
30th
Generics
31st Component
Declaration
32nd
Structural layout
9th
33rd
Class test-2 9th
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
for
Asynchronous
counter
34th
VHDL code for
Multiplexers
35th
VHDL code for
Demultiplexers
36th
VHDL code for
Half adder and
Full adder
10th
37th
VHDL code for
encoders
10th
Write VHDL
programs for the
following
circuits, check
the wave forms
and the
hardware
generated
for Synchronous
counter
38th
VHDL code for
decoders
39th
VHDL code for
code converters
40th
VHDL code for
BCD seven
segment
11th
41st VHDL code for
magnitude
Comparators
42nd
Implementation
of Boolean
functions
43rd
VHDL Models
and Simulation
of Sequential
Circuits
44th
VHDL code of
sequential
circuit using
Block statement
12th
45th
VHDL code for
FLIP FLOP
46th
VHDL code for
Shift Registers
47th
VHDL code for
Asynchonous&
synchronous
Counters
48th
Class test-3
13th
49th
Basic
components of a
computer,
specifications
50th
Architecture of a
simple
microcomputer
system
51st Implementation
of a simple
microcomputer
system using
VHDL
52nd
ROM
14th
53rd
PLAS
54th
PALS
55th
Gal
56th
PEEL
15th
57th
CPLD
58th
FPGA
59th
Design
implementation
using
CPLDS
60th
Design
implementation
using FPGAS
Lesson Plan
Name of the Faculty : Mr. Dinesh KumarYadav (Theory and Practical)
Discipline : B.TECH (ECE)
Semester : 6th
semester
Subject : MICROWAVE AND RADAR ENGINEERING
Lesson plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical – 01
WEEK Theory Practical
Lecture Day Topic(including
assignment/test)
Practical Day Topic
1st 1
st Introduction to
Radar.
1st Study of wave
guide
components 2nd
Comparison with
transmission
lines
3rd
Propagation in
TE
4th
Propagation in
TM mode
2nd
5th
rectangular wave
guide
2nd
To measure
frequency of
microwave
source and
demonstrate
relationship
among guide
dimensions, free
space wave
length and guide
wavelength.
6th
TEM mode in
rectangular wave
guide
7th
Characteristic
impedance
8th
Introduction to
circular
waveguides
3rd
9th
Planar
transmission
lines
3rd
To measure
VSWR of
unknown load
and determine its
impedance using
a smith chart
10th
Introduction to
microwave
components &
tubes
11th
Directional
couplers
12th
Tees
4th
13th
Hybrid ring 4th
Study of
characteristics of
Gunn oscillator
& Gunn diode as
modulated
source (PIN
modulation) and
determination of
modulation
depth
14th
Class test -1
15th
S -parameters
16th
Attenuators
5th
17th
Cavity resonators 5th
Study of
insulation &
coupling
coefficient of a
magic T &
coupling
coefficient and
directivity of a
directional
coupler
18th
Mixers
19th
Detector
20th
Matched Load
6th
21st Phase shifter 6
th Measurement of
attenuation of a
attenuator and
isolation,
insertion loss,
cross coupling
of an circulator
22nd
Wave meter
23rd
Ferrite devices:
Isolators
24th
Circulators
7th
25th
Limitation of
conventional
tubes
7th
Study of
waveguide horn
and its radiation
pattern and
determination of
the beam width
26th
Construction &
operation of
Klystron
amplifier
27th
properties of
Klystron
amplifier
28th
Reflex Klystron
8th
29th
Magnetron 8th
To study
working of MIC
Components like
Power Divider ,
Ring resonator ,
Filters &
Microwave
30th
TWT
31st BWO
32nd
Crossed field
amplifiers
Amplifier
9th
33rd
Class test-2 9th
To study
Measurement of
Guide
wavelength, Free
Space
wavelength. &
Concept
of reduction of
wavelength due
to substrate
material
34th
Introduction to
microwave solid
state devices &
measurements
35th
Varactor diode
36th
Tunnel
diode
10th
37th
Schottky diode 10th
Measurement of
SWR in a
Microwave
transmission line
38th
GUNN diode,
39th
IMPATT
40th
TRAPATT
Diodes
11th
41st PIN diodes
42nd
MASER
43rd
Parametric
amplifiers
44th
Power
measurement
using calorimeter
12th
45th
bolometers
measurement of
SWR,
frequency
46th
Wavelength and
impedance
47th
Microwave
bridges
48th
Class test-3
13th
49th
RADAR (history
of radar)
50th
Block Diagram
and operation of
radar
51st Radar
Frequencies
52nd
Simple form of
Radar Equation
14th
53rd
Prediction of
Range
54th
Factor affecting
of radar
55th
Types of radar.
56th
Performance of
radar
15th
57th
Pulse Repetition
frequency
58th
Range
Ambiguities
59th
Numericals
based on radar.
60th
Applications of
Radar
Lesson Plan
Name of Faculty : Mr. Pankaj Soni (Theory and Practical)
Discipline : B.Tech(ECE)
Semester : 6th
Semester
Subject : Microcontroller & Embedded Systems
Lesson Plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical – 01
Week Theory Practical
Lecture
Day
Topic ( including
Assignment/ Topic)
Practical
Day
Topic
1st 1
st Introduction to
microcontrollers
1st To study
development
tools/environment
for ATMEL/PIC
microcontroller
program and
Architecture.
2nd
Microcontroller architecture
3rd
Microcontroller memory types
4th
Microcontrollers
Features
2nd
5th
Microcontrollers
Features continued..
2nd
Write an ALP to
generate square of
10Khz using Timer
0.
6th
PIC microcontrollers
7th
Addressing modes
8th
Addressing modescontinued..
3rd
9th
CPU registers
3rd
Write an ALP to
display a string on
LCD. 10th
Instruction set
11th
Instruction setcontinued…
12th
Assignment 1 on CPU
Registers
4th
13th
Microcontroller 8051
Architecture/ Introduction
4th
Write an ALP to
interface seven
segment with 8051
and display 0-9 on it. 14th
Microcontroller 8051 Pin
diagram
15th
Class Test 1
16th
Microcontroller 8051 Internal
RAM and registers
5th
17th
Interrupts 5th
Write an ALP to
interface DC Motor
with 8051
18th
Microcontroller 8051 I/o ports
19th
Addressing modes
20th
Addressing modes continued
6th
21st Memory Organization and
External
Addressing
6th
Write an ALP to
transmit the data
using P1 of 8051 22
nd Register Mode
23rd
Direct Mode
24th
Indirect Mode
7th
25th
Immediate Mode 7th
Write an ALP to
interface 4x4
keyboard with 8051.
26th
Indexed addressing modes
27th
Assignment 2 on
Addressing Modes of
8051
28th
Real Time Applications of
Microcontroller
8th
29th
Interfacing with LCD 8th
Write an ALP to
interface
temperature sensor
using 8051
30th
Interfacing with DAC
31st Class Test 2
32nd
Interfacing with STEPPER
MOTOR
9th
33rd
Interfacing with KEYBOARD 9th
Write an ALP to
interface the lcd
16x2 to P16f877A
34th
Interfacing with SENSORS
35th
Interfacing with
ACTUATORS
36th
Interfacing with Memory
10th
37th
Interfacing with ADC 10th
Write an ALP to
Generate square
wave P16f877A
38th
Classification of Embedded
Systems
39th
Software
Embedded into System
40th
Tools used for ALP
11th
41st KIEL Software
42nd
Proteus Software
43rd
Assignment 3 on
Classification of
Embedded Systems
44th
Applications and Products of
Embedded Systems
12th
45th
Application in Telecom /
Smart Cards
46th
Missiles and Satellites
47th
Application in Computer
Networking
48th
Class Test 3
13th
49th
Application in Digital
Consumer Electronics, and
Automotive
50th
Structure of Processor
51st Memory data register
52nd
Memory address
register
14th
53rd
Bus Interface Unit
Program Counter or
Instruction Pointer
54th
Stack Pointer
Registers
55th
Assignment 4 on
Memory Registers
56th
Case Study of an Embedded
System for a Smart Card
15th
57th
Smart Card System
Requirements
58th
Classes and class
diagram
Hardware Architecture
59th
Software Architecture
60th
Smart OS RTOS used as
alternative to
MUCOS
Lesson Plan
Name of Faculty : Mr. Sarjender Yadav (Theory)
Discipline : B.Tech(ECE)
Semester : 6th
Semester
Subject : Computer Networks
Lesson Plan Duration : 15 Weeks (from January, 2018 to April, 2018)
Work Load (Lecture/Practical) per week (in hours): Lectures -04, Practical – 00
Week Theory Practical
Lecture
Day
Topic ( including
Assignment/ Topic)
Practical
Day
Topic
1st 1
st Introduction to Computer
Networks
2nd
Example networks ARPANET
3rd
Internet, Private Networks
4th
Network Topologies: Bus-,
Star-, Ring
2nd
5th
Ring-, Hybrid -, Tree
6th
Complete -, Irregular –
Topology
7th
Types of Networks : Local
Area Network
8th
Metropolitan Area Networks
3rd
9th
Wide Area Networks
10th
Layering architecture of
networks, OSI model
11th
Functions of each layer
12th
Services and Protocols of each
layer
4th
13th
Introduction, History of
TCP/IP
14th
Layers of TCP/IP, Protocols
15th
Internet Protocol,
Transmission Control Protocol
16th
User Datagram Protocol, IP
Addressing
5th
17th
IP address classes
18th
Subnet Addressing
19th
Internet Control Protocols,
20th
ARP, RARP
6th
21st ICMP, Application
22nd
Domain Name System, Email
– SMTP
23rd
POP,IMAP; FTP
24th
NNTP, HTTP
7th
25th
Overview of IP version 6
26th
Introduction to LANs
27th
Features of LANs
28th
Components of LANs
8th
29th
LAN Standards
30th
Usage of LANs
31st IEEE 802 standards
32nd
Channel Access Methods
9th
33rd
Aloha
34th
CSMA, CSMA/CD
35th
Token Passing, Ethernet
36th
Layer 2 & 3 switching
10th
37th
Fast Ethernet
38th
Gigabit Ethernet
39th
Token Ring
40th
Hubs, Switches, Bridges
11th
41st Routers, Gateways
42nd
Introduction of WANs
43rd
Routing, Congestion Control
44th
WAN Technologies
12th
45th
Distributed Queue Dual Bus
(DQDB)
46th
Synchronous Digital
Hierarchy (SDH)
47th
Synchronous Optical Network
(SONET)
48th
Asynchronous Transfer Mode
(ATM)
13th
49th
Frame Relay.,
50th
Wireless Links.
51st Remote Monitoring
Techniques: Polling
52nd
Traps
14th
53rd
Performance Management
54th
Class of Service
55th
Quality of Service
56th
Security management,
Firewalls
15th
57th
VLANs, Proxy Servers
58th Introduction to Network
Operating System
59th Client-Server infrastructure
60th Windows NT/2000