| S No |
Laboratory Name |
Room No |
Laboratory Incharge |
Contact Details |
Technician Incharge |
| 1 |
Measurements Laboratory |
R-005 |
Dr.S.V.Aswin Kumar |
svaswin@kluniversity.in |
Mrs.K.M.Kamala
Mr. Dibba Raju |
| 2 |
Electronic Devices Laboratory |
R-104 |
Dr.T.Ramakrishna |
ramakrishnaece@kluniversity.in |
Mr. sk.Noor Kamili
Mr. K. Sandeep |
| 3 |
Analog and Digital Communications Laboratory |
R-105 |
Dr Kumar Naik |
kumarnaik@kluniversity.in |
Mrs.V Satyavathi
Mrs.K Rajani |
| 4 |
VLSI Design Laboratory |
R-106 |
Dr.S.Vamsee Krishna |
vamseekrishna@kluniversity.in |
Mr.M.Ygundar
Mr.C.H.Vijay Babu |
| 5 |
Signal Processing Laboratory |
R-204 |
Mr.N.Suresh |
namgirisuresh@kluniversity.in |
Mrs.K.Parvathi
Mr.B.Vijaya Bhaskar |
| 6 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
Dr Aravind Kilaru |
aravind.kilaru@kluniversity.in |
Mr.G.Danaiah |
| 7 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Dr.I.Govardhani |
govardhanee_ec@kluniversity.in |
Mrs.V.Padmasri |
| 8 |
Embedded and IoT Laboratory |
R-207 |
Dr.S. Arun Metha |
sarunmetha@kluniversity.in |
Mr.Syed Abid |
| 9 |
Data Networks and Protocols Laboratory |
R-304A |
Dr.R Revathi |
rrevathi@kluniversity.in |
Mr.B.Koteswara Rao |
| 10 |
Computer Center |
R-304B |
Dr.R Revathi |
rrevathi@kluniversity.in |
Mr.Kasim Raju |
| 11 |
National Instruments Center of Excellence |
R-604A |
Dr.M.Sujatha |
sujakarthik77@kluniversity.in |
Mr.B.Ragavendra |
| 12 |
Robotics & Automation Laboratory |
R-604B |
Dr. S. Rooban |
rooban@kluniversity.in |
Mr.B.Ragavendra |
| Activities |
| S.No |
Name of the Laboratory |
Room No |
Subject Name |
S. No. |
Activities In Lab |
| 1 |
Measurements Laboratory |
R-005 |
Biomedical Electronics & IOT for Healthcare |
1 |
To study various leads for monitoring of electrocardiogram (ECG). |
| 2 |
Study of various leads and electrode position for monitoring of
electroencephalogram (EEG). |
| 3 |
Monitoring of Electroencephalogram (EEG) signal for different lobes. |
| 4 |
Design and simulate a Pacemaker Circuit and analyze output signals. |
| 5 |
Simulate the Hemodialysis Machine to filter the blood creatine. |
| 6 |
Simulate an Audiometry Instrument using a Standalone Board. |
| 7 |
Design a IoT Health Application to record the vital sign. |
| 8 |
Design a wearable device to monitor SPO2 and Heart Rate. |
| 9 |
Design and simulation of an Elderly Fall Detection circuit. |
| 10 |
Lab Project Execution and Review-1. |
| 11 |
Lab Project Execution and Review-2. |
| 12 |
Lab Project demonstrations. |
| 2 |
Measurements Laboratory |
R-005 |
Electronic Circuits for Medical Instrumentation |
1 |
Experiment to monitoring of Electrocardiogram (ECG) for bipolar limb
leads L1, L2 and L3. |
| 2 |
Experiment to monitoring of Electrocardiogram (ECG) for augmented
leads aVL, aVF and aVR. |
| 3 |
Experiment to monitoring of Electrocardiogram (ECG) for chest leads
V1-V6. |
| 4 |
Experimental simulation to study the performance of a bio-sensor. |
| 5 |
Experimental simulation to study the performance of a chemical
sensor. |
| 6 |
Experiment on Bio signal import and channel analysis. |
| 7 |
Measurement of pH and conductivity. |
| 8 |
Measurement of blood pressure using sphygmomanometer. |
| 9 |
Measurement of pulse-rate using Photo transducer. |
| 10 |
Design a Basic Instrumentation Amplifier on Breadboard and Test the
Unit. |
| 11 |
Design a Notch Filter in Breadboard to Remove 50 Hz Noise from
Acquired ECG Signal. |
| 12 |
Design and measure the CMRR , Input Impedance of a simple
differential biopotential amplifier. |
| 3 |
Signal Processing Laboratory |
R-204 |
Biomedical Signal and Image Processing |
1 |
Representation and analysis of fundamental bio-signals. |
| 2 |
Analysis of FFT and Inverse FFT of signals. |
| 3 |
Construction of Digital IIR Butterworth filter-LPF & HPF. |
| 4 |
Examining Digital IIR chebychev filter-LPF & HPF. |
| 5 |
Analysing Upsampling and downsampling of signals. |
| 6 |
Analyze the ECG signal using MATLAB. |
| 7 |
Analyze the EEG signal using MATLAB. |
| 8 |
Display of FFT(1-D & 2-D) of an biomedical image. |
| 9 |
Implementation of Image Intensity slicing technique for image
enhancement. |
| 10 |
Histogram analysis and Histogram Equalization of biomedical images. |
| 11 |
Binary & Gray Scale analysis of biomedical images. |
| 12 |
Edge detection in gray scale biomedical images. |
| 4 |
Electronic Devices Laboratory |
R-104 |
Analog Electronic Circuit Design |
1 |
Analyze BJT Transistor as Switch |
| 2 |
Analyze BJT Common base characteristic(Input and Output) |
| 3 |
Analyze Frequency response of BJT Amplifier in common emitter
configuration. |
| 4 |
Design Zener diode as Voltage regulator and transistor as voltage
regulator |
| 5 |
Design of Scalling Amplifer using LM741. |
| 6 |
Design of Active Low-Pass Filter and High-Pass Filter. |
| 7 |
Design of Active Band-Pass Filter. |
| 8 |
Design of Hartley Oscillator |
| 9 |
Design of Integrator |
| 10 |
Design of Comparator. |
| 11 |
Sine to Square Wave Converter |
| 12 |
Power BJT Switching With Speed-Up Capacitor |
| 5 |
VLSI Design Laboratory |
R-106 |
Analog VLSI Design |
1 |
Investigate the I-V characteristics of MOSFET |
| 2 |
Analyze the effect of substrate potential on the threshold voltage. |
| 3 |
Investigate the gain of a common source amplifier with resistive
load by varying the value of RL. |
| 4 |
Design and analyze the common gate amplifier with Resistive load |
| 5 |
Analyze the cascade amplifier with the parameters effecting the
gain. |
| 6 |
Design & analyze different current mirrors (Simple &Cascode) with
passive loads |
| 7 |
Design & analyze supply independent current mirrors. |
| 8 |
Design & analyze differential amplifier with passive load. |
| 9 |
Design & analyze of one stage operational amplifier. |
| 10 |
Investigate the high frequency response of CS amplifier. |
| 11 |
Analyze the noise effect of operational amplifiers. |
| 12 |
Design & analyze single balanced mixer. |
| |
List of Additional Experiments |
| 1 |
Design and analyze the common gate amplifier with active load |
| 2 |
Design and analyze the source follower with resistive load. |
| 3 |
Design and analyze the source follower with active load. |
| 4 |
Design & analyze differential amplifier with active load. |
| 5 |
Design & analyze the folded operational amplifier. |
| 6 |
Design & analyze the Two stage operational amplifier |
| 7 |
Investigate the high frequency response and analyze the noise effect
of cascode amplifier (CS-CG). |
| 8 |
Design & analyze double balanced mixer. |
| 6 |
VLSI Design Laboratory |
R-106 |
Low Power VLSI Design |
1 |
Realize the fundamental logic gates using CMOS-based PTL in cadence
virtuoso and calculate the PDP. |
| 2 |
Design and implement FFs with CMOS-based PTL using 90 nm and 45nm
technology with cadence virtuoso and calculate the PDP. |
| 3 |
Design and implement transmission gate-based combinational circuits
using 90 nm and 45nm technology with cadence virtuoso and calculate the
PDP. |
| 4 |
Design and verify the Sleep Transistor Technique with 45nm
technology using cadence virtuoso. |
| 5 |
Design and verify the Inverter Analysis Using Hspice Code. |
| 6 |
Design and verify Leakage Reduction Approaches for CMOS CS-Amplifier
with 45nm technology using cadence virtuoso. |
| 7 |
Design and verify the read and write operations of SRAM cell with
45/90 nm technology using cadence virtuoso. |
| 8 |
Design and plot the static (VTC) and dynamic characteristics of a
digital CMOS inverter with 45nm technology using cadence virtuoso. |
| 9 |
Design and plot the characteristics of a master-slave positive and
negative edge triggered registers based on multiplexers with 45nm
technology using cadence virtuoso. |
| 10 |
Design and Implementation of 16-Bit Carry Look Ahead Adder with 45nm
technology using cadence virtuoso. |
| 11 |
Design DRAM Memories with 45nm technology using cadence virtuoso. |
| 7 |
VLSI Design Laboratory |
R-106 |
VLSI Sub system Design and Design for Testability |
1 |
Design a Half adder using 90 nm technology and verify the circuit
using transient analysis. |
| 2 |
Design a Full Adder using 90 nm technology and verify the circuit
using transient analysis. |
| 3 |
Design a 2-Bit Ripple Carry Adder using 90 nm technology and verify
the circuit using transient analysis. |
| 4 |
Design a 2-Bit Carry Select Adder using 90 nm
technology and verify the circuit using transient analysis. |
| 5 |
Design a 2-Bit Carry Lookahead Adder using 90 nm
technology and verify the circuit using transient analysis. |
| 6 |
Design a 2-Bit Magnitude Comparator using 90 nm
technology and verify the circuit using transient analysis. |
| 7 |
Design 3-Bit LFSR using 90 nm technology and verify the circuit
using transient analysis. |
| 8 |
Verification of Basic logic gates using System Verilog Test Bench. |
| 9 |
Verification of Half/Full Adder Circuit using System Verilog Test
Bench. |
| 10 |
Verification of two bit Magnitude Comparator using System Verilog
Test Bench. |
| 11 |
Verification of Flip Flops using System Verilog Test Bench. |
| 12 |
Develop the system verilog code for LFSR and verify the
functionality of Test pattern generaation |
| 13 |
Develop and analyze the PODM and verify the functionality of Test
pattern generation |
| 8 |
Robotics & Automation Laboratory |
R-604B |
Introduction to Robotics |
1 |
Introduction to the SIMULINK toolboxes used for robot
implementation. |
| 2 |
Simulate forward kinematics of a Wheeled robot. |
| 3 |
Develop an inverse kinematics model for a robot and verify through
simulation. |
| 4 |
Design a Lane Keeping Assist robotic model with Lane Detection. |
| 5 |
Simulate a Traffic Light Negotiation System. |
| 6 |
Localization of robot with diffenrent environments. |
| 7 |
Develop a Collision Avoidance Assistance System. |
| 8 |
Develop a lane follower robot |
| 9 |
Develop a lane follower robot with obstacle avoidance. |
| 10 |
Design and analyse the Remote Control (USAR) |
| 11 |
Design and analyse Cruise Control System. |
| 12 |
Write a navigation program to respond to the sensor (stops when an
obstacle is detected or turns when a wall is touched). |
| 9 |
Robotics & Automation Laboratory |
R-604B |
Computer Vision Applications |
1 |
Perform basic Image Handling and processing operations on the image |
| 2 |
Perform basic of Image Processing Toolbox, Computer Vision Toolbox
and Medical Imaging Toolbox |
| 3 |
Perform Image Import, Processing, and Export using Image Processing
Toolbox |
| 4 |
Write a program for plotting the Histogram and Texture Analysis of 2
D signal/on the image |
| 5 |
Write a program to find the edge, line detector and corner detector
of different shape image |
| 6 |
Write a program to apply the different types of filters on image |
| 7 |
Write a program to calculate and analyze the feature extraction with
and without computer vision toolbox |
| 8 |
Write a program to compute the feature of 3 D signal/video signal |
| 9 |
Write a program to Classify the 3 D signal/video signal |
| 10 |
Write a program to texture Segmentation of a video signal |
| 11 |
Calibrate the camera and extract the intrinsic and extrinsic
parameters of the camera |
| 12 |
Write a program for predict/classify the image using deep learning
method |
| 10 |
Robotics & Automation Laboratory |
R-604B |
Advanced Robotics |
1 |
Introduction and study of Matlab wih various robotic tool boxes. |
| 2 |
Study of Robotic Arm (ABB). |
| 3 |
Interface the physical model of robotic arm to a computer for its
control. |
| 4 |
Develop an algorithm to move the robotic arm to 180 deg |
| 5 |
Develop an algorithm to move the robotic arm to 180 deg and return
back. |
| 6 |
Pick an object from the base level, lift it and put it back to the
base using the robotic arm. |
| 7 |
Develop a program to move an object from one place to another. |
| 8 |
Study of Fetch and Freight Robots. |
| 9 |
Design an optimized path for the robotic arm to move the object from
one place to another with energy consumption as the cost function. |
| 10 |
Moving an object from one place to another using the robotic arm
with the minimum distance travelled. |
| 11 |
Study of Cruise Control System. |
| 12 |
Robotic Soccer design and analysis. |
| 13 |
Design a Advanced Cruise Control System. |
| 14 |
Pick an object from the base level, lift it and put it back to the
base 90 degree in the clock wise direction using the robotic arm. |
| 15 |
Design of Service robots. |
| 16 |
Liquid spill detector and auto cleaner robot |
| 17 |
Design of Pancake flipper robot |
| 11 |
Robotics & Automation Laboratory |
R-604B |
Autonomous Vehicles & Automotive Electronics |
1 |
Study of various toolboxes required for Autonomous vehicle modeling. |
| 2 |
Autonomous Vehicle dynamics simulation. |
| 3 |
Position sensory systems in Autonomous Vehicles. |
| 4 |
Autonomous Vehicle sensor model based on Doppler effect. |
| 5 |
Analyze the Effect of uncertainty in the mobile robots. |
| 6 |
Perception filtering for Autonomous vehicule system. |
| 7 |
Bayesian method-based localiztion implementation. |
| 8 |
Design and analyse Kalman method-based estimation. |
| 9 |
PID controller to maintain the air-fuel ratio. |
| 10 |
Design and analyse wheel speed model. |
| 11 |
Modeling an Anti-Lock Braking System. |
| 12 |
Design Automatic window slider system |
| 12 |
Robotics & Automation Laboratory |
R-604B |
Autonomous mobile Robot systems |
1 |
Introduction to MATLAB software and tools related to autonomous
mobile robot. |
| 2 |
Design a single legged robot and verify the design by simulating it. |
| 3 |
Modeling a Running Robot. |
| 4 |
Study of centralization and decentralization |
| 5 |
Simulate and analyse the robot vacuum. |
| 6 |
Develop a frictionless navigation robot to move from one place to
another. |
| 7 |
Centralization wheeled robot swarms |
| 8 |
Simulate an Object Tracking System. |
| 9 |
Path Planning and Obstacle Avoidance with Nonholonomic Robots. |
| 10 |
Indoor Navigation and Exploration. |
| 11 |
Decentralization wheeled robot swarms |
| 12 |
Design and analysis of Advanced Solar Tracker. |
| 13 |
Develop a Security and Emergency System. |
| 14 |
Simultaneous localization and mapping (SLAM) based mapping for a
mobile robot |
| 15 |
Implementation of Multi-robot path planning |
| 16 |
Delivery service via unmanned aerial vehicle. |
| 17 |
Remote switch control for Smart Devices in mobile
Robot. |
| 18 |
Eye muscle controlled Wheelchair System to move forward and backward
directions. |
| 19 |
Simulator for autonomous mobile robot with flexibility to change
parameters according to the user. |
| 13 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Radiating System & Wave Propagation |
1 |
Determine the directive gain, directivity and beam solid angle of an
antenna. |
| 2 |
Analyse variations in radiation strength at a given distance from
the antenna with Antenna Trainer kit. |
| 3 |
Analyse variations in current strength at a given distance from the
antenna with Antenna Trainer kit. |
| 4 |
Plot the radiation pattern of small dipole antenna. |
| 5 |
Plot the radiation pattern of a Half wave dipole antenna. |
| 6 |
Plot the radiation pattern of a Broad side array. |
| 7 |
Plot the radiation pattern of an end-fire array. |
| 8 |
Perform the polarization test of antenna with Antenna Trainer kit. |
| 9 |
Analyse folded dipole antenna with Antenna Trainer kit |
| 10 |
Represent the field patterns of finite length dipole using EM tool. |
| 11 |
Determine the directivity of broad side array using MATLAB
programming. |
| 12 |
Determine the directivity of end-fire array using
MATLAB programming. |
| 13 |
Design a Six element optimized Yaggi Uda antenna Using MATLAB |
| 14 |
Radiation pattern of Binomial array using MATLAB |
| 14 |
Antennas and Microwave Engineering Laboratory |
R-205B |
RF Syatem Design |
1 |
Study of RF RLC circuit with lumped and Distributed elements. |
| 2 |
Study of scattering parameters of 2 port RF network |
| 3 |
Calculation of input impedance of an open circuited transmission
line |
| 4 |
Calculation of characteristic impedance of RLC circuit |
| 5 |
study of Transformation of scattering parameters to impedance
parameters |
| 6 |
Analysis of single stub to eliminate the impedance mismatch in a
transmission line |
| 7 |
Design of RF lowpass and High pass filters at desired RF
frequency |
| 8 |
Analyse Frequency response of bandpass and band stop type filters |
| 9 |
Design and analyse RF amplifier at 6GHz |
| 10 |
Inspect Small signal analysis on RF amplifiers |
| 11 |
Analyse of RF Oscillator at desired frequency |
| 12 |
Design and Analyse of RF multistage Amplifier |
| 15 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Microwave Engineering |
1 |
Study and Identify various Microwave components and instruments |
| 2 |
Measurement of scattering parameters of E-plane Tee |
| 3 |
Measurement of scattering parameters of H-plane Tee |
| 4 |
Study and measurement of scattering parameters of Magic Tee |
| 5 |
Measurement of scattering parameters of directional coupler |
| 6 |
Analyze the characteristics of reflex klystron |
| 7 |
Study and plot V - I characteristics of Gunn Diode |
| 8 |
Measurement of wave attenuation attenuation |
| 9 |
Analyze the VSWR of microwave by using
test bench |
| 10 |
Study and measurement of frequency of applied signal with microwave
test bench |
| 16 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Advanced Antenna Design for Wireless and 5G
Applications |
1 |
Design a rectangular patch antenna using EM tools and verify the
characteristics |
| 2 |
Design a Slot antenna using EM tools and verify the characteristics |
| 3 |
Design a Monopole antenna using EM tools and verify the
characteristics |
| 4 |
Design a Loop antenna using EM tools and verify the characteristics |
| 5 |
Design an Inverted-F antenna using EM tools and verify the
characteristics |
| 6 |
Design a Planar antenna using EM tools and verify the
characteristics |
| 7 |
Design a Slits antenna using EM tools and verify the characteristics |
| 8 |
Design a defected antenna using EM tools and verify the
characteristics |
| 9 |
Design an etched patch antenna using EM tools and verify the
characteristics |
| 10 |
Design smartphone antenna using EM tools and verify the
characteristics |
| 17 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Modern Radar systems & Navigational Aids |
1 |
To study and analyze Linear FM (LFM) pulse waveform |
| 2 |
To analyze Radar Link Budget |
| 3 |
Integration of Component RCS and to verify with the
complete RCS of a given target |
| 4 |
To create and plot an upsweep linear FM pulse waveform |
| 5 |
To analyze Sea Clutter Simulation for a Maritime Radar System |
| 6 |
To analyze Radar Network Coverage over Terrain |
| 7 |
Verifying the stealth design by RCS calculation. |
| 8 |
To detect a Target Using Stretch Processing |
| 9 |
To study and Simulating a Scanning Radar |
| 10 |
To verify the detection by varying the number of pulses required for
integration. |
| 11 |
To analyze Radar Scenario Clutter Simulation |
| 12 |
To Search and Track Scheduling for Multifunction Phased Array Radar |
| 13 |
To Study Adaptive Tracking of Manoeuvring Targets with Managed Radar |
| 14 |
To designing a Synthetic Aperture radar for a given specific
aperture. |
| 18 |
Antennas and Microwave Engineering Laboratory |
R-205B |
Satellite Design |
1 |
Case Study 1: Types of satellites which anyone can launch |
| 2 |
Case Study 2: Orbital perturbations and their effects |
| 3 |
Case Study 2: Launch and transfer orbits |
| 4 |
Case Study 3: Satellite Subsystems- Power subsystem |
| 5 |
Case Study 4: Types of payloads - requirements and specifications |
| 6 |
Case Study 4: Payload design considerations |
| 7 |
Case Study 4: Payload performance analysis and
testing |
| 8 |
Case Study 5: Structural Design and Analysis and Hands – on
Vibration and shock testing |
| 9 |
Case Study 6: Launch vehicle selection and integration |
| 10 |
Case Study 7 and Hands-on: Ground station design and operation |
| 11 |
Case Study 7 and Hands-on: Telemetry, tracking, and command
systems -Data processing and storage |
| 12 |
Case Study 8: Mission requirements and planning - Orbit maintenance
and manoeuvre planning |
| 13 |
Case Study 9 and Hands-on: CubeSat and SmallSat design
considerations |
| 14 |
Case Study 9 and Hands-on: Emerging technologies and future trends
in satellite design |
| 15 |
Case Study 9 and Hands-on: Case studies of successful and failed
satellite missions |
| 19 |
Data Networks and Protocols Laboratory |
R-304A |
Network Protocols and Security |
1 |
Introduction to the laboratory and the tool used Cisco packet tracer |
| 2 |
Basic switch setup using Huawei network switch |
| 3 |
Configure any topology using Huawei network switch |
| 4 |
Configure a switch to bridge two different networks. Observe how the
switch forwards frames between the two networks. |
| 5 |
Construct the straight through and cross over cable using colour
code in the ethernet cable and verify the connectivity |
| 6 |
Construction of Different VLANS and using Huawei network switch |
| 7 |
Basic Router setup using Huawei L3 network switch and Static Routing |
| 8 |
Configuration of RIP and OSPF using cisco packet tracer |
| 9 |
Configuration of Encapsulation dot 1Q using cisco packet tracer |
| 10 |
Configuration of VLAN trunking using Cisco packet tracer |
| 11 |
Configure a topology and analyse the PDU's for TCP and UDP
communications using cisco packet tracer |
| 12 |
Implementation of traffic congestion using cisco packet tracer |
| 13 |
Configuration of SMTP, DNS, HTTP in Cisco packet tracer |
| 14 |
Configuration of Network address translation in Cisco packet tracer |
| 15 |
Calculating and Performing Network Delay, Loss and Throughput in
Stream Control Transmission Protocol |
| 16 |
Implementation of RSA Algorithm |
| 17 |
Implementation of DES algorithm |
| 18 |
Implementation of Smart home using Cisco packet tracer |
| 19 |
Configuring simple network management protocol (SNMP) preferences. |
| 20 |
Configure network using distance vector routing protocol (RIPV1)
with NAT and PAT |
| 20 |
Data Networks and Protocols Laboratory |
R-304A |
TCP/IP and other Protocol suites |
1 |
Simulation of ARP in Cisco packet tracer |
| 2 |
Simulate and Implement Routing(OSPFv3) in a IPv6
network using cisco packet tracer |
| 3 |
Simulate and configure DHCPv6 to distribute IPv6 address in a subnet
suing cisco packet tracer |
| 4 |
Simulation of Dual Stack IPv4 and IPv6 configuration and testing in
cisco packet tracer |
| 5 |
Construct a small office network with two subnets in IPv4 and IPv6
and tunnel the traffic between the two subnets. |
| 6 |
Configuration of DHCP Server using Cisco packet tracer to assign IP
Address automatically |
| 7 |
Simulate DHCP Relay-Agent Configuration in Packet Tracer and verify
the functionality. |
| 8 |
Test various NAT traversal techniques, such as UPnP or
STUN to enable successful communication across the NAT
boundary. |
| 9 |
Implement network automation using DHCP client - server
configuration with a DHCP resolver for a small office network using
cisco packet tracer |
| 10 |
Configure the DHCPv6 server to delegate IPv6 prefixes to the client
router, allowing the router to dynamically assign IPv6 addresses to the
devices within its subnet. |
| 11 |
Set up a DNS server in Cisco Packet Tracer and configure basic DNS
zone records, such as A (Address) records and CNAME (Canonical Name)
records. |
| 12 |
Configure both forward and reverse DNS lookup zones on the DNS
server. |
| 13 |
Configure DNS caching on a DNS serverby enable caching of DNS
records to improve performance and reduce the load on the DNS server. |
| 14 |
Test the zone transfer functionality by updating a DNS record on one
server and verifying that the change propagates to the other DNS server. |
| 15 |
Configure a DNSSEC-enabled zone on the DNS server and test the
validation of DNSSEC signatures. |
| 16 |
Configure host devices in the network to send ICMPv6 Echo Request
(Ping) messages to other host devices and observe the ICMPv6 Echo Reply
messages. |
| 17 |
Simulate the NDP uses ICMPv6. Configure devices to
perform RS, RA, NS, and NA and examine the ICMPv6
messages. |
| 18 |
Simulate scenarios where ICMPv6 error messages are generated in
response to various IPv6 communication issues and analyse them. |
| 19 |
Configure devices to join and leave multicast groups and observe the
exchange of ICMPv6 Multicast Listener Discovery messages. |
| 20 |
Configure access control lists (ACLs) on routers to filter or block
specific ICMPv6 message types. |
| 21 |
Data Networks and Protocols Laboratory |
R-304A |
VoIP and Broadband networks |
1 |
Mated STP-Pair Configuration using cisco packet tracer |
| 2 |
Implementation of SIP trunking in IP telephoney networks using cisco
packet tracer |
| 3 |
Implementagtion of SS7 (Signaling System 7) is a signaling protocol
used in traditional telephony networks. |
| 4 |
Implementation of potential security vulnerabilities in SS7
signaling networks. |
| 5 |
Configuration Examples For SIP Out-of-Dialog OPTIONS Ping Group part
-1 |
| 6 |
Configuration Examples For SIP dial-in-Peers using CUBE |
| 7 |
Configuring RTCP Report Generation uinsg wireshark |
| 8 |
Configuring VoIP with Dial-Peer for Telephony Service |
| 9 |
Configuration of Network digram for GPON networks using cisco packet
tracer |
| 10 |
Anaysis of Downstream packet walk using wireshark |
| 11 |
Analysis of Upstream packet walk using wiresahrk |
| 12 |
Small Office Home Office/SOHO Network Design & Implementation
Project |
| 13 |
Verification if Quality of Service (QoS) in broadband access devices
using wireshark |
| 14 |
Conduct experiments to measure the actual bandwidth of different
broadband connections using tools like speed tests or network analyzers. |
| 15 |
Measurement the latency or delay in data transmission for various
broadband connections. |
| 16 |
Verification of coverage area of wireless broadband technologies
like Wi-Fi or cellular networks. |
| 17 |
SIP CALL FLOW Analyse&Troubleshooting in Wireshark |
| 18 |
Implementation of SIP basic call flow uisng wireshark |
| 19 |
Demonstrate SSL/TLS in action with Wireshark |
| 20 |
Troubleshoot TLS Handshake Failures using Wireshark |
| 22 |
Analog and Digital Communications Laboratory |
R-105 |
Digital communications |
1 |
Sampling theorem verification |
| 2 |
Sampling theorem verification |
| 3 |
Pulse amplitude modulation and demodulation |
| 4 |
Pulse amplitude modulation and demodulation in virtual lab |
| 5 |
Pulse width modulation and demodulation |
| 6 |
Pulse position modulation and demodulation |
| 7 |
Pulse code modulation |
| 8 |
Verification of large-scale fading -app |
| a.understanding the decibel measurement system |
| b.shadow lab app--gnu |
| 9 |
Differential pulse code modulation |
| 10 |
Delta modulation |
| 11 |
Amplitude shift keying(ask) generation,demodulation |
| 12 |
Monitoring 4g lte stations -wg |
| a.lte scanner-frequency need to be changed |
| b.capturing .dat file for python processing--gnu |
| 13 |
Frequency shift keying(fsk) generation,demodulation |
| 14 |
Phase shift keying generation |
| 15 |
Binary phase shift keying(bpsk) generation,demodulation |
| 16 |
Bit error rate measurement of bpsk |
| 17 |
Over-the-air transmission and reception of binary data using bpsk
modem |
| a. Deepradio, wi-guy(wg ip address to be entered in
exp35) and gnu radio (dr ip address to be entered) |
| 18 |
Matlab for QPSK data modulation |
| 19 |
Matlab for DPSK |
| 20 |
Verification of small-scale fading distribution -wg |
| |
a.autocorrelation of small-scale fading |
| 23 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
Wireless Communication |
1 |
To Monitor 2G, 3G, 4G Live Spectrum/Bands. |
| 2 |
To Monitor GSM stations and capturing .dat file for
python processing |
| 3 |
To Monitor 4G LTE stations and capturing .dat file for
python processing |
| 4 |
To Analyze Over-the-air transmission and reception of binary data
using BPSK Modem |
| 5 |
To verify large-scale fading and underatand Decibel
measurement system |
| 6 |
To verify AWGN channel distribution |
| 7 |
To verify small-scale fading distribution and
understanding Autocorrelation of small-scale fading |
| 8 |
To Analyze In spectrum and to capture and visualize GSM AND LTE
signals |
| 9 |
To Process GSM AND LTE signals, capture the .dat file from DR and
run the code in jupyter notebook |
| 10 |
To observe FM transmitter signals and understand
Demodulating the FM signals. |
| 11 |
To analyze Call flow/protocols in 4G cellular network using
Wireshark |
| 12 |
To Analyze Call flow/protocols in 5G cellular network using
Wireshark |
| 13 |
To Examine WLAN Protocol using WIRESHARK |
| 24 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
Radio Wave Propagations |
1 |
To Monitor 2G, 3G, 4G Live Spectrum/Bands. |
| 2 |
To Monitor GSM stations and capturing .dat file for
python processing |
| 3 |
To Monitor 4G LTE stations and capturing .dat file for
python processing |
| 4 |
To Analyze Over-the-air transmission and reception of binary data
using BPSK Modem |
| 5 |
To verify large-scale fading and underatand Decibel
measurement system |
| 6 |
To verify AWGN channel distribution |
| 7 |
To verify small-scale fading distribution and
understanding Autocorrelation of small-scale fading |
| 8 |
To Analyze In spectrum and to capture and visualize GSM AND LTE
signals |
| 9 |
To Process GSM AND LTE signals, capture the .dat file from DR and
run the code in jupyter notebook |
| 10 |
To observe FM transmitter signals and understand
Demodulating the FM signals. |
| 11 |
To analyze Call flow/protocols in 4G cellular network using
Wireshark |
| 12 |
To Analyze Call flow/protocols in 5G cellular network using
Wireshark |
| 13 |
To Examine WLAN Protocol using WIRESHARK |
| 25 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
4G Wireless Technologies and Cellular Communication |
1 |
Enabling 4G mobile network and registration of User Equipment. |
| 2 |
Analyzing User Equipment registration process in 4G mobile network. |
| 3 |
Analyzing PDN connectivity procedure in 4G mobile network. |
| 4 |
Analyzing registration process and authentication in
4G mobile network. |
| 5 |
Capturing of live LTE frames from the nearby mobile tower |
| 6 |
Capturing the LTE frames from 4G mobile network |
| 7 |
PSS and SSS generation using Python |
| 8 |
Extraction of 4G PSS, SSS, and PBSH signals using Python |
| 9 |
OFDM Transmission using Deep Radio |
| 10 |
Analysis and evaluation of PAPR |
| 11 |
Generation of 3GPP MIMO channel coefficients |
| 12 |
4G path loss model for UMi, Uma, SUMa, and RMa scenarios |
| 13 |
Distance estimation between UE and base station using Shadowlab App |
| 14 |
Coherence bandwidth and coherence time calculation with 3GPP channel
models |
| 15 |
Implementation of Milenage algorithm in Python |
| 16 |
Simulation of PRACH power control |
| 26 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
Modern Satellite Communications |
1 |
Build Scenarios |
| 2 |
Set the Satellite Propagator |
| 3 |
Design the Satellite Orbit |
| 4 |
Create a Pass Data Repor |
| 5 |
Display the Sun Vector |
| 6 |
Model the Satellite’s Camera |
| 7 |
Observing Solar Power Generation |
| 8 |
Create a Solar Panel Power Report & Graph |
| 9 |
Display the Moon Vector |
| 10 |
Build the Communication Link |
| 11 |
Add the Satellite Tracking Station |
| 12 |
Add the Ground Site’s Tracking Sensor |
| 13 |
Add the Ground Station Receiver |
| 14 |
Add the Spacecraft’s Tracking Sensor |
| 15 |
Adding the Spacecraft Transmitter (downlink) |
| 16 |
Compute Access Between the Transmitters and Receivers |
| 17 |
Generate a Link Budget Report |
| 18 |
Model Environmental Losses |
| 19 |
Modify the Modulator |
| 20 |
Create a Walker Constellation |
| 27 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
5G Wireless Technologies |
1 |
Enabling 5G mobile network and registration of User Equipment. |
| 2 |
Analyzing User Equipment registration process in 5G mobile network. |
| 3 |
Analyzing PDN connectivity procedure in 5G mobile network. |
| 4 |
Analyzing registration and authentication process in
5G mobile network. |
| 5 |
Capturing of live LTE frames from the nearby mobile tower |
| 6 |
Capturing the LTE frames from 5G mobile network |
| 7 |
Extraction of 5G PSS, SSS, and PBSH signals |
| 8 |
Simulation of LDPC coding |
| 9 |
Latency analysis for end-to-end system |
| 10 |
Simulation of uplink waveform design |
| 11 |
Simulation of downlink waveform design |
| 12 |
Simulation of PDSCH |
| 13 |
Live video streaming via 5G network |
| 14 |
Throughput calculation |
| 15 |
Energy detection-based spectrum sensing |
| 16 |
Simulation of PBCH |
| 17 |
Simulation of PUCCH |
| 18 |
TBS calculation |
| 28 |
5G & Beyond: Open Innovation Laboratory |
R-205A |
Machine Learning for Wireless Communications |
1 |
RF signal data collection Using Deep Radio and Wi-Guy-WG,DR,GNU |
| 2 |
Dataset generation using SDR |
| 3 |
Data pre-processing for ML and CNN |
| 4 |
Random Forest based RF signal classification |
| 5 |
Naive Bayes based RF signal classification |
| 6 |
KNN based RF signal classification |
| 7 |
Decision Tree based RF signal classification |
| 8 |
Support Vector Machine based RF signal classification |
| 9 |
CNN based RF signal classification |
| 10 |
LSTM RNN based RF signal classification |
| 11 |
Analysis of CNN model using testing dataset |
| 12 |
Analysis of CNN weight and bias, and feature maps |
| 13 |
OFDM channel estimation and detection using neural network |
| 29 |
Data Networks and Protocols Laboratory |
R-304A |
Cloud Computing and Network Security |
1 |
Installation of fusion compute using eNSP simulator |
| 2 |
Fusion compute resource configuration part-1 using eNSP simulator |
| 3 |
Configuring storage resources for using virtual machine’s |
| 4 |
Creating Virtual Machines to establish communication |
| 5 |
Configuring and Managing Virtual Networks |
| 6 |
Configure and test VM Desk Operations |
| 7 |
Configure and testing of DRS rule group for a cluster |
| 8 |
Configuring and testing of Availability considerations of VM |
| 9 |
Configuring and testing of Security groups |
| 10 |
Configuring and testing common O&M groups and functions |
| 11 |
Exercise Resource Management and Monitoring in VM's |
| 12 |
Exercise Patch Management in VM's |
| 13 |
Network configure Exercise using VM's |
| 14 |
Exercise Access of Virtualized Data Centre |
| 30 |
Data Networks and Protocols Laboratory |
R-304A |
IP Multimedia Subsystems and Emerging Technologies |
1 |
Introduction to Cisco Packet Tracer |
| 2 |
Implementation of SIP Session Establishment |
| 3 |
Implementation of IMS Presence using Cisco Packet Tracer |
| 4 |
Implementation of IMS call flow using Cisco Packet Tracer |
| 5 |
Implementation of RTP using Cisco Packet Tracer |
| 6 |
Implementation of RTCP using Cisco Packet Tracer |
| 7 |
Implementation of Web-mesaging call procedure using
Cisco Packet Tracer |
| 8 |
Implementation of IMS Security Cisco Packet Tracer |
| 9 |
Implementation of PSTN call procedure using Cisco
Packet Tracer |
| 10 |
Implementation of SIP Message Flows using Cisco Packet Tracer |
| 11 |
Implementation of IMS Multimedia Streaming using Cisco Packet Tracer |
| 12 |
Implementation of Web messages using Cisco Packet Tracer |
| 13 |
Implementation of VoLTE using Cisco Packet Tracer |
| 14 |
Implementation of IMS Call Control using Cisco Packet Tracer |
| 15 |
Implemnt and test the ability of the IMS network to stream
multimedia content, such as audio and video. |
| 16 |
Case study: Interoerrabilty of IMS networks |
| 31 |
Data Networks and Protocols Laboratory |
R-304A |
IT security : Defense against digital dark arts |
1 |
Capture and analyze network traffic to identify potential security
threats. |
| 2 |
Monitor network traffic to detect unauthorized devices or users. |
| 3 |
Implementation of Symmectric Key Cryptography using any software |
| 4 |
Implementation of Public Key Cryptography using any software |
| 5 |
Implementation of digital signatures using any software |
| 6 |
Configure a secure remote access solution, such as SSH (Secure
Shell) or SSL/TLS VPN.. |
| 7 |
Analyze SSL/TLS traffic to identify potential vulnerabilities or
misconfigurations. |
| 8 |
Configure and verify Firewall Configuration for a campus network |
| 9 |
Setup of Wi-fi security assistant using CPT or wireshark |
| 10 |
Perform a DNSSEC key rollover by generating new keys, updating the
DNSSEC records, and configuring the zone to use the new keys. |
| 11 |
Set up a DNS server and enable DNSSEC signing for a domain. |
| 12 |
Configure a site-to-site VPN between Site 1 and Site 3 |
| 13 |
Configure PAP and CHAP on a deveices for secure communciaiton using
cisco packet tracer |
| 14 |
Implememt differnet encryption techniques on a plain text and
analyze the level of security provided by it using any programming
language |
| 15 |
Configure a GRE tunnel using cisco packet tracer. |
| 16 |
Configure a wireless routers with WPA/WPA2/WPA3 using cisco packet
tracer. |
| 17 |
Construction of different topologies and verification of connetivity
between the devices. |
| 32 |
Data Networks and Protocols Laboratory |
R-304A |
Communication Networks |
1 |
Construction of two different topologies in hybrid mode and
establishing the connectivity between the devices using cisco packet
tracer |
| 2 |
Implementation of basic switch setup using cisco packet tracer. |
| 3 |
Establishment of VLANS and verification of connetivity between the
devices |
| 4 |
Creating Small Business Network with Network Switches, End users
configure and verify the connectives. |
| 5 |
Establishment VLAN trunking and verification of connetivity between
the devices |
| 6 |
Establishment of interVLAN cmmuncation using dot 1Q encapsualtion |
| 7 |
Implementation of basic Router setup and static routing using cisco
packet tracer. |
| 8 |
Implementation of RIP and verification of connectivity using cisco
packet tracer |
| 9 |
Implementation of OSPF and verification of connectivity using cisco
packet tracer |
| 10 |
Establishment of connectivity between wired and wireles networks |
| 11 |
Implementation of NAT and PAT using cisco packet tracer |
| 12 |
Verification of DHCP and SMTP unig cisco packet tracer |
| 13 |
Verification fo DNS and HTTP using Cisco packet tracer |
| 14 |
Implemnetation of smart home with wired and wireless netwoks |
| 15 |
Observe the TCP handshake process, including the three-way handshake
(SYN, SYN-ACK, ACK), and monitor the connection using Packet Tracer's
built-in tools. |
| 33 |
Data Networks and Protocols Laboratory |
R-304A |
Network Security |
1 |
Capture and analyze network traffic to identify potential security
threats or network attacks using wiresahrk |
| 2 |
Capture and analyze network traffic to identify
Malicious Traffic using Wireshark |
| 3 |
Implement basic firewall setup using cisco packet tracer |
| 4 |
Setting up Intrusion Detection and Prevention System (IDPS) using
cisco packet traacer |
| 5 |
Configuring Secure Shell (SSH) uisng cisco packet tracer |
| 6 |
Configure Web Server, DNS Server, HTTP, and HTTPS in Cisco Packet
Tracer |
| 7 |
Simulatate FTP server using Cisco Packet Tracer |
| 8 |
Configure IPsec VPN tunnel using cisco packet tracer |
| 9 |
Intercept and Prevent Server from DoS Attacks on Cisco Router |
| 10 |
Configuring Adaptive Ssecuirty Appliance Basic Settings and Firewall
Using CLI in cisco packet tracer |
| 11 |
Configuring Port Security using cisco packet tracer |
| 12 |
Configuring DHCP Snooping using packet tracer |
| 13 |
Implementing Role-Based Access Control (RBAC) using cisco packet
tracer |
| 14 |
Implementing Port Security and MAC Address Filtering using cisco
packet tracer |
| 15 |
Configuration of Dynamic and Static NAT using ACL on Cisco ASA
Firewall |
| 16 |
Implementation of Border Gateway Protocol(BGP) using Cisco Packet
tracer |
| 34 |
Data Networks and Protocols Laboratory |
R-304A |
Peer to Peer Networks |
1 |
Configure Peer-to-Peer Network with at least three hosts |
| 2 |
Create a Physical Network using Computers, Network Connecting
Devices and cables |
| 3 |
Draw the Network Layout with its Topology for Network set-up of your
Laboratory |
| 4 |
Establish a P2P network with devices equipped with voice/video
capabilities, such as PCs or smartphones and configure them for the
server network. |
| 5 |
Using a decentralized architecture construst an
unstructured P2P overlay network and connect multiple peers and
establish communication between them |
| 6 |
Simulate the process of peer discovery within the unstructured P2P
overlay networks. |
| 7 |
Configure the peers in the unstructured P2P overlay to support file |
| 8 |
Interpret the fault tolerance capabilities in node failures or
network partitions within the unstructured P2P overlay network |
| 9 |
Isimulate various P2P network decentralized or hybrid structure and
observe the impact on peer discovery, network resilience,
and scalability. |
| 10 |
Simualte and test network connectivity is restoration by introducing
network partitions within the P2P network |
| 11 |
Implement and test different security measures to understand their
impact on P2P network communication and protection against malicious
peer |
| 12 |
Configure NAT traversal in P2P networks to establish the
connectivity across NAT devices using cisco packet tracer. |
| 13 |
Configure peers r to join the overlay and observe how DHTs handle
key/value storage and lookup operations. |
| 14 |
Introduce varying loads on different peers within the structured P2P
overlay network and investigate the load balancing in the network |
| 15 |
Implement resource discovery mechanisms within the structured P2P
overlay network using cisco packet tracer |
| 16 |
Simulate the security mechanisms within the structured P2P overlay
network, such as authentication, authorization, and secure routing for
protection against malicious peers. |
| 35 |
Data Networks and Protocols Laboratory |
R-304A |
Wireless Local area networks |
1 |
Simulate a WLAN at its receptionof a netowrk ensure good internet
access experience for users. |
| 2 |
Trouble shooting of common faults such as Access Point(AP) join
faults, and other caused by incorrect configuration based on typical
acces control(AC) |
| 3 |
Set up multiple APs on different channels in close proximity. |
| 4 |
Configure different security mechanisms like WEP, WPA, or WPA2 on
the wireless network. |
| 5 |
Set up multiple wireless clients within the coverage area of an AP
and observe the exposed node problem, where one client refrains from
transmitting due to interference from another client, even though the AP
can handle both transmissions. |
| 6 |
Configure multiple virtual access points (VAPs) on a WLAN switch.
Set different SSIDs, security settings, and VLAN assignments for each
VAP. |
| 7 |
Set up WLAN switches in eNSP, configure basic settings such as SSID,
channel selection, and security parameters |
| 8 |
Configure various WLAN security mechanisms such as WEP, WPA, or WPA2
on the WLAN switches. |
| 9 |
Configure different modulation and coding schemes (MCS) in eNSP to
understand their impact on the data rate, range, and robustness of
wireless communication. |
| 10 |
Study the behavior of MAC layer protocols, such as Distributed
Coordination Function (DCF), Point Coordination Function (PCF), and
Hybrid Coordination Function (HCF). |
| 11 |
Set up multiple APs with overlapping coverage areas. Observe the
handover process as a wireless client moves between APs. |
| 12 |
Capture wireless packets using tools like Wireshark within eNSP. |
| 36 |
Embedded and IoT Laboratory |
R-207 |
Processor & Controllers |
1 |
Implement an 8086 Assembly language Program (ALP) to perform the
Arithmetic operations a) Addition b) Subtraction c) Multiplication d)
Division. |
| 2 |
Implement an 8086 ALP to find the POSITIVE & NEGATIVE numbers and
EVEN & ODD numbers in an array. |
| 3 |
Implement an 8086 ALP to Sort the Array of Numbers in ascending and
descending order |
| 4 |
Implement an 8051 ALP on the Addition of an array of elements of
8-bit data. |
| 5 |
Develop an 8051 a Bit/Byte Manipulations to Toggle a LED with random
delay (using Set, Clear, and Complement). |
| 6 |
Implement a Creating Patterns using 8 LEDs without Timers using 8051
microcontroller |
| 7 |
Develop 8051 ALP to perform the following |
| (i) to generate a square wave of frequency 5kHz on P2.3,
assume that XTAL=11.052 MHz. |
| (ii) to generate a square wave of frequency 5kHz with ON
time on P2.3 and OFF time on P3.3. Assume that XTAL=11.052 MHz (post
lab). |
| 8 |
Develop a system to Display Numbers using a 7-Segment Display and
Timers using 8051 microcontroller |
| 9 |
Interface 16X2 LCD to 8051 microcontrollers, then display your name
and ID number |
| 10 |
Develop a system to count the number of events that occurred and to
Display the count on LCD using 8051 microcontroller |
| 11 |
Develop a system to accept the external interrupt and toggle the LED
using 8051 microcontroller |
| 12 |
Interface the stepper motor with 8051 and control the clockwise and
anti-clockwise direction |
| 37 |
Embedded and IoT Laboratory |
R-207 |
Advanced Embedded Systems |
1 |
Preamble of the LPCLPC2148 microcontroller and interface with system |
| 2 |
Implement a Blinking of LED using LPC2148 microcontroller |
| 3 |
Interfacing Buzzer using LPC2148 microcontroller |
| 4 |
Perform a controllling an LED and buzzer using a switch with LPC2148
microcontroller |
| 5 |
Perform a display string on LCD using LPC2148 microcontroller |
| 6 |
Implement a Serial Transmission of data using LPC2148
microcontroller |
| 7 |
Implement a Serial Communication using LPC2148 microcontroller |
| 8 |
Interfacing temperature sensor to LPC2148 microcontroller and
displaying the values on serial window |
| 9 |
Interfacing relay to LPC2148 microcontroller to control any
peripheral device |
| 10 |
Interfacing RFID to LPC2148 microcontroller |
| 11 |
Interfacing a GSM module to LPC2148 microcontroller and perform a
process of sending an SMS |
| 12 |
Interfacing GPS module to LPC2148 microcontroller |
| 38 |
Embedded and IoT Laboratory |
R-207 |
Embedded Systems For IoT |
1 |
Preamble and setting up THINGSPEAK Cloud and ESP8266 Installation |
| 2 |
Implement an Interrupts and Timers on ESP 8266 using IDE |
| 3 |
Implementing Deep Sleep on ESP8266 using IDE |
| 4 |
Interfacing BMP 180 to ESP8266 using IDE |
| 5 |
Publishing Sensor Readings (Rain/Barometer) to ThingSpeak using
NodeMCU |
| 6 |
Preamble to Firebase with ESP8266 NodeMCU |
| 7 |
Develop an Firebase Authentication (Email and Password) with
ESP32/ESP8266 |
| 8 |
Implement a Sending Sensor Readings to Realtime Database using
ESP32/ESP8266 and Firebase |
| 9 |
Develop a system to control an Actuator through the BLYNK App |
| 10 |
Develop a IoT Device Control via ThingSpeak |
| 11 |
Develop a Home Automation using HTTP Protocol |
| 12 |
Develop a Home Automation using MQTT Protocol |
| 39 |
Embedded and IoT Laboratory |
R-207 |
Embedded and Real-Time Systems |
1 |
Preamble to Free RTOS, create an application that creates tasks |
| 2 |
Create an application that creates two tasks that wait on a timer
whilst the main task loops |
| 3 |
Implement a Blocking semaphores, priority scheduling using RTOS |
| 4 |
Implement a Test message queues and memory blocks, Test byte queues |
| 5 |
Implement a Estimation the execution time of real-time tasks |
| 6 |
Implement and evaluation of the system’s ability of meeting
deadlines |
| 7 |
Implement Sending messages to the mailbox by one task and reading
the message from a mailbox by another task. |
| 8 |
Implement a Creates a task that is scheduled when a button is
pressed, which illustrates the use of an event set between an ISR and a
task |
| 9 |
Demonstrates the interruptible ISRs |
| 10 |
Implement ISRs and analyse higher priority than the external
interrupt button |
| 11 |
Performance measures, dumping RTOS profile data to the PC |
| 12 |
Real-time operating system kernel (thread switching and
synchronization) |
| 40 |
Embedded and IoT Laboratory |
R-207 |
EDGE Computing & Data Analytics in IOT |
1 |
The preamble to Raspberry Pi 4 and OS installation |
| 2 |
Write an Python programming for Raspberry Pi 4 |
| 3 |
Preamble to Node-Red installation and Experiment on Input and output
interfaces |
| 4 |
Implementation of MQTT protocol using Node Red |
| 5 |
Implementation of MQTT-SN protocol using Node Red |
| 6 |
Interface an Raspberry Pi 4 into an Edge Gateway |
| 7 |
Implement an Enabling Analog Sensor for Edge Computing Using EdgeX |
| 8 |
Implement an Enabling Digital Sensor for Edge Computing Using EdgeX |
| 9 |
Preamble to Microsoft Azure / AWS |
| 10 |
Develop a Type-1 Data analytics using Microsoft Azure
/ AWS |
| 11 |
Develop a Type-2 Data analytics using Microsoft Azure / AWS |
| 12 |
Develop a Type-3 Data analytics using Microsoft Azure / AWS |
| 41 |
Signal Processing Laboratory |
R-204 |
Natural Langauge Processing and Applications |
1 |
Databases and API's for NLP (NLTK, SpaCY and Tensorflow) |
| 2 |
Tokenization of Text in different API's and Performance analysis. |
| 3 |
One - Hot - Encoding and Stop words elimination |
| 4 |
Implementation of chatbot. |
| 5 |
Grammar Word Orders using Nltk and SpaCy |
| 6 |
Parsing_in Nltk |
| 7 |
TF-IDF Vector Trnasformation of Text |
| 8 |
ZIPF's Law modelling. |
| 9 |
Bag-of-Words and Bag of N-Grams Feature Representation |
| 10 |
PCA on text feature modelling |
| 11 |
SVD as text feature represnation |
| 12 |
GloVe model implementation |
| 13 |
Topic Modelling and Sentiment analysis using RNN |
| 42 |
Signal Processing Laboratory |
R-204 |
Discrete Time Signal Processing |
1 |
Generation of discrete time signals |
| 2 |
Effect of sampling rate |
| 3 |
Operations on signals |
| 4 |
Properties of Linear time-invariant system. |
| 5 |
Computation of Z transform |
| 6 |
Compute the Discrete Fourier Transform and IDFT with and without fft
and ifft in MATLAB |
| 7 |
Discrete Fourier Transform (DFT) and Fast Fourier Transform (FFT) |
| 8 |
Properties of DFT |
| 9 |
Linear and Circular Convolution |
| 10 |
Correlation and Matched filtering using it |
| 11 |
FIR filter design using window method: Lowpass and highpass filter. |
| 12 |
FIR filter design using window method: Bandpass and Bandstop filter
. |
| 43 |
Computer Center |
R-304B |
Deep Network Architectures |
1 |
To implement CNN for image classification and compare it’s
performance metrics. |
| 2 |
To analyze SGD optimizer for object detection and compare it’s
performance metrics. |
| 3 |
To execute ADAM optimizer for object detection and compare it’s
performance metrics. |
| 4 |
To generate the text using RNN |
| 5 |
To examine and compare the performance of LSTM for speech
recognition |
| 6 |
To test the performance of GRU for handwriting
recognition |
| 7 |
To construct the DensNet for object detection |
| 8 |
To develope the AlexNet for medical images analysis |
| 9 |
To write the logic and program for VGG to
segment the images |
| 10 |
To implement the ResNet for facial recognition |
| 11 |
To compare the performance metrics of AlexNet Model for MNIST,
Fashion MNIST, Cifar10 and ImageNet datasets |
| 12 |
To analyze the performance metrics of VGG for MNIST, Fashion MNIST,
Cifar10 and ImageNet datasets. |
| 13 |
To differentiate the performance metrics of ResNet for MNIST,
Fashion MNIST, Cifar10 and ImageNet datasets |
| 44 |
Signal Processing Laboratory |
R-204 |
Speech Signal Processing |
1 |
Speech signal aquisition and recording ussing MATLAB. |
| 2 |
Demonstration of non-stationarity of signal using spectrogram |
| 3 |
Identification of voiced/unvoiced/silence regions in speech signal
uisng Short term energy and autocorrelation |
| 4 |
Study of different phonemes in English by plotting the sounds in
time-domian |
| 5 |
Estimation of pitch contour in voiced regions of speech signal. |
| 6 |
Study of Time-Frequency resolution tradeoff in speech signal using
STFT. |
| 7 |
Estimation LPC coefficients in a speech signal. |
| 8 |
Estimation Cepstrum of Speech Signal |
| 9 |
Demonstration of MFCC feature extraction from a speech signal |
| 10 |
Demonstration of enhancement of speech signal using wavelet
denoising. |
| 11 |
Study of speaker recognition system modeling. |
| 12 |
Study of formant analysis and synthesis in speech signal. |
| 45 |
Computer Center |
R-304B |
Introduction to quantum computing |
1 |
To design Quantum circuit |
| 2 |
To perform Quantum measurement |
| 3 |
To measure experimentally the Accuracy of Quantum Phase Estimation |
| 4 |
Accuracy of Quantum Phase Estimation and quantum error correction |
| 5 |
To perform Scalable Shor’s Algorithm |
| 6 |
To perform Grover’s search with an unknown number of solutions |
| 7 |
To perform experimentally the Quantum Simulation as a Search
Algorithm |
| 8 |
To explore quantum phenomena by using Quantum simulation as a
asearch algorithm |
| 9 |
To perform Quantum Error Correction |
| 10 |
To Perform Quantum Teleportation |
| 11 |
To Perform Quantum key distribution |
| 12 |
To perform secure transmission of cryptographic keys over long
distances |
| 13 |
To Perform Quantum walks |
| 46 |
Signal Processing Laboratory |
R-204 |
Digital Signal Processing |
1 |
Generation of Elementary signals |
| 2 |
Operations on signals |
| 3 |
Convolution of signals |
| 4 |
Discrete Time Fourier Transform |
| 5 |
Discrete Fourier Transform(DFT) |
| 6 |
Fast Fourier Transform(FFT) |
| 7 |
Sampling theorem |
| 8 |
Linear and circular convolution |
| 9 |
Linear Constant Coefficent Difference Equations |
| 10 |
Infinite Impulse Response Filters (IIR) |
| 11 |
Finite Impulse Response Filters(FIR) |
| 12 |
Fourier Analysis of the signals |
| 47 |
Computer Center |
R-304B |
Bio Medical Signal and Image Analysis |
1 |
Generation of Biomedical Signals |
| 2 |
To observe Registration of medical signals |
| 3 |
To observe Registration of medical image |
| 4 |
To peform time domain analysis techniques |
| 5 |
To peform frequency domain techniques |
| 6 |
Detection of medical signals |
| 7 |
To analyse Sampling and quantization |
| 8 |
To peform Frequency domain enhancement techniques. |
| 9 |
Spectral analysis of ECG and its visualization |
| 10 |
Analyse Wavelet decomposition |
| 11 |
To peform Speech coding |
| 12 |
Measures of waveform coding |
| 48 |
Computer Center |
R-304B |
Machine Learning with Python |
1 |
Exploring python libraries for Machine learning |
| 2 |
Understanding of K- Means Clustering |
| 3 |
Development of Gaussian mixture models for real world data |
| 4 |
Design of Naïve Bayes classifier |
| 5 |
Development Support Vector Machines for classification |
| 6 |
Development Linear Regression for prediction |
| 7 |
Development of Logistic regression for real time data |
| 8 |
Modelling Artificial neural networks |
| 9 |
Design of Convolutional Neural Networks for classfication |
| 10 |
Develoment Recurrent neural networks for realtime data |
| 11 |
Principal Component Analysis for data dimensionality reduction |
| 12 |
Development of Linear Discriminant Analysis |
| 49 |
Measurements Laboratory |
R-005 |
Electronic System Design (R) |
1 |
Design and Implementation of Temperature Controlled FAN using
Comparator |
| 2 |
Design and Implementation of LED Chaser using IC4017 |
| 3 |
Design and Implementation of DC Motor control using L293D |
| 4 |
Design and Implementation of FM Receiver |
| 5 |
Controlling GPIO pins andDC Motor using Node MCU |
| 6 |
Harmful gas monitoring using NodeMCU and ThingSpeak |
| 7 |
Designing Weather station by HTTP GET REQUEST-RESPONSE using NodeMCU |
| 8 |
Communication between Two NodeMCU using ESPNOW |
| 9 |
Servo Motor Control using NodeMCU |
| 10 |
PROJECT |
| 50 |
Measurements Laboratory |
R-005 |
Electronic System Design (A) |
1 |
Design and Implementation of Temperature Controlled FAN using Comparator |
| 2 |
Design and Implementation of Automatic Street Light using Comparator |
| 3 |
Design and Implementation of Automatic Day Load Control using Comparator |
| 4 |
Design and Implementation of ON Timer using Comparator |
| 5 |
Design and Implementation of OFF Timer using Comparator |
| 6 |
Design and Implementation of Clock Signal Generator using 555 Timer |
| 7 |
Design and Implementation of LED Chaser using IC4017 |
| 8 |
Design and Implementation of DC Motor control using L293D |
| 9 |
Design and Implementation of DC Motor control using L298N |
| 10 |
Design and Implementation of DC Motor control using DRV8833 |
| 11 |
Design and Implementation of FM Receiver |
| 12 |
Design and Implementation of FM Transmitter |
| 13 |
Generating Digital output using Node MCU |
| 14 |
Controlling GPIO using Node MCU |
| 15 |
Interfacing Potentiometer as Analog Input with Node MCU |
| 16 |
DC Motor Control using Node MCU |
| 17 |
Harmful gas monitoring using NodeMCU and ThingSpeak |
| 18 |
Barometric Pressure monitoring using Node MCU and ThingSpeak |
| 19 |
Setting the Date and Time in DS3231 RTC module using Node MCU |
| 20 |
Designing Weather station by HTTP GET REQUESTRESPONSE using Node MCU |
| 21 |
Servo Motor Control using Node MCU |
| 22 |
Communication between Two Node MCU using ESPNOW |
| 23 |
PROJECT |
| 51 |
Electronic Devices Laboratory |
R-104 |
Electronic System Design (R) |
1 |
Design and Implementation of Temperature Controlled FAN using
Comparator |
| 2 |
Design and Implementation of LED Chaser using IC4017 |
| 3 |
Design and Implementation of DC Motor control using L293D |
| 4 |
Design and Implementation of FM Receiver |
| 5 |
Controlling GPIO pins andDC Motor using Node MCU |
| 6 |
Harmful gas monitoring using NodeMCU and ThingSpeak |
| 7 |
Designing Weather station by HTTP GET REQUEST-RESPONSE using NodeMCU |
| 8 |
Communication between Two NodeMCU using ESPNOW |
| 9 |
Servo Motor Control using NodeMCU |
| 10 |
PROJECT |
| 52 |
Electronic Devices Laboratory |
R-104 |
Electronic System Design (A) |
1 |
Design and Implementation of Temperature Controlled FAN using Comparator |
| 2 |
Design and Implementation of Automatic Street Light using Comparator |
| 3 |
Design and Implementation of Automatic Day Load Control using Comparator |
| 4 |
Design and Implementation of ON Timer using Comparator |
| 5 |
Design and Implementation of OFF Timer using Comparator |
| 6 |
Design and Implementation of Clock Signal Generator using 555 Timer |
| 7 |
Design and Implementation of LED Chaser using IC4017 |
| 8 |
Design and Implementation of DC Motor control using L293D |
| 9 |
Design and Implementation of DC Motor control using L298N |
| 10 |
Design and Implementation of DC Motor control using DRV8833 |
| 11 |
Design and Implementation of FM Receiver |
| 12 |
Design and Implementation of FM Transmitter |
| 13 |
Generating Digital output using Node MCU |
| 14 |
Controlling GPIO using Node MCU |
| 15 |
Interfacing Potentiometer as Analog Input with Node MCU |
| 16 |
DC Motor Control using Node MCU |
| 17 |
Harmful gas monitoring using NodeMCU and ThingSpeak |
| 18 |
Barometric Pressure monitoring using Node MCU and ThingSpeak |
| 19 |
Setting the Date and Time in DS3231 RTC module using Node MCU |
| 20 |
Designing Weather station by HTTP GET REQUESTRESPONSE using Node MCU |
| 21 |
Servo Motor Control using Node MCU |
| 22 |
Communication between Two Node MCU using ESPNOW |
| 23 |
PROJECT |
| 53 |
Analog and Digital Communications Laboratory |
R-105 |
Signals and Communication Systems |
1 |
Signal processing operations |
| 2 |
Generation of basic signals |
| 3 |
Complex signals for communication systems |
| 4 |
Impulse response of Linear Time Invariant (LTI) System |
| 5 |
FFT and Invest FFT of the given signal |
| 6 |
Sampling and reconstruction of Signals |
| 7 |
Magnitude and phase spectrum of a given signal |
| 8 |
Amplitude Modulation and Demodulation |
| 9 |
DSB - SC Modulation and Demodulation |
| 10 |
Balanced Modulator |
| 11 |
Single sideband (SSB) System |
| 12 |
Designing an adaptive noise canceller |
| 13 |
Signal conditioning a real speech signal |
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