JIGNESH VANAM

ad3hut@r.postjobfree.com +* (***)- 287-7432

EDUCATION :

B.Tech. in Electronics and communication, Jawaharlal Nehru Technological University [08/2016- 05/2020] (GPA: 8.2/ 10.0)

M.Sc. in Electrical and Electronics Engineering, University Of New Haven, [01/2022 - 05/2023]

(GPA: 3.1/ 4.0)

SKILLS:

Proficient in Xilinx Vivado, Revit and other electrical engineering software

Knowledgeable in electrical system design, analysis, and testing

Programming skills: Verilog, C, Python, Matlab

Strong problem-solving skills and ability to lead and work collaboratively with team members

Excellent communication skills and ability to present technical information to non-technical audiences

Detail-oriented and able to manage multiple projects simultaneously Technical Works and Certifications:

Internship on IoT at Guru Nanak Institutions Technical campus

Internship based on Communications at Bharat Sanchar Nigam Limited (BSNL) located at kukatpally, Hyderabad,India.

Internship on Advance Diploma course on ASIC Design and Verification at NANO Scientific Research Center located at Ameerpet, Hyderabad.

Work Experience:

ASIC Verification Engineer- Semiconsoul Technologies- 01/2021 to 08/2021

Developed verification plans for validating the ASIC design which includes defining test environments, test scenarios, and coverage metrics to ensure comprehensive testing.

Created and implemented testbenches, which are simulation environments used to test the ASIC design, like writing test cases, creating stimulus for the design, and developing functional and timing models.

Ensured that the ASIC meets its timing requirements, which involve validating that the design operates within specified clock frequencies and that critical paths are optimized for performance.

Tracked and analyzed the coverage of the verification tests to ensure that all aspects of the design have been exercised. This helps identify areas that may need additional testing.

Identified and debugged issues found during the verification process. This may involve working closely with the design team to understand the root cause of problems and proposing solutions.

Worked on multi-clock domain designs, timing analysis, and optimization. Academic Projects:

Designed and Implemented a digital clock using Verilog HDL:

Create a Verilog module that describes the clock’s behaviour

Initially we have to define clock and reset inputs, Counters using registers and then we create a clocking block using verilog coding.

Create a testbench to simulate the behavior of your digital clock. This allows you to verify that your Verilog code functions correctly before implementing it on hardware.

Use a synthesis tool ( Xilinx Vivado ) to convert your Verilog code into a netlist that can be used to program an FPGA or ASIC

Networking in University:

The aim of this project is to design the topology of the university network with the implementation of wireless networking systems

In this project, we will define a simulation of campus networks based on wireless networking. The network will be divided into two sets: one for the campus area and the other for the hostel area.

The major aim of this project is to show the wireless connectivity that is used in universities to make the network efficient and mobile at the same time Smart Farming Using IOT:

The aim of the project was to develop a system which can ease the way of farming without human intervention

I Used different sensors like soil moisture sensors, temperature sensors, humidity sensors, and GPS devices across the farm to collect real-time data which provide insights into soil conditions, weather patterns, and crop health.

An automated water pump is connected to the system which will supply the water to the crops by itself depending upon the soil moisture levels.

Used ultra sonic sensors which protects the farms by raising the alarms if there is any unusual movements of animals during night time.

Predictive analytics based on weather data can help farmers plan their activities and make informed decisions.

This Enables farmers to monitor and manage their farms remotely through mobile applications or web platforms and allows for quick response to issues and reduces the need for physical presence on the farm.

Line following robot using Aurdino:

Line Follower Robot (LFR) is a simple autonomously guided robot that follows a line drawn on the ground to either detect a dark line on a white surface or a white line on a dark

We use two Infrared sensors,Infrared sensors consist of two elements, a transmitter and a receiver. The transmitter is basically an IR LED, which produces the signal and the IR receiver is a photodiode, which senses the signal produced by the transmitter.

A typical line follower robot has two sets of motors, let's call them left motor and right motor. Both motors rotate on the basis of the signal received from the left and the right sensors respectively.

The robot needs to perform 4 sets of motion which includes moving forward, turning left, turning right and coming to a halt.

I also used a Motor driver here because the output signal of an Arduino is not sufficient to drive the motor, furthermore, we need to rotate the motors in both directions, therefore we use a motor driver to drive the motor as required and also the motor driver is able to supply sufficient current to drive the motor.

All these are connected to an Arduino board and we use python to develop a code to assign the pin numbers to the board and give directions to the robot how to move on a line and dump the code to the board

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