I am working on electronics projects that involve designing, assembling, and testing electronic circuits using components such as sensors, microcontrollers, and communication modules. These projects focus on practical implementation, where I convert theoretical concepts into real-world working systems.
I analyze each electronics project by studying circuit behavior, component performance, and system efficiency. This includes testing sensors, monitoring outputs, and identifying issues to improve reliability and accuracy. Analytics helps me optimize designs and build better-performing systems.
Every project follows a clear strategy—from idea and planning to circuit design, coding, and testing. I choose the right components, platforms like Arduino or Raspberry Pi, and development approach to ensure the project is practical, scalable, and efficient.
My projects focus on real-world applications such as IoT systems, automation, safety devices, and robotics. Each build results in a functional working prototype that demonstrates problem-solving skills, hands-on electronics knowledge, and practical implementation.
This project detects gas leakage in real time using gas sensors and a microcontroller. When gas levels cross a safe limit, the system triggers alerts through a buzzer and sends notifications via the internet. The project focuses on safety, fast response, and remote monitoring, making it suitable for homes, kitchens, and small industries.
This project monitors vital health parameters such as heart rate and body temperature using biomedical sensors. The collected data is processed by a microcontroller and displayed in real time, with options for cloud storage and remote access. It demonstrates the integration of electronics with healthcare and IoT technologies.
This project allows users to control home appliances remotely using a smartphone or web interface. Devices such as lights, fans, and sockets are controlled through relays connected to a microcontroller. The system improves convenience, energy efficiency, and demonstrates practical IoT-based automation.
This robotics project uses ultrasonic sensors to detect obstacles and automatically change direction to avoid collisions. Controlled by an Arduino, the robot demonstrates basic robotics concepts such as sensor interfacing, motor control, and real-time decision making. It is widely used as a foundation for advanced autonomous robot development.
I am an electronics project developer with a strong interest in embedded systems, IoT, and robotics. I focus on building practical, real-world projects using microcontrollers, sensors, and automation techniques.
I enjoy hands-on development—designing circuits, programming controllers, testing hardware, and improving system performance. Through continuous learning and project-based work, I aim to develop innovative electronics solutions and strengthen my technical skills.
