Arduino Based Solar Tracker

Arduino Based Solar Tracker free download

Build an automatic dual-axis solar tracking system using Arduino sensors and servo motors to maximize solar energy captu

This course guides you through building a fully functional Arduino-powered solar tracker. Using light sensors and servo motors, you’ll create a system that detects sunlight direction and automatically adjusts the solar panel’s position for maximum efficiency.

Whether you’re working on a renewable energy project, a school assignment, or just want to develop your skills in sensor-based automation, this course delivers the complete process—from hardware setup to final working system.

Why Should You Take This Course?

• Hands-on Experience: The course provides students with hands-on experience in building a solar tracker from scratch, allowing them to apply the concepts and theories they learn in a practical setting.

• Understanding of Renewable Energy: By building a solar tracker, students will gain a deeper understanding of the principles of renewable energy and how it can be harnessed for practical applications.

• Development of Technical Skills: The course will help students develop a range of technical skills, including circuit design, coding, and troubleshooting, which are valuable in many areas of engineering and technology.

• Exposure to New Technologies: Students will be exposed to cutting-edge technologies, including the Arduino platform and solar tracking systems, and will learn how they can be used to solve real-world problems.

• Career Opportunities: Upon completion of the course, students will have a portfolio of projects that demonstrate their skills and experience in electronics, programming, and renewable energy, which can help them to pursue careers in these fields.

What You Will Learn

1. Understand the Principles of Solar Tracking
   Learn how light direction impacts energy efficiency and why tracking systems matter.

2. Interface LDR Sensors with Arduino
   Set up and calibrate light-dependent resistors (LDRs) to detect sunlight intensity.

3. Control Servo Motors Based on Sensor Input
   Program Arduino to adjust panel orientation using dual-axis movement.

4. Implement Conditional Logic in Embedded C
   Create decision-making code that moves the panel precisely toward the strongest light source.

5. Assemble the Full Tracking Mechanism
   Combine sensors, servos, and panel mounts to create a complete working model.

6. Test, Troubleshoot, and Optimize
   Fine-tune tracking accuracy and explore ways to adapt your design for different conditions.

Who This Course Is For

• Students building academic projects on renewable energy

• Makers and electronics hobbyists interested in automation

• Anyone learning Arduino and sensor integration

• DIY solar enthusiasts seeking energy-efficient designs

Requirements

• Basic knowledge of Arduino and electronics

• Arduino Uno (or compatible board)

• LDR sensors, resistors, servo motors (2), solar panel (for demonstration)

• Breadboard, jumper wires, and a stable mounting platform

Student Reviews

“Built it for my capstone project—easy to follow and worked as expected!” — Tariq H.

“I always wanted to work on solar automation. This was a great way to learn sensors and servo control.” — Julia P.

“One of the most complete Arduino tracking projects. Clear code, practical design.” — Elijah R.

Build Smarter Renewable Systems

Using simple components and real code, you’ll build a working solar tracker that mimics professional systems. This isn’t just a circuit—it’s an energy optimization tool powered by your code and logic.

About the Instructor

Educational Engineering Team

Team of Skilled Engineers Sharing Knowledge with the World

The Educational Engineering Team is a leading force in the Microcontroller Industry, boasting over 13 years of experience in teaching and practical projects. Their courses provide hands-on, real-world knowledge, enabling immediate application in projects and daily life. Led by Ashraf, an educator and Mechatronics engineer, the team is passionate about sharing their collective expertise. With over 250,000 students taught worldwide, Educational Engineering offers comprehensive courses, articles, and online support in various STEM fields. Ashraf's dedication to simplifying complex concepts through engaging content has garnered praise from students globally, making Educational Engineering a trusted resource for aspiring engineers and hobbyists alike.

Call to Action

Start designing smarter, self-adjusting systems powered by clean energy principles.
Enroll now and build your Arduino solar tracker step-by-step.

Enroll Now – Master Arduino-Based Solar Automation