Design, control, and optimize wireless energy systems using PIC microcontrollers and C programming.
Ready to explore cutting-edge embedded engineering? This course teaches you how to design and control wireless power transmission systems using PIC microcontrollers, fusing electrical theory with real-world application.
What you’ll learn
- Make your own PIC Microcontroller Wireless Powered Project.
- Learn How Wireless Electricity Can be transmitted using PIC Microcontroller.
- Learn Working Principle of Wireless Power Transmission.
Course Content
- Introduction & History of Wireless Power –> 8 lectures • 11min.
- Working Principle –> 4 lectures • 7min.
- Why We need wireless electricity –> 5 lectures • 7min.
- Range and Safety –> 5 lectures • 8min.
- Wireless Powered PIC Microcontroller Project –> 5 lectures • 5min.
- Circuit Diagram –> 5 lectures • 8min.
- Code –> 6 lectures • 18min.
- How does This Circuit Work –> 4 lectures • 4min.
- Practice Test –> 3 lectures • 2min.
- Course Project –> 5 lectures • 5min.
- Who we are? –> 1 lecture • 5min.
- Course Wrap-Up –> 1 lecture • 34min.
Requirements
Ready to explore cutting-edge embedded engineering? This course teaches you how to design and control wireless power transmission systems using PIC microcontrollers, fusing electrical theory with real-world application.
You’ll build low-power wireless transfer circuits and use PIC programming to monitor, control, and optimize them. Whether you’re into industrial design, IoT, or experimental tech, this course takes your embedded systems skills to the next level.
We guide you through designing inductive couplers, configuring PWM outputs, integrating voltage sensors, and building real-time feedback systems—all powered by your PIC firmware.
What makes this course powerful:
- Hands-on integration of wireless power hardware and PIC code
- Step-by-step labs that walk you through real circuit implementation
- Advanced insights into power optimization, signal stability, and safety
- Practical applications for wireless charging, automation, and sensing systems
What You Will Learn
- The physics of inductive wireless energy transfer
- Design and testing of basic wireless power circuits
- PIC microcontroller configuration for signal generation (PWM, timers)
- Implementing feedback using ADCs and voltage sensors
- Programming safety limits and power cutoffs
- Troubleshooting coil alignment, resonance issues, and thermal behavior
- Applications in contactless charging and embedded wireless solutions
Who Is This Course For
- Intermediate to advanced embedded system developers
- Engineering students and hardware designers
- IoT developers exploring wireless energy control
- Innovators working on automation and smart devices
- Anyone wanting to combine power electronics with microcontroller logic
Student Reviews
“Combining PIC with wireless power was a game-changer for my final year project. This course gave me the structure I needed.” — Daniel Y.
“The labs were challenging but super rewarding. I built a real wireless energy transfer system from scratch!” — Sophie W.
Requirements
- Working knowledge of C programming and PIC microcontrollers
- Basic electronics skills (oscilloscopes, circuit analysis)
- A PIC development board (e.g., PIC16F877A or similar)
- Wireless power modules or DIY coil materials (guided list provided)
Call to Action
Want to wirelessly transmit energy with precision microcontroller control?
Join this course and engineer the future of embedded wireless power with PIC programming.
→Enroll Now – Build Wireless Power Systems with PIC
FAQ
Q: Can I use any PIC microcontroller?
A: Yes—though examples are based on mid-range PIC16/PIC18 families. We explain how to adapt code for others.
Q: Do I need a wireless power kit?
A: Not necessarily—we include guides for building simple DIY systems from low-cost parts.
Q: Will I receive a certificate?
A: Yes! A Certificate of Completion is awarded after finishing the course.
Q: Is there a refund policy?
A: Absolutely—get a full refund within 7 days if the course doesn’t meet your needs.
Q: Do I need simulation software?
A: Optional—but tools like MPLAB X and Proteus help visualize and test your circuits virtually.