1. Final year Project 2006/07 Microcontroller and RF application for wearable power generators By Jeanette Mannion

2. Introduction Power harvesting using wasted energy Energy expended by a person walking can be tapped to power portable electronic devices. The foot has proven to dissipate the most energy while walking/running. When walking quickly a person can generate up to 67W. The sliding magnet structured generator has proven to output the highest voltages and power.

3. The sliding magnet structure This consists of sliding magnets inside a small copper coil. The magnets slide up and down through the coil causing a voltage to be induced.

4. The sliding magnet structure Work has been carried out on this previously to demonstrate this power LED’s, a digital clock, and an actual pedometer have been powered by this system But no sufficient applications have been demonstrated

5. Project Goals goal of this project is The ultimate goal of this project is to build and test a micro controller and RF system That could use the power produced by wearable electromagnetic generator structures i.e. a pedometer system And further development of the system with a sensor application

6. Project background investigation This project is a combination of two projects: –The wearable electromagnetic generator –And micro-controller pedometer project Firstly, I will be reviewing the performance of the EM generator, and the existing circuit solutions that have been investigated up until now by another student.

7. Project Overview Also the existing pedometer programs will have to be tested for both the transmitter and receiver sides. The results obtained will help identify the power requirements needed for such a system.

8. Demonstration of the pedometer Once the transmitter and receiver are placed on the board needed for testing the programs can be downloaded to the micro-controller A power supply and signal generator will be used Programs may need to be adjusted Current programs written are so the RF transmits for a short time Once steps are counted, power can be investigated

9. Schematics for transmitter

10. System improvements At this stage the system only counts steps on one foot. LED’s will need to be changed to an LCD display. Will need weight and step length inputs. Can improve system functionality by calculating –Calories burned –Distance traveled –And average speed

11. Sensor application Further development of system with a sensor application i.e. –Pressure –Temperature Possible medical benefits –Obesity prevention –Body fat analysis –Monitoring your heart rate

12. Time scale Background investigation –3 weeks Demo of pedometer system –1 month System improvement & sensor app –1 month Generator improvements –1 month (time permitting)

13. Possible problems encountered Understanding and tweaking the programs previously written. time