SensorFly : Controlled-mobile Sensing Platform for Indoor Emergency Response Applications

1. SensorFly: Controlled-mobile Sensing Platform for Indoor Emergency Response Applications AveekPurohit, Zheng Sun, Frank Mokaya and Pei Zhang - Twohsien 2011.5.9

2. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

3. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

4. Motivation

5. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

6. Contribution • Small, low-cost！(29g, $200) • Node capability vs. resource • Deployment autonomy

7. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

8. Hardware Design

9. Hardware Design, Key Constraints Cost Weight Interference and Noise Energy

10. Hardware Design, Design trade-offs • Processor • ARM7 based LPC2148 • AVR AtMega644 • Navigation Sensors

11. Hardware Design, Design trade-offs • Radio • DigiXBee • nanoLOC TRX transceiver module • Motors • Two 7mm core-less motors

12. Hardware Design, Board Layout

13. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

14. Software Architecture

15. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

16. Hardware Characterization • Height and Orientation Estimation • Ranging • Flight Time

17. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

18. Evaluation

19. Evaluation

20. Evaluation

21. Evaluation

22. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

23. Conclusion • 29g controlled-mobile aerial sensor network platform for indoor emergency fire monitoring applications. • Achieve performance in both sensing quality and coverage that matches or exceeds pre-deployed static network infrastructures.

24. OUTLINE • Motivation • Contribution • Hardware Design • Software Architecture • Hardware Characterization • Evaluation • Conclusion • Discussion

25. Discussion • Strength • Use simple devices to achieve performance needed. • Weakness • The platform is focus on fire monitoring applications, but the design did not use temperature and smoke information. • Flight time may not sufficient.