1. EMERGENCY LIGHTING SYSTEM

2. Power Outage Downed Power Lines due to Severe Weather Downed Power Lines due to Severe Weather Emergency Lighting (Key to Safe Evacuation) Emergency Lighting (Key to Safe Evacuation)

3. TEAM MEMBERS   Ryan Allen Documentation Circuit Testing   Chuck Crawford Documentation Circuit Design, Testing Software Design   Norman Cruse Documentation Circuit Testing Housing Fabricator   Brian Deck (Team Leader) Documentation Circuit Testing Circuit Design

4. Faculty Advisor Dr. Raymond Winton

5. Presentation Overview Problem Statement Problem Statement Hardware Components Hardware Components Remote Monitoring Options Remote Monitoring Options Test Plan Test Plan Packaging the Product Packaging the Product Cost Cost Project Timeline Project Timeline

6. Problem Emergency Lighting is Required in Industrial Settings Emergency Lighting is Required in Industrial Settings Current Emergency Lighting Systems Require Routine Maintenance Current Emergency Lighting Systems Require Routine Maintenance Battery LeakageBattery Leakage Monthly Battery TestingMonthly Battery Testing

7. Concerns Safety Safety Occupational Health and Safety Administration (OSHA)Occupational Health and Safety Administration (OSHA) Illumination StandardsIllumination Standards Placement of these SystemsPlacement of these Systems National Fire Protection Agency (NFPA) REQUIRES a MINIMUM Lighting Duration of 1.5 HOURS when Normal Lighting is Not Available.National Fire Protection Agency (NFPA) REQUIRES a MINIMUM Lighting Duration of 1.5 HOURS when Normal Lighting is Not Available.

8. Solution Build an Efficient System with Long Lasting Batteries and Lights Build an Efficient System with Long Lasting Batteries and Lights Exceed the Safety Standards Set by OSHA and the NPA Exceed the Safety Standards Set by OSHA and the NPA Incorporate Wireless Data Transmission into Emergency Lighting System Incorporate Wireless Data Transmission into Emergency Lighting System

9. Hardware Components Cont. Charging Circuitry Charging Circuitry –Detect State of Charge –Fast Charge –Float Charge 900 MHz XCite Wireless Module 900 MHz XCite Wireless Module

10. Hardware Components Long Lasting Phantom PAR-36 Light Emitting Diodes Long Lasting Phantom PAR-36 Light Emitting Diodes Two 6-Volt Carefree Eagle Picher AGM Batteries Two 6-Volt Carefree Eagle Picher AGM Batteries

11. Battery Discharge Curve The AGM Batteries Should Provide Light for at least 15 hours

12. Remote Monitoring Options X10 Technology vs. RF Serial Transmission Number of Nodes Number of Nodes –256 vs. 65535 Noise Noise –Electrical devices interfere when using X10 –Wireless devices interfere with RF reception Data Collision Data Collision –X10 transmits slower Range Range –X10 is indefinite with repeaters –RF is based on module and antenna Cost Cost –X10 incurs numerous hidden add-on costs –RF is less expensive overall

13. 900 MHz vs. 2.4 GHz Data Rate Capacity Data Rate Capacity Operating Distances Operating Distances –Wave Propagation –Penetrating Obstacles Signal Bending Signal Bending

14. Wireless Data Transmission XCite OEM RF Module XCite OEM RF Module Operates on the 900 MHz frequency band Operates on the 900 MHz frequency band Can support up to 65535 nodes Can support up to 65535 nodes Indoor Range of up to 300 ft. Indoor Range of up to 300 ft.

15. Test Plan Create Charge/Discharge Curve Create Charge/Discharge Curve –Monitor Voltage/Current vs. Time –Compare Curves to Data Sheets Wireless Transmission Range Test Wireless Transmission Range Test –Test in Urban Setting

16. Battery Discharge Test Results

17. Battery Charge Test Results

18. Transmission Range Test Typical Commercial Setting Typical Commercial Setting Transmitted data in Starkville’s Wal-Mart Transmitted data in Starkville’s Wal-Mart Known Interference Sources Known Interference Sources –900 MHz Scanners –900 MHz Repeaters –900 MHz CSM Handheld Device

19. Range Options Module Upgrade Module Upgrade –XStream Wireless Module  Max. Indoor Range of 1500 ft –XTend Wireless Module  Max. Indoor Range of 3000 ft Antenna Upgrade Antenna Upgrade –Least Expensive Option

21. Packaging the Product Housing Housing –12” L x 18” H x 6” W PCB Board PCB Board Lighting Mounts Lighting Mounts

22. Lighting Mounts

23. Budget Estimated Retail Price is $875.00

24. Project Timeline August August –Research Wireless Options –Preliminary PCB Layout September September –Order Wireless Module –Complete PCB Layout –Housing Design October October –Order PCB –Fabricate Housing –Test Wireless Module November November –Assemble and Test Lighting System –Finish Business Plan

25. Summary Battery/Lights Battery/Lights –Less Maintenance –Longer Lasting Charging Circuit Charging Circuit Wireless Module Wireless Module –900 MHz Xcite Module Housing Housing –Compact/Durable

26. Acknowledgements Dr. Raymond Winton Dr. Raymond Winton Dr. James Harden Dr. James Harden Dr. Bob Reese Dr. Bob Reese Nishant Chandra Nishant Chandra

27. Questions?