2007 AUVSI Undergraduate Student UAS Competition

1. 2007 AUVSI Undergraduate Student UAS Competition Mississippi State University March 23, 2007

2. Overview • Introduction of team X-ipiter • Budget and Schedule • What is a UAS? • AUVSI Competition Rules and Regulations • Air Vehicle • System Components • Real World Applications • Conclusion and Questions

3. Participating Departments Department of Kinesiology

4. 2006-2007 Team Advisors: Dr. Randolph Follett ECE Assistant Professor Calvin Walker ASE Research Associate Team Leads: Team Lead – Savannah Ponder, ASE – Jr. Air Vehicle Lead – Nathan Ingle, Kinesiology – Jr. Systems Lead – Brandon Lasseigne, ASE – Sr.

5. Team Members • Systems: • Chris Brown (Grad, EE) • Joshua Lasseigne (SR, • CPE) • Brittany Penland (SR, • ABE) • Chris Edwards (JR, EE) • Daniel Wilson (SO, • CPE) • William Cleveland (SO, • CPE/ASE) • Air Vehicle: • Marty Brennan (SR, ASE) • Sam Curtis (SR, ASE) • Jonathan Fikes (SR, ME) • Mike Hodges (SR, GR) • Richard Kirkpatrick (SO, ASE) • Trent Ricks (SO, ASE) • Wade Spurlock (FR, ASE)

6. Budget • Allocated Funds: $6,500 • ASE - $2,000 • ECE - $2,000 • Miltec - $1,000 • 5D Systems - $1,500 • Current Expenses: $2,232 • Approximate Travel Expenses: $5,000

7. Schedule

8. What is UAS?And what is the difference between UAV and UAS? • Unmanned Aerial Vehicle - A powered, aerial vehicle that does not carry a human operator, uses aerodynamic forces to provide vehicle lift, can fly autonomously or be piloted remotely, can be expendable or recoverable, and can carry a lethal or nonlethal payload. Ballistic or semiballistic vehicles, cruise missiles, and artillery projectiles are not considered unmanned aerial vehicles. • DOD Joint Publication 1-02 • Unmanned Aerial System – A system comprised of one or more UAVs and the associated Ground Control Station for command, control, and communication and applicable payloads to perform various missions in either the civilian or military environment.

9. Mission Objective “The complete mission objectives are for an unmanned, radio controllable aircraft to be launched and transition or continue to autonomous flight, navigate a specified course, use onboard payload sensors to locate and assess a series of man-made objects in a search area prior to returning to the launch point for landing.” - AUVSI Student Competition Rules

10. Scored Factors • Takeoff • Waypoint Navigation • Search Area • Landing • Total Mission Time

11. Scored Factors Takeoff • Manual or autonomous • Objective: autonomous takeoff • Paved asphalt surface

12. Scored Factors Waypoint Navigation • Autonomous Flight (Required) • Search • Must pass over each waypoint • Must avoid no-fly zones • Airspeed • Requirement of two speed variations • Waypoints • Announced prior to flight portion of the competition

13. Scored Factors Waypoint Navigation • In-route Search • Target positioned directly along the 500 feet MSL search zone • Targets may be positioned up to 250 feet from the search path, while at 200 feet MSL • Targets • Plywood targets • 7 possible shape configurations • 6 possible sizes • 7 possible background colors • 7 possible alphanumeric colors • 3 possible alphanumeric heights • 3 possible alphanumeric thicknesses • Threshold: identify two target parameters • Objective: identify five target parameters

14. Scored Factors Search Area • Can choose the search pattern • Flight altitude • Between 100 feet MSL and 750 feet MSL • Dynamically re-task in flight • Utilize to locate a “pop-up” target • Target Location Identification • Threshold: ddd.mm.ss.ssss within 250 ft • Objective: ddd.mm.ss.ssss within 50 ft

15. Scored Factors Landing • Manual or autonomous landing • Objective: autonomous landing • Control on landing • Scored • Completion • “When the air vehicle motion ceases, engine is shut down, and the mission data sheet and imagery have been provided to the judges.” – AUVSI Competition Rules

16. Scored Factors Total Mission Time • Allotted amount of time • 40 minutes • Objective: 20 minutes • Actionable Intelligence • Real time observation and target data recorded

17. Competition Scoring • 50% Mission Performance • 25% Journal Paper • 25% Oral Briefing/Static Display

18. Air Vehicle • Regulations from AUVSI • Evolutionary approach • Current Plane • Construction Methods • Performance • Static Stability and Control

19. Regulations from AUVSI • Weight • Less than 55 lbs • Manual override capability • Flight termination • Airspeed • 100 knots • Sensors • No ground based sensors • Capable of changes to airspeed and altitude • Environmental considerations • Crosswinds: 8 knots with 11 knots gusts • Wind: 15 knots with 20 knots gusts at the mission altitude • Temperature: 110 degrees F at 1000 ft MSL

20. Evolutionary Approach • Telemaster • X-1 • X-2 • X-2.5

21. Evolutionary ApproachTelemaster • Used in the 2004 AUVSI Undergraduate Student UAV Competition • Configuration: • Tail dragger • High wing • Split horizontal stabilizer • Glow fuel engine • Flat bottom airfoil • Problems: • Insufficient internal space • Insufficient payload capacity

22. Evolutionary ApproachX-1 • Used for 2005 AUVSI Undergraduate Student UAV Competition • Configuration • Tricycle landing gear • Conventional propulsion configuration • Main fuselage with central wing placement • Gasoline powered engine • SD7062 airfoil • Problems • Access to the payload area very limited • Weight • Camera interference • Electromagnetic Interference

23. Evolutionary ApproachX-2 • Used in 2006 AUVSI Undergraduate Student UAV Competition • Data from camera interference solved • Configuration • Twin boom • Pusher • Tricycle landing gear • Main fuselage with central wing configuration • High horizontal stabilizer configuration • SD7062 airfoil • Problems • High cruise airspeed • Weight

24. X-2.5 • Current configuration • Evolutionary design of X-2 • Improvement methods • Decreased the minimum flight speed • Increased the fuselage length to handle volumetric problems • Modified layup schedule to reduce weight • Brakes to reduce landing distance • Camera control software • Connectors

25. X-2.5 continued • Wings: • Airfoil: SD7062 • Span: 128.00 in • Chord: 16.00 in • Area: 2048.00 in2 • Aspect ratio: 8.00 • Wing loading: 3.80 psf • Fuselage: • Length: 45.00 in

26. X-2.5 continued Empennage • Horizontal • Airfoil: J5012 • Span: 32.25 in • Chord: 9.00 in • Area: 290.25 in2 • Aspect Ratio: 3.59 • Vertical (twin) • Airfoil: J5012 • Height: 7.0 in • Chord: 9.25 in • Area: 129.50 in2 • Aspect Ratio: 0.76

27. Evolutionary Solutions to Problems • Materials • More robust • Increased payload capability • Internal Space • Increased volume • Accessibility • Layout • Camera Interference • Relocated the engine behind the camera • Suspend the camera in the interior of the fuselage • Engine vibration isolation mount

28. Evolutionary Solutions to Problems Continued • Electromagnetic Interference • Shielded and grounded electronic components • Composite airframe • Manufacturability • Molds • Weight • Modified the layup schedule • Airspeed • Decreased cruise airspeed

29. X-2.5 Construction • Fuselage • Wings • Empennage • Landing Gear

30. X-2.5 ConstructionFuselage • Fuselage skin • Sandwich construction with fiberglass/Divinycell foam • Bulkheads: • Sandwich construction with carbon/birch wood or honeycomb

31. Wing Skins Sandwich construction with graphite/Divinycell foam Ribs Sandwich construction with graphite/polyurethane foam Tubular carbon main spar and anti-torque spar X-2 Construction ContinuedWings

32. X-2 Construction ContinuedEmpennage • Horizontal and Vertical stabilizers: • Sandwich construction with graphite/balsa wood • Ribs: • Sandwich construction with graphite/balsa wood • Booms: • Carbon composite tubes

33. X-2 Construction ContinuedLanding Gear • Tricycle landing gear formation • Wet lay up carbon composite construction

34. Performance • Airspeed • Maximum: 100 knots • Minimum cruise speed: 38 knots • Ceiling • 2,000 feet • Endurance • 1 hour • Takeoff distance • 200 feet • Landing distance • 200 feet

35. Static Stability and Control • Cma = -1.725 per radian - Static Margin: 21% - Statically stable longitudinally • Cnb = 0.063 per radian - Statically stable directionally • Clb = -0.012 per radian - Statically stable laterally

36. Systems Team • Required by AUVSI • Air vehicle electrical layout • Ground control station layout • Command/Telemetry • Autopilot • Camera control • Surveillance

37. Required by AUVSI • Takeoff and landing • May or may not be autonomous • Continuous flight • Must be autonomous • Manual Override • Waypoint navigation • Autonomous • Show the search area • Dynamically re-task • Change the search area • Imagery • Show imagery in real-time or record the required data for each target

38. Air Vehicle Electrical Layout

39. Ground Control Station Layout

40. Command/Telemetry

41. Autopilot • Micropilot 2028g • Weight: 28 grams • Dimensions: • Length: 10 centimeters • Width: 4 centimeters • Height: 1.5 centimeters • Programmable waypoints • Complete autonomous operations: takeoff, flight, landing. • Supports 24 servos

42. Autopilot • Horizon Ground Control Software • Takeoff and landing • Dynamically re-tasking • Testing with X-2

43. Camera Control • Programmed in C# • Receives input from camera control device • Communicates with camera • Sets pan/tilt/zoom • Receives pan/tilt/zoom information for calculations • Captures digital video from camera • Can take snapshots for analysis

44. Surveillance • Camera • Sony D70 Pan/Tilt/Zoom • Micropilot/Camera • Used to find the GPS coordinates of each target • X-ipiter Base Station Software (XBS) • Labview based program

45. XBS

46. X-ipiter Unmanned Aerial System

47. Real World ApplicationWarfare Today • Theater Wide Demand • Real Time Intelligence • Response To Troops in Contact • Managed Chaos Real world application section of this brief was prepared by SGT Mike Hodges, Aviation Operations Specialist, 2-20th Special Forces Group (Airborne), member of Team X-ipiter.

48. Real World ApplicationCurrent UAV Gap

49. Practical Applications of X-2.5 • Law enforcement • Border patrol • Agriculture • Surveying • Search and rescue

50. Sponsors