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THE PHOENIX PROJECT Coordinated Flight of Multiple Unmanned Vehicles Michael P. Anthony & Christopher M. Gerson Lab for Control and Automation Princeton.

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Presentation on theme: "THE PHOENIX PROJECT Coordinated Flight of Multiple Unmanned Vehicles Michael P. Anthony & Christopher M. Gerson Lab for Control and Automation Princeton."— Presentation transcript:

1 THE PHOENIX PROJECT Coordinated Flight of Multiple Unmanned Vehicles Michael P. Anthony & Christopher M. Gerson Lab for Control and Automation Princeton University Princeton, NJ, 08544 Professor Robert Stengel

2 Goals Long Term –Fleet of 4 Aircraft –Way Point Navigation –Coordinated Aerobatic Maneuvers Short Term –Derivation of Longitudinal Controller –Refine Lateral Controller –Integrate System and Flight Test

3 The Hobbico Hobbistar 60 Advantages –Remote Pilot –Inexpensive –Almost Ready to Fly Disadvantages –Small Payload Phoenix 1 [1]

4 Lateral Control System

5 Refinement of Control System –Correction of Simulink Simulation –Alteration of LQR Control Cost

6 Simulink Analysis of LQR State Estimate with R=30*I 2 State Estimate with R=I 2

7 Longitudinal Control System Derivation of Control System –Plant Model (P above) –Control Block (C)

8 Longitudinal Plant Pole/Zero Map Pole/Zero Map showing Poles of Longitudinal Plant Model

9 PD Control Derivation PD Controller (C) –Proportional to control rise time –Derivative to control damping –Elimination of Integral Control No need for 0 steady state error Integral Control usually slows transient response –Non-computationally heavy, easier to maintain real-time

10 Longitudinal Control System C P

11 Closed Loop Step Response

12 The Cassiopeia Payload Bay

13 Onboard System Control Channel 5 Channel 1-4 Servos Rate Gyros Receiver Safety Switch Cassiopeia CF port WLan Card RS-232 TattleTale TPU Channels GPS Receiver RS-232 MUX Computed Controls MUX

14 Tattletale Data Logger from Onset Computers Acts as Data Acquisition Board –Reads Gyro data Pulses –Transmits Gyro data to Cassiopeia –Receives Servo data from Cassiopeia –Controls Servos via TPU Channels Sampling Time: 10Hz TattleTale Model 8 [2]

15 Casio Cassiopeia Main Processor –Lateral Control –Longitudinal Control Wireless LAN –2-way communication with ground laptop Cassiopeia E-125 [3]

16 Wireless LAN Symbol 802.11 Wireless LAN –Designed for PDAs –Dynamically adjusts speed to increase range –Communicates with Ground Laptop Symbol CF WLan Card [4]

17 GPS Pharos iGPS Receiver Read by TattleTale –1Hz Sampling –RS-232 Protocol Data Sent to Cassiopeia Data Transmitted to Laptop Data plotted by Laptop Pharos iGPS [5]

18 Ground-Based Laptop Receives Data from Cassiopeia –  and  Ensures Onboard System is functioning –GPS Data Transmits Data to Cassiopeia: –  and  (desired) –‘Enter Flight Path’ Command –‘RESET’ Controls –Adjusts assumed Average Rate Gyro Values

19 Control System Interface

20 Ground Tests What Worked: Safety Switch System remained in Real-time Reliable Network Software –System reestablishes communications Controllers reacted to Disturbances What Didn’t: Integration of GPS prevented system from remaining in real-time

21 Flight Test

22 When it Rains, It Pours

23 Conclusions Controller Flight Test was Inconclusive –Failure before Automated Control Test –Controller Performance known only to the extent of simulations What did Work –Wireless Communications –Tattletale/Casio Communications –Sensors and Integration

24 Changes Next Semester New PDA Smaller PDA’s exist that would fit in the Aircraft Alternative OS’s exist for PDA’s with the Intel StrongARM PDA and Laptop will log all data GPS: Direct Communication with PDA Avoids GPS / TattleTale Interaction Would allow system to remain in real-time Control to the TattleTale More modular Design Avoids excess communications

25 Special Thanks Professor Stengel: for allowing our involvement in this project Professor Littman: for his advice and counsel Professor Leonard’s Dynamics Lab: for their assistance George Miller: for generously donating his time to fly our airplane

26 References [1] Robert F. Stengel. http://www.princeotn.edu/~stengel/Phoenix.html Accessed on 8/15/00. [2] “TattleTale Model 8v2.” 2001 Onset computers Accessed on 1/5/2002 http://www.onsetcomp.com/Products/Product_Pages/Tattletale_pages/ TT8.html http://www.onsetcomp.com/Products/Product_Pages/Tattletale_pages/ TT8.html [3] “E-125- Cassiopeia.” 2001 Casio Corporation. Accessed on 2/15/2001 http://www.casio.com/personalpcs/product.cfm?section=19&product= 3553&display=10&cid=3897 http://www.casio.com/personalpcs/product.cfm?section=19&product= 3553&display=10&cid=3897 [4] “Wireless Systems.” 2001 Symbol Technology. Accessed on 1/5/2002 http://www.symbol.com/news/reporters_only/ph_lib_wireless_la4137. html http://www.symbol.com/news/reporters_only/ph_lib_wireless_la4137. html [5] “Pharos iGPS-180 Receiver.” 2001 Pharos. Accessed on 1/5/2002 http://www.pharosgps.com/products/igps-180.htm

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