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Multi-vehicle Cooperative Control Raffaello D’Andrea Mechanical & Aerospace Engineering Cornell University u Hierarchical Decomposition u Example: RoboCup.

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Presentation on theme: "Multi-vehicle Cooperative Control Raffaello D’Andrea Mechanical & Aerospace Engineering Cornell University u Hierarchical Decomposition u Example: RoboCup."— Presentation transcript:

1 Multi-vehicle Cooperative Control Raffaello D’Andrea Mechanical & Aerospace Engineering Cornell University u Hierarchical Decomposition u Example: RoboCup u Concluding Remarks OUTLINE

2 Hierarchical Decomposition Objective: Develop hierarchy-based tools for designing complex, multi-asset systems in uncertain and adversarial environments MAIN IDEAS: System level decomposition Bottom up design Simplification of models via relaxations and reduction Propagation of uncertainty to higher levels Adoption of heuristics, coupled with verification

3 Example: RoboCup u International competition: cooperation, adversaries, uncertainty –1997: Nagoya Carnegie Mellon –1998: Paris Carnegie Mellon –1999: Stockholm Cornell –2000: Melbourne Cornell –2001: Seattle u Involvement –Universities, Research Labs, Companies Cornell

4 Example

5 Competition Highlights (1999)

6 ROBOT K K INTELLIGENCE AND CONTROL Wheel velocity System Level Decomposition

7 Bottom Up Design Relaxation and Simplified Dynamics: ROBOT K Robust Control Design Restrict possible motions, design low level system to behave like simplified dynamical model

8 Mid-Level Control Trajectory Primitives: minimum time, minimum energy minimum time

9 STRATEGY TRAJECTORY GENERATION LOCAL CONTROL DESIRED FINAL POSITIONS AND VELOCITIES, TIME TO TARGET FEASIBILITY OF REQUESTS DESIRED VELOCITIES Intelligence and Control Current design: finite state machine Obstacle avoidance: Frazzoli, Feron, Dahleh no adaptation no formal methods

10

11 BACK-PASS PASS-PLAY

12 Example: Goalie

13 Formation Flight Testbed “ satellite” type of applications ( Wolfe, Chichka and Speyer ‘96) MAVs and UAVs, extend range MOTIVATION Use upwash created by neighbouring craft to provide extra lift

14 Formation Flight test bed 5 wings in low speed wind tunnel roll and translation along y axis

15 Concluding Remarks Relaxation, Restriction COMPLEXITY PERFORMANCE 1

16 Robust Control Design... Hierarchical Design

17 Current Activities Propagation of uncertainy/mismatch Randomized Algorithms for planning (MIT) Game Theoretic tools (delayed information) Verification Human in the loop New test-beds

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