Energy-Based Cooperative Control for Landing Fixed-Wing UAVs on Mobile Platforms Under Communication Delays

Energy-Based Cooperative Control for Landing Fixed-Wing UAVs on Mobile Platforms Under Communication Delays

The landing of a fixed-wing UAV on top of a mobile landing platform requires a cooperative control strategy, which is based on relative motion estimates. These estimates typically suffer from communication or processing time delays, which can render an otherwise stable control system unstable. Such...

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Veröffentlicht in:IEEE robotics and automation letters 2020-10, Vol.5 (4), p.5081-5088
Hauptverfasser: Muskardin, Tin, Coelho, Andre, Noce, Eduardo Rodrigues Della, Ollero, Anibal, Kondak, Konstantin
Format: Artikel
Sprache:eng
Schlagworte:
Active damping
Adaptive systems
aerial systems: applications
Aerospace control
Aircraft
Computer architecture
Computer simulation
Control systems
Controllers
cooperating robots
Cooperative control
Delays
Energy flow
Field robots
Fixed wings
Land vehicles
Landing
Mathematical models
Mobile communication systems
Passivity
Synchronization
telerobotics and teleoperation
Unmanned aerial vehicles
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Beschreibung
Zusammenfassung:The landing of a fixed-wing UAV on top of a mobile landing platform requires a cooperative control strategy, which is based on relative motion estimates. These estimates typically suffer from communication or processing time delays, which can render an otherwise stable control system unstable. Such effects must therefore be considered during the design process of the cooperative landing controller. In this letter the application of a model-free passivity-based stabilizing controller is proposed, which is based on the monitoring of energy flows in the system, and actively dissipating any given active energy by means of adaptive damping elements. In doing so, overall system passivity and consequently stability is enforced in a straightforward and easy to implement way. The proposed control system is validated in numerical simulations for round trip delays of up to 4 seconds.
ISSN:2377-3766
2377-3766
DOI:10.1109/LRA.2020.3005374