The safe integration of Unmanned Aircraft Vehicles (UAV) within the civil airspace is of great interest to NASA’s Advanced Air Mobility project, which envisions high density of operations in and around urban areas that include both UAV and AAM aircraft. To enable safe autonomous operations of both platforms, reliable airspace surveillance strategies must be designed and experimentally validated in relevant scenarios, where multiple small UAV operate flying in low altitude conditions. An example of such a scenario is described in this paper which provides performance assessment of various sensing strategies experimentally tested during flight campaigns with four UAV completing simultaneous missions from vertiports. Such campaigns are performed by the High Density Vertiplex subproject which assesses a prototype of Urban Air Mobility ecosystem. For the purposes of this work, the flights are observed from multiple sensing nodes each with radar and camera sensors. The visual detection and tracking algorithms achieved 96.1% to 99.9% average tracking coverage of the UAV above the horizon, reaching detection ranges larger than 1 kilometer for octocopter. Radar-based tracking shows a lower coverage mainly due to ground clutter removal challenges but provides comparable detection ranges and meter-level range accuracy.

Assessing Performance of Radar and Visual Sensing Techniques for Ground-To-Air Surveillance in Advanced Air Mobility / Vitiello, Federica; Causa, Flavia; Opromolla, Roberto; Fasano, Giancarmine; Dolph, Chester; Ferrante, Todd; Lombaerts, Thomas; Ippolito, Corey. - (2023), pp. 1-10. (Intervento presentato al convegno Digital Avionics Systems Conference (DASC) tenutosi a Barcelona, Spain nel 01-05 October 2023) [10.1109/DASC58513.2023.10311270].

Assessing Performance of Radar and Visual Sensing Techniques for Ground-To-Air Surveillance in Advanced Air Mobility

Federica Vitiello;Flavia Causa;Roberto Opromolla;Giancarmine Fasano;
2023

Abstract

The safe integration of Unmanned Aircraft Vehicles (UAV) within the civil airspace is of great interest to NASA’s Advanced Air Mobility project, which envisions high density of operations in and around urban areas that include both UAV and AAM aircraft. To enable safe autonomous operations of both platforms, reliable airspace surveillance strategies must be designed and experimentally validated in relevant scenarios, where multiple small UAV operate flying in low altitude conditions. An example of such a scenario is described in this paper which provides performance assessment of various sensing strategies experimentally tested during flight campaigns with four UAV completing simultaneous missions from vertiports. Such campaigns are performed by the High Density Vertiplex subproject which assesses a prototype of Urban Air Mobility ecosystem. For the purposes of this work, the flights are observed from multiple sensing nodes each with radar and camera sensors. The visual detection and tracking algorithms achieved 96.1% to 99.9% average tracking coverage of the UAV above the horizon, reaching detection ranges larger than 1 kilometer for octocopter. Radar-based tracking shows a lower coverage mainly due to ground clutter removal challenges but provides comparable detection ranges and meter-level range accuracy.
2023
979-8-3503-3357-2
979-8-3503-3358-9
Assessing Performance of Radar and Visual Sensing Techniques for Ground-To-Air Surveillance in Advanced Air Mobility / Vitiello, Federica; Causa, Flavia; Opromolla, Roberto; Fasano, Giancarmine; Dolph, Chester; Ferrante, Todd; Lombaerts, Thomas; Ippolito, Corey. - (2023), pp. 1-10. (Intervento presentato al convegno Digital Avionics Systems Conference (DASC) tenutosi a Barcelona, Spain nel 01-05 October 2023) [10.1109/DASC58513.2023.10311270].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/945903
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