Distributed pressure sensing–based flight control for small fixed-wing unmanned aerial systems
Distributed pressure sensing–based flight control for small fixed-wing unmanned aerial systems
Small fixed-wing unmanned aerial systems (UAS) may require increased agility when operating in turbulent wind fields. In these conditions, conventional sensor suites could be augmented with additional flow-sensing to extend the aircraft’s usable flight envelope. Inspired by distributed sensor arrays in biological systems, a UAS with a chordwise array of pressure sensors was developed. Wind-tunnel testing characterized these sensors alongside a conventional airspeed sensor and an angle-of-attack (AoA) vane, and showed a single pressure measurement gave a linear response to AoA prestall. Flight tests initially manually piloted the vehicle through pitching maneuvers, then in a series of automated maneuvers based on closed-loop feedback using an estimate of AoA from the single pressure port. The AoA estimate was successfully used to control the attitude of the aircraft. An artificial neural network (ANN) was trained to estimate the AoA and airspeed using all pressure ports in the array, and validated using flight-trial data. The ANN more accurately estimated the AoA over a single-port method with good robustness to stall and unsteady flow. Distributed flow sensors could be used to supplement conventional flight control systems, providing enhanced information about wing flow conditions with application to systems with highly flexible or morphing wings.
1951-1960
Wood, Kieran T.
f56adf1e-ceec-40c8-9d2a-35b3f25f7ff7
Araujo-Estrada, Sergio
87793c63-f2bd-4169-b93d-ec1525909a7a
Richardson, Thomas
3a172fcd-d000-47ad-98e1-5f7dd9dd7a84
Windsor, Shane
85e45dbd-8c49-45d6-a100-80e513f84440
15 September 2019
Wood, Kieran T.
f56adf1e-ceec-40c8-9d2a-35b3f25f7ff7
Araujo-Estrada, Sergio
87793c63-f2bd-4169-b93d-ec1525909a7a
Richardson, Thomas
3a172fcd-d000-47ad-98e1-5f7dd9dd7a84
Windsor, Shane
85e45dbd-8c49-45d6-a100-80e513f84440
Wood, Kieran T., Araujo-Estrada, Sergio, Richardson, Thomas and Windsor, Shane
(2019)
Distributed pressure sensing–based flight control for small fixed-wing unmanned aerial systems.
Journal of Aircraft, 56 (5), .
(doi:10.2514/1.C035416).
Abstract
Small fixed-wing unmanned aerial systems (UAS) may require increased agility when operating in turbulent wind fields. In these conditions, conventional sensor suites could be augmented with additional flow-sensing to extend the aircraft’s usable flight envelope. Inspired by distributed sensor arrays in biological systems, a UAS with a chordwise array of pressure sensors was developed. Wind-tunnel testing characterized these sensors alongside a conventional airspeed sensor and an angle-of-attack (AoA) vane, and showed a single pressure measurement gave a linear response to AoA prestall. Flight tests initially manually piloted the vehicle through pitching maneuvers, then in a series of automated maneuvers based on closed-loop feedback using an estimate of AoA from the single pressure port. The AoA estimate was successfully used to control the attitude of the aircraft. An artificial neural network (ANN) was trained to estimate the AoA and airspeed using all pressure ports in the array, and validated using flight-trial data. The ANN more accurately estimated the AoA over a single-port method with good robustness to stall and unsteady flow. Distributed flow sensors could be used to supplement conventional flight control systems, providing enhanced information about wing flow conditions with application to systems with highly flexible or morphing wings.
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FlowSensing_preprint
- Author's Original
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FlowSensing_accepted
- Accepted Manuscript
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e-pub ahead of print date: 27 June 2019
Published date: 15 September 2019
Identifiers
Local EPrints ID: 470533
URI: http://eprints.soton.ac.uk/id/eprint/470533
ISSN: 0021-8669
PURE UUID: cfd26bb6-3862-41e5-bba2-651d3e5918a3
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Date deposited: 12 Oct 2022 16:46
Last modified: 17 Mar 2024 07:25
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Contributors
Author:
Kieran T. Wood
Author:
Sergio Araujo-Estrada
Author:
Thomas Richardson
Author:
Shane Windsor
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