Wing aerostructural optimization under uncertain aircraft range and payload weight
Wing aerostructural optimization under uncertain aircraft range and payload weight
An uncertainty-based approach is undertaken to deal with multipoint wing aerostructural optimization. The flight points are determined by the quadruple set of parameters: Mach number, cruise altitude, carried payload, and flight range. From this set, the payload and range are modeled as probabilistically uncertain based on U.S. flight data for the operations of an A320 aircraft. The fuel burn is selected as the performance metric to optimize. Structural failure criteria, aileron efficiency, and field performance considerations are formulated as constraints. The wing is parametrized by its planform, airfoil sections, and structural thickness. The analyses disciplines consist of an aerostructural solver and a surrogate-based mission analysis. For the optimization task, a gradient-based algorithm is used in conjunction with coupled adjoint methods and a fuel burn sensitivity analytical formula. Another key enabler is a cost-effective nonintrusive uncertainty propagator that allows optimization of an aircraft with legacy analysis codes, within a computational budget.
Jacome, Luis Bahamonde
6c8463f7-c536-435b-8346-0adb48aa7e5b
Elham, A.
676043c6-547a-4081-8521-1567885ad41a
1 May 2017
Jacome, Luis Bahamonde
6c8463f7-c536-435b-8346-0adb48aa7e5b
Elham, A.
676043c6-547a-4081-8521-1567885ad41a
Jacome, Luis Bahamonde and Elham, A.
(2017)
Wing aerostructural optimization under uncertain aircraft range and payload weight.
Journal of Aircraft, 54 (3).
(doi:10.2514/1.C034050).
Abstract
An uncertainty-based approach is undertaken to deal with multipoint wing aerostructural optimization. The flight points are determined by the quadruple set of parameters: Mach number, cruise altitude, carried payload, and flight range. From this set, the payload and range are modeled as probabilistically uncertain based on U.S. flight data for the operations of an A320 aircraft. The fuel burn is selected as the performance metric to optimize. Structural failure criteria, aileron efficiency, and field performance considerations are formulated as constraints. The wing is parametrized by its planform, airfoil sections, and structural thickness. The analyses disciplines consist of an aerostructural solver and a surrogate-based mission analysis. For the optimization task, a gradient-based algorithm is used in conjunction with coupled adjoint methods and a fuel burn sensitivity analytical formula. Another key enabler is a cost-effective nonintrusive uncertainty propagator that allows optimization of an aircraft with legacy analysis codes, within a computational budget.
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Accepted/In Press date: 16 September 2016
Published date: 1 May 2017
Additional Information:
Copyright © 2016 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved. All requests for copying and permission to reprint should be submitted to CCC at www.copyright.com; employ the ISSN 0021-8669
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Local EPrints ID: 470915
URI: http://eprints.soton.ac.uk/id/eprint/470915
ISSN: 0021-8669
PURE UUID: 19ac7e31-2a4c-4bc4-adbc-eb7bfd15c3e9
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Date deposited: 20 Oct 2022 16:56
Last modified: 16 Mar 2024 21:27
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Author:
Luis Bahamonde Jacome
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