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Credibility-based multidisciplinary design optimization of hybrid and fully electric aircraft

Credibility-based multidisciplinary design optimization of hybrid and fully electric aircraft
Credibility-based multidisciplinary design optimization of hybrid and fully electric aircraft
Aircraft designs for future electric aircraft often have large discrepancies in the underlying assumptions for highly influential design parameters. More optimistic assumptions on these parameters could result in better aircraft performance but include higher risks in the realization of the design in the defined timeline. In this work, the novel concept of design credibility is introduced to be used for quantifying the effect of assumptions on the underlying technologies on the design performance and the risks. For a range of highly important parameters, probability curves have been created that can predict a range of assumed future performance by 2035. A credibility-based multidisciplinary design optimization framework is created, which evaluates the maximum achievable mission ranges for hybrid electric aircraft under credibility constraints. The optimizations are performed using a surrogate-based global optimization routine, the efficient global optimization. With the full framework, the multiple aircraft designs are optimized under a range of credibility limits to create range-credibility Pareto curves. The results show that battery gravimetric energy density is the most dominant factor for the optimization. Motor and airframe parameters have a smaller effect on the achievable range. Their influence on the optimal design depends on the desired credibility level. For high credibilities, the motor is found to be more relevant. For low credibilities, airframe technology improvements are dominant. The shape of the underlying credibility distributions of secondary parameters has a strong effect on their relevance for the optimal configuration.
1533-3868
Wahler, Nicolas F.M.
5dd46272-f3b7-4662-8979-b56e3d33bbf0
Maruyama, Daigo
de628000-f428-4a23-959d-13809c8718fc
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
Wahler, Nicolas F.M.
5dd46272-f3b7-4662-8979-b56e3d33bbf0
Maruyama, Daigo
de628000-f428-4a23-959d-13809c8718fc
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a

Wahler, Nicolas F.M., Maruyama, Daigo and Elham, Ali (2025) Credibility-based multidisciplinary design optimization of hybrid and fully electric aircraft. Journal of Aircraft. (doi:10.2514/1.C037516).

Record type: Article

Abstract

Aircraft designs for future electric aircraft often have large discrepancies in the underlying assumptions for highly influential design parameters. More optimistic assumptions on these parameters could result in better aircraft performance but include higher risks in the realization of the design in the defined timeline. In this work, the novel concept of design credibility is introduced to be used for quantifying the effect of assumptions on the underlying technologies on the design performance and the risks. For a range of highly important parameters, probability curves have been created that can predict a range of assumed future performance by 2035. A credibility-based multidisciplinary design optimization framework is created, which evaluates the maximum achievable mission ranges for hybrid electric aircraft under credibility constraints. The optimizations are performed using a surrogate-based global optimization routine, the efficient global optimization. With the full framework, the multiple aircraft designs are optimized under a range of credibility limits to create range-credibility Pareto curves. The results show that battery gravimetric energy density is the most dominant factor for the optimization. Motor and airframe parameters have a smaller effect on the achievable range. Their influence on the optimal design depends on the desired credibility level. For high credibilities, the motor is found to be more relevant. For low credibilities, airframe technology improvements are dominant. The shape of the underlying credibility distributions of secondary parameters has a strong effect on their relevance for the optimal configuration.

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Credibility_based_MDO_Journal_of_Aircraft__Revision_-1 - Accepted Manuscript
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Accepted/In Press date: 19 November 2024
Published date: 28 January 2025

Identifiers

Local EPrints ID: 498797
URI: http://eprints.soton.ac.uk/id/eprint/498797
DOI: doi:10.2514/1.C037516
ISSN: 1533-3868
PURE UUID: 2a626cea-f44e-4ed8-87d6-0afd922f964e

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Date deposited: 28 Feb 2025 17:43
Last modified: 28 Feb 2025 17:43

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Contributors

Author: Nicolas F.M. Wahler
Author: Daigo Maruyama
Author: Ali Elham

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