An ℋ<sub>∞</sub>full information approach for the feedforward controller design of a large blended wing body flexible aircraft

Westermayer, Christian; Schirrer, Alexander; Hemedi, Mark; Kozek, Martin

doi:10.1051/eucass/201306685

Cited by 3 publications

(2 citation statements)

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“…24,29,30 For active load alleviation systems to be effective on such platforms, they need to incorporate the effect of wing deformations on the vehicle stability characteristics. 28 39 proposed a H ∞ full information approach.…”

Section: -26mentioning

confidence: 99%

Dynamic Load Alleviation in Wake Vortex Encounters

Hesse

Palacios

2016

Journal of Guidance, Control, and Dynamics

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This paper introduces an integrated approach for flexible-aircraft timedomain aeroelastic simulation and controller design suitable for wake encounter situations. The dynamic response of the vehicle, which may be subject to large wing deformations in trimmed flight, is described by a geometrically-nonlinear finite-element model. The aerodynamics are modeled using the unsteady vortex lattice method and include the arbitrary

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Section: -26mentioning

confidence: 99%

Dynamic Load Alleviation in Wake Vortex Encounters

Hesse

Palacios

2016

Journal of Guidance, Control, and Dynamics

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“…Wildschek et al [23]. The design of a preElter for longitudinal motion control of a large flexible BWB aircraft is presented in Westermayer et al [24]. The final control surface layout will be published in subsequent publications of the ACFA project.…”

Section: Control Surface Designmentioning

confidence: 99%

Design of a 450-passenger blended wing body aircraft for active control investigations

Mohr

Paulus

Baier

et al. 2011

Proceedings of the Institution of Mechanical Engineers, Part G:

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ACFA 2020 (active control for flexible aircraft) is a collaborative research project funded by the European Commission under the seventh research framework programme. The project deals with innovative active control concepts for 2020 aircraft configurations like the blended wing body (BWB) aircraft. The main objectives of ACFA are the design of a new ultra efficient 450 passenger BWB type aircraft as well as the provision of robust adaptive multichannel control architectures for such aircraft. The objective of the newly designed controllers is an ambitious improvement of ride comfort and handling qualities, as well as load reduction on BWB type aircraft. Based on the attained load reduction, the structure of the 450-passenger aircraft can be resized with the goal of an ambitious weight saving for further improvement of fuel efficiency. Active control requirements influence the design process of control surfaces and overall aircraft design, respectively. Hence, the conventional aircraft design process had to be adapted to the new requirements. The aircraft design framework described in this article has proven its efficiency in the development of the ACFA BWB aircraft. Within a time period of 1 year, an airframe has been developed under the constraints of multiple domain requirements. This article presents the process and the results of the design activities of the BWB aircraft, which form the basis for a detailed concept analysis as well as the investigation of multiple-input multipleoutput control architectures.

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Feed-Forward Control Designs

Haniš

Hromčík

Schirrer

et al. 2014

Modeling and Control for a Blended Wing Body Aircraft

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An ℋ_∞full information approach for the feedforward controller design of a large blended wing body flexible aircraft

Cited by 3 publications

References 15 publications

Dynamic Load Alleviation in Wake Vortex Encounters

Dynamic Load Alleviation in Wake Vortex Encounters

Design of a 450-passenger blended wing body aircraft for active control investigations

Feed-Forward Control Designs

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An ℋ∞full information approach for the feedforward controller design of a large blended wing body flexible aircraft

Cited by 3 publications

References 15 publications

Dynamic Load Alleviation in Wake Vortex Encounters

Dynamic Load Alleviation in Wake Vortex Encounters

Design of a 450-passenger blended wing body aircraft for active control investigations

Feed-Forward Control Designs

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Product

Resources

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An ℋ_∞full information approach for the feedforward controller design of a large blended wing body flexible aircraft