53rd AIAA Aerospace Sciences Meeting 2015
DOI: 10.2514/6.2015-0761
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Review of Aerofoil Parameterisation Methods for Aerodynamic Shape Optimisation

Abstract: This paper presents a review of aerofoil shape parameterisation methods that can be used for aerodynamic shape optimisation. Six parameterisation methods are considered for a range in design variables: Class function/Shape function Transformations (CST); B-splines; Hicks-Henne bump functions; a domain element approach using Radial Basis functions (RBF); Bèzier surfaces; and a singular value decomposition modal extraction method (SVD); plus the PARSEC method. The performance of each method is analysed by consid… Show more

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Cited by 50 publications
(35 citation statements)
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“…as used by Wu [27] and Masters [21,28] and thickness parameters will be set to t i = 1. Due to the symmetry of the problem being investigated the upper and lower surface design variables were again taken to be equal.…”
Section: Hicks-henne Bump Functionsmentioning
confidence: 99%
“…as used by Wu [27] and Masters [21,28] and thickness parameters will be set to t i = 1. Due to the symmetry of the problem being investigated the upper and lower surface design variables were again taken to be equal.…”
Section: Hicks-henne Bump Functionsmentioning
confidence: 99%
“…Within an optimisation procedure the choice of shape parameterisation controls the relationship between the optimisation design variables and the aerodynamic surface itself. Consequently the choice of shape parameterisation method can have a significant impact on the effectiveness and efficiency of the overall procedure 3 . Many different methods have been used within an aerodynamic optimisation framework, from standard geometric curve definitions such as B-splines 4 or NURBS 5 to aerospace-specific methods such as CST 6,7 , HicksHenne bump functions 8,9 or PARSEC 9,10 to Free-Form Deformation [11][12][13][14] , proper orthogonal decomposition 2,15,16 or the discrete method 17 .…”
Section: Introductionmentioning
confidence: 99%
“…Within an optimisation procedure the choice of shape parameterisation controls the relationship between the optimisation design variables and the aerodynamic surface itself. Consequently the choice of shape parameterisation method can have a significant impact on the effectiveness and efficiency of the overall procedure [3]. Many different methods have been used within an aerodynamic optimisation framework, from standard geometric curve definitions such as B-Splines [4] or NURBS [5] to aerospace-specific methods such as CST [6,7], Hicks-Henne bump functions [8,9] or PARSEC [9,10] to Free-Form Deformation [11,12,13,14], proper orthogonal decomposition [2,15,16] or the discrete method [17].…”
Section: Introductionmentioning
confidence: 99%