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Effect of Shape Parameterization on

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Title: Effect of Shape Parameterization on


1
Effect of Shape Parameterization on Aerodynamic
Shape Optimization
Patrice Castonguay Undergraduate Student Siva
Nadarajah Assistant Professor Department of
Mechanical Engineering McGill University Quebec,
Canada
45th AIAA Aerospace Science Meeting and
Exhibit Reno, Nevada January 8-11, 2007
2
Outline
  • Motivations
  • Objectives
  • CFD as a Design Tool
  • The Adjoint Method
  • Optimization Procedure
  • Shape Parameterization Techniques
  • Results
  • Conclusions
  • Current and Future Work

3
1. Motivations
  • Only few works have studied the effect of shape
    parameterization on the aerodynamic optimization
    process
  • Need to address the following questions
  • Effect of smoothing the gradient
  • Design space provided from Hicks-Henne bump
    functions
  • Mesh-points method for industrial strength design
    ?
  • B-Spline curves and PARSEC for inverse design and
    drag minimization ?

3
4
2. Objectives
  • Study the effect of shape parameterization on
    aerodynamic shape optimization by comparing four
    shape representation methods
  • Mesh Points
  • B-spline Curves
  • Hicks-Henne Bump Functions
  • PARSEC Method
  • Compare them based on accuracy and impact on the
    computational cost in the context of 2D inverse
    design and drag minimization cases

5
3. CFD as a Design Tool
6
4. The Adjoint Method
  • The aerodynamic properties that define the cost
    function I depends on the flow variables
  • (?) and on the design variables (F) which
    represent the geometry. Then,
  • and
  • Now, suppose a governing equation R which
    expresses the dependence of the
  • flow variables (?) and the design variables (F)
    is given by
  • Then

7
4. The Adjoint Method
  • Because dR 0, it can be multiplied by a
    Lagrange multiplier ? and substracted from the
  • variation dI. Thus, we get
  • By choosing ? to satisfy the adjoint equation
  • we find that
  • where

8
5. Optimization Procedure
  • Let represent the design variable, and the
    gradient. An improvement can be made with a
  • shape change
  • The gradient can be replaced by a smoothed
    value in the descent process. This ensures
  • that each new shape in the optimization sequence
    remains smooth and acts as a
  • preconditioner which allows the use of larger
    steps. The smoothed gradient may be
  • calculated from
  • where is the smoothing parameter. The
    smoothing leads to a large reduction in the
    number
  • of design iterations needed for convergence.

9
6. Shape Parameterization Techniquesa) Mesh
Points
  • Design variables are the x and y location of the
    mesh points representing the surface to
  • be optimized
  • Easy to implement
  • Large number of design variables to represent 2D
    or 3D geometries
  • Displacement of a single mesh point can lead to
    unsmooth shapes and cause the flow
  • solver to become ill-conditioned

10
6. Shape Parameterization Techniquesb)
Hicks-Henne Bump Functions
Geometry can be parameterized using the weighted
sum of a number of Hicks-Henne bump functions as
follows
where t1 locates the maximum point of the bump
and t2 controls the width of the bump. The
design variables are the weights aj multiplying
each Hicks-Henne bump functions.
A set of 16 Hicks-Henne bump functions with
parameter t2 10
11
6. Shape Parameterization Techniquesc) B-Spline
Curves
Airfoil is initially represented as a B-spline
curve. Design is accomplished by directly moving
the control points representing the airfoil. The
design variables are therefore the x and y
locations of the control points. The position
vector along a curve is given by
where the Bi are the position vectors of the n1
control points, Ni,k(t) are the B-spline basis
functions of order k.
Airfoil represented from a set of 11 B-spline
control points
12
6. Shape Parameterization Techniquesd) PARSEC
Method
PARSEC method uses 11 parameters to represent an
airfoil. They are
  • Leading edge radius
  • Upper crest position
  • Upper crest curvature
  • -Lower crest position
  • -Lower crest curvature
  • Trailing edge location
  • Trailing edge angles

Two polynomials are used to define the upper and
lower surface of the airfoil
The coefficients an and bn can be found from the
11 PARSEC parameters.
13
7. Results Inverse Design
  • - NACA 0012 to ONERA M6, M0.75, a 2
  • Objective Function
  • Design Procedure

14
7. Results Inverse DesignB-Spline Control
Points with Smoothed Gradient
Final Airfoil Shapes for Various of B-Spline
Control Points
Convergence of Objective Function
15
7. Results Inverse DesignB-Spline Control
Points with Smoothed Gradient
Final Pressure Distribution
Final Pressure Distribution Leading Edge
15
16
7. Results Inverse DesignB-Spline Control
Points without Smoothed Gradient
Final Airfoil Shapes for Various of B-Spline
Control Points
Convergence of Objective Function
Final Pressure Distribution
Convergence of Objective Function
17
7. Results Inverse DesignHicks-Henne Bump
Functions with Smoothed Gradient
Final Airfoil Shapes for Various of Bump
Functions
Convergence of Objective Function
Final Pressure Distribution - LE
Final Pressure Distribution
18
7. Results Inverse DesignHicks-Henne Bump
Functions without Smoothed Gradient
Final Airfoil Shapes for Various of Bump
Functions
Convergence of Objective Function
Final Pressure Distribution
Final Pressure Distribution - LE
19
7. Results Inverse DesignB-Spline Curves vs
Hicks-Henne Bump Functions
L2 Norm of Objective Function after 300 design
cycles for various cases
20
7. Results Inverse DesignB-Spline Curves vs
Hicks-Henne Bump Functions
Number of design cycles for Objective Function
1.0E10-5
20
21
7. Results Inverse DesignHicks-Henne Bump
Functions Effect of Bump Width
Bump width (controlled by parameter t2) affects
convergence of objective function
Optimum value of t2 depends on the number of bump
functions used
22
7. Results Inverse DesignPARSEC Method
Target and Final Airfoil Shapes using PARSEC
method
Final Pressure Distribution
23
7. Results Drag Minimization
  • - NACA 0012, M0.75, a 2
  • Objective Function
  • Coefficients were chosen as 1/3

  • 5
  • - Airfoil thickness is constrained as well

24
7. Results Drag MinimizationB-Spline Curves vs
Hicks-Henne Bump Functions
Final Airfoil Shapes
Final Pressure Distribution
Convergence of Objective Function
25
7. Results Drag MinimizationB-Spline Curves vs
Hicks-Henne Bump Functions
Initial Lift and Drag cl 0.373
cd 0.0151
Final Lift and Drag for Various Cases
26
8. Conclusions
  • The smoothing of the gradient accelerates the
    convergence of the objective function even when
    using B-Spline curves as design variables
  • Without the smoothing of the gradient, increasing
    the number of B-spline control points leads to a
    final shape that departs from the target shape
    due to unsmooth gradients
  • The Hicks-Henne bump function are able to provide
    a design space where the target pressure is
    obtainable but the level of accuracy is lower
    than that achieved from the mesh points and
    B-spline curves
  • The width of the Hicks-Henne bump functions
    affects the convergence of the objective function

27
8. Conclusions
  • The PARSEC method is unable to modify the leading
    edge shape of the NACA 0012 airfoil to reproduce
    the target shape (Onera M6 airfoil)
  • Both Hicks-Henne bump functions and B-spline can
    sucessfully be used for drag minimization
  • The Hicks-Henne bump function are able to modify
    the upper surface in the vicinity of the shock
    wave to eliminate the pressure discontinuity,
    however it was unable to provide the necessary
    shape modifications for the inverse design
    problem

28
9. Current and Future Work
  • Use an optimization algorithm that requires the
    Hessian matrix and a more accurate line search
    algorithm
  • Study the effect of shape parameterization
    techniques for unsymmetrical airfoils
  • Study the PARSEC method for drag minimization
  • Extend the study for three dimensional shapes

29
Questions ???
  • Patrice Castonguay
  • patrice.castonguay_at_mail.mcgill.ca
  • Siva Nadarajah
  • siva.nadarajah_at_mcgill.ca

29
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