The Python XFOIL optimization toolbox can be used to optimize airfoils for a specific operating range. I initially made it to be able to optimize the shape of a strut.
NOTE: Windows and Mac XFOIL binaries are included, see xfoil folder. You might have to rename them. It would be nice if the correct binary is automatically detected, should be quite easy to implement using sys.platform. Feel free to implement this if you want a small programming challenge :)
of its three different toolsets:
/xfoilmodule: Communicates with XFOIL, makes it possible to retrieve polar data with just one function call./airfoil_generators: Contains parametric airfoil generators which convert a list of numbers into an airfoil shape. Currently implemented:- NACA 4-series (for testing and fun)
- PARSEC (is limited in the shapes it can produce but produces reasonable airfoil shapes, play around with it here)
/optimization_algorithms: An optimization algorithm tries to find a point in a multidimensional space with the lowest score (e.g. point (x,y) within 1<x<5 and 4<y<6, scored by calculating drag of NACAxy15 at alpha=0 and Re=1M). Currently implemented:- Particle Swarm Optimization: robust, easy-to-use, gradient-free optimization algorithm that often outperforms more complex algorithms.
Being able to easily generate airfoils and communicate with XFOIL is very powerful. With not too much effort, you can make a plot like this:
Go to code
PSO is an optimization technique inspired by a flock of birds searching for food. It is relatively simple, doesn't concern itself with gradients, and often outperforms more complex techniques like genetic algorithms. See it working on the Rastrigin function in this code example.
It can easily be applied to airfoils, simply by translating the list of constrained numbers into an airfoil, then scoring the airfoil using the xfoil module to get lift, drag, moment or anything else at a specified Re and alpha or Cl. An attempt at optimizing a PARSEC airfoil shape for lowest drag at an angle of attack of 0 and a Reynolds number of 1 million, produces the following:
Go to code
http://eprints.soton.ac.uk/50031/1/Sobe07.pdf
Follows the method implemented in this paper. It reduces the number of paramters from 12(required in PARSEC) to 6, helping in reducing the computational resource need for the optimization process. The only drawback being, it doesn't work too well with transonic airfoils, as reducing the number of paramters also
means giving up some control over the airfoil spline. The figure below shows NURBS working with PSO particle optimizer.
- NURBS airfoils: A great idea would be to add NURBS airfoils to the airfoil generators, as NURBS can define very smooth airfoils using very few parameters, so it's a good fit for optimization purposes. Ideally, its shape can be initialized by fitting it to some existing shape, to start off with a reasonable airfoil.
- Simulated Annealing optimization technique: Would be interesting to compare this technique with PSO.