Research Model Wing Benchmark. AIAA Journal, 2014 (to be published). The final published article may differ from this preprint. Aerodynamic Shape Optimization Investigations of the Common Research Model Wing Benchmark

Abstract Despite considerable research on aerodynamic shape optimization, there is no stan-dard benchmark problem allowing researchers to compare results. This work addresses this issue by solving a series of aerodynamic shape optimization problems based on the Common Research Model wing benchmark case defined by the Aerodynamic Design Optimization Discussion Group (ADODG). The aerodynamic model solves the Reynolds-averaged Navier–Stokes equations with a Spalart–Allmaras turbulence model. A gradient-based optimization algorithm is used in con-junction with an adjoint method that computes the required derivatives. The drag coefficient is minimized subject to lift, pitching moment, and geometric constraints. A multilevel technique is used to reduce the computational cost of the optimization. A single-point optimization is solved with 720 shape variables using a 28.8-million-cell mesh, reducing the drag by 8.5%. A more real-istic design is achieved through a multipoint optimization. Multiple local minima are found when starting from multiple randomly generated geometries, but the minimum drag values are within 0.1 drag counts of each other, and the geometries differ by only 0.4 % of the mean aerodynamic chord. The effect of varying the number of shape design variables is examined. The Common Re-search Model wing benchmark problem proved to be useful for evaluating our design optimizatio