Abstract
Design candidates obtained from optimization techniques may have meaningful information, which provides not only the best solution, but also a relationship between object functions and design variables. In particular, trade-off studies for optimum airfoil shape design involving various objectives and design variables require the effective analysis tool to take into account a complexity between objectives and design variables. In this study, for the multiple-conflicting objectives that need to be simultaneously fulfilled, the real-coded Adaptive Range Multi-Objective Genetic Algorithm code, which represents the global and stochastic multi-objective evolutionary algorithm, was developed for an airfoil shape design. Furthermore, the PARSEC method reflecting geometrical properties of airfoil is adopted to generate airfoil shapes. In addition, the Self-Organizing Maps, based on the neural network, are used to visualize trade-offs of a relationship between the objective function space and the design variable space obtained by evolutionary computation. The Self-Organizing Maps that can be considered as data mining of the engineering design generate clusters of object functions and design variables as an essential role of trade-off studies. The aerodynamic data for all candidate airfoils is obtained through Computational Fluid Dynamics. Lastly, the relationship between the maximum lift coefficient and maximum lift-to-drag ratio as object functions and 12 airfoil design parameters based on the PARSEC method is investigated using the Self-Organizing Maps method.
Highlights
A reference airfoil, with the aerodynamic characteristics being obtained by the Computational Fluid Dynamics (CFD) solver; the same grid topology and CFD methods applied for validations of NACA 0012 airfoil are adopted
Tournament selection, uniform crossover, and 4% of mutation are applied to the developed Adaptive Range MultiObject Genetic Algorithm (ARMOGA) code
Considering the minimum and maximum range of design variables within ± 20% of PARSEC parameters of the reference airfoil, the parameters over than 10% may be regarded as dominant to improve the aerodynamic characteristics of the reference airfoil
Summary
AN INTEGRATED OPTIMIZATION SYSTEM FOR AIRFOIL DESIGN EXPLORATIONS oPtiMiZAtion Module. As an alternative of the binary-based EAs, the real-coded ARMOGA (Sasaki and Obayashi 2005) may be attractive, since it allows the use of computer resources by using the real numbers with respect to design variables. For the range adaptation, Arakawa and Hagiwara (1998) originally proposed a normal distribution representing the design space in binary-coded Adaptive Range Genetic Algorithms (ARGA) for single-objective problem. The whole process of the real-coded ARMOGA is exactly the same of Multi-Objective Evolutionary Algorithm (MOEA), except for the range adaptation. The developed ARMOGA code (Jung and Kim 2013; Choi et al 2015), as an optimization module, is evaluated by applying it to the MO problems in Eq 1. From the comparisons between the exact solutions and the present results, the accuracy and diversities of Pareto solutions of the developed ARMOGA code are guaranteed with many samples of Pareto front
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