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Acta Aeronautica et Astronautica Sinica ›› 2023, Vol. 44 ›› Issue (18): 128327-128327.doi: 10.7527/S1000-6893.2023.28327

• Fluid Mechanics and Flight Mechanics • Previous Articles     Next Articles

Application of orthogonal matching pursuit to airfoil uncertainty quantification

Handuo HU, Yanping SONG, Jianyang YU(), Yao LIU, Fu CHEN, Wenxiu GAO   

  1. School of Energy Science and Engineering,Harbin Institute of Technology,Harbin 150001,China
  • Received:2022-11-29 Revised:2023-02-17 Accepted:2023-03-20 Online:2023-09-25 Published:2023-03-31
  • Contact: Jianyang YU E-mail:yujianyang@hit.edu.cn
  • Supported by:
    National Natural Science Foundation of China(52006045)

Abstract:

Uncertainties exist widely in realistic systems. To evaluate the stochastic response of the system output with various uncertainties, traditional uncertainty quantification methods such as Monte Carlo Sampling (MCS) and Polynomial Chaos Expansion (PCE) require large quantities of samples, restricting their application to complex systems such as aircraft airfoils. The rapidly developed compressive sensing in signal processing field enables precise reconstruction of the signal based on the sparsity of original signals with only a small number of samples. This feature has attracted researchers to explore the application of compressive sensing to uncertainty quantification research. This study considers the geometrical uncertainty of the RAE2822 airfoil in manufacturing, assembly, and flight, and parameterizes the original shape with the Class-Shape Transformation (CST) method. We combine compressive sensing with polynomial chaos expansion for uncertainty quantification, and adopt the Orthogonal Matching Pursuit (OMP) algorithm to reconstruct the polynomial coefficients. In this way, the mean values and standard deviations of the aerodynamic forces and flow field quantities with geometrical uncertainty are obtained and compared to those of the Monte Carlo sampling and Full-Rank Probabilistic Collocations (FRPC) method. Comparison of convergence, sample number requirement and accuracy shows that the orthogonal matching pursuit can use fewer samples to obtain similar results as traditional methods. Since most of the stochastic responses of actual systems have sparse representations on polynomial chaos bases, the application of compressive sensing to uncertainty quantification can significantly decrease the required samples, thereby reducing time costs and improving computational efficiency.

Key words: compressive sensing, orthogonal matching pursuit, polynomial chaos expansion, uncertainty quantification, airfoil uncertainty, class-shape transformation

CLC Number: