Analysis of Nonlinear Aeroelastic Panel Response Using Proper Orthogonal Decomposition-Reference-Cited by-同舟云学术

Analysis of Nonlinear Aeroelastic Panel Response Using Proper Orthogonal Decomposition

Published:2004-07-01 Issue:3 Volume:126 Page:416-421
ISSN:1048-9002
Container-title:Journal of Vibration and Acoustics
language:en
Short-container-title:

Author:

Mortara Sean A.¹,Slater Joseph¹,Beran Philip²

Affiliation:

1. Dept. of Mech. & Mat. Engr., Wright State University, Dayton, Ohio 45435 (937)-775-5085

2. Air Force Research Laboratory, VASD, Wright-Patterson AFB, Dayton, Ohio 45433

Abstract

The nonlinear panel flutter problem solved by Dowell in 1966 is used to investigate the new application of the proper orthogonal decomposition model reduction technique to aeroelastic analysis. Emphasis is placed on the nonlinear structural dynamic equations with nonconservative forcing modeled assuming a supersonic, inviscid flow. Here the aeroelastic coupled equation is presented in discrete form using a finite difference approach, and subsequently in state space form, to be integrated as a set of first order differential equations. In this paper, a POD approach is developed for generalized second-order differential equations; however, the application of POD to the governing equations in state space form is also discussed. This study compares the results and effectiveness of the model reduction technique for integration of the full set of degrees of freedom. The solution is compared to Dowell’s classic results which forms the base reference for the model reduction study. The reduced order model is then created from the full simulation model. Accuracy of the solution, reduced computational time, limits of stability, and the strengths and weaknesses of the model reduction are investigated.

Publisher

ASME International

Subject

General Engineering

Link

http://asmedigitalcollection.asme.org/vibrationacoustics/article-pdf/126/3/416/5827534/416_1.pdf

Reference16 articles.

1. Dowell, E. H. , 1966, “Nonlinear Oscillations of a Fluttering Plate,” AIAA J., 4(7), July, pp. 1267–1275.

2. Dowell, E. H., 1975, Aeroelasticity of Plates and Shells, chap. 3: “Nonlinear Theoretical Aeroelastic Models,” pp. 35–36.

3. Slater, J., Petit, C., and Beran, P., 2002, “In-Situ Subspace Evaluation in Reduced Order Modeling,” Shock Vib., 9, pp. 105–122.

4. Beran, P., and Silva, W., 2001, “Reduced-Order Modeling: New Approaches for Computational Physics,” 39th Aerospace Sciences Meeting & Exhibit, No. 2001-0853, Reno, NV, Jan 2001.

5. Romanowski, M., 1996, “Reduced Order Unsteady Aerodynamic and Aeroelastic Models Using Karhunen-Loeve Eigenmodes,” Part 3, Bellevue, WA, Sept., AIAA 96-3981-CP.

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