Abstract
This paper investigates the effect of model uncertainty on the nonlinear dynamics of a generic aeroelastic system. Among the most dangerous phenomena to which these systems are prone, Limit Cycle Oscillations are periodic isolated responses triggered by the nonlinear interactions among elastic deformations, inertial forces, and aerodynamic actions. In a dynamical systems setting, these responses typically emanate from Hopf bifurcation points, and thus a recently proposed framework, which address the problem of robustness from a nonlinear dynamics viewpoint, is employed. Briefly, the notion of robust bifurcation margin extends the concept of mu analysis technique from the robust control theory. The main contribution of this article is a systematic investigation of the numerous scenarios arising in the study of nonlinear flutter when uncertainties in the model are accounted for in the analyses. The advantages of adopting this framework include the possibility to: quantify relevant information for the determination of the nonlinear stability envelope; gain a more in-depth understanding of the physical mechanisms triggering subcritical and supercritical Hopf bifurcations; and reveal properties of the nominal system by identifying isolated branches not straightforward to detect with conventional numerical approaches.
Highlights
Aeroelasticity studies fluid-structure interaction problems governed by the coupling among inertial, elastic, and aerodynamic forces
These problems are relevant for flexible aerodynamic bodies, where these interactions result in different stress levels and aerodynamic performance compared to those computed considering a purely structural dynamics and aerodynamic problem, respectively
It has been introduced in the early stages of aeroelasticity to investigate dynamic instabilities such as flutter [6], and it has been since widely used for analysis of linear and nonlinear aeroelastic systems [12,29,31,38]
Summary
Aeroelasticity studies fluid-structure interaction problems governed by the coupling among inertial, elastic, and aerodynamic forces. The aims in UQ works devoted to aeroelastic problems are typically to investigate the effect of uncertainty on: the change of linear (or linearized) flutter speed [37]; features of the post-critical behavior (e.g., amplitude or frequencies of the LCO) [4,16] Aimed at the latter goal, but building on different tools, namely robust control techniques, in [22] a method was developed to allow the degradation of the LCO properties in the worst-case scenario to be analyzed. Preliminary results of this work were presented in [18]
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