Abstract
The Operational Modal Analysis technique is a methodology very often applied for the identification of dynamic systems when the input signal is unknown. The applied methodology is based on a technique to estimate the Frequency Response Functions and extract the modal parameters using only the structural dynamic response data, without assuming the knowledge of the excitation forces. Such approach is an adequate way for measuring the aircraft aeroelastic response due to random input, like atmospheric turbulence. The in-flight structural response has been measured by accelerometers distributed along the aircraft wings, fuselage and empennages. The Enhanced Frequency Domain Decomposition technique was chosen to identify the airframe dynamic parameters. This technique is based on the hypothesis that the system is randomly excited with a broadband spectrum with almost constant power spectral density. The system identification procedure is based on the Single Value Decomposition of the power spectral densities of system output signals, estimated by the usual Fast Fourier Transform method. This procedure has been applied to different flight conditions to evaluate the modal parameters and the aeroelastic stability trends of the airframe under investigation. The experimental results obtained by this methodology were compared with the predicted results supplied by aeroelastic numerical models in order to check the consistency of the proposed output-only methodology. The objective of this paper is to compare in-flight measured aeroelastic damping against the corresponding parameters computed from numerical aeroelastic models. Different aerodynamic modeling approaches should be investigated such as the use of source panel body models, cruciform and flat plate projection. As a result of this investigation it is expected the choice of the better aeroelastic modeling and Operational Modal Analysis techniques to be included in a standard aeroelastic certification process.
Highlights
Aeroelastic flight testing is associated frequently to flutter testing, defined as an experimental way to predict aeroelastic stability margins from measured aeroelastic damping
Within the perspective extracted from previous investigation on Operational Modal Analysis (OMA), this paper aims to continue the investigation reported by Ferreira et al (2008)
Theoretical Aeroelastic Analysis Results The results of the present investigation are divided into theoretical aeroelastic analysis results and in-flight operational modal analysis results
Summary
Background Aeroelastic flight testing is associated frequently to flutter testing, defined as an experimental way to predict aeroelastic stability margins from measured aeroelastic damping. Several methods have been developed with that goal These methods include approaches based on extrapolating damping trends from available aeroelastic damping and assuming data extrapolation (Kehoe 1995). All of these approaches lead to a prediction of flutter speed from subcritical conditions. Dimitriadis and Cooper (2001) and Lind and Brenner (2002) present comparisons between most of the known flutter prediction methodologies. These references are good texts for understanding some flutter testing techniques to be commented
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