An alternative representation of the receptance: The ‘elliptical plane’ and its modal properties
Authors: Montalvão, D. and Amafabia, D.A.M.
Journal: Mechanical Systems and Signal Processing
Volume: 103
Pages: 236-249
eISSN: 1096-1216
ISSN: 0888-3270
DOI: 10.1016/j.ymssp.2017.10.012
Abstract:Modal Identification from Frequency Response Functions (FRFs) has been extensively investigated up to the point its research reached a stagnation state. Yet, a new approach to determine the modal damping factors from FRFs was recently proposed, showing that there still is scope for new findings in the field. Contrary to other modal identification methods which are based on the dynamic motion governing equations, the method used the dissipated energy per cycle of vibration as a starting point. For lightly damped systems with conveniently spaced modes, it produced quite accurate results, especially when compared to the well-known method of the inverse. The method used a plot of the sine of the phase of the receptance against its amplitude, whereby damping was determined from the slope of a linear fit to the resulting plot. In this paper, it is shown that this plot has other (perhaps more important) special properties that were not explored before. Near resonant frequencies, its shape is elliptical, whereby the real and imaginary parts of the modal constants can be determined from numerical curve-fitting. This finding allowed developing a new method which formulation is presented in this paper. The method is discussed through numerical and experimental examples. Although the intention is not to present a new modal identification method that is superior to other existing ones (like the method of the inverse or those based on the Nyquist plot), the authors believe that this new representation of the receptance and its properties may bring valuable insights for other researchers in the field.
https://eprints.bournemouth.ac.uk/29839/
Source: Scopus
An alternative representation of the receptance: The 'elliptical plane' and its modal properties
Authors: Montalvao, D. and Amafabia, D.-A.M.
Journal: MECHANICAL SYSTEMS AND SIGNAL PROCESSING
Volume: 103
Pages: 236-249
ISSN: 0888-3270
DOI: 10.1016/j.ymssp.2017.10.012
https://eprints.bournemouth.ac.uk/29839/
Source: Web of Science (Lite)
An alternative representation of the receptance: the ‘elliptical plane’ and its modal properties.
Authors: Montalvao, D. and Amafabia, D.M.
Journal: Mechanical Systems and Signal Processing
Volume: 103
Pages: 236-249
Publisher: Academic Press
ISSN: 0888-3270
DOI: 10.1016/j.ymssp.2017.10.012
Abstract:Modal Identification from Frequency Response Functions (FRFs) has been extensively investigated up to the point its research reached a stagnation state. Yet, a new approach to determine the modal damping factors from FRFs was recently proposed, showing that there still is scope for new findings in the field. Contrary to other modal identification methods which are based on the dynamic motion governing equations, the method used the dissipated energy per cycle of vibration as a starting point. For lightly damped systems with conveniently spaced modes, it produced quite accurate results, especially when compared to the well-known method of the inverse. The method used a plot of the sine of the phase of the receptance against its amplitude, whereby damping was determined from the slope of a linear fit to the resulting plot. In this paper, it is shown that this plot has other (perhaps more important) special properties that were not explored before. Near resonant frequencies, its shape is elliptical, whereby the real and imaginary parts of the modal constants can be determined from numerical curve-fitting. This finding allowed developing a new method which formulation is presented in this paper. The method is discussed through numerical and experimental examples. Although the intention is not to present a new modal identification method that is superior to other existing ones (like the method of the inverse or those based on the Nyquist plot), the authors believe that this new representation of the receptance and its properties may bring valuable insights for other researchers in the field.
https://eprints.bournemouth.ac.uk/29839/
Source: Manual
An alternative representation of the receptance: the ‘elliptical plane’ and its modal properties.
Authors: Montalvão, D. and Amafabia, D.M.
Journal: Mechanical Systems and Signal Processing
Volume: 103
Issue: March
Pages: 236-249
ISSN: 0888-3270
Abstract:Modal Identification from Frequency Response Functions (FRFs) has been extensively investigated up to the point its research reached a stagnation state. Yet, a new approach to determine the modal damping factors from FRFs was recently proposed, showing that there still is scope for new findings in the field. Contrary to other modal identification methods which are based on the dynamic motion governing equations, the method used the dissipated energy per cycle of vibration as a starting point. For lightly damped systems with conveniently spaced modes, it produced quite accurate results, especially when compared to the well-known method of the inverse. The method used a plot of the sine of the phase of the receptance against its amplitude, whereby damping was determined from the slope of a linear fit to the resulting plot. In this paper, it is shown that this plot has other (perhaps more important) special properties that were not explored before. Near resonant frequencies, its shape is elliptical, whereby the real and imaginary parts of the modal constants can be determined from numerical curve-fitting. This finding allowed developing a new method which formulation is presented in this paper. The method is discussed through numerical and experimental examples. Although the intention is not to present a new modal identification method that is superior to other existing ones (like the method of the inverse or those based on the Nyquist plot), the authors believe that this new representation of the receptance and its properties may bring valuable insights for other researchers in the field.
https://eprints.bournemouth.ac.uk/29839/
Source: BURO EPrints