Operational modal analysis explained

Ambient modal identification, also known as operational modal analysis (OMA), aims at identifying the modal properties of a structure based on vibration data collected when the structure is under its operating conditions, i.e., no initial excitation or known artificial excitation. The modal properties of a structure include primarily the natural frequencies, damping ratios and mode shapes. In an ambient vibration test the subject structure can be under a variety of excitation sources which are not measured but are assumed to be 'broadband random'. The latter is a notion that one needs to apply when developing an ambient identification method. The specific assumptions vary from one method to another. Regardless of the method used, however, proper modal identification requires that the spectral characteristics of the measured response reflect the properties of the modes rather than those of the excitation.

Pros and cons

Implementation economy is one primary advantage of ambient vibration tests as only the (output) vibration of the structure needs to be measured. This is particularly attractive for civil engineering structures (e.g., buildings, bridges) where it can be expensive or disruptive to carry out free vibration or forced vibration tests (with known input).

Identifying modal properties using ambient data does have disadvantages:

Methods

Methods of OMA can be broadly classified by two aspects, 1) frequency domain or time domain, and 2) Bayesian or non-Bayesian. Non-Bayesian methods were developed earlier than Bayesian ones. They make use of some statistical estimators with known theoretical properties for identification, e.g., the correlation function or spectral density of measured vibrations. Common non-Bayesian methods include stochastic subspace identification[2] (time domain) and frequency domain decomposition[3] (frequency domain). Bayesian methods have been developed in the time-domain[4] and frequency-domain.[5] [6] [7]

Frequency domain and time domain operational modal analysis of structures

The objective of operational modal analysis is to extract resonant frequencies, damping, and/or operating shapes (unscaled mode shapes) of a structure. This method sometime called output-only modal analysis because only the response of the structure is measured. The structure might be excited using natural operating conditions or some other excitations might be applied to the structure;[8] however, as long as the operating shapes are not scaled based on the applied force, it is called operational modal analysis (e.g. operating shapes of a wind turbine blade excited by a shaker are measured using operating modal analysis[9]). This method has been used to extract operating modes of a hovering helicopter.[10]

Operational modal analysis versus operational deflection shape

The two terms, Operational Modal Analysis and Operational Deflection Shape, are very similar, but refer to two different analysis approaches. Both use ambient vibration data as inputs, but in the case of Operational Deflection Shapes, a shape that corresponds to the overall vibration response is created. It is based on the vibration amplitude only, there is no attempt to extract a mode shape and no quantification of the modal damping can be obtained. While Operational Modal Analysis, when the main assumptions are met, yields a representation of a system characteristic in its operating environment, an Operational Deflection Shape will simply extract the system response under the currently applied loads.[11]

Notes

See also

Notes and References

  1. Ghalishooyan. M.. Shooshtari. May 12–14, 2015. Operational Modal Analysis Techniques and Their Theoretical and Practical Aspects: A Comprehensive Review and Introduction. 5th International Operational Modal Analysis Conference (IOMAC 2015). Gijon, Spain.
  2. Book: Van Overschee , P. . De Moor, B.. Subspace Identification for Linear Systems. 1996. Kluwer Academic Publisher. Boston.
  3. Brincker. R.. Zhang. L.. Andersen. P.. 2001. Modal identification of output-only systems using frequency domain decomposition. Smart Materials and Structures. 10. 3. 441. 2001SMaS...10..441B. 10.1088/0964-1726/10/3/303. 250917814 .
  4. Yuen. K.V.. Katafygiotis, L.S.. Bayesian time-domain approach for modal updating using ambient data. Probabilistic Engineering Mechanics. 2001. 16. 3. 219–231. 10.1016/S0266-8920(01)00004-2.
  5. Yuen. K.V.. Katafygiotis, L.S.. Bayesian spectral density approach for modal updating using ambient data. Earthquake Engineering & Structural Dynamics. 2001. 30. 8. 1103–1123. 10.1002/eqe.53. 110355068.
  6. Yuen. K.V.. Katafygiotis, L.S.. Bayesian Fast Fourier Transform approach for modal updating using ambient data. Advances in Structural Engineering. 2003. 6. 2. 81–95. 10.1260/136943303769013183. 62564168.
  7. Book: Au , S.K. . Operational Modal Analysis: Modeling, Inference, Uncertainty Laws. 2017. Springer.
  8. http://www.sandv.com/downloads/1406avit.pdf Improved Modal Characterization Using Hybrid Data
  9. http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=1315174 Using Stereophotogrammetry to Measure Vibrations of a Wind Turbine Blade
  10. Book: https://link.springer.com/chapter/10.1007/978-1-4614-6546-1_44 . 10.1007/978-1-4614-6546-1_44 . Using High-Speed Stereophotogrammetry to Collect Operating Data on a Robinson R44 Helicopter . Special Topics in Structural Dynamics, Volume 6 . Conference Proceedings of the Society for Experimental Mechanics Series . 2013 . Lundstrom . Troy . Baqersad . Javad . Niezrecki . Christopher . 401–410 . 978-1-4614-6545-4 .
  11. Web site: Operational Modal Analysis vs Operational Deflection Shape . community.sw.siemens.com . ODS.
  12. Book: Schipfors , M. . Fabbrocino, G.. Operational Modal Analysis of Civil Engineering Structures. 2014. Springer.
  13. Book: Brincker , R. . Ventura, C.. Introduction to Operational Modal Analysis. 2015. John Wiley & Sons. 10.1002/9781118535141. 9781118535141.
  14. Web site: Operational Modal Analysis Dataverse .