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Original scientific paper

Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic

Hinko Wolf

Fulltext: english, pdf (1 MB) pages 117-131 downloads: 243* cite
APA 6th Edition
Wolf, H. (2008). Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic. Interdisciplinary Description of Complex Systems, 6 (2), 117-131. Retrieved from https://hrcak.srce.hr/76859
MLA 8th Edition
Wolf, Hinko. "Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic." Interdisciplinary Description of Complex Systems, vol. 6, no. 2, 2008, pp. 117-131. https://hrcak.srce.hr/76859. Accessed 23 Jul. 2019.
Chicago 17th Edition
Wolf, Hinko. "Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic." Interdisciplinary Description of Complex Systems 6, no. 2 (2008): 117-131. https://hrcak.srce.hr/76859
Harvard
Wolf, H. (2008). 'Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic', Interdisciplinary Description of Complex Systems, 6(2), pp. 117-131. Available at: https://hrcak.srce.hr/76859 (Accessed 23 July 2019)
Vancouver
Wolf H. Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic. Interdisciplinary Description of Complex Systems [Internet]. 2008 [cited 2019 July 23];6(2):117-131. Available from: https://hrcak.srce.hr/76859
IEEE
H. Wolf, "Response and Dynamical Stability of Oscillators with Discontinuous or Steep First Derivative of Restoring Characteristic", Interdisciplinary Description of Complex Systems, vol.6, no. 2, pp. 117-131, 2008. [Online]. Available: https://hrcak.srce.hr/76859. [Accessed: 23 July 2019]

Abstracts
Response and dynamical stability of oscillators with discontinuous or steep first derivative of restoring characteristic is considered in this paper. For that purpose, a simple single-degree-offreedom system with piecewise-linear force-displacement relationship subjected to a harmonic force
excitation is analysed by the method of piecing the exact solutions (MPES) in the time domain and by the incremental harmonic balance method (IHBM) in the frequency domain. The stability of the periodic solutions obtained in the frequency domain by IHBM is estimated by the Floquet-Lyapunov theorem. Obtained frequency response characteristic is very complex and includes multi-frequency response for a single frequency excitation, jump phenomenon, multi-valued and non-periodic solutions. Determining of frequency response characteristic in the time domain by MPES is exceptionally time consuming, particularly inside the frequency ranges of co-existence of multiple stable solutions. In the frequency domain, IHBM is very efficient and very well suited for obtaining wide range frequency response characteristics, parametric studies and bifurcation analysis. On the other hand, neglecting of very small harmonic terms (which in-significantly influence the r.m.s. values of the response and are very small in comparison to other terms of the spectrum) can cause very large error in evaluation of the eigenvalues of the monodromy matrix, and so they can lead to incorrect prediction of the dynamical stability of the solution. Moreover, frequency ranges are detected inside which the procedure of evaluation of eigenvalues of the monodromy matrix does not converge with increasing the number of harmonics included in the supposed approximate solution.

Keywords
dynamical stability; response characteristic; non-linear vibrations; piecewise-linear system

Hrčak ID: 76859

URI
https://hrcak.srce.hr/76859

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