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Osama, F., Amer, Y., raslan, K. (2021). Suppress the vibration of a nonlinear dynamical system subjected to external force using a positive position feedback control.. Al-Azhar Bulletin of Science, 32(Issue 1-B), 1-16. doi: 10.21608/absb.2020.46646.1090
Fagr Osama; Yaser Amer; Kamal raslan. "Suppress the vibration of a nonlinear dynamical system subjected to external force using a positive position feedback control.". Al-Azhar Bulletin of Science, 32, Issue 1-B, 2021, 1-16. doi: 10.21608/absb.2020.46646.1090
Osama, F., Amer, Y., raslan, K. (2021). 'Suppress the vibration of a nonlinear dynamical system subjected to external force using a positive position feedback control.', Al-Azhar Bulletin of Science, 32(Issue 1-B), pp. 1-16. doi: 10.21608/absb.2020.46646.1090
Osama, F., Amer, Y., raslan, K. Suppress the vibration of a nonlinear dynamical system subjected to external force using a positive position feedback control.. Al-Azhar Bulletin of Science, 2021; 32(Issue 1-B): 1-16. doi: 10.21608/absb.2020.46646.1090

Suppress the vibration of a nonlinear dynamical system subjected to external force using a positive position feedback control.

Article 2, Volume 32, Issue 1-B, June 2021, Page 1-16  XML PDF (1.4 MB)
Document Type: Review Article
DOI: 10.21608/absb.2020.46646.1090
Authors
Fagr Osama email 1; Yaser Amer2; Kamal raslan3
1Department of Basic Science, Higher Technological Institute, Tenth of Ramadan City, Egypt.
2a Department of Mathematics, Faculty of Science, Zagazig University, Zagazig, Egypt
3Department of Mathematics, Faculty of Science, Al-Azhar University, Nasr City, Egypt
Abstract
 
Vibration suppression using a positive position feedback (PPF) control for a nonlinear dynamical system which subjected to an external force is studied. The proposed model is the vertical dynamic excitation of structures induced by a single pedestrian walking along a straight path on flat and relatively stiff surfaces. The multiple scale perturbation technique was applied to derive the first order approximate solution of the system. The response equation and the stability criteria for the system were derived near the simultaneous primary and internal resonance cases. MATLAB 14.0 have been used for the numerical studying to show the time history of the main system with and without PPF controller. Also, the effect of the system parameters on the response system have been studied. A comparison between the approximate and numerical solutions is illustrated and it show a good agreement between them. It is found that (PPF) controller is very suitable for small natural frequency dynamical systems subjected to primary resonance excitations.
Keywords
Positive position feedback controller; multiple scale perturbation method; response equation; primary resonance case; external force
Main Subjects
Mathematics
References
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