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extended-hamilton-s-principle
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Closed-form solution of natural frequencies of a cantilever beam under longitudinal rotation of the support
, Article DETC2005: ASME International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, Long Beach, CA, 24 September 2005 through 28 September 2005 ; Volume 1 A , 2005 , Pages 145-151 ; 0791847381 (ISBN); 9780791847381 (ISBN) ; Durali, M ; Jalili, N ; Sharif University of Technology
American Society of Mechanical Engineers
2005
Abstract
This paper presents the modeling steps towards development of frequency equations for a cantilever beam with a tip mass under general base excitations. More specifically, the beam is considered to vibrate in all the three directions, while subjected to a base rotational motion around its longitudinal direction. This is a common configuration utilized in many vibrating beam gyroscopes and well drilling systems. The governing equations are derived using Extended Hamilton's Principle with general 6-DOF base motion. The natural frequency equations are then extracted in closed-form for the case where the base undergoes longitudinal rotation. For validation purposes, the resulting natural...
Modeling and vibration analysis of vibrating beam microgyroscopes under longitudinal rotation of the support
, Article 2005 ASME International Mecahnical Engineering Congress and Exposition, IMECE 2005, Orlando, FL, 5 November 2005 through 11 November 2005 ; Volume 7 MEMS , 2005 , Pages 345-351 ; 1096665X (ISSN); 079184224X (ISBN); 9780791842249 (ISBN) ; Durali, M ; Jalili, N ; ASME Micro Electro Mecahnical Systems Division ; Sharif University of Technology
2005
Abstract
This paper discusses the effects of substrate motions on the performance of a microgyroscope modeled as a suspended beam with a tip mass. These motions can be either along or around the three axes. Using the Extended Hamilton's Principle, the equations of motion are derived. In these equations, the effects of beam distributed mass, tip mass, angular accelerations, centripetal and coriolis accelerations are well apparent. The effect of electrostatic forces inducing the excitation vibrations are considered as linear functions of beam displacement. The response of the system to different inputs is studied and the system sensitivity to input parameter changes are examined. Finally, the sources...