Extended framework of Hamilton’s principle for single-degree-of-freedom nonlinear damping systems

Extended framework of Hamilton’s principle for single-degree-of-freedom nonlinear damping systems

The paper explores application of the variational formalism called extended framework of Hamilton’s principle to nonlinear damping systems. Single-degree-of-freedom systems with dominant source of nonlinearity from polynomial powers of the velocity are initially considered. Appropriate variational f...

Full description

Bibliographic Details
Main Author:	Jinkyu Kim
Format:	Article
Language:	English
Published:	SAGE Publishing 2021-09-01
Series:	Journal of Low Frequency Noise, Vibration and Active Control
Online Access:	https://doi.org/10.1177/1461348420961611

Similar Items

Criticality of damping in multi-degree-of-freedom systems
by: Bhaskar, A.
Published: (1997)

Lyapunov Equivalent Representation Form of Forced, Damped, Nonlinear, Two Degree-of-Freedom Systems
by: Alex Elías-Zúñiga, et al.
Published: (2018-04-01)

Single degree of freedom transformation of multi-layer sandwich damped beams
by: Chung Weiwen, et al.
Published: (2011)

The stability analysis for the motion of a nonlinear damped vibrating dynamical system with three-degrees-of-freedom
by: T.S. Amer, et al.
Published: (2021-09-01)

Particle Damping with Granular Materials for Multi Degree of Freedom System
by: Masanobu Inoue, et al.
Published: (2011-01-01)

Nonlinear compensation of a single degree of freedom magnetic suspension system
by: Olson, Sean Michael
Published: (2005)

Determination of the motion of free nonlinear single degree of freedom vibration systems
by: Kearl, Russell Reid
Published: (2007)

A study of the Hermitian numerical method applied to the single degree of freedom, damped oscillator.
by: Van Sickle, Garth Allan
Published: (2012)

Experimental added modal damping induced by confined granular media on a single degree of freedom system
by: Sternberger Antoine, et al.
Published: (2017-01-01)

Nonlinear Structure Identification of Single Degree of Freedom System Using NARMAX Algorithm
by: Srinivasa, Manjunath Cheekur
Published: (2017)

Derivation of Equations for Flexible Multibody Systems in Terms of Quasi-Coordinates from the Extended Hamilton’s Principle
by: L. Meirovitch
Published: (1993-01-01)

Principle Research on a Single Mass Piezoelectric Six-Degrees-of-Freedom Accelerometer
by: Jingcheng Liu, et al.
Published: (2013-08-01)

Energy diffusion in nonlinear systems of large degrees of freedom
by: Tsaur,Gin-yih, et al.
Published: (1996)

Dynamics of three-degree-of-freedom systems with quadratic nonlinearities
by: Nayfeh, Tariq Ali
Published: (2014)

Nonlinear resonances in systems having many degrees of freedom
by: Sridhar, Seshadri
Published: (2014)

Feedback control for two-degree-of-freedom vibration system with fractional-order derivative damping
by: Canchang Liu, et al.
Published: (2018-09-01)

Analysis of a multi-degree of freedom vibrating system with viscous damping using the digital computer.
by: Miklos, Thomas J.
Published: (2012)

Hamiltonicity, Pancyclicity, and Cycle Extendability in Graphs
by: Arangno, Deborah C.
Published: (2014)

Critical Response of Single-Degree-of-Freedom Damped Bilinear Hysteretic System under Double Impulse As Substitute for Near-Fault Ground Motion
by: Hiroki Akehashi, et al.
Published: (2018-03-01)

Evaluation of Strength Reduction Factor for Concentrically Braced Frames Based on Nonlinear Single Degree-of-Freedom Systems
by: Slein, Ryan Michael
Published: (2016)

Linear and nonlinear compensation techniques for control of a single degree of freedom magnetic bearing
by: Salvatore, Claudio, 1974-
Published: (2005)

Vibration isolation systems, considered as systems with single degree of freedom
by: Zebilila Mohammed, et al.
Published: (2017-01-01)

Hamilton’s Principle for Circuits with Dissipative Elements
by: Zdeněk Biolek, et al.
Published: (2019-01-01)

Hamilton´s Principle and Electric Circuits Tudory
by: Daniel Mayer
Published: (2006-01-01)

Design and construction of a three degree-of-freedom lightweigh passively-damped robot arm
by: Tomlinson, Charles M.
Published: (2007)

Nonlinear Oscillations in a Self-Oscillatory System with Two Degrees of Freedom
by: Kuramitsu, Masami
Published: (2012)

Identification of multi-degree-of-freedom nonlinear systems with focus on spectral methods /
by: Richards, Christopher M.
Published: (1998)

Free steady motion in undamped nonlinear two degree of freedom systems
by: Henry, R. F.
Published: (1961)

Enriched degree of freedom locking in crack analysis using the extended finite element method
by: Han-Soo Kim, et al.
Published: (2019-06-01)

Torque and thermal characteristics analysis of a fluid damping based multi-degree-of-freedom motor
by: Zheng Li, et al.
Published: (2017-03-01)

Reach on damping control and stability analysis of vehicle with double time-delay and five degrees of freedom
by: Kaiwei Wu, et al.
Published: (2021-06-01)

Parametrically Excited Nonlinear Two-Degree-of-Freedom Systems with Repeated Natural Frequencies
by: A. H. Nayfeh, et al.
Published: (1995-01-01)

A Transformation Method for Solving Conservative Nonlinear Two-Degree-of-Freedom Systems
by: Alex Elías-Zúñiga, et al.
Published: (2014-01-01)

Hamilton's principle applied to dynamic analysis of bridges
by: Goodwin, E.
Published: (1982)

A Study of The Two-Dimensional Three-Degree-of-Freedom Nonlinear Vibration System
by: Po-Han Chen, et al.
Published: (2007)

Response of a nonlinear two-degree-of-freedom system subjected to an impact loading
by: Theisen, Jerome G.
Published: (2014)

Rigid-plastic membrane response of thin plates under impulsive blast loads using the extended Hamilton principle
by: Alotaibi, S.A.E, et al.
Published: (2023)

Oscillations in a nonlinear spring mechanism with one degree of freedom
by: Kondratenko Leonid, et al.
Published: (2020-01-01)

Achievability of nonlinear degrees of freedom in correlatively changing fading channels
by: Karzand, Mina, et al.
Published: (2014)

A Corotational Formulation Based on Hamilton’s Principle for Geometrically Nonlinear Thin and Thick Planar Beams and Frames
by: Hesham A. Elkaranshawy, et al.
Published: (2018-01-01)