Description
Advanced Nonlinear Strategies for Vibration Mitigation and System Identification, 2010
CISM International Centre for Mechanical Sciences Series, Vol. 518
Language: English
Advanced Nonlinear Strategies for Vibration Mitigation and System Identification
Publication date: 06-2012
300 p. · 15.5x23.5 cm · Paperback
Publication date: 06-2012
300 p. · 15.5x23.5 cm · Paperback
Advanced nonlinear strategies for vibration mitigation and system identification (CISM international centre for mechanical sciences, Vol. 518)
Publication date: 05-2010
300 p. · 15.5x23.5 cm · Hardback
Publication date: 05-2010
300 p. · 15.5x23.5 cm · Hardback
Description
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The papers in this volume address advanced nonlinear topics in the general areas of vibration mitigation and system identification, such as, methods of analysis of strongly nonlinear dyanmical systems; techniques and methodologies for interpreting complex, multi-frequency transitions in damped nonlinear responses; new approaches for passive vibration mitigation based on nonlinear targeted energy transfer (TET) and the associated concept of nonlinear energy sink (NES); and an overview and assessment of current nonlinear system identification techniques.
Mitigation Strategies for Systems Subjected to Vibratory, Shock and Seismic Loads.- Targeted Energy Transfer in Systems with Periodic Excitations.- Advanced Strategies for Nonlinear System Identification.- CISM Courses and Lectures: Resonant energy exchange in nonlinear oscillatory chains and Limiting Phase Trajectories: from small to large systems.- Signal Processing for Experiments with Nonlinear Energy Sinks.- Nonlinear Targeted Energy Transfer and its Application to Vibration Mitigation.
A detailed discussion of advanced nonlinear topics in vibration mitigation and system ID
Discusses methodologies for interpreting complex, multi-frequency transitions in damped nonlinear responses
Provides an overview and assessment of current nonlinear system identification techniques
Discusses methodologies for interpreting complex, multi-frequency transitions in damped nonlinear responses
Provides an overview and assessment of current nonlinear system identification techniques
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