Reprint

Advances in Mechanical Systems Dynamics

Edited by
February 2020
236 pages
  • ISBN978-3-03928-188-6 (Paperback)
  • ISBN978-3-03928-189-3 (PDF)

This is a Reprint of the Special Issue Advances in Mechanical Systems Dynamics that was published in

Biology & Life Sciences
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary
Modern dynamics was established many centuries ago by Galileo and Newton before the beginning of the industrial era. Presently, we are in the presence of the fourth industrial revolution, and mechanical systems are increasingly being integrated with electronic, electrical, and fluidic systems. This trend is present not only in the industrial environment, which will soon be characterized by the cyber-physical systems of industry 4.0, but also in other environments like mobility, health and bio-engineering, food and natural resources, safety, and sustainable living. In this context, purely mechanical systems with quasi-static behavior will become less common and the state-of-the-art will soon be represented by integrated mechanical systems, which need accurate dynamic models to predict their behavior. Therefore, mechanical system dynamics are going to play an increasingly central role. Significant research efforts are needed to improve the identification of the mechanical properties of systems in order to develop models that take non-linearity into account, and to develop efficient simulation tools. This Special Issue aims at disseminating the latest research achievements, findings, and ideas in mechanical systems dynamics, with particular emphasis on applications that are strongly integrated with other systems and require a multi-physical approach.
Format
  • Paperback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
dynamics; mesh stiffness; forced response; time-variant parameters; Method of Multiple Time-Scales; cyclic-symmetric systems dynamics; lumped parameters model; quadruped robots; high-speed locomotion; leg trajectory planning; trot gait; motion capture sensor; low-speed stability; balancing; motorcycle dynamics; rider control; unsteady flow control; vortex dynamics; separation flow; Detached-Eddy Simulation; natural motion; natural dynamics; energy saving; robotic system; trajectory planning; optimization; landing gear; emergency extension; reliability sensitivity analysis; driving mechanism; mixture of models; damper force; pitch angle; seeder dynamics; simulation model; reaching law; sliding mode control (SMC); ground-based laser communication turntable; chatter-free; quasi-sliding mode domain (QSMD); under-platform damper; bladed disc’s rotation; compositive motion; relative displacement; dynamical characteristic; variable compression ratio; adjustable hydraulic volume; mathematical model; dynamic characteristics; simulation; switched reluctance motor; vibration prediction; multi-physics modelling; personal mobility vehicle; active tilting; inner wheel lifting; obstacle avoidance; energy efficiency; n/a