Advances in Mechanical Systems Dynamics

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...

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Auteurs principaux: Massaro, Matteo, Boschetti, Giovanni, Doria, Alberto
Format: Online
Langue:anglais
Publié: MDPI - Multidisciplinary Digital Publishing Institute 2021
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Accès en ligne:44750
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author Massaro, Matteo
Boschetti, Giovanni
Doria, Alberto
author_browse Boschetti, Giovanni
Doria, Alberto
Massaro, Matteo
author_facet Massaro, Matteo
Boschetti, Giovanni
Doria, Alberto
author_sort Massaro, Matteo
collection Directory of Open Access Books
description 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.
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spelling doab-20.500.12854ir-403062024-04-11T15:10:16Z Advances in Mechanical Systems Dynamics Massaro, Matteo Boschetti, Giovanni Doria, Alberto TA1-2040 TA349-359 T1-995 n/a pitch angle Method of Multiple Time-Scales lumped parameters model simulation dynamical characteristic dynamics unsteady flow control driving mechanism damper force optimization relative displacement bladed disc’s rotation energy efficiency ground-based laser communication turntable landing gear quasi-sliding mode domain (QSMD) variable compression ratio dynamic characteristics inner wheel lifting trot gait vortex dynamics emergency extension natural dynamics high-speed locomotion under-platform damper reliability sensitivity analysis seeder dynamics natural motion Detached-Eddy Simulation sliding mode control (SMC) obstacle avoidance active tilting robotic system switched reluctance motor cyclic-symmetric systems dynamics low-speed stability vibration prediction mesh stiffness compositive motion mixture of models leg trajectory planning trajectory planning motorcycle dynamics multi-physics modelling reaching law rider control energy saving quadruped robots separation flow balancing personal mobility vehicle chatter-free time-variant parameters simulation model mathematical model forced response motion capture sensor adjustable hydraulic volume thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology 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. 2021-02-11T07:49:18Z 2021-02-11T07:49:18Z 2020-04-07 23:07:08 2020 book 44750 9783039281893 9783039281886 https://directory.doabooks.org/handle/20.500.12854/40306 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/2025 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03928-189-3 10.3390/books978-3-03928-189-3 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783039281893 9783039281886 236 open access
spellingShingle TA1-2040
TA349-359
T1-995
n/a
pitch angle
Method of Multiple Time-Scales
lumped parameters model
simulation
dynamical characteristic
dynamics
unsteady flow control
driving mechanism
damper force
optimization
relative displacement
bladed disc’s rotation
energy efficiency
ground-based laser communication turntable
landing gear
quasi-sliding mode domain (QSMD)
variable compression ratio
dynamic characteristics
inner wheel lifting
trot gait
vortex dynamics
emergency extension
natural dynamics
high-speed locomotion
under-platform damper
reliability sensitivity analysis
seeder dynamics
natural motion
Detached-Eddy Simulation
sliding mode control (SMC)
obstacle avoidance
active tilting
robotic system
switched reluctance motor
cyclic-symmetric systems dynamics
low-speed stability
vibration prediction
mesh stiffness
compositive motion
mixture of models
leg trajectory planning
trajectory planning
motorcycle dynamics
multi-physics modelling
reaching law
rider control
energy saving
quadruped robots
separation flow
balancing
personal mobility vehicle
chatter-free
time-variant parameters
simulation model
mathematical model
forced response
motion capture sensor
adjustable hydraulic volume
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
Massaro, Matteo
Boschetti, Giovanni
Doria, Alberto
Advances in Mechanical Systems Dynamics
title Advances in Mechanical Systems Dynamics
title_full Advances in Mechanical Systems Dynamics
title_fullStr Advances in Mechanical Systems Dynamics
title_full_unstemmed Advances in Mechanical Systems Dynamics
title_short Advances in Mechanical Systems Dynamics
title_sort advances in mechanical systems dynamics
topic TA1-2040
TA349-359
T1-995
n/a
pitch angle
Method of Multiple Time-Scales
lumped parameters model
simulation
dynamical characteristic
dynamics
unsteady flow control
driving mechanism
damper force
optimization
relative displacement
bladed disc’s rotation
energy efficiency
ground-based laser communication turntable
landing gear
quasi-sliding mode domain (QSMD)
variable compression ratio
dynamic characteristics
inner wheel lifting
trot gait
vortex dynamics
emergency extension
natural dynamics
high-speed locomotion
under-platform damper
reliability sensitivity analysis
seeder dynamics
natural motion
Detached-Eddy Simulation
sliding mode control (SMC)
obstacle avoidance
active tilting
robotic system
switched reluctance motor
cyclic-symmetric systems dynamics
low-speed stability
vibration prediction
mesh stiffness
compositive motion
mixture of models
leg trajectory planning
trajectory planning
motorcycle dynamics
multi-physics modelling
reaching law
rider control
energy saving
quadruped robots
separation flow
balancing
personal mobility vehicle
chatter-free
time-variant parameters
simulation model
mathematical model
forced response
motion capture sensor
adjustable hydraulic volume
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
topic_facet TA1-2040
TA349-359
T1-995
n/a
pitch angle
Method of Multiple Time-Scales
lumped parameters model
simulation
dynamical characteristic
dynamics
unsteady flow control
driving mechanism
damper force
optimization
relative displacement
bladed disc’s rotation
energy efficiency
ground-based laser communication turntable
landing gear
quasi-sliding mode domain (QSMD)
variable compression ratio
dynamic characteristics
inner wheel lifting
trot gait
vortex dynamics
emergency extension
natural dynamics
high-speed locomotion
under-platform damper
reliability sensitivity analysis
seeder dynamics
natural motion
Detached-Eddy Simulation
sliding mode control (SMC)
obstacle avoidance
active tilting
robotic system
switched reluctance motor
cyclic-symmetric systems dynamics
low-speed stability
vibration prediction
mesh stiffness
compositive motion
mixture of models
leg trajectory planning
trajectory planning
motorcycle dynamics
multi-physics modelling
reaching law
rider control
energy saving
quadruped robots
separation flow
balancing
personal mobility vehicle
chatter-free
time-variant parameters
simulation model
mathematical model
forced response
motion capture sensor
adjustable hydraulic volume
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
url 44750
work_keys_str_mv AT massaromatteo advancesinmechanicalsystemsdynamics
AT boschettigiovanni advancesinmechanicalsystemsdynamics
AT doriaalberto advancesinmechanicalsystemsdynamics