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035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/76891
035   $a(oapen)doab76891
035   $a(EXLCZ)995400000000042297
100   $a20202201d2021      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aWearable Movement Sensors for Rehabilitation: From Technology to Clinical Practice
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (328 p.)
311 08$a3-0365-2063-5 
311 08$a3-0365-2064-3 
330   $aThis Special Issue shows a range of potential opportunities for the application of wearable movement sensors in motor rehabilitation. However, the papers surely do not cover the whole field of physical behavior monitoring in motor rehabilitation. Most studies in this Special Issue focused on the technical validation of wearable sensors and the development of algorithms. Clinical validation studies, studies applying wearable sensors for the monitoring of physical behavior in daily life conditions, and papers about the implementation of wearable sensors in motor rehabilitation are under-represented in this Special Issue. Studies investigating the usability and feasibility of wearable movement sensors in clinical populations were lacking. We encourage researchers to investigate the usability, acceptance, feasibility, reliability, and clinical validity of wearable sensors in clinical populations to facilitate the application of wearable movement sensors in motor rehabilitation.
517   $aWearable Movement Sensors for Rehabilitation
606   $aTechnology: general issues$2bicssc
610   $a3-D motion analysis
610   $aaccelerometer
610   $aaccelerometers
610   $aaccelerometry
610   $aarm use
610   $aassistive device
610   $aassistive devices
610   $abody-worn sensors
610   $acenter of pressure
610   $acerebral palsy
610   $acircadian motor behavior
610   $aclinical
610   $aclinical setting
610   $aconstrained extended Kalman filter
610   $aconstraint
610   $adistance measurement
610   $aembedded sensors
610   $aexercise
610   $afalls
610   $aFourier transform
610   $afunctional linear model
610   $agait
610   $agait analysis
610   $agait planning
610   $agait rehabilitation
610   $aGMFCS level
610   $agoniometer
610   $ahemiplegia
610   $ahuman-machine interaction
610   $aimplementation
610   $aIMU
610   $ainertial measurement unit
610   $ainertial measurement units
610   $ainertial motion units
610   $ainsole pressure sensors
610   $akinematics
610   $aLie group
610   $alocomotion
610   $alow back pain
610   $alower limb amputation
610   $amachine learning
610   $amagnetometer-free
610   $ameasurement
610   $amotion capture
610   $amotion tracking
610   $amotor function
610   $an/a
610   $aneurological disorders
610   $aolder adults
610   $aoutcomes
610   $apathological gait
610   $aperinatal stroke
610   $aphysical activity
610   $aphysical therapy
610   $aphysically active workers
610   $apose estimation
610   $arange of motion
610   $areal-time gait detection
610   $arehabilitation
610   $arelative orientation estimation
610   $asensor
610   $ashoulder
610   $asingle leg squat
610   $aspinal cord injury
610   $astride length
610   $astroke
610   $atetraplegia
610   $aupper extremity
610   $aupper limb performance
610   $avalidity
610   $awalking
610   $awalking distance
610   $awearable devices
610   $awearable sensor
610   $awearable sensors
610   $awearable technology
610   $awireless sensors network
615  7$aTechnology: general issues
700   $aRibbers$b Gerard M$4edt$01302209
702   $aRegterschot$b G.R.H$4edt
702   $aBussmann$b J.B.J$4edt
702   $aRibbers$b Gerard M$4oth
702   $aRegterschot$b G.R.H$4oth
702   $aBussmann$b J.B.J$4oth
906   $aBOOK
912   $a9910557359503321
996   $aWearable Movement Sensors for Rehabilitation: From Technology to Clinical Practice$93026253
997   $aUNINA

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