scholarly article | Q13442814 |
P2093 | author name string | John J Jeka | |
Tim Kiemel | |||
Yuanfen Zhang | |||
P2860 | cites work | The case for and against muscle synergies | Q24652206 |
The uncontrolled manifold concept: identifying control variables for a functional task | Q28138160 | ||
Structured variability of muscle activations supports the minimal intervention principle of motor control | Q30488884 | ||
Optimal feedback control as a theory of motor coordination | Q34156556 | ||
Optimality principles in sensorimotor control | Q34716269 | ||
Identification of the plant for upright stance in humans: multiple movement patterns from a single neural strategy. | Q37018581 | ||
A model of postural control in quiet standing: robust compensation of delay-induced instability using intermittent activation of feedback control | Q37248398 | ||
The pupil as a paradigm for neurological control systems | Q40200610 | ||
Postural strategies associated with somatosensory and vestibular loss | Q41214376 | ||
Postural feedback responses scale with biomechanical constraints in human standing | Q47383652 | ||
Multisensory fusion: simultaneous re-weighting of vision and touch for the control of human posture | Q48580686 | ||
An optimal state estimation model of sensory integration in human postural balance | Q48793478 | ||
Postural responses evoked by platform pertubations are dominated by continuous feedback. | Q51017853 | ||
Comparison of different methods to identify and quantify balance control. | Q51451485 | ||
Control and estimation of posture during quiet stance depends on multijoint coordination. | Q51921848 | ||
Sensorimotor integration in human postural control. | Q52115371 | ||
An optimal control model for analyzing human postural balance. | Q52358551 | ||
Role of somatosensory and vestibular cues in attenuating visually induced human postural sway | Q52361479 | ||
A biomechanical analysis of muscle strength as a limiting factor in standing posture. | Q52403691 | ||
A unified view of quiet and perturbed stance: simultaneous co-existing excitable modes. | Q53625777 | ||
Postural control model interpretation of stabilogram diffusion analysis. | Q53912324 | ||
Time-varying mechanical behavior of multijointed arm in man. | Q54240662 | ||
Identification of human postural dynamics | Q67970324 | ||
Central programming of postural movements: adaptation to altered support-surface configurations | Q69572894 | ||
Loop gain of reflexes controlling human standing measured with the use of postural and vestibular disturbances | Q71951029 | ||
Preferred placement of the feet during quiet stance: development of a standardized foot placement for balance testing | Q74054850 | ||
A multisensory integration model of human stance control | Q77870687 | ||
P433 | issue | 42 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 15144-15153 | |
P577 | publication date | 2011-10-01 | |
P1433 | published in | Journal of Neuroscience | Q1709864 |
P1476 | title | Identification of neural feedback for upright stance in humans: stabilization rather than sway minimization | |
P478 | volume | 31 |
Q46298770 | A Sensitivity Analysis of an Inverted Pendulum Balance Control Model. |
Q48439587 | A new paradigm for human stick balancing: a suspended not an inverted pendulum. |
Q98181098 | Adaptation of balancing behaviour during continuous perturbations of stance. Supra-postural visual tasks and platform translation frequency modulate adaptation rate |
Q51765434 | Aging effects on leg joint variability during walking with balance perturbations. |
Q35672824 | Ashtanga-Based Yoga Therapy Increases the Sensory Contribution to Postural Stability in Visually-Impaired Persons at Risk for Falls as Measured by the Wii Balance Board: A Pilot Randomized Controlled Trial |
Q41707185 | Assessment of the underlying systems involved in standing balance: the additional value of electromyography in system identification and parameter estimation. |
Q33799975 | Asymmetric sensory reweighting in human upright stance |
Q91637641 | Attainment of Quiet Standing in Humans: Are the Lower Limb Joints Controlled Relative to a Misaligned Postural Reference? |
Q41945103 | Balancing on tightropes and slacklines |
Q50281382 | Body sway adaptation to addition but not withdrawal of stabilizing visual information is delayed by a concurrent cognitive task. |
Q30374511 | Calibration of the Leg Muscle Responses Elicited by Predictable Perturbations of Stance and the Effect of Vision. |
Q35709267 | Direction of balance and perception of the upright are perceptually dissociable |
Q36080955 | Does the type of visual feedback information change the control of standing balance? |
Q30765483 | Dynamic modulation of visual and electrosensory gains for locomotor control |
Q55343726 | Effects of a powered ankle-foot orthosis on perturbed standing balance. |
Q47279862 | Effects of visual and cognitive interference on joint contributions in perturbed standing: a temporal and spectral analysis |
Q54936325 | Evidence in Support of the Independent Channel Model Describing the Sensorimotor Control of Human Stance Using a Humanoid Robot. |
Q53287321 | Function dictates the phase dependence of vision during human locomotion. |
Q34368975 | Functional synergies underlying control of upright posture during changes in head orientation |
Q45329751 | Haptic feedback enhances rhythmic motor control by reducing variability, not improving convergence rate |
Q47239178 | How visual information links to multijoint coordination during quiet standing |
Q45924696 | Human standing: does the control strategy preprogram a rigid knee? |
Q26770125 | Human upright posture control models based on multisensory inputs; in fast and slow dynamics |
Q38913290 | Identification of the Unstable Human Postural Control System |
Q36871077 | Identification of the contribution of the ankle and hip joints to multi-segmental balance control |
Q60956704 | Implementation of a Central Sensorimotor Integration Test for Characterization of Human Balance Control During Stance |
Q35269048 | Intra-session test-retest reliability of magnitude and structure of center of pressure from the Nintendo Wii Balance Board™ for a visually impaired and normally sighted population. |
Q37068379 | Learning dynamic control of body roll orientation |
Q36593349 | Myoelectric activity along human gastrocnemius medialis: different spatial distributions of postural and electrically elicited surface potentials |
Q64061848 | Non-specific Low Back Pain and Postural Control During Quiet Standing—A Systematic Review |
Q48516151 | Parkinson's disease patients compensate for balance control asymmetry. |
Q50629833 | Perceptual and motor learning underlies human stick-balancing skill. |
Q64058732 | Postural control of a musculoskeletal model against multidirectional support surface translations |
Q30447916 | Top-down approach to vestibular compensation: translational lessons from vestibular rehabilitation |
Q37578223 | Using a System Identification Approach to Investigate Subtask Control during Human Locomotion |
Q92872237 | Variability in locomotor dynamics reveals the critical role of feedback in task control |
Q37511940 | Visual conflict and cognitive load modify postural responses to vibrotactile noise |
Q47156432 | Visuo-manual tracking: does intermittent control with aperiodic sampling explain linear power and non-linear remnant without sensorimotor noise? |
Q27307832 | Young, Healthy Subjects Can Reduce the Activity of Calf Muscles When Provided with EMG Biofeedback in Upright Stance |
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