| scholarly article | Q13442814 |
| P50 | author | Ian Loram | Q43181467 |
| P2093 | author name string | Martin Lakie | |
| Nicholas Caplan | |||
| P2860 | cites work | Direct measurement of human ankle stiffness during quiet standing: the intrinsic mechanical stiffness is insufficient for stability | Q24641852 |
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| Tensile properties of in vivo human tendinous tissue | Q34749281 | ||
| Dynamic Tensile Properties of the Plantaris Tendon of Sheep (Ovis Aries) | Q41638525 | ||
| Human balancing of an inverted pendulum: is sway size controlled by ankle impedance? | Q47213350 | ||
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| Moment dependency of the series elastic stiffness in the human plantar flexors measured in vivo. | Q52052976 | ||
| THEORY OF THE HUMAN OPERATOR IN CONTROL SYSTEMS1 | Q56029338 | ||
| THEORY OF THE HUMAN OPERATOR IN CONTROL SYSTEMS | Q56029340 | ||
| Ankle stiffness of standing humans in response to imperceptible perturbation: reflex and task-dependent components | Q67976820 | ||
| Dynamics of human ankle stiffness: variation with displacement amplitude | Q70543923 | ||
| The contribution of foot deformation to the changes of muscular length and angle in the ankle joint during standing in man | Q72343971 | ||
| Stiffness control of balance in quiet standing | Q77323531 | ||
| In vivo measurement of the series elasticity release curve of human triceps surae muscle | Q77514048 | ||
| Ankle muscle stiffness alone cannot stabilize balance during quiet standing | Q78328167 | ||
| Motor mechanisms of balance during quiet standing | Q78679498 | ||
| The intermittency of control movements and the psychological refractory period | Q79583433 | ||
| P433 | issue | Pt 1 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | bias | Q742736 |
| P1104 | number of pages | 14 | |
| P304 | page(s) | 357-370 | |
| P577 | publication date | 2003-06-27 | |
| P1433 | published in | Journal of Physiology | Q7743612 |
| P1476 | title | Human balancing of an inverted pendulum with a compliant linkage: neural control by anticipatory intermittent bias | |
| P478 | volume | 551 |
| Q45781308 | A multi-joint model of quiet, upright stance accounts for the "uncontrolled manifold" structure of joint variance. |
| Q51690710 | Active control of bias for the control of posture and movement. |
| Q81300246 | Active, non-spring-like muscle movements in human postural sway: how might paradoxical changes in muscle length be produced? |
| Q33914364 | Adaptation to altered balance conditions in unilateral amputees due to atherosclerosis: a randomized controlled study |
| Q59813021 | An Initial Passive Phase That Limits the Time to Recover and Emphasizes the Role of Proprioceptive Information |
| Q48580259 | Balance control under different passive contributions of the ankle extensors: quiet standing on inclined surfaces |
| Q38055238 | Biomechanical and neurophysiological mechanisms related to postural control and efficiency of movement: a review |
| Q83311976 | Changes in muscle and joint elasticity following long-term strength training in old age |
| Q36672556 | Contributions of feed-forward and feedback strategies at the human ankle during control of unstable loads |
| Q35411693 | Day-time effect on postural stability in young sportsmen |
| Q48085120 | Effectiveness of electrical noise in reducing postural sway: a comparison between imperceptible stimulation applied to the anterior and to the posterior leg muscles. |
| Q48271155 | Effects of maintaining touch contact on predictive and reactive balance. |
| Q24170029 | Evaluation of the roles of passive and active control of balance using a balance control model |
| Q59589824 | Human Machine Interaction and Communication in Cooperative Actions |
| Q48170219 | Human control of an inverted pendulum: is continuous control necessary? Is intermittent control effective? Is intermittent control physiological? |
| Q24545754 | Human postural sway results from frequent, ballistic bias impulses by soleus and gastrocnemius |
| Q48749309 | Imperceptible electrical noise attenuates isometric plantar flexion force fluctuations with correlated reductions in postural sway |
| Q36600762 | Influence of environmental stability on the regulation of end-point impedance during the maintenance of arm posture |
| Q40306248 | Intermittent Feedback-Control Strategy for Stabilizing Inverted Pendulum on Manually Controlled Cart as Analogy to Human Stick Balancing. |
| Q38403261 | Intermittent control models of human standing: similarities and differences |
| Q55030907 | Intrinsic ankle stiffness during standing increases with ankle torque and passive stretch of the Achilles tendon. |
| Q57809188 | Is the stabilization of quiet upright stance in humans driven by synchronized modulations of the activity of medial and lateral gastrocnemius muscles? |
| Q34743880 | Learning an intermittent control strategy for postural balancing using an EMG-based human-computer interface |
| Q80229036 | Manually controlled human balancing using visual, vestibular and proprioceptive senses involves a common, low frequency neural process |
| Q73636676 | More pulsating movement |
| Q48460542 | Multisensory information for postural control: sway-referencing gain shapes center of pressure variability and temporal dynamics |
| Q36920883 | Neural Excitability and Joint Laxity in Chronic Ankle Instability, Coper, and Control Groups |
| Q46115896 | Neuromuscular responses of trained ballet dancers to postural perturbations |
| Q30568461 | POSTURAL CONTROL MECHANISMS IN HEALTHY ADULTS IN SITTING AND STANDING POSITIONS. |
| Q24677771 | Paradoxical muscle movement in human standing |
| Q91828732 | Parameters of the crossing points between center of pressure and center of mass signals are potential markers of postural control efficiency |
| Q50629833 | Perceptual and motor learning underlies human stick-balancing skill. |
| Q48892081 | Postural control at the human wrist. |
| Q48052429 | Quantifying levels of function between different subgroups of chronic ankle instability |
| Q34141769 | Stabilization strategies for unstable dynamics |
| Q34757814 | Stiffness and damping in postural control increase with age. |
| Q35185959 | Strategy switching in the stabilization of unstable dynamics |
| Q37183347 | Sway-dependent changes in standing ankle stiffness caused by muscle thixotropy |
| Q45850386 | The dynamics of postural sway cannot be captured using a one-segment inverted pendulum model: a PCA on segment rotations during unperturbed stance |
| Q59100402 | The filtering of the posturographic signals shows the age related features |
| Q48926195 | The frequency of human, manual adjustments in balancing an inverted pendulum is constrained by intrinsic physiological factors |
| Q47976175 | The modulatory influence of end-point controllability on decisions between actions. |
| Q51906477 | The passive, human calf muscles in relation to standing: the non-linear decrease from short range to long range stiffness. |
| Q83482138 | The proprioceptive and agonist roles of gastrocnemius, soleus and tibialis anterior muscles in maintaining human upright posture |
| Q48941804 | Use of ultrasound to make noninvasive in vivo measurement of continuous changes in human muscle contractile length |
| Q48860298 | Visual control of stable and unstable loads: what is the feedback delay and extent of linear time-invariant control? |
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