Progress in Motor Control: A Multidisciplinary PerspectiveDagmar Sternad Springer Science & Business Media, 25 Δεκ 2008 - 734 σελίδες It has become widely acknowledged, and almost trivial to state, that the study of the control and coordination of biological movement – motor control – is inherently multidisciplinary. From the investigation of overt functional behavior to the int- cacies of neuronal activations, the issues are numerous and invite many different levels of analysis, methods, and perspectives. Clearly, the biological movement system is simultaneously a dynamical, neurophysiological, electrophysiological, and intentional system, in short, a complex system in the technical sense of the word. While multidisciplinarity in motor control research is a necessity, it also presents a stumbling block to developing a coherent body of knowledge that represents the science of the control and coordination of movement. Research thrusts are developing from different academic backgrounds that are not easily understood by peers with entirely different disciplinary training. Not only for the student of motor control, but also for the advanced researcher, it can be daunting to make connections, for example, between cognitive issues like pl- ning or attention and functional properties of the peripheral nervous system, between motor cortical activation and the biomechanics of the multi-joint limb system. Yet, all of these approaches aim to shed light on the same phenomenon – the astonishing ability of biological systems to move, perceive, grow, adapt, use tools, and do infinitely more things. For the science of motor control to progress more integration of disciplines is therefore necessary. |
Περιεχόμενα
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Control from an Allometric Perspective | 57 |
Atoms of Brain and BehaviorThe term behavior here is meant in a most general way refering to the coordinated spatiotemporal behavior of living thi... | 83 |
Perspectives and Issues | 92 |
What is Encoded in the Brain? | 124 |
The Case of Visuomotor Rotation | 405 |
Cortical Processing during Dynamic Motor Adaptation | 423 |
Changes in the Structure of Variability in a Redundant Task | 439 |
Time Scales DifficultySkill Duality and the Dynamics of Motor Learning | 457 |
Bridging of Models for Complex Movements in 3D | 477 |
Bridging of Models for Complex Movements in 3D | 478 |
New Findings Related to Object Manipulation Moving Around Obstacles Moving in Three Spatial Dimensions and Haptic Tracking | 485 |
Grasping Occams Razor | 498 |
Past Present and Emerging Principles in the Neural Encoding of Movement | 125 |
Motor Cortex and the Control of Reaching Movements | 139 |
Control of Muscle Synergies by Cortical Ensembles | 179 |
Behavioral and Neurophysiological Aspects of Target Interception | 200 |
What Can Visuomotor Adaptations Tell us About the Neuronal Representation of Movement? | 221 |
The Problem of Parametric Neural Coding in the Motor System | 243 |
Perception and Action | 260 |
Introduction to Section on Perception and Action | 261 |
Mutuality in the Perception of Affordances and the Control of Movement | 273 |
Object Avoidance During Locomotion | 293 |
The Roles of Vision and Proprioception in the Planning of Reaching Movements | 317 |
Behavioral and Neuroanatomical Perspectives | 336 |
The Human Mirror Neuron System and Embodied Representations | 355 |
Disorders of the PerceptualMotor System | 377 |
Motor Learning | 392 |
Some Contemporary Issues in Motor Learning | 393 |
Review of Models for the Generation of MultiJoint Movements in 3D | 523 |
The Hand as a Complex System | 551 |
Why the Hand? | 553 |
Selective Activation of Human Finger Muscles after Stroke or Amputation | 558 |
Neural Control of Hand Muscles During Prehension | 577 |
Control of a Redundant Mechanical System | 597 |
A Mathematical Approach to the Mechanical Capabilities of Limbs and Fingers | 619 |
Forty Years of EquilibriumPoint Hypothesis | 634 |
Origin and Advances of the EquilibriumPoint Hypothesis | 637 |
The Biomechanics of Force Production | 644 |
The Implications of Force Feedback for the lambda Model | 663 |
Control and Calibration of MultiSegment Reaching Movements | 680 |
The EquilibriumPoint Hypothesis Past Present and Future | 699 |
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Άλλες εκδόσεις - Προβολή όλων
Progress in Motor Control: A Multidisciplinary Perspective Dagmar Sternad Δεν υπάρχει διαθέσιμη προεπισκόπηση - 2016 |
Progress in Motor Control: A Multidisciplinary Perspective Dagmar Sternad Δεν υπάρχει διαθέσιμη προεπισκόπηση - 2008 |
Συχνά εμφανιζόμενοι όροι και φράσεις
adaptation arm movements Bizzi cells components coordination Coriolis forces correlated cortical digits dynamics effect encoding endpoint Exp Brain Res Experimental Brain Research experiments Feldman finger force force feedback function Georgopoulos grasping grip hand haptic human hypothesis input interception internal models joint Journal of Neurophysiology Kalaska kinematic kinetics Latash limb locomotion M1 neurons mechanical mirror neurons modulated monkeys motion motoneurons motor control motor learning motor unit move movement direction muscle activity muscle spindle nervous system Neurophysiol Neurosci object observed obstacle optic ataxia parameters parietal pattern perception and action performance perturbation phase position posture power law predictions premotor premotor cortex primary motor cortex properties proprioceptive reaching movements representation result robotic role rotation Santello sensorimotor sensory signals Soechting space spatial spinal Springer Science+Business Media Sternad stiffness studies subjects synergies target task threshold tion torque trajectory trials tuning Turvey variables vector velocity visuomotor