about
Resonant Cholinergic Dynamics in Cognitive and Motor Decision-Making: Attention, Category Learning, and Choice in Neocortex, Superior Colliculus, and Optic Tectum.Voluntary saccadic eye movements in humans studied with a double-cue paradigmVisual motion shifts saccade targetsGaze holding in healthy subjects.Sensorimotor adaptation error signals are derived from realistic predictions of movement outcomesError correcting mechanisms during antisaccades: contribution of online control during primary saccades and offline control via secondary saccades.A model of self-organizing head-centered visual responses in primate parietal areas.A kinematic model for 3-D head-free gaze-shifts.Modeling Inter-trial Variability of Saccade Trajectories: Effects of Lesions of the Oculomotor Part of the Fastigial Nucleus.Sensorimotor transformation for visually guided saccades.Cognitive Control of Saccadic Eye Movements in Children with Developmental Coordination DisorderStrength of baseline inter-trial correlations forecasts adaptive capacity in the vestibulo-ocular reflex.Neuronal responses to moving targets in monkey frontal eye fieldsCoupling between horizontal and vertical components of saccadic eye movements during constant amplitude and direction gaze shifts in the rhesus monkeyRevisiting corrective saccades: role of visual feedbackCoordination of the eyes and head during visual orientingShort-term adaptive modification of dynamic ocular accommodationThe same oculomotor vermal Purkinje cells encode the different kinematics of saccades and of smooth pursuit eye movementsMechanisms for generating and compensating for the smallest possible saccades.Distinct neural circuits for control of movement vs. holding still.Gaze-evoked nystagmus induced by alcohol intoxication.Not moving: the fundamental but neglected motor function.What stops a saccade?Spatial transformations between superior colliculus visual and motor response fields during head-unrestrained gaze shifts.Visual control of orientation behaviour in the fly. Part II. Towards the underlying neural interactions.Oculomotor localization relies on a damped representation of saccadic eye displacement in human and nonhuman primates.Integrated Bayesian models of learning and decision making for saccadic eye movementsSaccadic Adaptation in 10-41 Month-Old Children.Response Properties of Motor Equivalence Neurons of the Primate Premotor Cortex.Modeling trade-off between time-optimal and minimum energy in saccade main sequence.Adaptive calibration of dynamic accommodation--implications for accommodating intraocular lenses.The brain stem saccadic burst generator encodes gaze in three-dimensional space.Dynamic eye plant models and the control of eye movements.Fitts' Theorem and Movement Time Dissociation for Amplitude and Width Manipulations: Replying to Hoffmann.Model of the control of saccades by superior colliculus and cerebellum.Contrasting speed-accuracy tradeoffs for eye and hand movements reveal the optimal nature of saccade kinematics.Analog VLSI-based modeling of the primate oculomotor system.Human sound-localization behavior accounts for ocular drift.Unravelling cerebellar pathways with high temporal precision targeting motor and extensive sensory and parietal networks.Model with distributed vectorial premotor bursters accounts for the component stretching of oblique saccades.
P2860
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P2860
description
1973 nî lūn-bûn
@nan
1973年の論文
@ja
1973年学术文章
@wuu
1973年学术文章
@zh
1973年学术文章
@zh-cn
1973年学术文章
@zh-hans
1973年学术文章
@zh-my
1973年学术文章
@zh-sg
1973年學術文章
@yue
1973年學術文章
@zh-hant
name
Models of the saccadic eye movement control system.
@en
Models of the saccadic eye movement control system.
@nl
type
label
Models of the saccadic eye movement control system.
@en
Models of the saccadic eye movement control system.
@nl
prefLabel
Models of the saccadic eye movement control system.
@en
Models of the saccadic eye movement control system.
@nl
P356
P1433
P1476
Models of the saccadic eye movement control system.
@en
P2093
D A Robinson
P2860
P356
10.1007/BF00288906
P577
1973-12-01T00:00:00Z