人类在无头部追随过程中头部和注视运动的独立控制。
Independent control of head and gaze movements during head-free pursuit in humans.
作者信息
Collins C J, Barnes G R
机构信息
Medical Research Council, Human Movement and Balance Unit, Institute of Neurology, Queen Square, London, WC1N 3BG, UK.
出版信息
J Physiol. 1999 Feb 15;515 ( Pt 1)(Pt 1):299-314. doi: 10.1111/j.1469-7793.1999.299ad.x.
Abstract
- Head and gaze movements are usually highly co-ordinated. Here we demonstrate that under certain circumstances they can be controlled independently and we investigate the role of anticipatory activity in this process. 2. In experiment 1, subjects tracked, with head and eyes, a sinusoidally moving target. Overall, head and gaze trajectories were tightly coupled. From moment to moment, however, the trajectories could be very different and head movements were significantly more variable than gaze movements. 3. Predictive head and gaze responses can be elicited by repeated presentation of an intermittently illuminated, constant velocity target. In experiment 2 this protocol elicited a build-up of anticipatory head and gaze velocity, in opposing directions, when subjects made head movements in the opposite direction to target movement whilst maintaining gaze on target. 4. In experiment 3, head and gaze movements were completely uncoupled. Subjects followed, with head and gaze, respectively, two targets moving at different, harmonically unrelated frequencies. This was possible when both targets were visual, and also when gaze followed a visual target at one frequency whilst the head was oscillated in time with an auditory tone modulated at the second frequency. 5. We conclude that these results provide evidence of a visuomotor predictive mechanism that continuously samples visual feedback information and stores it such that it can be accessed by either the eye or the head to generate anticipatory movements. This overcomes time delays in visuomotor processing and facilitates time-sharing of motor activities, making possible the performance of two tasks simultaneously.
摘要
- 头部和注视运动通常高度协调。在此我们证明,在某些情况下它们可以被独立控制,并且我们研究了预期活动在此过程中的作用。2. 在实验1中,受试者用头部和眼睛跟踪一个做正弦运动的目标。总体而言,头部和注视轨迹紧密耦合。然而,在每一刻,轨迹可能非常不同,并且头部运动的变化明显大于注视运动。3. 通过反复呈现一个间歇照明、匀速运动的目标,可以引发预测性的头部和注视反应。在实验2中,当受试者在保持注视目标的同时,头部向与目标运动相反的方向移动时,该方案引发了预期的头部和注视速度在相反方向上的累积。4. 在实验3中,头部和注视运动完全解耦。受试者分别用头部和注视跟踪两个以不同的、非谐波相关频率运动的目标。当两个目标都是视觉目标时,以及当注视跟随一个以一种频率运动的视觉目标,而头部随着以第二种频率调制的听觉音调同步振荡时,这都是可能的。5. 我们得出结论,这些结果提供了一种视觉运动预测机制的证据,该机制持续采样视觉反馈信息并存储它,以便眼睛或头部可以访问它以产生预期运动。这克服了视觉运动处理中的时间延迟,并促进了运动活动的时间共享,使得同时执行两项任务成为可能。
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