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物体轨迹判断过程中的多感官自我运动补偿

Multisensory self-motion compensation during object trajectory judgments.

作者信息

Dokka Kalpana, MacNeilage Paul R, DeAngelis Gregory C, Angelaki Dora E

机构信息

Department of Neuroscience, Baylor College of Medicine, Houston, TX 77030, USA.

German Center for Vertigo and Balance Disorders, University Hospital of Munich, Munich, Germany and.

出版信息

Cereb Cortex. 2015 Mar;25(3):619-30. doi: 10.1093/cercor/bht247. Epub 2013 Sep 22.

DOI:10.1093/cercor/bht247
PMID:24062317
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4318529/
Abstract

Judging object trajectory during self-motion is a fundamental ability for mobile organisms interacting with their environment. This fundamental ability requires the nervous system to compensate for the visual consequences of self-motion in order to make accurate judgments, but the mechanisms of this compensation are poorly understood. We comprehensively examined both the accuracy and precision of observers' ability to judge object trajectory in the world when self-motion was defined by vestibular, visual, or combined visual-vestibular cues. Without decision feedback, subjects demonstrated no compensation for self-motion that was defined solely by vestibular cues, partial compensation (47%) for visually defined self-motion, and significantly greater compensation (58%) during combined visual-vestibular self-motion. With decision feedback, subjects learned to accurately judge object trajectory in the world, and this generalized to novel self-motion speeds. Across conditions, greater compensation for self-motion was associated with decreased precision of object trajectory judgments, indicating that self-motion compensation comes at the cost of reduced discriminability. Our findings suggest that the brain can flexibly represent object trajectory relative to either the observer or the world, but a world-centered representation comes at the cost of decreased precision due to the inclusion of noisy self-motion signals.

摘要

判断自我运动过程中的物体轨迹是移动生物与环境交互的一项基本能力。这项基本能力要求神经系统补偿自我运动的视觉后果,以便做出准确判断,但这种补偿机制却鲜为人知。我们全面考察了在前庭、视觉或视觉 - 前庭联合线索定义自我运动时,观察者判断世界中物体轨迹能力的准确性和精确性。在没有决策反馈的情况下,受试者对仅由前庭线索定义的自我运动未表现出补偿,对视觉定义的自我运动表现出部分补偿(47%),而在视觉 - 前庭联合自我运动过程中表现出显著更大的补偿(58%)。有决策反馈时,受试者学会了准确判断世界中的物体轨迹,并且这种能力能推广到新的自我运动速度。在各种条件下,对自我运动更大的补偿与物体轨迹判断的精确性降低相关,这表明自我运动补偿是以降低可辨别性为代价的。我们的研究结果表明,大脑可以灵活地相对于观察者或世界来表征物体轨迹,但以世界为中心的表征会因包含有噪声的自我运动信号而导致精确性降低。

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