Kopiske Karl K, Bozzacchi Chiara, Volcic Robert, Domini Fulvio
Center for Neuroscience and Cognitive Systems@UniTN, Istituto Italiano di Tecnologia, Rovereto, Italy.
Cognitive Systems Lab, Institute of Physics, Chemnitz University of Technology, 09126, Chemnitz, Germany.
Psychol Res. 2019 Feb;83(1):147-158. doi: 10.1007/s00426-018-1101-9. Epub 2018 Sep 27.
The perceived distance of objects is biased depending on the distance from the observer at which objects are presented, such that the egocentric distance tends to be overestimated for closer objects, but underestimated for objects further away. This leads to the perceived depth of an object (i.e., the perceived distance from the front to the back of the object) also being biased, decreasing with object distance. Several studies have found the same pattern of biases in grasping tasks. However, in most of those studies, object distance and depth were solely specified by ocular vergence and binocular disparities. Here we asked whether grasping objects viewed from above would eliminate distance-dependent depth biases, since this vantage point introduces additional information about the object's distance, given by the vertical gaze angle, and its depth, given by contour information. Participants grasped objects presented at different distances (1) at eye-height and (2) 130 mm below eye-height, along their depth axes. In both cases, grip aperture was systematically biased by the object distance along most of the trajectory. The same bias was found whether the objects were seen in isolation or above a ground plane to provide additional depth cues. In two additional experiments, we verified that a consistent bias occurs in a perceptual task. These findings suggest that grasping actions are not immune to biases typically found in perceptual tasks, even when additional cues are available. However, online visual control can counteract these biases when direct vision of both digits and final contact points is available.
物体的感知距离会因物体呈现时与观察者的距离而产生偏差,即,对于较近的物体,自我中心距离往往被高估,而对于较远的物体则被低估。这会导致物体的感知深度(即从物体前部到后部的感知距离)也出现偏差,并随物体距离的增加而减小。多项研究在抓握任务中发现了相同的偏差模式。然而,在大多数这些研究中,物体距离和深度仅由眼动辐辏和双眼视差来确定。在这里,我们探讨从上方观察物体时抓握是否会消除与距离相关的深度偏差,因为这种视角会引入有关物体距离的额外信息(由垂直注视角度给出)及其深度信息(由轮廓信息给出)。参与者沿着物体的深度轴抓握在不同距离呈现的物体,(1)在眼睛高度处,(2)在眼睛高度以下130毫米处。在这两种情况下,抓握孔径在大部分轨迹上都因物体距离而产生系统性偏差。无论物体是单独呈现还是在地面上方呈现以提供额外的深度线索,都发现了相同的偏差。在另外两个实验中,我们验证了在感知任务中会出现一致的偏差。这些发现表明,抓握动作也无法避免感知任务中常见的偏差,即使有额外的线索可用。然而,当手指和最终接触点都能直接看到时,在线视觉控制可以抵消这些偏差。
