Mugge Winfred, Schuurmans Jasper, Schouten Alfred C, van der Helm Frans C T
Department of BioMechanical Engineering, Delft University of Technology, 2628 CD Delft, The Netherlands.
J Neurosci. 2009 Apr 29;29(17):5476-82. doi: 10.1523/JNEUROSCI.0116-09.2009.
In daily life humans integrate force and position feedback from mechanoreceptors, proprioception, and vision. With handling relatively soft, elastic objects, force and position are related and can be integrated to improve the accuracy of an estimate of either one. Sensory weighting between different sensory systems (e.g., vision and proprioception) has been extensively studied. This study investigated whether similar weighting can be found within the proprioceptive sensory system, more specifically between the modalities force and position. We hypothesized that sensory weighting is governed by object stiffness: position feedback is weighted heavier on soft objects (large deflections), while force feedback is weighted heavier on stiff objects (small deflections). Subjects were instructed to blindly reproduce either position or force while holding a one degree of freedom haptic manipulator that simulated a linear spring with one of four predetermined stiffnesses. In catch trials the spring was covertly replaced by a nonlinear spring. The difference in force (DeltaF) and position (DeltaX) between the regular and the catch trials revealed the sensory weighting between force and position feedback. A maximum likelihood estimation model predicted that: (1) task instruction did not affect the outcome measures, and (2) force feedback is weighted heavier with increasing object stiffness as was hypothesized. Both effects were found experimentally, and the subjects' sensory weighting closely resembled the optimal model predictions. To conclude, this study successfully demonstrated sensory weighting within the proprioceptive system.
在日常生活中,人类整合来自机械感受器、本体感觉和视觉的力反馈和位置反馈。在处理相对柔软、有弹性的物体时,力和位置是相关的,并且可以整合起来以提高对其中任何一个的估计精度。不同感觉系统(如视觉和本体感觉)之间的感觉加权已得到广泛研究。本研究调查了在本体感觉系统内是否能发现类似的加权,更具体地说是在力和位置这两种模态之间。我们假设感觉加权受物体刚度的支配:在软物体上(大变形)位置反馈的权重更大,而在硬物体上(小变形)力反馈的权重更大。受试者被要求在握住一个具有一个自由度的触觉操纵器时盲目地重现位置或力,该操纵器模拟了具有四种预定刚度之一的线性弹簧。在捕捉试验中,弹簧被暗中替换为非线性弹簧。常规试验和捕捉试验之间的力差(ΔF)和位置差(ΔX)揭示了力反馈和位置反馈之间的感觉加权。一个最大似然估计模型预测:(1)任务指令不影响结果指标,(2)如所假设的那样,随着物体刚度的增加,力反馈的权重更大。这两种效应都在实验中被发现,并且受试者的感觉加权与最优模型预测非常相似。总之,本研究成功地证明了本体感觉系统内的感觉加权。