Latash Mark L
Pennsylvania State University, University Park, PA 16802, United States of America.
J Hum Kinet. 2016 Sep 10;52:7-20. doi: 10.1515/hukin-2015-0190. eCollection 2016 Sep 1.
Biomechanics and motor control are discussed as parts of a more general science, physics of living systems. Major problems of biomechanics deal with exact definition of variables and their experimental measurement. In motor control, major problems are associated with formulating currently unknown laws of nature specific for movements by biological objects. Mechanics-based hypotheses in motor control, such as those originating from notions of a generalized motor program and internal models, are non-physical. The famous problem of motor redundancy is wrongly formulated; it has to be replaced by the principle of abundance, which does not pose computational problems for the central nervous system. Biomechanical methods play a central role in motor control studies. This is illustrated with studies with the reconstruction of hypothetical control variables and those exploring motor synergies within the framework of the uncontrolled manifold hypothesis. Biomechanics and motor control have to merge into physics of living systems, and the earlier this process starts the better.
生物力学和运动控制作为生命系统物理学这一更广义科学的组成部分进行讨论。生物力学的主要问题涉及变量的精确界定及其实验测量。在运动控制方面,主要问题与阐述目前未知的、生物对象运动所特有的自然规律相关。运动控制中基于力学的假设,比如那些源自广义运动程序和内部模型概念的假设,是不符合物理原理的。著名的运动冗余问题表述有误;它必须被丰富性原理所取代,丰富性原理不会给中枢神经系统带来计算问题。生物力学方法在运动控制研究中发挥着核心作用。这通过对假设控制变量的重建研究以及在非受控流形假设框架内探索运动协同作用的研究得以说明。生物力学和运动控制必须融入生命系统物理学,而且这一过程越早开始越好。