Braun Daniel A, Aertsen Ad, Wolpert Daniel M, Mehring Carsten
Department of Engineering, University of Cambridge, UK.
Curr Biol. 2009 Feb 24;19(4):352-7. doi: 10.1016/j.cub.2009.01.036. Epub 2009 Feb 12.
When we have learned a motor skill, such as cycling or ice-skating, we can rapidly generalize to novel tasks, such as motorcycling or rollerblading [1-8]. Such facilitation of learning could arise through two distinct mechanisms by which the motor system might adjust its control parameters. First, fast learning could simply be a consequence of the proximity of the original and final settings of the control parameters. Second, by structural learning [9-14], the motor system could constrain the parameter adjustments to conform to the control parameters' covariance structure. Thus, facilitation of learning would rely on the novel task parameters' lying on the structure of a lower-dimensional subspace that can be explored more efficiently. To test between these two hypotheses, we exposed subjects to randomly varying visuomotor tasks of fixed structure. Although such randomly varying tasks are thought to prevent learning, we show that when subsequently presented with novel tasks, subjects exhibit three key features of structural learning: facilitated learning of tasks with the same structure, strong reduction in interference normally observed when switching between tasks that require opposite control strategies, and preferential exploration along the learned structure. These results suggest that skill generalization relies on task variation and structural learning.
当我们学会一项运动技能,比如骑自行车或滑冰后,我们能够迅速将其推广到新的任务中,比如骑摩托车或轮滑[1-8]。学习的这种促进作用可能通过运动系统调整其控制参数的两种不同机制产生。首先,快速学习可能仅仅是控制参数初始设置和最终设置接近的结果。其次,通过结构学习[9-14],运动系统可以将参数调整限制为符合控制参数的协方差结构。因此,学习的促进作用将依赖于新任务参数位于一个可以更有效探索的低维子空间的结构上。为了在这两种假设之间进行检验,我们让受试者接触固定结构的随机变化的视觉运动任务。尽管这种随机变化的任务被认为会阻碍学习,但我们发现,当随后呈现新任务时,受试者表现出结构学习的三个关键特征:具有相同结构的任务学习得到促进,在需要相反控制策略的任务之间切换时通常观察到的干扰大幅减少,以及沿着所学结构进行优先探索。这些结果表明,技能推广依赖于任务变化和结构学习。
