Lukashin A V, Wilcox G L, Georgopoulos A P
Brain Sciences Center, Department of Veterans Affairs Medical Center, Minneapolis, MN 55417.
Proc Natl Acad Sci U S A. 1994 Aug 30;91(18):8651-4. doi: 10.1073/pnas.91.18.8651.
The hypothesis was tested that learned movement trajectories of different shapes can be stored in, and generated by, largely overlapping neural networks. Indeed, it was possible to train a massively interconnected neural network to generate different shapes of internally stored, dynamically evolving movement trajectories using a general-purpose core part, common to all networks, and a special-purpose part, specific for a particular trajectory. The weights of connections between the core units do not carry any information about trajectories. The core network alone could generate externally instructed trajectories but not internally stored ones, for which both the core and the trajectory-specific part were needed. All information about the movements is stored in the weights of connections between the core part and the specialized units and between the specialized units themselves. Due to these connections the core part reveals specific dynamical behavior for a particular trajectory and, as the result, discriminates different tasks. The percentage of trajectory-specific units needed to generate a certain trajectory was small (2-5%), and the total output of the network is almost entirely provided by the core part, whereas the role of the small specialized parts is to drive the dynamical behavior. These results suggest an efficient and effective mechanism for storing learned motor patterns in, and reproducing them by, overlapping neural networks and are in accord with neurophysiological findings of trajectory-specific cells and with neurological observations of loss of specific motor skills in the presence of otherwise intact motor control.
不同形状的习得运动轨迹能够存储于大量重叠的神经网络中,并由这些网络生成。实际上,通过一个所有网络通用的核心部分和一个特定轨迹专用的特殊部分,训练一个大规模互联的神经网络来生成内部存储的、动态演变的不同形状的运动轨迹是可行的。核心单元之间连接的权重并不携带任何关于轨迹的信息。仅核心网络就能生成外部指令的轨迹,但无法生成内部存储的轨迹,生成内部存储的轨迹则需要核心部分和特定轨迹部分两者。所有关于运动的信息都存储在核心部分与专用单元之间以及专用单元自身之间连接的权重中。由于这些连接,核心部分针对特定轨迹展现出特定的动态行为,结果是能够区分不同任务。生成特定轨迹所需的特定轨迹单元的比例很小(2 - 5%),并且网络的总输出几乎完全由核心部分提供,而小的专用部分的作用是驱动动态行为。这些结果表明了一种高效且有效的机制,用于在重叠的神经网络中存储习得的运动模式并通过其进行再现,这与轨迹特定细胞的神经生理学发现以及在其他运动控制完好的情况下特定运动技能丧失的神经学观察结果相符。