神经状态空间下线性脑机接口解码器的性能评价

Islam S. Badreldin, K. Oweiss
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摘要

脑机接口(bmi)有可能恢复严重运动障碍患者失去的感觉运动功能。已经提出了几种BMI解码策略,将运动神经元的活动转化为驱动人工设备的控制信号。其中,线性解码器类,特别是维纳滤波器,已知在简单任务中表现良好,但随着任务复杂性的增加,其性能会显著下降。在这项工作中,我们研究了维纳解码器解子空间的数学性质,以努力推导出给定解码器的理想神经状态轨迹和理想的仿生运动学解。我们表明,在二维到达任务的执行过程中,期望的神经轨迹与实际测量的神经轨迹之间的误差为任务空间中的性能提供了可靠的估计和预测。我们证明了神经状态空间中的误差测量与任务空间中的误差测量之间存在显著的相关性,这使得该误差测量在未来有可能被用于估计BMI受试者的真实运动意图和学习解码器的程度,并可能作为反馈信号来提高他们的在线解码性能。
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Performance evaluation of linear brain machine interface decoders in neural state space
Brain-Machine Interfaces (BMIs) have the potential to restore lost sensorimotor functions in people with severe motor disabilities. Several BMI decoding strategies have been suggested to translate activity of motor neurons into control signals that ac-tuate artificial devices. Among these, the class of linear decoders, particularly Wiener filters, is known to perform well for simple tasks, but degrades considerably as a function of increasing task complexity. In this work, we study the mathematical properties of the solution subspace of Wiener decoders in an effort to derive a desired neural state trajectory that is optimal for a given decoder and a desired biomimetic kinematic solution. We show that the error between the desired neural trajectory and the actual one measured during the performance of a 2D reach task provides reliable estimation and prediction of the performance in the task space. We demonstrate a significant correlation between the error measure in the neural state space and the error measure in the task space, which allows potential future use of this error measure as a way to estimate the true motor intent and the extent of learning the decoder by BMI subjects, and possibly as a feedback signal to improve their online decoding performance.
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