Improved Neurophysiological Process Imaging Through Optimization of Kalman Filter Initial Conditions.

IF 6.6 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Yun Zhao, Felix Luong, Simon Teshuva, Andria Pelentritou, William Woods, David Liley, Daniel F Schmidt, Mario Boley, Levin Kuhlmann
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引用次数: 0

Abstract

Recent work presented a framework for space-time-resolved neurophysiological process imaging that augments existing electromagnetic source imaging techniques. In particular, a nonlinear Analytic Kalman filter (AKF) has been developed to efficiently infer the states and parameters of neural mass models believed to underlie the generation of electromagnetic source currents. Unfortunately, as the initialization determines the performance of the Kalman filter, and the ground truth is typically unavailable for initialization, this framework might produce suboptimal results unless significant effort is spent on tuning the initialization. Notably, the relation between the initialization and overall filter performance is only given implicitly and is expensive to evaluate; implying that conventional optimization techniques, e.g. gradient or sampling based, are inapplicable. To address this problem, a novel efficient framework based on blackbox optimization has been developed to find the optimal initialization by reducing the signal prediction error. Multiple state-of-the-art optimization methods were compared and distinctively, Gaussian process optimization decreased the objective function by 82.1% and parameter estimation error by 62.5% on average with the simulation data compared to no optimization applied. The framework took only 1.6[Formula: see text]h and reduced the objective function by an average of 13.2% on 3.75[Formula: see text]min 4714-source channel magnetoencephalography data. This yields an improved method of neurophysiological process imaging that can be used to uncover complex underpinnings of brain dynamics.

通过优化卡尔曼滤波初始条件改进神经生理过程成像。
最近的工作提出了一个时空分辨神经生理过程成像的框架,增强了现有的电磁源成像技术。特别是,开发了一种非线性解析卡尔曼滤波器(AKF),以有效地推断电磁源电流产生的神经质量模型的状态和参数。不幸的是,由于初始化决定了卡尔曼滤波器的性能,而初始化通常无法获得基本事实,除非花费大量精力来调整初始化,否则该框架可能会产生次优结果。值得注意的是,初始化和整体滤波器性能之间的关系只是隐式给出的,并且很难评估;这意味着传统的优化技术,如梯度或基于抽样的,是不适用的。为了解决这一问题,提出了一种新的基于黑盒优化的高效框架,通过减小信号预测误差来寻找最优初始化。比较了几种最先进的优化方法,与未进行优化相比,高斯过程优化使仿真数据的目标函数平均降低82.1%,参数估计误差平均降低62.5%。该框架仅占用1.6 h[公式:见文本],在3.75 min(4714)源通道脑磁图数据上平均降低了13.2%的目标函数。这产生了一种改进的神经生理过程成像方法,可用于揭示大脑动力学的复杂基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
International Journal of Neural Systems
International Journal of Neural Systems 工程技术-计算机:人工智能
CiteScore
11.30
自引率
28.80%
发文量
116
审稿时长
24 months
期刊介绍: The International Journal of Neural Systems is a monthly, rigorously peer-reviewed transdisciplinary journal focusing on information processing in both natural and artificial neural systems. Special interests include machine learning, computational neuroscience and neurology. The journal prioritizes innovative, high-impact articles spanning multiple fields, including neurosciences and computer science and engineering. It adopts an open-minded approach to this multidisciplinary field, serving as a platform for novel ideas and enhanced understanding of collective and cooperative phenomena in computationally capable systems.
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