Adaptive unscented Kalman filter for neuronal state and parameter estimation.

IF 1.5 4区医学 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY Journal of Computational Neuroscience Pub Date : 2023-05-01 DOI:10.1007/s10827-023-00845-z

Loïc J Azzalini, David Crompton, Gabriele M T D'Eleuterio, Frances Skinner, Milad Lankarany

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引用次数: 2

Abstract

Data assimilation techniques for state and parameter estimation are frequently applied in the context of computational neuroscience. In this work, we show how an adaptive variant of the unscented Kalman filter (UKF) performs on the tracking of a conductance-based neuron model. Unlike standard recursive filter implementations, the robust adaptive unscented Kalman filter (RAUKF) jointly estimates the states and parameters of the neuronal model while adjusting noise covariance matrices online based on innovation and residual information. We benchmark the adaptive filter's performance against existing nonlinear Kalman filters and explore the sensitivity of the filter parameters to the system being modelled. To evaluate the robustness of the proposed solution, we simulate practical settings that challenge tracking performance, such as a model mismatch and measurement faults. Compared to standard variants of the Kalman filter the adaptive variant implemented here is more accurate and robust to faults.

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用于神经元状态和参数估计的自适应无气味卡尔曼滤波。

用于状态和参数估计的数据同化技术经常应用于计算神经科学。在这项工作中，我们展示了无气味卡尔曼滤波器(UKF)的自适应变体如何对基于电导的神经元模型进行跟踪。与标准递归滤波器实现不同，鲁棒自适应无气味卡尔曼滤波器(RAUKF)在基于创新和残差信息在线调整噪声协方差矩阵的同时，联合估计神经元模型的状态和参数。我们将自适应滤波器的性能与现有的非线性卡尔曼滤波器进行比较，并探讨了滤波器参数对被建模系统的灵敏度。为了评估所提出的解决方案的鲁棒性，我们模拟了挑战跟踪性能的实际设置，例如模型不匹配和测量错误。与标准卡尔曼滤波相比，本文实现的自适应卡尔曼滤波具有更高的精度和对故障的鲁棒性。

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来源期刊

Journal of Computational Neuroscience 生物-神经科学

CiteScore

2.00

自引率

8.30%

发文量

审稿时长

3 months

期刊介绍： The Journal of Computational Neuroscience provides a forum for papers that fit the interface between computational and experimental work in the neurosciences. The Journal of Computational Neuroscience publishes full length original papers, rapid communications and review articles describing theoretical and experimental work relevant to computations in the brain and nervous system. Papers that combine theoretical and experimental work are especially encouraged. Primarily theoretical papers should deal with issues of obvious relevance to biological nervous systems. Experimental papers should have implications for the computational function of the nervous system, and may report results using any of a variety of approaches including anatomy, electrophysiology, biophysics, imaging, and molecular biology. Papers investigating the physiological mechanisms underlying pathologies of the nervous system, or papers that report novel technologies of interest to researchers in computational neuroscience, including advances in neural data analysis methods yielding insights into the function of the nervous system, are also welcomed (in this case, methodological papers should include an application of the new method, exemplifying the insights that it yields).It is anticipated that all levels of analysis from cognitive to cellular will be represented in the Journal of Computational Neuroscience.