Ultra-early medical treatment-oriented system identification using High-Dimension Low-Sample-Size data

IF 1.8 Q3 AUTOMATION & CONTROL SYSTEMS IFAC Journal of Systems and Control Pub Date : 2024-02-05 DOI:10.1016/j.ifacsc.2024.100245
Xun Shen , Naruto Shimada , Hampei Sasahara , Jun-ichi Imura
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Abstract

Ultra-early detection of diseases with High-Dimension Low-Sample-Size (HDLSS) data has been effectively addressed by the Dynamical Network Biomarkers (DNBs) theory. After ultra-early detection, it is crucial to consider ultra-early medical treatment for the detected disease. From the viewpoint of control engineering, ultra-early medical treatment is achieved by increasing the system’s stability and preventing the bifurcation, called re-stabilization. To implement effective re-stabilization, the system matrix is necessary. However, the available data in biological systems are often HDLSS, which is insufficient to identify the system matrix. In this paper, to realize HDLSS-based ultra-early medical treatment, we investigate an HDLSS data-based system matrix estimation method. First, HDLSS data is applied to compute the sample covariance matrix of the steady state. By assuming that the system matrix is sparse and the structure of the system matrix is known, it can utilize the Lyapunov equation to estimate the system matrix from the covariance matrix. The Lyapunov equation-based method gives a unique optimal estimation if the covariance matrix is full-rank. Otherwise, the optimal estimation is not unique. The sample covariance matrix computed from the HDLSS data is not full-rank. Thus, we apply shrinkage estimation to overcome the under-determined issue to obtain a well-conditioned covariance matrix with full rank. In addition, we confirm the effectiveness of the proposed method through numerical simulations.

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利用高维低样本量数据进行面向超早期医疗的系统识别
动态网络生物标志物(DNBs)理论有效地解决了利用高维低样本量(HDLSS)数据进行疾病超早期检测的问题。超早期检测之后,关键是要考虑对检测出的疾病进行超早期治疗。从控制工程的角度来看,超早期医疗是通过提高系统的稳定性和防止分叉来实现的,这就是所谓的再稳定。要实现有效的再稳定,系统矩阵是必要的。然而,生物系统中的可用数据往往是 HDLSS,不足以确定系统矩阵。为了实现基于 HDLSS 的超早期医疗,本文研究了一种基于 HDLSS 数据的系统矩阵估计方法。首先,应用 HDLSS 数据计算稳定状态的样本协方差矩阵。假设系统矩阵稀疏且系统矩阵结构已知,则可利用 Lyapunov 方程从协方差矩阵估计系统矩阵。如果协方差矩阵是全秩的,基于 Lyapunov 方程的方法就能给出唯一的最优估计值。否则,最优估计值不是唯一的。根据 HDLSS 数据计算的样本协方差矩阵不是全秩的。因此,我们采用收缩估计法来克服欠定问题,从而获得条件良好的全秩协方差矩阵。此外,我们还通过数值模拟证实了所提方法的有效性。
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来源期刊
IFAC Journal of Systems and Control
IFAC Journal of Systems and Control AUTOMATION & CONTROL SYSTEMS-
CiteScore
3.70
自引率
5.30%
发文量
17
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