全参数估计连续时间分数系统的递归系统识别

IF 4.9 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Control Systems Technology Pub Date : 2024-06-07 DOI:10.1109/TCST.2024.3407580

Jean-François Duhé;Stéphane Victor;Pierre Melchior;Youssef Abdelmoumen;François Roubertie

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引用次数: 0

摘要

事实证明，分数阶系统可以很好地模拟扩散或传播现象。本文探讨了连续时间分数模型的递归或在线系统识别。当微分阶数已知时，只需估计系数：最小二乘法、预测误差法（PEM）和工具变量等经典递归方法适用于分数模型。然后将这些方法与我们新的长记忆 PEM 进行比较，以证明其效率。当微分阶未知时（这在实践中经常发生），提出了系数和微分阶估计的两阶段算法。提出了一种单一的微分阶次估计方法，然后将其与两种最佳系数估计方法（长记忆 PEM 和工具变量）相结合，创建了两种混合算法。通过蒙特卡罗模拟比较了这些算法的性能，以突出参数估计在更复杂情况下的影响。最后，递归识别被应用到肺热阻抗的模拟实例中。

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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Recursive System Identification of Continuous-Time Fractional Systems for All Parameter Estimation

Fractional-order systems have proven to be useful to well model diffusion or propagation phenomena. Recursive or online system identification of continuous-time fractional models is explored in this article. When differentiation orders are known, only the coefficients are to be estimated: the classic recursive methods of least squares, prediction error method (PEM), and instrumental variable are adapted for fractional models. They are then compared to our new long memory PEM to prove its efficiency. When differentiation orders are unknown, which is often the case in practice, two-stage algorithms are proposed for both coefficient and differentiation order estimation. A single method of differentiation order estimation is proposed, which is then combined with the two best coefficient estimation methods (long-memory PEM and instrumental variable) to create two hybrid algorithms. The performances of these algorithms are compared through Monte Carlo simulations in order to highlight the influence of the parameter estimation in a more complex scenario. Finally, recursive identification is applied to a simulation example of a thermal lung impedance.

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来源期刊

IEEE Transactions on Control Systems Technology 工程技术-工程：电子与电气

CiteScore

10.70

自引率

2.10%

发文量

218

审稿时长

6.7 months

期刊介绍： The IEEE Transactions on Control Systems Technology publishes high quality technical papers on technological advances in control engineering. The word technology is from the Greek technologia. The modern meaning is a scientific method to achieve a practical purpose. Control Systems Technology includes all aspects of control engineering needed to implement practical control systems, from analysis and design, through simulation and hardware. A primary purpose of the IEEE Transactions on Control Systems Technology is to have an archival publication which will bridge the gap between theory and practice. Papers are published in the IEEE Transactions on Control System Technology which disclose significant new knowledge, exploratory developments, or practical applications in all aspects of technology needed to implement control systems, from analysis and design through simulation, and hardware.