port - hamilton系统的定阶h∞控制器设计

P. Schwerdtner, M. Voigt
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引用次数: 0

摘要

我们提出了一种新的定阶h∞控制器设计方法,用于潜在的大规模port- hamilton (pH)装置。我们的方法计算的控制器也是pH值(因此是被动的),这样得到的闭环系统再次是被动的,这确保了闭环的稳定性,仅仅从植物和控制器矩阵的结构。通过这种方式,我们可以避免计算上昂贵的特征值计算,否则将是必要的。结合基于样本的目标函数,使我们能够避免对h -∞范数的多次评估(这通常是定阶h -∞控制器合成中的主要计算负担),这使得我们的方法非常适合具有高状态空间维度的植物。在我们的数值实验中,我们表明,在使用成熟的h -∞合成方法后,应用强制无源后处理步骤通常会导致h -∞性能恶化。与此相反,我们的方法计算pH控制器,它是自动被动的,同时旨在最小化闭环传递函数的h∞范数。此外,我们的实验表明,对于大型对象,我们的方法明显快于成熟的定阶h∞控制器合成方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fixed-Order H-Infinity Controller Design for Port-Hamiltonian Systems
We present a new fixed-order H-infinity controller design method for potentially large-scale port-Hamiltonian (pH) plants. Our method computes controllers that are also pH (and thus passive) such that the resulting closed-loop systems is again passive, which ensures closed-loop stability simply from the structure of the plant and controller matrices. In this way, we can avoid computationally expensive eigenvalue computations that would otherwise be necessary. In combination with a sample-based objective function which allows us to avoid multiple evaluations of the H-infinity norm (which is typically the main computational burden in fixed-order H-infinity controller synthesis), this makes our method well-suited for plants with a high state-space dimension. In our numerical experiments, we show that applying a passivity-enforcing post-processing step after using well-established H-infinity synthesis methods often leads to a deteriorated H-infinity performance. In constrast to that, our method computes pH controllers, that are automatically passive and simultaneously aim to minimize the H-infinity norm of the closed-loop transfer function. Moreover, our experiments show that for large-scale plants, our method is significantly faster than the well-established fixed-order H-infinity controller synthesis methods.
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