Co-design of reduced-order models and observers from thermo-fluid data

IF 1.8 Q3 AUTOMATION & CONTROL SYSTEMS IFAC Journal of Systems and Control Pub Date : 2022-03-01 DOI:10.1016/j.ifacsc.2021.100181

Sanjana Vijayshankar , Ankush Chakrabarty , Piyush Grover , Saleh Nabi

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引用次数: 1

Abstract

This paper presents a method of co-design of models and observers for buoyancy-driven turbulent flows. Recent work on data-driven techniques for estimating turbulent flows typically involve obtaining a dynamical model using Dynamical Mode Decomposition (DMD) and using the model to design estimators. Unfortunately, such a sequential design could result in state-space models that do not possess control-theoretic properties (such as detectability) that ensure guaranteed performance of the observer. In this paper, we propose semi-definite programs (SDPs) that allow us to simultaneously construct observer gains, along with DMD models which exhibit desired properties. Since DMD models for turbulent flows are typically high-dimensional, we provide a tractable algorithm for solving the high-dimensional SDP. We demonstrate the potential of our proposed approach on an industrial application using real-world data, and illustrate that the co-design significantly outperforms sequential design.

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从热流体数据中共同设计降阶模型和观测者

本文提出了一种浮力驱动湍流模型与观测者共同设计的方法。最近关于紊流估计的数据驱动技术的工作通常涉及使用动态模态分解(DMD)获得一个动态模型，并使用该模型来设计估计器。不幸的是，这样的顺序设计可能会导致状态空间模型不具有控制理论特性(如可检测性)，从而无法保证观察者的性能。在本文中，我们提出了半确定程序(sdp)，它允许我们同时构建观测器增益，以及显示所需属性的DMD模型。由于湍流的DMD模型通常是高维的，我们提供了一种易于处理的算法来求解高维SDP。我们使用真实世界的数据证明了我们提出的方法在工业应用中的潜力，并说明了协同设计显着优于顺序设计。

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来源期刊

IFAC Journal of Systems and Control AUTOMATION & CONTROL SYSTEMS-

CiteScore

3.70

自引率

5.30%

发文量