A big data-driven predictive control approach for nonlinear processes using behaviour clusters

IF 3.3 2区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS Journal of Process Control Pub Date : 2024-06-07 DOI:10.1016/j.jprocont.2024.103252

Shuangyu Han , Yitao Yan , Jie Bao , Biao Huang

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Abstract

A novel big data-driven predictive control (BDPC) approach for nonlinear processes is proposed. To deal with nonlinear process behaviours, the process behaviour space, represented by a set of input–output variable trajectories, is partitioned into linear sub-behaviour spaces (clusters), based on linear inclusion of nonlinear behaviours. A behaviour space (represented using Hankel matrices) partitioning approach is developed based on subspace angles. During online control, the BDPC controller locates the most relevant linear sub-behaviour based on the current online trajectory, which is then used to determine predictive control actions using receding horizon optimisation. The incremental stability and dissipativity conditions are developed to attenuate the effect of the error of approximating linear sub-behaviours on the output and guarantee closed-loop stability. These conditions are implemented as additional constraints during online data-driven predictive control. An example of controlling the Hall–Héroult process is used to illustrate the proposed approach.

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使用行为集群的非线性过程大数据驱动预测控制方法

针对非线性过程提出了一种新颖的大数据驱动预测控制（BDPC）方法。为了处理非线性过程行为，根据非线性行为的线性包含关系，将输入输出变量轨迹集所代表的过程行为空间划分为线性子行为空间（群组）。基于子空间角度，开发了一种行为空间（使用汉克尔矩阵表示）划分方法。在在线控制过程中，BDPC 控制器会根据当前的在线轨迹找到最相关的线性子行为，然后利用后退视界优化来确定预测控制行动。开发增量稳定性和耗散性条件是为了减弱近似线性子行为的误差对输出的影响，并保证闭环稳定性。这些条件在在线数据驱动预测控制中作为附加约束条件实施。以控制霍尔-赫鲁特过程为例，说明了所提出的方法。

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来源期刊

Journal of Process Control 工程技术-工程：化工

CiteScore

7.00

自引率

11.90%

发文量

159

审稿时长

74 days

期刊介绍： This international journal covers the application of control theory, operations research, computer science and engineering principles to the solution of process control problems. In addition to the traditional chemical processing and manufacturing applications, the scope of process control problems involves a wide range of applications that includes energy processes, nano-technology, systems biology, bio-medical engineering, pharmaceutical processing technology, energy storage and conversion, smart grid, and data analytics among others. Papers on the theory in these areas will also be accepted provided the theoretical contribution is aimed at the application and the development of process control techniques. Topics covered include: • Control applications• Process monitoring• Plant-wide control• Process control systems• Control techniques and algorithms• Process modelling and simulation• Design methods Advanced design methods exclude well established and widely studied traditional design techniques such as PID tuning and its many variants. Applications in fields such as control of automotive engines, machinery and robotics are not deemed suitable unless a clear motivation for the relevance to process control is provided.