Switching probabilistic slow feature extraction for semisupervised industrial inferential modeling

IF 3.3 2区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS

Journal of Process Control Pub Date : 2024-07-18 DOI:10.1016/j.jprocont.2024.103277

Chao Jiang , Xin Peng , Biao Huang , Weimin Zhong

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引用次数: 0

Abstract

Predicting quality-relevant process variables is of paramount importance in optimizing and controlling chemical processes. Probabilistic Slow Feature Analysis (PSFA), a potent data-driven technique, plays a pivotal role in deducing quality indices by abstracting gradual variations in processes distinctly characterized by pronounced inertia. Nevertheless, PSFA’s predictive efficacy encounters a substantial bottleneck due to the assumption of a single operating condition, compromising its accuracy, particularly in industries represented by switching operating conditions. To surmount this limitation, this study proposes an innovative approach that enriches PSFA with multi-operating condition process data and limited labels within a Bayesian framework, effectively combining continuous and discrete first-order Markov chains to capture the processes’ inertia and dynamic shifts. The proposed method updates latent posterior distributions and model parameters iteratively via the Expectation–Maximization algorithm. The effectiveness of the proposed methodology is verified through a numerical case and industrial hydrocracking process data.

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用于半监督工业推理建模的开关概率慢速特征提取

预测与质量相关的过程变量对于优化和控制化学过程至关重要。概率慢特征分析法（PSFA）是一种有效的数据驱动技术，通过抽象出具有明显惯性特征的过程中的渐进变化，在推导质量指数方面发挥着举足轻重的作用。然而，由于假设运行条件单一，PSFA 的预测功效遇到了很大的瓶颈，影响了其准确性，尤其是在以运行条件切换为代表的行业中。为了克服这一局限性，本研究提出了一种创新方法，即在贝叶斯框架内利用多运行条件过程数据和有限标签来丰富 PSFA，有效地结合连续和离散一阶马尔可夫链来捕捉过程的惯性和动态变化。所提出的方法通过期望最大化算法迭代更新潜在后验分布和模型参数。通过一个数值案例和工业加氢裂化过程数据验证了所提方法的有效性。

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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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.