Capturing connectivity information from process flow diagrams by sequential-orthogonalized PLS to improve soft-sensor performance

IF 3.7 2区 化学 Q2 AUTOMATION & CONTROL SYSTEMS Chemometrics and Intelligent Laboratory Systems Pub Date : 2024-07-30 DOI:10.1016/j.chemolab.2024.105192
Qiang Zhu , Pierantonio Facco , Zhonggai Zhao , Massimiliano Barolo
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Abstract

In the development of data-driven soft sensors for product quality assessment in multi-unit manufacturing processes, the only information that is typically used as an input to the model is real-time measurements from field sensors. However, even if detailed knowledge of the mechanistic behavior of the process may not be available, information about the sequence of processing units, and their connectivity, is available, typically in graphical form through process flow diagrams. In this study, we investigate the use of sequential-orthogonalized partial least-squares (SO-PLS) regression as a way to capture connectivity information from a process flow diagram, and transfer it into a data-driven model to be used as a soft sensor in a multi-unit process. Connectivity between units is captured and translated into a block order that establishes a sequence for block regressions. Orthogonalization between two blocks is then carried out with the aim of eliminating overlapping data and retaining information that is unique to each block. Product quality is finally predicted by summing the contributions from each block, and the accuracy of prediction is enhanced due to the embedded dual feature-extraction procedure, which combines orthogonalization and latent-variable extraction. The effectiveness of the proposed approach is illustrated by comparing the quality prediction performance of two soft sensors for a simulated multi-unit continuous process: one using standard PLS and one using SO-PLS. Superior performance of the SO-PLS soft sensor is achieved, even more markedly so when fewer field measurements are available to build the soft sensor.

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通过顺序正交化 PLS 从工艺流程图中获取连接性信息,提高软传感器性能
在开发用于多单元制造过程产品质量评估的数据驱动型软传感器过程中,作为模型输入的唯一信息通常是来自现场传感器的实时测量值。不过,即使无法获得流程机械行为的详细信息,也可以获得有关处理单元顺序及其连接性的信息,这些信息通常通过流程图以图形形式呈现。在本研究中,我们研究了使用顺序正交化偏最小二乘(SO-PLS)回归作为一种从工艺流程图中捕捉连接性信息的方法,并将其转换为数据驱动模型,用作多单元工艺中的软传感器。捕捉单元之间的连接性并将其转化为区块顺序,从而建立区块回归序列。然后在两个区块之间进行正交化,目的是消除重叠数据,保留每个区块独有的信息。最后,通过对每个区块的贡献进行求和来预测产品质量,由于采用了嵌入式双特征提取程序,将正交化和潜在变量提取结合在一起,因此预测的准确性得到了提高。通过比较两种软传感器在模拟多单元连续过程中的质量预测性能,说明了所提方法的有效性:一种使用标准 PLS,另一种使用 SO-PLS。SO-PLS 软传感器的性能优越,当可用于构建软传感器的现场测量数据较少时,其性能更为显著。
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来源期刊
CiteScore
7.50
自引率
7.70%
发文量
169
审稿时长
3.4 months
期刊介绍: Chemometrics and Intelligent Laboratory Systems publishes original research papers, short communications, reviews, tutorials and Original Software Publications reporting on development of novel statistical, mathematical, or computer techniques in Chemistry and related disciplines. Chemometrics is the chemical discipline that uses mathematical and statistical methods to design or select optimal procedures and experiments, and to provide maximum chemical information by analysing chemical data. The journal deals with the following topics: 1) Development of new statistical, mathematical and chemometrical methods for Chemistry and related fields (Environmental Chemistry, Biochemistry, Toxicology, System Biology, -Omics, etc.) 2) Novel applications of chemometrics to all branches of Chemistry and related fields (typical domains of interest are: process data analysis, experimental design, data mining, signal processing, supervised modelling, decision making, robust statistics, mixture analysis, multivariate calibration etc.) Routine applications of established chemometrical techniques will not be considered. 3) Development of new software that provides novel tools or truly advances the use of chemometrical methods. 4) Well characterized data sets to test performance for the new methods and software. The journal complies with International Committee of Medical Journal Editors'' Uniform requirements for manuscripts.
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