A framework for model maintenance using kernel-based forward propagating neural networks

IF 3.7 3区工程技术 Q2 ENGINEERING, CHEMICAL

Chemical Engineering Research & Design Pub Date : 2024-09-03 DOI:10.1016/j.cherd.2024.09.002

Deepak Kumar , Manojkumar Ramteke , Hariprasad Kodamana

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引用次数: 0

Abstract

Deep learning models possess limited flexibility in computational burden in model adaptation owing to the conventional use of backpropagation for model training. To address this problem, we propose an alternate training methodology inspired by the forward–forward algorithm originally designed for classification tasks. We extend this concept through a kernel-based modification, enabling its application to regression tasks, which are commonly encountered in process system modeling. Our proposed Kernel-based Forward Propagating Neural Network (K-FP-NN) eliminates backpropagation, using layer-wise updates for better adaptability. We introduce a real-time (RT) updating framework, RT-K-FP-NN, to continuously refine model parameters with new data. Results indicate that when applied to model predictive control of a continuous stirred tank reactor (CSTR) system, our approach updates the model within 100 s, achieving better performance metrics compared to backpropagation-based real-time models, which require 326 s. This framework can be applied to various dynamic systems, enhancing real-time decision-making by improving predictive accuracy and system adaptability.

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使用基于核的前向传播神经网络的模型维护框架

由于传统上使用反向传播进行模型训练，深度学习模型在模型适应方面的计算负担灵活性有限。为了解决这个问题，我们提出了另一种训练方法，其灵感来自最初为分类任务设计的前向算法。我们通过基于内核的修改扩展了这一概念，使其能够应用于过程系统建模中经常遇到的回归任务。我们提出的基于内核的前向传播神经网络（K-FP-NN）取消了反向传播，使用层更新以获得更好的适应性。我们引入了实时（RT）更新框架 RT-K-FP-NN，以根据新数据不断完善模型参数。结果表明，当应用于连续搅拌罐反应器（CSTR）系统的模型预测控制时，我们的方法能在 100 秒内更新模型，与需要 326 秒的基于反向传播的实时模型相比，性能指标更好。

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

Chemical Engineering Research & Design 工程技术-工程：化工

CiteScore

6.10

自引率

7.70%

发文量

623

审稿时长

42 days

期刊介绍： ChERD aims to be the principal international journal for publication of high quality, original papers in chemical engineering. Papers showing how research results can be used in chemical engineering design, and accounts of experimental or theoretical research work bringing new perspectives to established principles, highlighting unsolved problems or indicating directions for future research, are particularly welcome. Contributions that deal with new developments in plant or processes and that can be given quantitative expression are encouraged. The journal is especially interested in papers that extend the boundaries of traditional chemical engineering.