Soft Sensor Modeling Method for the Marine Lysozyme Fermentation Process Based on ISOA-GPR Weighted Ensemble Learning

Lu, Na; Wang, Bo; Zhu, Xianglin

doi:10.3390/s23229119

Cited by 2 publications

(2 citation statements)

References 22 publications

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“…It has been widely utilized globally and extensively researched by scholars, yielding fruitful results. For instance, Lu et al [5] proposed a weighted ensemble learning soft sensor modeling method based on an improved seagull optimization algorithm and Gaussian process regression to address the issue of traditional single methods failing to describe the nonlinear characteristics of the entire fermentation process. Applying this soft sensor method to predict key biochemical parameters in the fermentation process of marine lysozyme, the results indicate relatively small errors.…”

Section: Introductionmentioning

confidence: 99%

Modeling and Optimization of an Enhanced Soft Sensor for the Fermentation Process of Pichia pastoris

Wang,

Yu,

Wang

et al. 2024

Sensors

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This paper proposes a novel soft sensor modeling approach, MIC-TCA-INGO-LSSVM, to address the decline in performance of soft sensor models during the fermentation process of Pichia pastoris, caused by changes in working conditions. Initially, the transfer component analysis (TCA) method is utilized to minimize the differences in data distribution across various working conditions. Subsequently, a least squares support vector machine (LSSVM) model is constructed using the dataset adapted by TCA, and strategies for improving the northern goshawk optimization (INGO) algorithm are proposed to optimize the parameters of the LSSVM model. Finally, to further enhance the model’s generalization ability and prediction accuracy, considering the transfer of knowledge from multiple-source working conditions, a sub-model weighted ensemble scheme is proposed based on the maximum information coefficient (MIC) algorithm. The proposed soft sensor model is employed to predict cell and product concentrations during the fermentation process of Pichia pastoris. Simulation results indicate that the RMSE of the INGO-LSSVM model in predicting cell and product concentrations is reduced by 47.3% and 42.1%, respectively, compared to the NGO-LSSVM model. Additionally, TCA significantly enhances the model’s adaptability when working conditions change. Moreover, the soft sensor model based on TCA and the MIC-weighted ensemble method achieves a reduction of 41.6% and 31.3% in the RMSE for predicting cell and product concentrations, respectively, compared to the single-source condition transfer model TCA-INGO-LSSVM. These results demonstrate the high reliability and predictive performance of the proposed soft sensor method under varying working conditions.

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Section: Introductionmentioning

confidence: 99%

Modeling and Optimization of an Enhanced Soft Sensor for the Fermentation Process of Pichia pastoris

Wang,

Yu,

Wang

et al. 2024

Sensors

Self Cite

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“…The application of soft sensors is possible in several fields. In biology and environmental studies, an example is the work of Lu et al [9], in which an intelligent algorithm named the improved seagull optimization algorithm (ISOA) and the Gaussian process regression (GPR) were chosen as the central element of a soft sensor able to estimate some key biochemical parameters in marine lysozyme fermentation. ISOA-GPR weighted ensemble learning was shown to perform better (in terms of root mean square and maximum absolute errors) than ISOA-GPR single global predicted value.…”

Section: Introductionmentioning

confidence: 99%

A Soft Sensor for Flow Estimation and Uncertainty Analysis Based on Artificial Intelligence: A Case Study of Water Supply Systems

Alencar,

Fernandes,

Moura Duarte

et al. 2024

Automation

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The fourth industrial revolution has transformed the industry, with information technology playing a crucial role in this shift. The increasing digitization of industrial systems demands efficient sensing and control methods, giving rise to soft sensors that have the potential to replace traditional physical sensors in order to reduce costs and enhance efficiency. This study explores the implementation of an artificial neural network (ANN) based soft sensor model in a water supply system to predict flow rates within the system. The soft sensor is centered on a Long Short-Term Memory (LSTM) artificial neural network model using Monte Carlo dropout to reduce uncertainty and improve estimation performance. Based on the results of this work, it is concluded that the proposed soft sensor (with Monte Carlo dropout) can predict flow rates more precisely, contributing to the reduction in water losses, as well as cost savings. This approach offers a valuable solution for minimizing water losses and ensuring the efficient use of this vital resource. Regarding the use of soft sensors based on LSTM neural networks with a careful choice of Monte Carlo dropout parameters, when compared to the multilayer perceptron model, the LSTM model with Monte Carlo dropout showed better mean absolute error, root mean square error, and coefficient of determination: 0.2450, 0.3121, and 0.996437 versus 0.2556, 0.3522, and 0.9954. Furthermore, this choice of Monte Carlo dropout parameters allowed us to achieve an LSTM network model capable of reducing uncertainty to 1.8290, keeping the error metrics also at low levels.

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Soft Sensor Modeling Method for the Marine Lysozyme Fermentation Process Based on ISOA-GPR Weighted Ensemble Learning

Cited by 2 publications

References 22 publications

Modeling and Optimization of an Enhanced Soft Sensor for the Fermentation Process of Pichia pastoris

Modeling and Optimization of an Enhanced Soft Sensor for the Fermentation Process of Pichia pastoris

A Soft Sensor for Flow Estimation and Uncertainty Analysis Based on Artificial Intelligence: A Case Study of Water Supply Systems

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