Decoupling control of multivariable biologic fermentation process

Guohai Liu; Yukun Sun; Li Quan; Xianxing Liu; Xingqiao Liu

Decoupling control of multivariable biologic fermentation process

Guohai Liu^*, Yukun Sun, Li Quan, Xianxing Liu, Xingqiao Liu

^*Corresponding author for this work

Jiangsu University

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Based on neural network inverse system a decoupling control strategy for multivariable fermentation process is proposed, in which the inverse system linearizing method of the nonlinear system is combined with the nonlinear identifying technology of the neural networks. When adequate prior information concerning the dynamics of the fermentation processes is not available and parameters of the processes change with time, the good control performance can be obtained by using the proposed strategy. The simulation experiments demonstrate that the presented decoupling approach is more effective than inverse system method based on differential geometry, because in inverse system method the design of the controller relies on the exact process model and its control performance is sensitive to the parameters of the model, which results in low accuracy and poor robust.

Original language	English
Pages (from-to)	155-159
Number of pages	5
Journal	Dongnan Daxue Xuebao (Ziran Kexue Ban)/Journal of Southeast University (Natural Science Edition)
Volume	34
Issue number	SUPPL.
Publication status	Published - Nov 2004
Externally published	Yes

Keywords

Fermentation process
Inverse system
Neural network
Nonlinear system

Cite this

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title = "Decoupling control of multivariable biologic fermentation process",

abstract = "Based on neural network inverse system a decoupling control strategy for multivariable fermentation process is proposed, in which the inverse system linearizing method of the nonlinear system is combined with the nonlinear identifying technology of the neural networks. When adequate prior information concerning the dynamics of the fermentation processes is not available and parameters of the processes change with time, the good control performance can be obtained by using the proposed strategy. The simulation experiments demonstrate that the presented decoupling approach is more effective than inverse system method based on differential geometry, because in inverse system method the design of the controller relies on the exact process model and its control performance is sensitive to the parameters of the model, which results in low accuracy and poor robust.",

keywords = "Fermentation process, Inverse system, Neural network, Nonlinear system",

author = "Guohai Liu and Yukun Sun and Li Quan and Xianxing Liu and Xingqiao Liu",

year = "2004",

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language = "English",

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TY - JOUR

T1 - Decoupling control of multivariable biologic fermentation process

AU - Liu, Guohai

AU - Sun, Yukun

AU - Quan, Li

AU - Liu, Xianxing

AU - Liu, Xingqiao

PY - 2004/11

Y1 - 2004/11

N2 - Based on neural network inverse system a decoupling control strategy for multivariable fermentation process is proposed, in which the inverse system linearizing method of the nonlinear system is combined with the nonlinear identifying technology of the neural networks. When adequate prior information concerning the dynamics of the fermentation processes is not available and parameters of the processes change with time, the good control performance can be obtained by using the proposed strategy. The simulation experiments demonstrate that the presented decoupling approach is more effective than inverse system method based on differential geometry, because in inverse system method the design of the controller relies on the exact process model and its control performance is sensitive to the parameters of the model, which results in low accuracy and poor robust.

AB - Based on neural network inverse system a decoupling control strategy for multivariable fermentation process is proposed, in which the inverse system linearizing method of the nonlinear system is combined with the nonlinear identifying technology of the neural networks. When adequate prior information concerning the dynamics of the fermentation processes is not available and parameters of the processes change with time, the good control performance can be obtained by using the proposed strategy. The simulation experiments demonstrate that the presented decoupling approach is more effective than inverse system method based on differential geometry, because in inverse system method the design of the controller relies on the exact process model and its control performance is sensitive to the parameters of the model, which results in low accuracy and poor robust.

KW - Fermentation process

KW - Inverse system

KW - Neural network

KW - Nonlinear system

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M3 - Article

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SN - 1001-0505

VL - 34

SP - 155

EP - 159

JO - Dongnan Daxue Xuebao (Ziran Kexue Ban)/Journal of Southeast University (Natural Science Edition)

JF - Dongnan Daxue Xuebao (Ziran Kexue Ban)/Journal of Southeast University (Natural Science Edition)

IS - SUPPL.

ER -

Decoupling control of multivariable biologic fermentation process

Abstract

Keywords

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