A controller design method for high-order unstable linear time-invariant systems

Gengjin Shi; Zhiqiang Gao; YangQuan Chen; Donghai Li; Yanjun Ding

doi:10.1016/j.isatra.2022.04.012

A controller design method for high-order unstable linear time-invariant systems

Gengjin Shi
, Zhiqiang Gao
, YangQuan Chen
, Donghai Li
, Yanjun Ding

Electrical and Computer Engineering

Tsinghua University
Cleveland State University
School of Engineering

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

10 Scopus citations

Abstract

This paper deals with high-order unstable systems, which are dangerous and more difficult to control. Their presence is increasingly prevalent, posing a great challenge to both traditional PID-based industrial designs and various advanced control strategies which are difficult to implement on common industrial control platforms. In this paper, the generalized desired dynamic equational (G-DDE) PID controller, developed by authors earlier, is proposed as a viable alternative. In addition to guarantee the closed-loop stability, its simple structure and tuning procedure are specifically appealing to practitioners. Simulations and experimental results show advantages of G-DDE PID in reference tracking, disturbance rejection and robustness, thus making G-DDE PID a convenient and effective control strategy for high-order unstable systems, readily implementable on common industrial platforms.

Original language	English
Pages (from-to)	500-515
Number of pages	16
Journal	ISA Transactions
Volume	130
DOIs	https://doi.org/10.1016/j.isatra.2022.04.012
State	Published - Nov 1 2022

Keywords

Desired dynamic equational
Generalized PID
High-order unstable systems

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10.1016/j.isatra.2022.04.012

Cite this

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abstract = "This paper deals with high-order unstable systems, which are dangerous and more difficult to control. Their presence is increasingly prevalent, posing a great challenge to both traditional PID-based industrial designs and various advanced control strategies which are difficult to implement on common industrial control platforms. In this paper, the generalized desired dynamic equational (G-DDE) PID controller, developed by authors earlier, is proposed as a viable alternative. In addition to guarantee the closed-loop stability, its simple structure and tuning procedure are specifically appealing to practitioners. Simulations and experimental results show advantages of G-DDE PID in reference tracking, disturbance rejection and robustness, thus making G-DDE PID a convenient and effective control strategy for high-order unstable systems, readily implementable on common industrial platforms.",

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T1 - A controller design method for high-order unstable linear time-invariant systems

AU - Shi, Gengjin

AU - Gao, Zhiqiang

AU - Chen, YangQuan

AU - Li, Donghai

AU - Ding, Yanjun

PY - 2022/11/1

Y1 - 2022/11/1

N2 - This paper deals with high-order unstable systems, which are dangerous and more difficult to control. Their presence is increasingly prevalent, posing a great challenge to both traditional PID-based industrial designs and various advanced control strategies which are difficult to implement on common industrial control platforms. In this paper, the generalized desired dynamic equational (G-DDE) PID controller, developed by authors earlier, is proposed as a viable alternative. In addition to guarantee the closed-loop stability, its simple structure and tuning procedure are specifically appealing to practitioners. Simulations and experimental results show advantages of G-DDE PID in reference tracking, disturbance rejection and robustness, thus making G-DDE PID a convenient and effective control strategy for high-order unstable systems, readily implementable on common industrial platforms.

AB - This paper deals with high-order unstable systems, which are dangerous and more difficult to control. Their presence is increasingly prevalent, posing a great challenge to both traditional PID-based industrial designs and various advanced control strategies which are difficult to implement on common industrial control platforms. In this paper, the generalized desired dynamic equational (G-DDE) PID controller, developed by authors earlier, is proposed as a viable alternative. In addition to guarantee the closed-loop stability, its simple structure and tuning procedure are specifically appealing to practitioners. Simulations and experimental results show advantages of G-DDE PID in reference tracking, disturbance rejection and robustness, thus making G-DDE PID a convenient and effective control strategy for high-order unstable systems, readily implementable on common industrial platforms.

KW - Desired dynamic equational

KW - Generalized PID

KW - High-order unstable systems

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A controller design method for high-order unstable linear time-invariant systems

Abstract

Keywords

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