Design and Analysis of Precision Active Disturbance Rejection Control for Noncircular Turning Process

In this paper, a new fast tool servocontrol method for noncircular turning process (NCTP) is presented. Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and feedforward arrangement by exploiting...

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Published in	IEEE transactions on industrial electronics (1982) Vol. 56; no. 7; pp. 2746 - 2753
Main Authors	Dan Wu, Dan Wu, Ken Chen, Ken Chen
Format	Journal Article
Language	English
Published	New York IEEE 01.07.2009 The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects	Acceleration Acceleration feedforward Active control active disturbance rejection control (ADRC) Design engineering Disturbances Dynamical systems fast tool servo (FTS) Feedforward Mathematical models noncircular turning Nonlinear dynamical systems Nonlinear dynamics Observers Pi control Proportional control Rejection Signal design State estimation Studies Transfer functions Turning Uncertainty
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ISSN	0278-0046 1557-9948
DOI	10.1109/TIE.2009.2019774

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Abstract	In this paper, a new fast tool servocontrol method for noncircular turning process (NCTP) is presented. Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and feedforward arrangement by exploiting the unique disturbance estimation and compensation concept and the known reference acceleration signals. In such a design framework, an extended state observer is applied to estimate and compensate for the variant dynamics of the system, nonlinearly variable cutting load, and other uncertainties. Then, a simple proportional integral controller and the acceleration feedforward design produce the control law. To quantify the controller performances, the transfer function description of the controller is derived, and the dynamic stiffness and tracking have been analyzed. By defining the vector margin variation rate, the effects of the plant parameter variations on closed-loop stability are also addressed. Experimental results of machining the first- and second-order oval profiles demonstrate that the tracking error is less than 3 mum for different cutting parameters.
AbstractList	In this paper, a new fast tool servocontrol method for noncircular turning process (NCTP) is presented. Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and feedforward arrangement by exploiting the unique disturbance estimation and compensation concept and the known reference acceleration signals. In such a design framework, an extended state observer is applied to estimate and compensate for the variant dynamics of the system, nonlinearly variable cutting load, and other uncertainties. Then, a simple proportional integral controller and the acceleration feedforward design produce the control law. To quantify the controller performances, the transfer function description of the controller is derived, and the dynamic stiffness and tracking have been analyzed. By defining the vector margin variation rate, the effects of the plant parameter variations on closed-loop stability are also addressed. Experimental results of machining the first- and second-order oval profiles demonstrate that the tracking error is less than 3 mum for different cutting parameters. In this paper, a new fast tool servocontrol method for noncircular turning process (NCTP) is presented. Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and feedforward arrangement by exploiting the unique disturbance estimation and compensation concept and the known reference acceleration signals. In such a design framework, an extended state observer is applied to estimate and compensate for the variant dynamics of the system, nonlinearly variable cutting load, and other uncertainties. Then, a simple proportional integral controller and the acceleration feedforward design produce the control law. To quantify the controller performances, the transfer function description of the controller is derived, and the dynamic stiffness and tracking have been analyzed. By defining the vector margin variation rate, the effects of the plant parameter variations on closed-loop stability are also addressed. Experimental results of machining the first- and second-order oval profiles demonstrate that the tracking error is less than 3muhbox{m} for different cutting parameters. Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and feedforward arrangement by exploiting the unique disturbance estimation and compensation concept and the known reference acceleration signals.
Author	Dan Wu Ken Chen
Author_xml	– sequence: 1 givenname: Dan Wu surname: Dan Wu fullname: Dan Wu, Dan Wu – sequence: 2 givenname: Ken Chen surname: Ken Chen fullname: Ken Chen, Ken Chen
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Snippet	In this paper, a new fast tool servocontrol method for noncircular turning process (NCTP) is presented. Based on the tracking and disturbance rejection... Based on the tracking and disturbance rejection requirements for NCTP, the controller is designed through a combined active disturbance rejection control and...
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SubjectTerms	Acceleration Acceleration feedforward Active control active disturbance rejection control (ADRC) Design engineering Disturbances Dynamical systems fast tool servo (FTS) Feedforward Mathematical models noncircular turning Nonlinear dynamical systems Nonlinear dynamics Observers Pi control Proportional control Rejection Signal design State estimation Studies Transfer functions Turning Uncertainty
Title	Design and Analysis of Precision Active Disturbance Rejection Control for Noncircular Turning Process
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