Networked servomotor control method based on disturbance observer

A technology of interference observer and networked control, applied in the direction of motor generator control, electronic commutation motor control, control system, etc., can solve the problem of ignoring the delay from sensor to controller, limiting practical application, not considering the unknown interference of the system, etc. problems, to achieve the effect of improving interoperability and flexibility, compensating for network-induced delays, and improving steady-state performance

Inactive Publication Date: 2013-09-18
三亚哈尔滨工程大学南海创新发展基地
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Problems solved by technology

Although the above literatures have effectively compensated the influence of network delay, they have not considered the influence of unknown disturbances in the system, which limits their practical application. In the literature "Sliding mode controller design for a class of uncertain and Decision Making, 2006,21(10):1197-1200)", a sliding mode control method is designed for the n

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  • Networked servomotor control method based on disturbance observer
  • Networked servomotor control method based on disturbance observer
  • Networked servomotor control method based on disturbance observer

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Embodiment Construction

[0016] The present invention will be described in more detail below in conjunction with the accompanying drawings and embodiments, but this embodiment is based on the technical solution of the present invention and is not intended to limit the present invention.

[0017] Such as figure 1 As shown, the disturbance observer-based servo motor network control system of the present invention includes a measuring element 2 , a disturbance observer 5 , a sliding mode controller 9 and a control variable buffer 10 .

[0018] Since the networked control system is essentially a discrete time system, the discrete equation of the system can be obtained by integrating in a sampling period T first:

[0019] x k + 1 = Φ x k + ...

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Abstract

The invention provides a networked servomotor control method based on a disturbance observer. According to the method, a measuring element acquires the angular displacement and angular velocity of a servomotor and sends the angular displacement and the angular velocity to the disturbance observer and a sliding mode controller through a network, the disturbance observer simultaneously reads historical control quantity values, stored in a control quantity buffer, and estimates a disturbance size and sends the disturbance size to the sliding mode controller, and the sliding mode controller obtains a control voltage signal through solving and sends the control voltage signal to the servomotor through the network so as to form closed-loop network control on the servomotor. The method is applied to a servomotor system with external disturbance, and the networked control is realized through network connection, so that the interoperability, flexibility and the like of the system are improved; through selecting a sliding mode function with historical control input, the network-induced time delay is compensated, and the stability of the system is improved; and through designing the disturbance observer, the disturbance suppression is realized, the buffeting of the system is reduced, and the dynamic performance of the system is improved.

Description

technical field [0001] The invention relates to a sliding mode control method, which is mainly aimed at a discrete sliding mode control method for a networked servo motor system with external interference. Background technique [0002] With the continuous development of computer and network technology, automation technology is gradually developing towards networking and informationization, and the network control system (NCS) has emerged as the times require, and its application range has become wider and wider. Especially in recent years, network control is used in motors, Aerospace and other fields have received extensive attention. Compared with traditional point-to-point control, the main advantages of NCS are fewer connections, easy resource sharing and remote operation, low cost, and convenient expansion and maintenance. However, the transmission of information through the network is accompanied by uncertain factors such as time delay and packet loss, which increases ...

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Application Information

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IPC IPC(8): H02P21/13
Inventor 夏国清武慧勇杨月栾添添赵昂
Owner 三亚哈尔滨工程大学南海创新发展基地
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