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Constructing method for decoupling controller of support vector machine inverter of bearingless asynchronous motor

A support vector machine inverse and support vector machine technology, applied in motor generator control, electronic commutation motor control, vector control system and other directions, can solve the problems of difficult optimization of network structure, long training time, slow learning speed, etc. Achieve stable suspension operation, improve control performance, and improve the effect of performance indicators

Inactive Publication Date: 2012-11-21
JIANGSU UNIV
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Problems solved by technology

As a complex nonlinear system, bearingless asynchronous motors have significant changes in rotor parameters with various operating conditions, making it difficult to apply the inverse system method in practice.
Although the neural network inverse method solves the shortcomings of the inverse system method, the neural network inverse control method has local minimum problems, slow learning speed, long training time, difficulty in extracting ideal samples, and difficult optimization of the network structure. The method of bearingless asynchronous motor decoupling control effect is not good

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  • Constructing method for decoupling controller of support vector machine inverter of bearingless asynchronous motor
  • Constructing method for decoupling controller of support vector machine inverter of bearingless asynchronous motor
  • Constructing method for decoupling controller of support vector machine inverter of bearingless asynchronous motor

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Embodiment Construction

[0017] The embodiment of the present invention is: firstly based on the prototype body of the bearingless asynchronous motor, then two Clark inverse transforms, two current tracking inverters and the load of the bearingless asynchronous motor are used as a whole to form a composite controlled object, the composite is The control object is equivalent to a 6-order differential equation model, and the relative order of the system vector is {2,2,1,1}. A support vector machine with 10 input nodes and 4 output nodes plus 6 integrators s -1 Construct the support vector machine inverse of a compound plant with 10 input nodes and 4 output nodes. Then connect the inverse of the support vector machine in front of the compound controlled object, and the inverse of the support vector machine and the compound controlled object are synthesized into two displacement second-order integral subsystems, a rotational speed first-order integral subsystem and a flux linkage first-order integral sub...

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Abstract

The invention discloses a constructing method for a decoupling controller of a support vector machine inverter of a bearingless asynchronous motor. The support vector machine inverter is constructed by a support vector machine with 10 input nodes and 4 output nodes and six integrators s-1 and is arranged in front of a complex controlled object to form a pseudo-linear system, and two corresponding displacement regulators, one speed regulator and one flux linkage regulator are respectively designed for integral type pseudo-linear subsystems; a linear closed-loop controller is constructed by four regulators; and the decoupling controller is constructed by the linear closed-loop controller, the support vector machine inverter, two Clark inverse transformers and two current tracking inverters. According to the constructing method, control on a multi-variable, nonlinear and strong-coupling time-changing system is converted into control on two displacement second-order integral linear subsystems, one speed first-order integral linear subsystem and one flux linkage first-order integral linear subsystem, and dynamic decoupling of the radial force, the speed and the flux linkage can be realized.

Description

technical field [0001] The invention belongs to the technical field of electric drive control equipment, and relates to a construction method for a decoupling controller of a bearingless asynchronous motor, which is suitable for high-performance control of a bearingless asynchronous motor. Bearingless asynchronous motors integrate the advantages of magnetic bearings and asynchronous motors, and have broad application prospects in special power transmission fields such as compressors, centrifuges, electromechanical energy storage, turbomolecular pumps, machine tool electric spindles, and aerospace. Background technique [0002] Bearingless asynchronous motors not only have a series of advantages such as uniform air gap, simple structure, firmness and reliability, and low cost, but also have the characteristics of wide field weakening range and low cogging pulsating torque. It is one of the most promising bearingless motors. . However, the bearingless asynchronous motor has a...

Claims

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Application Information

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IPC IPC(8): H02P21/00H02P21/14
Inventor 李可孙晓东杨泽斌杨辉汪明涛
Owner JIANGSU UNIV
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