Cross Coupling Controller for Accurate Motion Synchronization of Dual Servo Systems

Ishizaki, Kosuke; Sencer, Burak; Shamoto, Eiji

doi:10.20965/ijat.2013.p0514

Cited by 29 publications

(13 citation statements)

References 12 publications

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“…Burak Sencer and Eiji Shamoto in 2014 Introduced a control system used to operate a gantry-type machine tool. It consists of two controllers for each PMDC motor, a PI controller for speed P controller for the position [17] . In 2017 Nishant Kumar and Tiwari presented a speed control system with a cross-coupling technique used to synchronizing movement for several DC motors.…”

Section: Introductionmentioning

confidence: 99%

Position - Velocity Control for Two PMDC Motors Connected by a Cross-Coupling Technique with Butterflies Optimization Algorithm

Abdulhussein

Yasin

Hasan

2021

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In this paper, two contributions are presented. the first is to design two cascade controllers to control the velocity and position for two Permanent Magnet DC motors (PMDC) working together at the same time for use in many applications such as CNC machines, robotics, and others. Furthermore, the cross-coupling technique is used to connect these motors and adjust the precise synchronization of their movement on the axes. The second contribution is the use of the butterfly’s optimization algorithm (BOA) with the objective function Integral Time Absolute Error (ITAE) to extract the optimal parameter values for the two cascade controllers and the synchronization controller in order to obtain the best accurate results. The simulation results showed high accuracy to reach the desired position at a regular velocity of both the PMDC motors with accurate synchronization and tracking trajectory on the axes. In addition, a very small position deviation of 0.021 rad was observed, and the system returned to a steady-state after 2 seconds of applying the full load.

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Section: Introductionmentioning

confidence: 99%

Position - Velocity Control for Two PMDC Motors Connected by a Cross-Coupling Technique with Butterflies Optimization Algorithm

Abdulhussein

Yasin

Hasan

2021

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“…Part of the reasons might be due to the absence of an accurate dynamical model, leading the uncomplete knowledge of the system. Commonly, the motion of each motor is modeled individually [7][8][9], while the mechanical coupling between •3• two parallel motors is essentially ignored, which makes the resulting model actually have no guidance meaning on controller development. Other researches on the coupling effects can mainly be concluded into two categories.…”

Section: Introductionmentioning

confidence: 99%

“…Limited by the aforementioned situation of modeling, earlier synchronized control schemes are usually based on the pure motion synchronization, e.g., the synchronized master command approach [17][18], the master-slave control [7][8], and the well-known cross-coupled control [8][9], [19]- [21]. Due to the ignorance of the mechanical coupling in dual-driven systems and the following internal forces issue, the achievable synchronization performance is actually limited, which has been detailedly examined in [14].…”

Section: Introductionmentioning

confidence: 99%

Accurate physical modeling and synchronization control of dual-linear-motor-driven gantry with dynamic load

Chen

Yang

et al. 2020

Preprint

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To achieve high-accuracy tracking of dual-linear-motor-driven (DLMD) gantry, high-level synchronization between redundant actuators is a nonnegligible factor and also a difficult issue to be solved prior. Especially, when both XY axes are simultaneously operating to accomplish complex tasks efficiently, additional coupling effects will be generated by the dynamic load presented on the crossbeam, which makes the synchronization issue more complicated compared to the case with static load. However, due to the absence of an accurate model to fully reveal the complete coupling characteristics, existing approaches to this issue still have inherent limitations. Therefore, this paper focuses on the systematic physical modeling and synchronization control of DLMD gantry with a dynamic load presented on the crossbeam. A complete coupling mathematical model is established firstly, by fully considering two linear motions (X-axis and Y-axis) and also including the additional rotational motion of the crossbeam. Built upon the effective model information, corresponding solutions by compensating the dynamic load effects and actively controlling the rotational dynamic to regulate the internal forces have been proposed, leading to a novel adaptive robust synchronization control method. Comparative experiments are carried out, and the results show the effectiveness and superiority of the proposed method in dealing with synchronization issue subjected to dynamic load effects.

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“…The research results show that the cross-coupling controller is a more effective way to improve the contour accuracy compared with the advanced single-axis servo controller. [2][3][4] The key technology to realize crosscoupling control is to establish real-time contour error calculation model and contour error compensation amount calculation method. [5][6] Yeh and Hsu 7 transformed the cross-coupling controller to the equivalent single-input single-output system with the introduced contour error transfer function and defined the distance from the actual cutter position to the tangent through the instruction position on the reference curve as contour error approximately.…”

Section: Introductionmentioning

confidence: 99%

Cross-coupling control method for five-axis computer numerical control machine with dual rotary tables

Zhao

Zhuang

Zheng

et al. 2017

Advances in Mechanical Engineering

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The contour error cross-coupling control is very important to improve contour accuracy for the five-axis computer numerical control machine. The change in cutter orientation can cause the nonlinear motion of cutter tip, so the contour error calculation and compensation are very complex. For the five-axis computer numerical control machine with dual rotary tables, the forward kinematics model and inverse kinematics model are set up, and the influence laws of feed axis deviation to cutter tip deviation and cutter orientation deviation are studied. Then the simple and accurate calculation models for cutter tip contour error and cutter orientation contour error are established. Finally, the novel contour error cross-coupling control method based on kinematics model is developed. The experimental results show that the developed method can effectively improve contour accuracy of the five-axis computer numerical control machine.

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Cross Coupling Controller for Accurate Motion Synchronization of Dual Servo Systems

Cited by 29 publications

References 12 publications

Position - Velocity Control for Two PMDC Motors Connected by a Cross-Coupling Technique with Butterflies Optimization Algorithm

Position - Velocity Control for Two PMDC Motors Connected by a Cross-Coupling Technique with Butterflies Optimization Algorithm

Accurate physical modeling and synchronization control of dual-linear-motor-driven gantry with dynamic load

Cross-coupling control method for five-axis computer numerical control machine with dual rotary tables

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