Model Decoupled Synchronization Control Design with Fractional Order Filter for H-Type Air Floating Motion Platform

In this paper, a novel design method for the reset controller structure (i.e., fractional‐order proportional and integral plus Clegg integrator (PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$)), is proposed for a second‐order plus time delay plant. To this end, the designer can get an optimal fractional reset controller that gives the control system more phase margin over the base linear PI controller and robust to loop gain variation. The describing function method is used to investigate the capability of phase lead and the frequency domain properties of PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$. The gain crossover frequency and phase margin specifications ensure the stability of the control system, and the flat phase constraint makes the control system robust to loop gain variations. Meanwhile, the integral of time and absolute error (ITAE) value is applied to achieve the optimal dynamic performance as the cost function. PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$ is compared with its integer‐order counterpart (i.e., proportional and integral plus Clegg integrator (PI + CI) controller) and their base controllers (i.e., integer‐order PI and fractional‐order PI controllers) in terms of the step response and robustness to loop gain variations. The simulation results illustrate that the PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$ control system obtains lower overshoot and oscillation and better robustness to loop gain variations than others. The experiments are performed on the speed control of an air bearing stage. Experimental results show that the designed PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$ control system behaves better than others. The proposed PI α$$ {}&#x0005E;{\alpha } $$ + CI α$$ {}&#x0005E;{\alpha } $$ design method can be applied to other general control plants easily.

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“…The experiments in this paper are applied on an air bearing stage [46]. The structure is shown in Figure 13.…”

Section: Plant Overview and Model Identificationmentioning

confidence: 99%

An optimal robust design method for fractional‐order reset controller

Wang

Sun

et al. 2022

Asian Journal of Control

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Coupling Modeling Analysis of Synchronous Direct-Drive Gantry Laser Cutting Stage with Heavy-Load

Xie

Wang

2022

2022 4th International Conference on Control and Robotics (ICCR)

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Modeling Dual-Drive Gantry Stages with Heavy-Load and Optimal Synchronous Controls with Force-Feed-Forward Decoupling

Xie

Wang

2022

Entropy

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The application of precision dual-drive gantry stages in intelligent manufacturing is increasing. However, the loads of dual drive motors can be severely inconsistent due to the movement of heavy loads on the horizontal crossbeam, resulting in synchronization errors in the same direction movement of dual-drive motors. This phenomenon affects the machining accuracy of the gantry stage and is an critical problem that should be immediately solved. A novel optimal synchronization control algorithm based on model decoupling is proposed to solve the problem. First, an accurate physical model is established to obtain the essential characteristics of the heavy-load dual-drive gantry stage in which the rigid-flexible coupling dynamic is considered. It includes the crossbeam’s linear motion and rotational motion of the non-constant moment of inertia. The established model is verified by using the actual system. By defining the virtual centroid of the crossbeam, the cross-coupling force between dual-drive motors is quantified. Then, the virtual-centroid-based Gantry Synchronization Linear Quadratic Regulator (GSLQR) optimal control and force-Feed-Forward (FF) decoupling control algorithm is proposed. The result of the comparative experiment shows the effectiveness and superiority of the proposed algorithm.

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Model Decoupled Synchronization Control Design with Fractional Order Filter for H-Type Air Floating Motion Platform

Cited by 4 publications

References 29 publications

An optimal robust design method for fractional‐order reset controller

An optimal robust design method for fractional‐order reset controller

Coupling Modeling Analysis of Synchronous Direct-Drive Gantry Laser Cutting Stage with Heavy-Load

Modeling Dual-Drive Gantry Stages with Heavy-Load and Optimal Synchronous Controls with Force-Feed-Forward Decoupling

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