Convex Parameterization and Optimization for Robust Tracking of a Magnetically Levitated Planar Positioning System

Ma, Jun; Cheng, Zilong; Zhu, Haiyue; Li, Xiaocong; Tomizuka, Masayoshi; Lee, Tong Heng

doi:10.48550/arxiv.2103.11569

Cited by 3 publications

(5 citation statements)

References 40 publications

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“…where r ∈ R 3 is the reference signal vector of the three axes, w i ∈ R 3 is the iterative variable vector during the consecutive iterations. ( 15) and (16) show that the iterative learning control input will be added to the reference signal. Generally, a lowpass filter will be used in the iterative learning law, and thus the original reference signal is not allowed to be changed by the filter.…”

Section: A Synthesis Of the Model-free Controllermentioning

confidence: 99%

“…As alternatives in the literature, the multi-axis coupling can also be modeled with certain assumptions and then a decentralized control scheme is developed for the gantry system [13], [14]. However, the system identification for such multi-axis systems is inevitably inaccurate [15], [16]. With regards to the issues of multi-axis cooperation, the methodology of coordinated frames is also further proposed in the literature; such as the global task coordinate frame (GTCF) [17], [18] and the Newton-ILC contouring control method [19].…”

Section: Introductionmentioning

confidence: 99%

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Global Iterative Sliding Mode Control of an Industrial Biaxial Gantry System for Contouring Motion Tasks

Wang,

Ma,

Cheng

et al. 2021

Preprint

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This paper proposes a global iterative sliding mode control approach for high-precision contouring tasks of a flexurelinked biaxial gantry system. For such high-precision contouring tasks, it is the typical situation that the involved multi-axis cooperation is one of the most challenging problems. As also would be inevitably encountered, various factors render the multi-axis cooperation rather difficult; such as the strong coupling (which naturally brings nonlinearity) between different axes due to its mechanical structure, the backlash and deadzone caused by the friction, and the difficulties in system identification, etc. To overcome the above-mentioned issues, this work investigates an intelligent model-free contouring control method for such a multiaxis motion stage. Essentially in the methodology developed here, it is firstly ensured that all the coupling, friction, nonlinearity, and disturbance (regarded as uncertain dynamics in each axis) are suitably posed as 'uncertainties'. Then, a varying-gain sliding mode control method is proposed to adaptively compensate for the matched unknown dynamics in the time domain, while an iterative learning law is applied to suppress the undesirable effects (arising from the repetitive matched and unmatched uncertainties in the iteration domain). With this approach, the chattering that typically results from the overestimated control gains in the sliding mode control is thus suppressed during the iterations. To analyze the contouring performance and show the improved outcomes, rigorous proof is furnished on both the stability in the time domain and the convergence in the iteration domain; and the real-time experiments also illustrate that the requirements of precision motion control towards highspeed and complex-curvature references can be satisfied using the proposed method, without prior knowledge of the boundary to the unknown dynamics.

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Section: A Synthesis Of the Model-free Controllermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Global Iterative Sliding Mode Control of an Industrial Biaxial Gantry System for Contouring Motion Tasks

Wang,

Ma,

Cheng

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…However, because there exists the presence of unmodeled dynamics, disturbances, and uncertainties in the system, a highfrequency phenomenon called chattering is always arisen in implementing SMC [15]. The chattering effect could reduce the accuracy or damage the actuators, as pointed out in several works [16]- [18]. Significatnly, the chattering is relevant to the disturbance [19].…”

Section: Introductionmentioning

confidence: 99%

Adaptive Fractional-Order Sliding Mode Controller with Neural Network Compensator for an Ultrasonic Motor

Chen,

Liang,

Zhao

et al. 2021

Preprint

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Ultrasonic motors (USMs) are commonly used in aerospace, robotics, and medical devices, where fast and precise motion is needed. Remarkably, sliding mode controller (SMC) is an effective controller to achieve precision motion control of the USMs. To improve the tracking accuracy and lower the chattering in the SMC, the fractionalorder calculus is introduced in the design of an adaptive SMC in this paper, namely, adaptive fractional-order SMC (AFOSMC), in which the bound of the uncertainty existing in the USMs is estimated by a designed adaptive law. Additionally, a short memory principle is employed to overcome the difficulty of implementing the fractional-order calculus on a practical system in real-time. Here, the short memory principle may increase the tracking errors because some information is lost during its operation. Thus, a compensator according to the framework of Bellman's optimal control theory is proposed so that the residual errors caused by the short memory principle can be attenuated. Lastly, experiments on a USM are conducted, which comparative results verify the performance of the designed controller.

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“…Mechatronic systems have been widely used in manufacturing industry, such as inspection process, transmission task, stepping and scanning device. As a popular application, timing-belt driven tray indexing is applied for industrial transmission tasks in such areas due to its strong transmission force and low cost [1], [2]. Nevertheless here, there are actually some high-order modes and other unmodeled dynamics which exert inevitable affects on the system performance [3]- [5].…”

Section: Introductionmentioning

confidence: 99%

“…Meanwhile, the motion accuracy could be ensured at a high level versus the uncertainties. (2). The architecture combines the merits of each term organically.…”

Section: Introductionmentioning

confidence: 99%

Iterative Super-Twisting Sliding Mode Control: A Case Study on Tray Indexing

Wang

et al. 2020

2020 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

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Mechatronic systems are commonly used in the industry, where fast and accurate motion performance is always required to guarantee the manufacturing precision and efficiency. Nevertheless, the system model and parameters are difficult to be obtained accurately. Moreover, the high-order modes, strong coupling in multi-axis system, or unmodeled frictions will bring uncertain dynamics to the system. To overcome the above-mentioned issues and enhance the motion performance, this paper introduces a novel intelligent and totally model-free control method for mechatronic systems with unknown dynamics. In detail, a 2-degree-of-freedom (DOF) architecture is designed, which organically merges a generalized super-twisting algorithm with a unique iterative learning law. The controller solely utilizes the input-output data collected in iterations such that it works without any knowledge of the system parameters. The rigorous proof of convergence ability is given and a case study on flexture-joint dual-drive H-gantry stage is shown to validate the effectiveness of the proposed method.

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Convex Parameterization and Optimization for Robust Tracking of a Magnetically Levitated Planar Positioning System

Cited by 3 publications

References 40 publications

Global Iterative Sliding Mode Control of an Industrial Biaxial Gantry System for Contouring Motion Tasks

Global Iterative Sliding Mode Control of an Industrial Biaxial Gantry System for Contouring Motion Tasks

Adaptive Fractional-Order Sliding Mode Controller with Neural Network Compensator for an Ultrasonic Motor

Iterative Super-Twisting Sliding Mode Control: A Case Study on Tray Indexing

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