Development of Precision Positioning Stage

Niranjan, Prabha; Karinka, Shashikantha; Sairam, Kvssss

doi:10.1142/s0219686719500057

J. Adv. Manuf. Syst.

2019

DOI: 10.1142/s0219686719500057

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Development of Precision Positioning Stage

Prabha Niranjan¹,

Shashikantha Karinka²,

Kvssss Sairam³

Abstract: The growing demand for positioning accuracy in machines with high speed plays an important role in achieving high productivity gain. A system that is capable to achieve both coarse (macro) and fine (micro) positioning finds a variety of applications in precision positioning. In the proposed work, a macro positioning stage is developed with a ball screw actuator and a micro positioning stage is developed with an additional gear reduction unit. The coarse and fine positioning with friction compensation is achiev… Show more

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Cited by 3 publications

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“…a direct influence on the product quality [2], [3], which leads to higher performance requirements for the stages , such as higher tracking accuracy, larger velocity and acceleration. In the control system of the precision motion stages, the feedback control is usually used to suppress the unstructured external disturbance and the system uncertainty, while the feedforward control is used to compensate for the orderly disturbance, such as thrust ripple [4].…”

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confidence: 99%

Frequency-Domain Data-Driven Adaptive Iterative Learning Control Approach: With Application to Wafer Stage

Yang

Zanchetta

et al. 2021

IEEE Trans. Ind. Electron.

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The feedforward control is becoming increasingly important in ultra-precision stages. However, the conventional model-based methods can not achieve expected performance in new-generation stages since it is hard to obtain the accurate plant model due to the complicated stage dynamical properties. To tackle this problem, this paper develops a model-free data-driven adaptive iterative learning approach that is designed in the frequency-domain. Explicitly, the proposed method utilizes the frequency-response data to learn and update the output of the feedforward controller online, which benefits that both the structure and parameters of the plant model are not required. An unbiased estimation method for the frequency response of the closed-loop system is proposed and proved through the theoretical analysis. Comparative experiments on a linear motor confirm the effectiveness and superiority of the proposed method, and show that it has the ability to avoid the performance deterioration caused by the model mismatch with the increasing iterative trials.Index Terms-adaptive ILC, data-driven, frequency domain, feedforward control, linear motor. I. INTRODUCTIONN OWADAYS, the ultra-precision motion stages have been widely applied in many nanoscale manufacturing industries like IC manufacturing [1]. The precision motion stage has Manuscript

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mentioning

confidence: 99%

Frequency-Domain Data-Driven Adaptive Iterative Learning Control Approach: With Application to Wafer Stage

Yang

Zanchetta

et al. 2021

IEEE Trans. Ind. Electron.

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Research on geometric error compensation of ultra-precision turning-milling machine tool based on macro–micro composite technology

Sun,

Qiao,

Zhang

et al. 2024

Int J Adv Manuf Technol

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Iterative learning control of an inverse novel ball screw transmission system

Hsieh

Chen

2021

IFS

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Iterative Learning Control is a branch of intelligent control which combines artificial intelligence and control theory. This objective of this study aims at reducing the cyclic error of an inverse ball screw transmission system by using iterative learning control approach. Firstly, kinematic and dynamic analyses are conducted by using the vectorial loop closure and Lagrange equations, respectively. Then, system identification is performed followed by controller design. Moreover, controller parameters are optimized to minimize the error. Finally, the feasibility and the effectiveness of the proposed approach are verified by computer simulation and prototype experiment. The experimental results showed that the reducing percentage of the square error sum of the output speed is 90.64% by using PID control only. If ILC is applied additionally, the error is further reduced to 94.21%. Therefore, the proposed approach is not only feasible and but also effective.

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Development of Precision Positioning Stage

Cited by 3 publications

References 16 publications

Frequency-Domain Data-Driven Adaptive Iterative Learning Control Approach: With Application to Wafer Stage

Frequency-Domain Data-Driven Adaptive Iterative Learning Control Approach: With Application to Wafer Stage

Research on geometric error compensation of ultra-precision turning-milling machine tool based on macro–micro composite technology

Iterative learning control of an inverse novel ball screw transmission system

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