Large Range of a High-Precision, Independent, Sub-Mirror Three-Dimensional Co-Phase Error Sensing and Correction Method via a Mask and Population Algorithm

Li, Dequan; Wang, Dong; Li, Jingquan

doi:10.3390/s24010279

Cited by 3 publications

(1 citation statement)

References 30 publications

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“…Although this system has a simple structure, the accuracy of a single-branched chain directly impacts the overall performance, necessitating the sacrifice of motion stroke (only a few tens of micrometers) to achieve high-precision single-branched chains [10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Design and Testing of a Compliant ZTTΘ Positional Adjustment System with Hybrid Amplification

Liao,

Lin,

Tang

et al. 2024

Micromachines

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This article presents the design, analysis, and prototype testing of a four-degrees-of-freedom (4-DoFs) spatial pose adjustment system (SPAS) that achieves high-precision positioning with 4-DoFs (Z/Tip/Tilt/Θ). The system employs a piezoelectric-driven amplification mechanism that combines a bridge lever hybrid amplification mechanism, a double four-bar guide mechanism, and a multi-level lever symmetric rotation mechanism. By integrating these mechanisms, the system achieves low coupling, high stiffness, and wide stroke range. Analytical modeling and finite element analysis are employed to optimize geometric parameters. A prototype is fabricated, and its performance is verified through testing. The results indicate that the Z-direction feed microstroke is 327.37 μm, the yaw motion angle around the X and Y axes is 3.462 mrad, and the rotation motion angle around the Z axis is 12.684 mrad. The x-axis and y-axis motion magnification ratio can reach 7.43. Closed-loop decoupling control experiments for multiple-input-multiple-outputs (MIMO) systems using inverse kinematics and proportional-integral-derivative feedback controllers were conducted. The results show that the Z-direction positioning accuracy is ±100 nm, the X and Y axis yaw motion accuracy is ±2 μrad, and the Z-axis rotation accuracy is ±25 μrad. Due to the ZTTΘ mechanism, the design proved to be feasible and advantageous, demonstrating its potential for precision machining and micro-nano manipulation.

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Section: Introductionmentioning

confidence: 99%

Design and Testing of a Compliant ZTTΘ Positional Adjustment System with Hybrid Amplification

Liao,

Lin,

Tang

et al. 2024

Micromachines

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Intelligent decision-making algorithm for airborne phased array radar search tasks based on a hierarchical strategy framework

LI,

WANG,

WANG

et al. 2024

Chinese Journal of Aeronautics

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Piston Error Automatic Correction for Segmented Mirrors via Deep Reinforcement Learning

Li,

Wang,

Yan

2024

Sensors

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The segmented mirror co-phase error identification technique based on supervised learning methods has the advantages of simple application conditions, no dependence on custom sensors, a fast calculation speed, and low computing power requirements compared with other methods. However, it is often difficult to obtain a high accuracy in practical application situations with this method because of the difference between the training model and the actual model. The reinforcement learning algorithm does not need to model the real system when operating the system. However, it still retains the advantages of supervised learning. Thus, in this paper, we placed a mask on the pupil plane of the segmented telescope optical system. Moreover, based on the wide spectrum, point spread function, and modulation transfer function of the optical system and deep reinforcement learning—without modeling the optical system—a large-range and high-precision piston error automatic co-phase method with multiple-submirror parallelization was proposed. Finally, we carried out relevant simulation experiments, and the results indicate that the method is effective.

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Large Range of a High-Precision, Independent, Sub-Mirror Three-Dimensional Co-Phase Error Sensing and Correction Method via a Mask and Population Algorithm

Cited by 3 publications

References 30 publications

Design and Testing of a Compliant ZTTΘ Positional Adjustment System with Hybrid Amplification

Design and Testing of a Compliant ZTTΘ Positional Adjustment System with Hybrid Amplification

Intelligent decision-making algorithm for airborne phased array radar search tasks based on a hierarchical strategy framework

Piston Error Automatic Correction for Segmented Mirrors via Deep Reinforcement Learning

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