Closed-Loop Optical Tracking of a Micro-Conveyor over a Smart Surface

IF 3.3 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS
Saly Malak, Hani Al Hajjar, E. Dupont, M. Khan, C. Prelle, F. Lamarque
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Abstract

In this work, a closed loop control system is developed to optically localize and track micro-robots with high precision. These micro-robots (i.e., micro-conveyors) are in motion simultaneously across a smart surface.The developed method’s primary objectives are to optimize their trajectories, avoid collisions between them, and control their position with micrometric resolution. This article presents and characterizes the tracking of a single micro-conveyor, and the method works similarly when multiple micro-robots move over the surface. Our tracking method starts with a scanning phase, where a 2D steering mirror, placed above the smart surface, reflects a laser beam toward the conveying surface seeking for the target. Localization occurs when this light beam reaches the micro-conveyor. By adding a retro-reflective element, that reflects the light in the same direction of the the incident light, onto the surface of the micro-conveyor, the light will be reflected towards a photodetector. Depending on the feedback from the photodetector, the steering mirror rotates to track the trajectory of the micro-conveyor. The tip-tilt angular values of the steering mirror allows the micro-conveyor position to be obtained via calibrated localization system. The aim of this work is to regulate the micro-conveyor, within a closed-loop control system, to reduce the positional error between the actual and desired position. The actual position value is measured in real-time application using our developed optical sensor. Results for tracking in the x-and y-axis have validated the proposed method, with an average tracking error less than 30 µm within a range 150 mm × 150 mm.
在智能表面上对微型输送机进行闭环光学跟踪
本研究开发了一种闭环控制系统,用于高精度光学定位和跟踪微型机器人。这些微型机器人(即微型输送机)在智能表面上同时运动。所开发方法的主要目标是优化它们的运动轨迹,避免它们之间的碰撞,并以微米级的分辨率控制它们的位置。本文介绍了单个微型输送机的跟踪方法和特点,当多个微型机器人在表面上运动时,该方法也能发挥类似的作用。我们的跟踪方法从扫描阶段开始,智能表面上方的二维转向镜将激光束反射到输送表面,寻找目标。当光束到达微型输送机时,就会进行定位。通过在微型输送机表面添加一个逆反射元件,将光线反射到与入射光线方向相同的地方,光线就会被反射到光电探测器上。根据光电探测器的反馈,转向镜旋转以跟踪微型传送器的轨迹。转向镜的尖端倾斜角度值可通过校准定位系统获得微型输送机的位置。这项工作的目的是在一个闭环控制系统中调节微型输送机,以减少实际位置与期望位置之间的位置误差。实际位置值是通过我们开发的光学传感器实时测量的。X 轴和 Y 轴的跟踪结果验证了所提出的方法,在 150 毫米 × 150 毫米的范围内,平均跟踪误差小于 30 微米。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Sensor and Actuator Networks
Journal of Sensor and Actuator Networks Physics and Astronomy-Instrumentation
CiteScore
7.90
自引率
2.90%
发文量
70
审稿时长
11 weeks
期刊介绍: Journal of Sensor and Actuator Networks (ISSN 2224-2708) is an international open access journal on the science and technology of sensor and actuator networks. It publishes regular research papers, reviews (including comprehensive reviews on complete sensor and actuator networks), and short communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced.
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