MICRON: Small Autonomous Robot for Cell Manipulation Applications

Proceedings of the 2005 IEEE International Conference on Robotics and Automation Pub Date : 2005-04-18 DOI:10.1109/ROBOT.2005.1570222

J. Brufau-Penella, M. Puig-Vidal, J. López-Sánchez, J. Samitier, W. Driesen, J. Breguet, N. Snis, U. Simu, S. Johansson, T. Velten

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引用次数: 86

Abstract

Manipulating in the micro- or even nano world still poses a great challenge to robotics. Conventional (stationary) systems suffer from drawbacks regarding integration into process supervision and multi-robot approaches, which become highly relevant to fight scaling effects. This paper describes work currently being carried out which aims to make automated manipulation of micrometer-scaled objects possible by robots with nanometer precision. The goal is to establish a small cluster of (up to five) micro robots equipped with on-board electronics, sensors and wireless power supply. Power autonomy has been reached using inductive energy transmission from an external wireless power supply system or a battery based system. Electronics requirements are fulfilled in the electronic module with the full custom integrated circuit design for the robot locomotion control and the closed loop force control for AFM tool in cell manipulation applications. The maximum velocity obtained is about 0.4 mm/s with a saw tooth voltage signals of 20Vpp and 2500 Hz. In order to keep a AFM tool on micro-robot a specific tip with integrated piezoresistance, instead of the classical laser beam methodology, is validated for force measurement.

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MICRON:用于细胞操作应用的小型自主机器人

在微观甚至纳米世界中进行操作仍然是机器人技术面临的巨大挑战。传统(固定)系统在集成到过程监督和多机器人方法方面存在缺陷，这与对抗缩放效应高度相关。本文描述了目前正在进行的工作，其目的是使机器人具有纳米精度的微米尺度物体的自动操作成为可能。目标是建立一个小型集群(最多5个)微型机器人，配备车载电子设备、传感器和无线电源。通过外部无线供电系统或电池供电系统的感应能量传输，实现了电力自主。电子模块满足了机器人运动控制的完整定制集成电路设计和细胞操作应用中AFM工具的闭环力控制的电子要求。在锯齿电压信号为20Vpp和2500 Hz时，获得的最大速度约为0.4 mm/s。为了在微型机器人上安装AFM工具，采用集成压阻的特定尖端代替传统的激光束方法进行力测量。

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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Proceedings of the 2005 IEEE International Conference on Robotics and Automation

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