A cable-driven underwater robotic system for delicate manipulation of marine biology samples

IF 4.2 2区 计算机科学 Q2 ROBOTICS
Mahmoud Zarebidoki, Jaspreet Singh Dhupia, Minas Liarokapis, Weiliang Xu
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Abstract

Underwater robotic systems have the potential to assist and complement humans in dangerous or remote environments, such as in the monitoring, sampling, or manipulation of sensitive underwater species. Here we present the design, modeling, and development of an underwater manipulator (UM) with a lightweight cable-driven structure that allows for delicate deep-sea reef sampling. The compact and lightweight design of the UM and gripper decreases the coupling effect between the UM and the underwater vehicle (UV) significantly. The UM and gripper are equipped with force sensors, enabling them for soft and sensitive object manipulation and grasping. The accurate force exertion capabilities of the UM ensure efficient operation in the process of localization and approaching reef samples, such as the corals and sponges. The active force control of the tendon-driven gripper ensures gentle/delicate grasping, handling, and transporting of the marine samples without damaging their tissues. A complete simulation of the UM is provided for deriving the required specifications of actuators and sensors to be compatible with the UVs with a speed range of 1–4 Knots. The system's performance for accurate trajectory tracking and delicate grasping of two different types of underwater species (a sponge skeleton and a Neptune's necklace seaweed) is verified using a model-free robust-adaptive position/force controller.

Abstract Image

用于精细操作海洋生物样本的缆索驱动水下机器人系统
水下机器人系统有可能在危险或偏远的环境中协助和辅助人类,如监测、取样或操纵敏感的水下物种。在此,我们介绍了一种具有轻型缆索驱动结构的水下机械手(UM)的设计、建模和开发情况,该机械手可进行精细的深海珊瑚礁采样。水下机械手和抓取器的紧凑轻便设计大大降低了水下机械手和水下航行器(UV)之间的耦合效应。UM 和抓取器配备了力传感器,可对柔软而敏感的物体进行操作和抓取。在定位和接近珊瑚礁样本(如珊瑚和海绵)的过程中,UM 的精确施力能力可确保高效运行。腱驱动抓手的主动力控制可确保轻柔/精细地抓取、处理和运输海洋样本,而不会损坏其组织。对 UM 进行了完整的模拟,以推导出所需的执行器和传感器规格,使其与速度范围为 1-4 海里/小时的紫外线兼容。使用无模型鲁棒自适应位置/力控制器验证了该系统在精确轨迹跟踪和精细抓取两种不同类型的水下物种(海绵骨架和海王星项链海藻)方面的性能。
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 Field Robotics
Journal of Field Robotics 工程技术-机器人学
CiteScore
15.00
自引率
3.60%
发文量
80
审稿时长
6 months
期刊介绍: The Journal of Field Robotics seeks to promote scholarly publications dealing with the fundamentals of robotics in unstructured and dynamic environments. The Journal focuses on experimental robotics and encourages publication of work that has both theoretical and practical significance.
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