Integrated kinematic control of mobile-manipulator systems

移动机械手系统的集成运动控制

• 批准号: 312537-2011
• 负责人: Nokleby, Scott
• 金额: $ 1.46万
• 依托单位: University of Ontario Institute of Technology
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=571770
• 关键词: Integrated; kinematic; control; mobile; manipulator

A mobile manipulator is a system comprised of a robot arm (or manipulator) mounted on a mobile base. Examples of such systems include robot arms mounted on Remotely-Operated Vehicles (ROVs) or remotely operated mining equipment. Such systems offer great advantages in terms of workspace and manipulability compared to fix-mounted robot arms. However, such systems are more difficult to control due to the inherent redundancy of these systems. To position and orient an object in space requires 6-DOF (degrees-of-freedom). Typical mobile manipulators have more than 6-DOF making the control of these systems a challenge. At present, mobile manipulator operators must control both the mobile base and its associated robot manipulator separately, which makes it very challenging for the operator to perform intricate tasks. The objective of this research program is to develop a variety of aids for mobile-manipulator operators to make their jobs more intuitive and less demanding, thus enabling the operators to perform more complex tasks and increase their productivity. Specifically, this research program will develop new optimal kinematic control algorithms for the integrated control of mobile manipulators, create a semi-autonomous tele-operating mode for mobile manipulators, and will develop routines for using haptic devices and virtual fixtures for tele-operating mobile manipulators. These developments will form the basis for advanced robotic systems which will enable real-world users to operate these systems in a user-friendly manner. As the recent oil leak in the Gulf of Mexico has proven, mobile-manipulator systems are playing an increasingly vital role to society. However, as was demonstrated by the difficulties encountered in tele-operating these ROVs at remote depths, there is an opportunity for improved methods of operating mobile-manipulator systems. The results of this research program will contribute to the development of advanced robotic systems for hazardous material handling; undersea exploration, resource extraction, and construction/maintenance; terrestrial mining; manufacturing; and security.

移动的机械手是由安装在移动的基座上的机器人臂（或机械手）组成的系统。 这种系统的例子包括安装在遥控潜水器（ROV）或遥控采矿设备上的机器人臂。与固定安装的机器人臂相比，这种系统在工作空间和可操作性方面具有很大的优势。然而，由于这些系统的固有冗余，这些系统更难以控制。要在空间中定位和定向对象，需要6个自由度（degrees of freedom）。 典型的移动的机械手具有多于6个自由度，使得这些系统的控制成为挑战。目前，移动的机械手操作者必须分别控制移动的基座和与其相关联的机器人机械手，这使得操作者执行复杂的任务非常具有挑战性。 该研究计划的目标是为移动机械手操作员开发各种辅助工具，使他们的工作更加直观，要求更低，从而使操作员能够执行更复杂的任务并提高生产率。 具体而言，本研究计划将开发新的最佳运动控制算法的综合控制的移动的机械手，创建一个半自主的远程操作模式的移动的机械手，并将开发使用触觉设备和虚拟夹具的远程操作移动的机械手的例程。 这些发展将成为先进机器人系统的基础，使现实世界的用户能够以用户友好的方式操作这些系统。 正如最近墨西哥湾的石油泄漏所证明的那样，移动机械手系统正在对社会发挥越来越重要的作用。 然而，正如远程操作这些ROV在远程深度遇到的困难所证明的那样，有机会改进操作移动机械手系统的方法。 该研究计划的结果将有助于开发先进的机器人系统，用于危险材料处理;海底勘探，资源开采和建设/维护;陆地采矿;制造业;和安全。