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针对空间手爪在抓握目标物体的过程中,因接触碰撞而产生的扰动力可能会造成机械臂抖动和初始位姿改变,甚至将目标物体弹出捕获区,造成捕获失败的问题,提出了基于抓握力的模糊自适应控制策略,以削弱在抓握过程中因接触碰撞产生的扰动力,减小对机械臂造成的扰动。首先介绍了哈尔滨工业大学(HIT)自行研制的三手指空间手爪,对其抓握过程和接触碰撞进行了分析,提出一种柔顺控制策略,设计了基于抓握力的模糊自适应控制器。通过模糊控制器实时地调整控制参数,不仅可使系统稳定,而且具有良好的动态品质;控制器中的滑模控制还可以增强系统的鲁棒性。采用HIT在轨自维护机械臂在空间微重力运动平台上进行了抓握实验,实验结果表明设计的控制器和提出的抓握策略能够有效削弱抓握过程中的扰动力。 相似文献
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Due to the intense vibration during launching and rigorous orbital temperature environment, the kinematic parameters of space
robot may be largely deviated from their nominal parameters. The disparity will cause the real pose (including position and
orientation) of the end effector not to match the desired one, and further hinder the space robot from performing the scheduled
mission. To improve pose accuracy of space robot, a new self-calibration method using the distance measurement provided by
a laser-ranger fixed on the end-effector is proposed. A distance-measurement model of the space robot is built according to
the distance from the starting point of the laser beam to the intersection point at the declining plane. Based on the model,
the cost function about the pose error is derived. The kinematic calibration is transferred to a non-linear system optimization
problem, which is solved by the improved differential evolution (DE) algorithm. A six-degree of freedom (6-DOF) robot is used
as a practical simulation example, and the simulation results show: 1) A significant improvement of pose accuracy of space
robot can be obtained by distance measurement only; 2) Search efficiency is increased by improved DE; 3) More calibration
configurations may make calibration results better. 相似文献
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空间机器人将用于对空间目标的跟踪、接近、包络和抓捕,由于机器人和抓捕目标均处于无约束自由飘浮状态,因此顺利进入捕获区并完成抓捕较为困难。针对漂浮机器人和漂浮目标对接困难的问题,利用末端操作器上的手眼视觉作为传感器系统对末端操作器的运行轨迹加以控制;利用动量守恒和动量矩守恒两大基本定理,推导了手眼视觉引导下空间机器人末端操作器为达到期望捕获位姿的轨迹规划,使得末端操作器可以规避末端操作器手指外形实现对目标的无接触跟踪和包络;利用气浮平台、被动6自由度模拟器实现了地面模拟空间失重环境,并在该试验平台上试验了机器人末端操作器对漂浮目标的跟踪和捕获。研究结果表明,基于视觉的轨迹规划可以协助机器人完成对漂浮目标的跟踪和抓捕。 相似文献
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