Haptic Object Parameter Estimation during Within-Hand- Manipulation with a Simple Robot Gripper

Delara Mohtasham, Gokul Narayanan, B. Çalli, A. Spiers
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引用次数: 3

Abstract

Though it is common for robots to rely on vision for object feature estimation, there are environments where optical sensing performs poorly, due to occlusion, poor lighting or limited space for camera placement. Haptic sensing in robotics has a long history, but few approaches have combined this with within-hand-manipulation (WIHM), in order to expose more features of an object to the tactile sensing elements of the hand. As in the human hand, these sensing structures are generally non-homogenous in their coverage of a gripper's manipulation surfaces, as the sensitivity of some hand or finger regions is often different to other regions. In this work we use a modified version of the recently developed 2-finger Model VF (variable friction) robot gripper to acquire tactile information while rolling objects within the robot's grasp. This new gripper has one high-friction passive finger surface and one high-friction tactile sensing surface, equipped with 12 low-cost barometric force sensors encased in urethane. We have developed algorithms that use the data generated during these rolling actions to determine parametric aspects of the object under manipulation. Namely, two parameters are currently determined 1) the location of an object within the grasp 2) the object's shape (from three alternatives). The algorithms were first developed on a static test rig with passive object rolling and later evaluated with the robot gripper platform using active WIHM, which introduced artifacts into the data. With an object set consisting of 3 shapes and 5 sizes, an overall shape estimation accuracy was achieved of 88% and 78% for the test rig and hand respectively. Location estimation, of each object's centroid during motion, achieved a mean error of less than 2mm, along the 95mm length of the tactile sensing finger.
简单机械手手内操作过程中触觉对象参数估计
虽然机器人依靠视觉来估计物体特征是很常见的,但由于遮挡、光线不足或相机放置空间有限,光学传感表现不佳的环境仍然存在。机器人中的触觉传感有着悠久的历史,但很少有方法将其与手内操作(WIHM)相结合,以便将物体的更多特征暴露给手部的触觉传感元件。就像在人手中一样,这些传感结构在抓手的操作表面上的覆盖范围通常是不均匀的,因为某些手或手指区域的灵敏度通常与其他区域不同。在这项工作中,我们使用了最近开发的2指模型VF(可变摩擦)机器人抓取器的改进版本,以获取机器人抓取物体时的触觉信息。这种新夹具有一个高摩擦被动手指表面和一个高摩擦触觉感应表面,配备了12个低成本的气压力传感器,包裹在聚氨酯中。我们已经开发了算法,使用这些滚动动作中产生的数据来确定操作对象的参数方面。也就是说,目前确定了两个参数1)物体在抓握中的位置2)物体的形状(从三个备选项中)。这些算法首先是在一个静态测试平台上开发的,该平台具有被动物体滚动,然后在机器人抓取平台上使用主动WIHM进行评估,该平台将伪像引入数据中。在由3种形状和5种尺寸组成的目标集上,试验台和手的整体形状估计精度分别达到88%和78%。在运动过程中,每个物体质心的位置估计沿触觉感应手指的95mm长度实现了小于2mm的平均误差。
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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