The Mechanics and Control of Leaning to Lift Heavy Objects with a Dynamically Stable Mobile Robot

Fabian Sonnleitner, Roberto Shu, and Ralph L. Hollis

Conference Paper, Proceedings of (ICRA) International Conference on Robotics and Automation, pp. 9264 - 9270, May, 2019

Abstract

A control algorithm is developed to enable dynamically stable spherical-wheel robots (ballbots) with arms to detect a heavy object of unknown mass, navigate to it, lift it, transport it, and place it in a desired location semi-autonomously. Previous work has successfully demonstrated two-wheeled dynamically stable mobile manipulator robots transporting heavy objects. We report here the first ballbot to reliably achieve such a task. A successful semi-autonomous lift and transport of a 15 kg heavy box whose actual mass was unknown was achieved using a combination of feedforward and feedback control laws based on a quasi-static center of mass computation. The ballbot’s pan and tilt sensor turret tracked fiducial markers on the box. Ballbot-to-human and human-to-ballbot exchanges of a 10 kg heavy object was achieved while dynamically balancing.

BibTeX

@conference{Sonnleitner-2019-122027,
author = {Fabian Sonnleitner and Roberto Shu and Ralph L. Hollis},
title = {The Mechanics and Control of Leaning to Lift Heavy Objects with a Dynamically Stable Mobile Robot},
booktitle = {Proceedings of (ICRA) International Conference on Robotics and Automation},
year = {2019},
month = {May},
pages = {9264 - 9270},
}

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