%0 Generic %1 rosenfelder2023experiment %A Rosenfelder, Mario %A Ebel, Henrik %A Eberhard, Peter %D 2023 %K darus mult ubs_10007 ubs_10021 ubs_20011 ubs_20019 ubs_30115 ubs_30165 ubs_40177 unibibliografie %R 10.18419/darus-3331 %T Experiment Videos of the Force-Based Non-Prehensile Cooperative Transportation of Objects with Mobile Robots %X The videos provided show two experimental results of cooperative object transportation using lightweight omnidirectional mobile robots. In particular, the mobile robots shall transport two different polygonal, but non-convex, objects along predefined paths. No central decision entity is employed; the tasks are accomplished in a purely distributed manner using inter-robot communication. Novelly, the formation synthesis relies on a force-based consideration that explicitly takes into account the physical limitations of the robotic agents. Due to this, if necessary, multiple robots are placed along one edge in order to exert the desired force acting on the object. This is exemplarily shown in the video and demonstrates one crucial advantage compared to purely position-based approaches. Furthermore, an underlying hybrid position-force controller is utilized to govern the individual pushing forces of the robots. The interacting force is measured by each agent using a self-designed onboard force-sensing unit. In the videos, the direction of the unilateral force sensor is indicated by white rectangles. Moreover, the measured force is visualized by the red rectangles superimposed onto the white ones.

@misc{rosenfelder2023experiment, abstract = {The videos provided show two experimental results of cooperative object transportation using lightweight omnidirectional mobile robots. In particular, the mobile robots shall transport two different polygonal, but non-convex, objects along predefined paths. No central decision entity is employed; the tasks are accomplished in a purely distributed manner using inter-robot communication. Novelly, the formation synthesis relies on a force-based consideration that explicitly takes into account the physical limitations of the robotic agents. Due to this, if necessary, multiple robots are placed along one edge in order to exert the desired force acting on the object. This is exemplarily shown in the video and demonstrates one crucial advantage compared to purely position-based approaches. Furthermore, an underlying hybrid position-force controller is utilized to govern the individual pushing forces of the robots. The interacting force is measured by each agent using a self-designed onboard force-sensing unit. In the videos, the direction of the unilateral force sensor is indicated by white rectangles. Moreover, the measured force is visualized by the red rectangles superimposed onto the white ones. }, added-at = {2023-02-03T08:49:36.000+0100}, affiliation = {Rosenfelder, Mario/Universität Stuttgart, Ebel, Henrik/Universität Stuttgart, Eberhard, Peter/Universität Stuttgart}, author = {Rosenfelder, Mario and Ebel, Henrik and Eberhard, Peter}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/22f49c54d5fdfb208d643d1c03ab119da/unibiblio}, doi = {10.18419/darus-3331}, howpublished = {Dataset}, interhash = {f5b3cb15f37ca659a8e4dce4cf811807}, intrahash = {2f49c54d5fdfb208d643d1c03ab119da}, keywords = {darus mult ubs_10007 ubs_10021 ubs_20011 ubs_20019 ubs_30115 ubs_30165 ubs_40177 unibibliografie}, note = {Related to: Rosenfelder, M., Ebel, H., Eberhard, P. (2023). A Force-Based Formation Synthesis Approach for the Cooperative Transportation of Objects. In: Petrič, T., Ude, A., Žlajpah, L. (eds) Advances in Service and Industrial Robotics. RAAD 2023. Mechanisms and Machine Science, vol 135. Springer, Cham. doi: 10.1007/978-3-031-32606-6_37}, orcid-numbers = {Rosenfelder, Mario/0000-0003-0460-0612, Ebel, Henrik/0000-0002-2632-6960, Eberhard, Peter/0000-0003-1809-4407}, timestamp = {2023-07-17T10:17:25.000+0200}, title = {Experiment Videos of the Force-Based Non-Prehensile Cooperative Transportation of Objects with Mobile Robots}, year = 2023 }