Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Palenicek, Daniel, Gruner, Theo, Schneider, Tim, Böhm, Alina, Lenz, Janis, Pfenning, Inga, Krämer, Eric, Peters, Jan
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2405.00383
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866913453217677312
author Palenicek, Daniel
Gruner, Theo
Schneider, Tim
Böhm, Alina
Lenz, Janis
Pfenning, Inga
Krämer, Eric
Peters, Jan
author_facet Palenicek, Daniel
Gruner, Theo
Schneider, Tim
Böhm, Alina
Lenz, Janis
Pfenning, Inga
Krämer, Eric
Peters, Jan
contents Humans have exceptional tactile sensing capabilities, which they can leverage to solve challenging, partially observable tasks that cannot be solved from visual observation alone. Research in tactile sensing attempts to unlock this new input modality for robots. Lately, these sensors have become cheaper and, thus, widely available. At the same time, the question of how to integrate them into control loops is still an active area of research, with central challenges being partial observability and the contact-rich nature of manipulation tasks. In this study, we propose to use Reinforcement Learning to learn an end-to-end policy, mapping directly from tactile sensor readings to actions. Specifically, we use Dreamer-v3 on a challenging, partially observable robotic insertion task with a Franka Research 3, both in simulation and on a real system. For the real setup, we built a robotic platform capable of resetting itself fully autonomously, allowing for extensive training runs without human supervision. Our preliminary results indicate that Dreamer is capable of utilizing tactile inputs to solve robotic manipulation tasks in simulation and reality. Furthermore, we find that providing the robot with tactile feedback generally improves task performance, though, in our setup, we do not yet include other sensing modalities. In the future, we plan to utilize our platform to evaluate a wide range of other Reinforcement Learning algorithms on tactile tasks.
format Preprint
id arxiv_https___arxiv_org_abs_2405_00383
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Learning Tactile Insertion in the Real World
Palenicek, Daniel
Gruner, Theo
Schneider, Tim
Böhm, Alina
Lenz, Janis
Pfenning, Inga
Krämer, Eric
Peters, Jan
Robotics
Humans have exceptional tactile sensing capabilities, which they can leverage to solve challenging, partially observable tasks that cannot be solved from visual observation alone. Research in tactile sensing attempts to unlock this new input modality for robots. Lately, these sensors have become cheaper and, thus, widely available. At the same time, the question of how to integrate them into control loops is still an active area of research, with central challenges being partial observability and the contact-rich nature of manipulation tasks. In this study, we propose to use Reinforcement Learning to learn an end-to-end policy, mapping directly from tactile sensor readings to actions. Specifically, we use Dreamer-v3 on a challenging, partially observable robotic insertion task with a Franka Research 3, both in simulation and on a real system. For the real setup, we built a robotic platform capable of resetting itself fully autonomously, allowing for extensive training runs without human supervision. Our preliminary results indicate that Dreamer is capable of utilizing tactile inputs to solve robotic manipulation tasks in simulation and reality. Furthermore, we find that providing the robot with tactile feedback generally improves task performance, though, in our setup, we do not yet include other sensing modalities. In the future, we plan to utilize our platform to evaluate a wide range of other Reinforcement Learning algorithms on tactile tasks.
title Learning Tactile Insertion in the Real World
topic Robotics
url https://arxiv.org/abs/2405.00383