Multi-Level Structure vs. End-to-End-Learning in High-Performance Tactile Robotic Manipulation
Abstract
In this paper we apply a multi-level structure to robotic manipulation learning. It consists of a hybrid dynamical system we denote skill and a parameter learning layer that leverages the underlying structure to simplify the problem at hand. For the learning layer we introduce a novel algorithm based on the idea of learning to partition the parameter solution space to quickly and efficiently find good and robust solutions to complex manipulation problems. In a benchmark comparison we show a significant performance increase compared with other black-box optimization algorithms such as HiREPS and particle swarm optimization. Furthermore, we validate and compare our approach on a very hard real-world manipulation problem, namely inserting a key into a lock, with state-of-the-art deep reinforcement learning.
Cite
Text
Voigt et al. "Multi-Level Structure vs. End-to-End-Learning in High-Performance Tactile Robotic Manipulation." Conference on Robot Learning, 2020.Markdown
[Voigt et al. "Multi-Level Structure vs. End-to-End-Learning in High-Performance Tactile Robotic Manipulation." Conference on Robot Learning, 2020.](https://mlanthology.org/corl/2020/voigt2020corl-multilevel/)BibTeX
@inproceedings{voigt2020corl-multilevel,
title = {{Multi-Level Structure vs. End-to-End-Learning in High-Performance Tactile Robotic Manipulation}},
author = {Voigt, Florian and Johannsmeier, Lars and Haddadin, Sami},
booktitle = {Conference on Robot Learning},
year = {2020},
pages = {2306-2316},
volume = {155},
url = {https://mlanthology.org/corl/2020/voigt2020corl-multilevel/}
}