TY - GEN
T1 - Autonomous Rock Instance Segmentation for Extra-Terrestrial Robotic Missions
AU - Durner, Maximilian
AU - Boerdijk, Wout
AU - Fanger, Yunis
AU - Sakagami, Ryo
AU - Risch, David Lennart
AU - Triebel, Rudolph
AU - Wedler, Armin
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - The collection and analysis of extra-terrestrial matter are two of the main motivations for space exploration missions. Due to the inherent risks for participating astronauts during space missions, autonomous robotic systems are often considered as a promising alternative. In recent years, many (inter)national space missions containing rovers to explore celestial bodies have been launched. Hereby, the communication delay as well as limited bandwidth creates a need for highly self-governed agents that require only infrequent interaction with scientists at a ground station. Such a setting is explored in the ARCHES mission, which seeks to investigate different means of collaboration between scientists and autonomous robots in extra-terrestrial environments. The analog mission focuses a team of hetero-geneous agents (two Lightweight Rover Units and ARDEA, a drone), which together perform various complex tasks under strict communication constraints. In this paper, we highlight three of these tasks that were successfully demonstrated during a one-month test mission on Mt. Etna in Sicily, Italy, which was chosen due to its similarity to the Moon in terms of geological structure. All three tasks have in common, that they leverage an instance segmentation approach deployed on the rovers to detect rocks within camera imagery. The first application is a mapping scheme that incorporates semantically detected rocks into its environment model to safely navigate to points of interest. Secondly, we present a method for the collection and extraction of in-situ samples with a rover, which uses rock detection to localize relevant candidates to grasp. For the third task, we show the usefulness of stone segmentation to autonomously conduct a spectrometer measurement experiment. We perform a throughout analysis of the presented methods and evaluate our experimental results. The demonstrations on Mt. Etna show that our approaches are well suited for navigation, geological analysis, and sample extraction tasks within autonomous robotic extra-terrestrial missions.
AB - The collection and analysis of extra-terrestrial matter are two of the main motivations for space exploration missions. Due to the inherent risks for participating astronauts during space missions, autonomous robotic systems are often considered as a promising alternative. In recent years, many (inter)national space missions containing rovers to explore celestial bodies have been launched. Hereby, the communication delay as well as limited bandwidth creates a need for highly self-governed agents that require only infrequent interaction with scientists at a ground station. Such a setting is explored in the ARCHES mission, which seeks to investigate different means of collaboration between scientists and autonomous robots in extra-terrestrial environments. The analog mission focuses a team of hetero-geneous agents (two Lightweight Rover Units and ARDEA, a drone), which together perform various complex tasks under strict communication constraints. In this paper, we highlight three of these tasks that were successfully demonstrated during a one-month test mission on Mt. Etna in Sicily, Italy, which was chosen due to its similarity to the Moon in terms of geological structure. All three tasks have in common, that they leverage an instance segmentation approach deployed on the rovers to detect rocks within camera imagery. The first application is a mapping scheme that incorporates semantically detected rocks into its environment model to safely navigate to points of interest. Secondly, we present a method for the collection and extraction of in-situ samples with a rover, which uses rock detection to localize relevant candidates to grasp. For the third task, we show the usefulness of stone segmentation to autonomously conduct a spectrometer measurement experiment. We perform a throughout analysis of the presented methods and evaluate our experimental results. The demonstrations on Mt. Etna show that our approaches are well suited for navigation, geological analysis, and sample extraction tasks within autonomous robotic extra-terrestrial missions.
UR - http://www.scopus.com/inward/record.url?scp=85160569096&partnerID=8YFLogxK
U2 - 10.1109/AERO55745.2023.10115717
DO - 10.1109/AERO55745.2023.10115717
M3 - Conference contribution
AN - SCOPUS:85160569096
T3 - IEEE Aerospace Conference Proceedings
BT - 2023 IEEE Aerospace Conference, AERO 2023
PB - IEEE Computer Society
T2 - 2023 IEEE Aerospace Conference, AERO 2023
Y2 - 4 March 2023 through 11 March 2023
ER -