TY - GEN
T1 - Reconfiguration and Locomotion with Joint Movements in the Amoebot Model
AU - Padalkin, Andreas
AU - Kumar, Manish
AU - Scheideler, Christian
N1 - Publisher Copyright:
© Andreas Padalkin, Manish Kumar, and Christian Scheideler.
PY - 2024/6/1
Y1 - 2024/6/1
N2 - We are considering the geometric amoebot model where a set of n amoebots is placed on the triangular grid. An amoebot is able to send information to its neighbors, and to move via expansions and contractions. Since amoebots and information can only travel node by node, most problems have a natural lower bound of Ω(D) where D denotes the diameter of the structure. Inspired by the nervous and muscular system, Feldmann et al. have proposed the reconfigurable circuit extension and the joint movement extension of the amoebot model with the goal of breaking this lower bound. In the joint movement extension, the way amoebots move is altered. Amoebots become able to push and pull other amoebots. Feldmann et al. demonstrated the power of joint movements by transforming a line of amoebots into a rhombus within O(log n) rounds. However, they left the details of the extension open. The goal of this paper is therefore to formalize the joint movement extension. In order to provide a proof of concept for the extension, we consider two fundamental problems of modular robot systems: reconfiguration and locomotion. We approach these problems by defining meta-modules of rhombical and hexagonal shapes, respectively. The meta-modules are capable of movement primitives like sliding, rotating, and tunneling. This allows us to simulate reconfiguration algorithms of various modular robot systems. Finally, we construct three amoebot structures capable of locomotion by rolling, crawling, and walking, respectively.
AB - We are considering the geometric amoebot model where a set of n amoebots is placed on the triangular grid. An amoebot is able to send information to its neighbors, and to move via expansions and contractions. Since amoebots and information can only travel node by node, most problems have a natural lower bound of Ω(D) where D denotes the diameter of the structure. Inspired by the nervous and muscular system, Feldmann et al. have proposed the reconfigurable circuit extension and the joint movement extension of the amoebot model with the goal of breaking this lower bound. In the joint movement extension, the way amoebots move is altered. Amoebots become able to push and pull other amoebots. Feldmann et al. demonstrated the power of joint movements by transforming a line of amoebots into a rhombus within O(log n) rounds. However, they left the details of the extension open. The goal of this paper is therefore to formalize the joint movement extension. In order to provide a proof of concept for the extension, we consider two fundamental problems of modular robot systems: reconfiguration and locomotion. We approach these problems by defining meta-modules of rhombical and hexagonal shapes, respectively. The meta-modules are capable of movement primitives like sliding, rotating, and tunneling. This allows us to simulate reconfiguration algorithms of various modular robot systems. Finally, we construct three amoebot structures capable of locomotion by rolling, crawling, and walking, respectively.
KW - locomotion
KW - modular robot system
KW - programmable matter
KW - reconfiguration
UR - http://www.scopus.com/inward/record.url?scp=85195380984&partnerID=8YFLogxK
U2 - 10.4230/LIPIcs.SAND.2024.18
DO - 10.4230/LIPIcs.SAND.2024.18
M3 - Conference contribution
AN - SCOPUS:85195380984
T3 - Leibniz International Proceedings in Informatics, LIPIcs
BT - 3rd Symposium on Algorithmic Foundations of Dynamic Networks, SAND 2024
A2 - Casteigts, Arnaud
A2 - Kuhn, Fabian
PB - Schloss Dagstuhl- Leibniz-Zentrum fur Informatik GmbH, Dagstuhl Publishing
T2 - 3rd Symposium on Algorithmic Foundations of Dynamic Networks, SAND 2024
Y2 - 5 June 2024 through 7 June 2024
ER -