An Algorithmic Framework for Shape Formation Problems in Self-Organizing Particle Systems
Abstract
Many proposals have already been made for realizing programmable matter, ranging from shape-changing molecules, DNA tiles, and synthetic cells to reconfigurable modular robotics. Envisioning systems of nano-sensors devices, we are particularly interested in programmable matter consisting of systems of simple computational elements, called particles, that can establish and release bonds and can actively move in a self-organized way, and in shape formation problems relevant for programmable matter in those self-organizing particle systems (SOPS). In this paper, we present a general algorithmic framework for shape formation problems in SOPS, and show direct applications of this framework to the problems of having the particle system self-organize to form a hexagonal or triangular shape. Our algorithms utilize only local control, require only constant-size memory particles, and are asymptotically optimal both in terms of the total number of movements needed to reach the desired shape configuration.
Cite
@article{arxiv.1504.00744,
title = {An Algorithmic Framework for Shape Formation Problems in Self-Organizing Particle Systems},
author = {Zahra Derakhshandeh and Robert Gmyr and Andrea W. Richa and Christian Scheideler and Thim Strothmann},
journal= {arXiv preprint arXiv:1504.00744},
year = {2015}
}
Comments
Corrected typos. Algorithms and results unchanged. arXiv admin note: text overlap with arXiv:1503.07991