Structural Complexity of One-Dimensional Random Geometric Graphs
Abstract
We study the richness of the ensemble of graphical structures (i.e., unlabeled graphs) of the one-dimensional random geometric graph model defined by nodes randomly scattered in that connect if they are within the connection range . We provide bounds on the number of possible structures which give universal upper bounds on the structural entropy that hold for any , and distribution of the node locations. For fixed , the number of structures is with , and therefore the structural entropy is upper bounded by . For large , we derive bounds on the structural entropy normalized by , and evaluate them for independent and uniformly distributed node locations. When the connection range is , the obtained upper bound is given in terms of a function that increases with and asymptotically attains bits per node. If the connection range is bounded away from zero and one, the upper and lower bounds decrease linearly with , as and , respectively. When is vanishing but dominates (e.g., ), the normalized entropy is between and bits per node. We also give a simple encoding scheme for random structures that requires bits per node. The upper bounds in this paper easily extend to the entropy of the labeled random graph model, since this is given by the structural entropy plus a term that accounts for all the permutations of node labels that are possible for a given structure, which is no larger than .
Cite
@article{arxiv.2107.13495,
title = {Structural Complexity of One-Dimensional Random Geometric Graphs},
author = {Mihai-Alin Badiu and Justin P. Coon},
journal= {arXiv preprint arXiv:2107.13495},
year = {2022}
}
Comments
44 pages, 9 figures; revised some of results; significant additional results included