English

Algebraic and Geometric Models for Space Networking

Algebraic Topology 2023-10-06 v2 Machine Learning Networking and Internet Architecture Category Theory

Abstract

In this paper we introduce some new algebraic and geometric perspectives on networked space communications. Our main contribution is a novel definition of a time-varying graph (TVG), defined in terms of a matrix with values in subsets of the real line P(R). We leverage semi-ring properties of P(R) to model multi-hop communication in a TVG using matrix multiplication and a truncated Kleene star. This leads to novel statistics on the communication capacity of TVGs called lifetime curves, which we generate for large samples of randomly chosen STARLINK satellites, whose connectivity is modeled over day-long simulations. Determining when a large subsample of STARLINK is temporally strongly connected is further analyzed using novel metrics introduced here that are inspired by topological data analysis (TDA). To better model networking scenarios between the Earth and Mars, we introduce various semi-rings capable of modeling propagation delay as well as protocols common to Delay Tolerant Networking (DTN), such as store-and-forward. Finally, we illustrate the applicability of zigzag persistence for featurizing different space networks and demonstrate the efficacy of K-Nearest Neighbors (KNN) classification for distinguishing Earth-Mars and Earth-Moon satellite systems using time-varying topology alone.

Keywords

Cite

@article{arxiv.2304.01150,
  title  = {Algebraic and Geometric Models for Space Networking},
  author = {William Bernardoni and Robert Cardona and Jacob Cleveland and Justin Curry and Robert Green and Brian Heller and Alan Hylton and Tung Lam and Robert Kassouf-Short},
  journal= {arXiv preprint arXiv:2304.01150},
  year   = {2023}
}

Comments

Figures updated and improved based on more exhaustive simulations. Conjecture 2.27 now has weak and strong variations

R2 v1 2026-06-28T09:47:15.041Z