English

Spatial Network Calculus and Performance Guarantees in Wireless Networks

Information Theory 2023-09-07 v3 Networking and Internet Architecture math.IT

Abstract

This work develops a novel approach toward performance guarantees for all links in arbitrarily large wireless networks. It introduces a spatial network calculus, consisting of spatial regulation properties for stationary point processes and the first steps of a calculus for this regulation, which can be seen as an extension to space of the classical network calculus. Specifically, two classes of regulations are defined: one includes ball regulation and shot-noise regulation, which are shown to be equivalent and upper constraint interference; the other one includes void regulation, which lower constraints the signal power. These regulations are defined both in the strong and weak sense: the former requires the regulations to hold everywhere in space, whereas the latter only requires the regulations to hold as observed by a jointly stationary point process. Using this approach, we derive performance guarantees in device-to-device, ad hoc, and cellular networks under proper regulations. We give universal bounds on the SINR for all links, which gives link service guarantees based on information-theoretic achievability. They are combined with classical network calculus to provide end-to-end latency guarantees for all packets in wireless queuing networks. Such guarantees do not exist in networks that are not spatially regulated, e.g., Poisson networks.

Keywords

Cite

@article{arxiv.2302.02001,
  title  = {Spatial Network Calculus and Performance Guarantees in Wireless Networks},
  author = {Ke Feng and François Baccelli},
  journal= {arXiv preprint arXiv:2302.02001},
  year   = {2023}
}

Comments

Submitted to IEEE Transactions on Wireless Communications

R2 v1 2026-06-28T08:31:45.412Z