BIER-Star: Stateless Geographic Multicast for Scalable Satellite-Terrestrial Integration

TL;DR

BIER-Star introduces a stateless, scalable multicast protocol for integrated satellite-terrestrial networks using geospatial cell identifiers, reducing overhead and improving reliability in dynamic, mobile environments.

Contribution

It proposes BIER-Star, a novel stateless multicast protocol leveraging geospatial gridding to enhance scalability and efficiency in TN-NTN networks.

Findings

Reduces header size compared to BIER

Eliminates per-flow state and complex signaling

Avoids geographic path-finding failures

Abstract

The rapid expansion of LEO satellite constellations has enabled an integrated terrestrial network and non-terrestrial network (TN-NTN), connecting diverse users such as aircraft, ships, and remote communities. These networks increasingly need a scalable and efficient multicast protocol for critical applications like emergency alerts, large-scale software updates, and real-time broadcasting. However, traditional multicast protocols, such as IP-based multicast and software-defined multicast approaches, introduce significant control overhead and struggle to adapt to the dynamic and mobile nature of satellite topologies. This paper presents BIER-Star, a stateless multicast protocol designed for the integrated TN-NTN. BIER-Star uses a two-layer geospatial gridding scheme (i.e., H3) to encode destinations as Earth- and space-cell identifiers rather than per-terminal addresses. This cell-based abstraction shortens the header bitstring, simplifies forwarding, and eliminates per-flow state and complex signaling. Our simulations indicate that BIER-Star reduces header size versus BIER and avoids geographic path-finding failures seen in greedy methods.