Use Cases, Metrics, and Challenges of Nomadic Non-Public Networks for the 6G Standardization
Daniel Lindenschmitt, Michael Gundall, Ainur Daurembekova, Marcos Rates Crippa, Mohammad Asif Habibi, Bin Han, Philipp Rosemann, Dennis Krummacker, Benedikt Veith, Hans D. Schotten
TL;DR
The paper investigates nomadic non-public networks (NNPNs) as a mobility-enabled evolution of 5G NPNs for 6G standardization. It analyzes use cases across agriculture, construction, and transport, and details backhaul options including non-terrestrial networks; defines a KPI framework aligned with ITU-R M.2160-0 and clusters use cases by mobility and regulatory needs. It discusses architectural and regulatory realization challenges, including mobility of infrastructure, network-in-network concepts, and cross-border spectrum licensing. The authors propose a structured evaluation framework to inform standardization and emphasize the need for flexible regulatory policies and adaptable network architectures to enable NNPN deployment in diverse environments.
Abstract
Wireless communication is evolving with the adoption of dynamic and self-organizing networks. They are expected to play a crucial role in shaping sixth-generation (6G) systems and the ongoing standardization process. The concept of non-public networks (NPNs) introduced in fifth-generation (5G) will be enhanced by nomadic non-public networks (NNPNs), extending mobility and adaptability beyond fixed locations. These networks help overcome the limitations of traditional static infrastructures, making them applicable to areas such as emergency response, transportation, agriculture, and others. This paper examines the transition from NPNs to NNPNs, highlighting key technical aspects such as network architecture, dynamic resource allocation, and wireless backhauling. Several use cases illustrate how NNPNs improve connectivity in environments where traditional networks are limited. Additionally, the study defines Key Performance Indicators (KPIs) to evaluate NNPN applications and establishes a framework for categorizing them based on mobility and operational requirements. Despite their advantages, NNPNs introduce architectural, regulatory, and security challenges such as new approaches for handovers, spectrum policies or cross-border functionality, and trust mechanisms to maintain reliable operations. By identifying use cases, defining evaluation criteria, and addressing technical and regulatory challenges, this paper provides insights into integrating NNPNs into future 6G networks. These findings contribute to ongoing standardization efforts and emphasize the need for adaptable policies and network architectures to maximize the benefits of NNPNs in next-generation communication systems.