Integrating Low-Power Wide-Area Networks for Enhanced Scalability and Extended Coverage

TL;DR

This paper proposes a scalable, integrated LPWAN architecture using multiple SNOW networks over TV white spaces, addressing coverage and interference challenges for IoT in rural areas with proven algorithms and real-world deployment.

Contribution

It introduces a novel integration framework for multiple SNOW LPWANs, formulates a scalability-interference tradeoff as an NP-hard problem, and provides efficient heuristic and approximation algorithms.

Findings

Algorithms achieve high reliability and low latency.

Deployment demonstrates practical scalability and energy efficiency.

The approach extends coverage significantly in rural areas.

Abstract

Low-Power Wide-Area Networks (LPWANs) are evolving as an enabling technology for Internet-of-Things (IoT) due to their capability of communicating over long distances at very low transmission power. Existing LPWAN technologies, however, face limitations in meeting scalability and covering very wide areas which make their adoption challenging for future IoT applications, especially in infrastructure-limited rural areas. To address this limitation, in this paper, we consider achieving scal-ability and extended coverage by integrating multiple LPWANs. SNOW (Sensor Network Over White Spaces), a recently proposed LPWAN architecture over the TV white spaces, has demonstrated its advantages over existing LPWANs in performance and energy-efficiency. In this paper, we propose to scale up LPWANs through a seamless integration of multiple SNOWs which enables concurrent inter-SNOW and intra-SNOW communications. We then formulate the tradeoff between scalability and inter-SNOW interference as a constrained optimization problem whose objective is to maximize scalability by managing white space spectrum sharing across multiple SNOWs. We also prove the NP-hardness of this problem. To this extent, We propose an intuitive polynomial-time heuristic algorithm for solving the scalability optimization problem which is highly efficient in practice. For the sake of theoretical bound, we also propose a simple polynomial-time 1/2-approximation algorithm for the scalability optimization problem. Hardware experiments through deployment in an area of (25x15)sq. km as well as large scale simulations demonstrate the effectiveness of our algorithms and feasibility of achieving scalability through seamless integration of SNOWs with high reliability, low latency, and energy efficiency.