Integrating Low-Power Wide-Area Networks in White Spaces

2018 IEEE/ACM Third International Conference on Internet-of-Things Design and Implementation (IoTDI) Pub Date : 2018-04-17 DOI:10.1109/IoTDI.2018.00033

Mahbubur Rahman, Abusayeed Saifullah

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引用次数: 16

Abstract

Low-Power Wide-Area Networks (LPWANs) are evolving as an enabling technology for Internet-of-Things (IoT) that offer long communication range at low power. Despite their promise, existing LPWANs still face limitations in meeting scalability and covering much wider area which make their adoption challenging for future IoT applications, specially in infrastructure-limited rural areas. To address this, we consider achieving scalability by integrating multiple LPWANs that need to coordinate for extended coverage. Recently proposed SNOW (Sensor Network Over White Spaces) has demonstrated advantages over existing LPWANs in its performance. In this paper, we propose to scale up LPWANs through a seamless integration of multiple SNOWs that 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. We then propose an intuitive polynomial time heuristic algorithm for solving the scalability optimization problem. Hardware experiments through deployment in an area of (15x10)sq. km demonstrate the effectiveness of our algorithm and feasibility of achieving scalability through seamless integration of SNOWs with high reliability, low latency, and energy efficiency.

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在空白空间集成低功耗广域网

低功耗广域网(lpwan)正在发展成为物联网(IoT)的使能技术，可以在低功耗下提供长距离通信。尽管他们的承诺，现有的lpwan在满足可扩展性和覆盖更广泛的区域方面仍然面临限制，这使得它们的采用对未来的物联网应用具有挑战性，特别是在基础设施有限的农村地区。为了解决这个问题，我们考虑通过集成多个需要协调扩展覆盖的lpwan来实现可伸缩性。最近提出的SNOW(白色空间传感器网络)已经证明了其性能优于现有的lpwan。在本文中，我们建议通过多个snow的无缝集成来扩展lpwan，从而实现snow间和snow内的并发通信。然后，我们将可伸缩性和snow间干扰之间的权衡制定为一个约束优化问题，其目标是通过管理多个snow之间的空白频谱共享来最大化可伸缩性。我们还证明了这个问题的np -硬度。然后，我们提出了一种直观的多项式时间启发式算法来解决可扩展性优化问题。硬件实验通过部署在一个区域(15 × 10)平方。km验证了我们算法的有效性，以及通过高可靠性、低延迟和能效的snow无缝集成实现可扩展性的可行性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2018 IEEE/ACM Third International Conference on Internet-of-Things Design and Implementation (IoTDI)

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