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Urban wireless traffic evolution: the role of new devices and the effect of policy

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  • Jaume Benseny
  • Jarno Lahteenmaki
  • Juuso Toyli
  • Heikki Hammainen

Abstract

The emergence of new wireless technologies, such as the Internet of Things, allows digitalizing new and diverse urban activities. Thus, wireless traffic grows in volume and complexity, making prediction, investment planning, and regulation increasingly difficult. This article characterizes urban wireless traffic evolution, supporting operators to drive mobile network evolution and policymakers to increase national and local competitiveness. We propose a holistic method that widens previous research scope, including new devices and the effect of policy from multiple government levels. We provide an analytical formulation that combines existing complementary methods on traffic evolution research and diverse data sources. Results for a centric area of Helsinki during 2020-2030 indicate that daily volumes increase, albeit a surprisingly large part of the traffic continues to be generated by smartphones. Machine traffic gains importance, driven by surveillance video cameras and connected cars. While camera traffic is sensitive to law enforcement policies and data regulation, car traffic is less affected by transport electrification policy. High-priority traffic remains small, even under encouraging autonomous vehicle policies. We suggest that 5G small cells might be needed around 2025, albeit the utilization of novel radio technology and additional mid-band spectrum could delay this need until 2029. We argue that mobile network operators inevitably need to cooperate in constructing a single, shared small cell network to mitigate the high deployment costs of massively deploying small cells. We also provide guidance to local and national policymakers for IoT-enabled competitive gains via the mitigation of five bottlenecks. For example, local monopolies for mmWave connectivity should be facilitated on space-limited urban furniture or risk an eventual capacity crunch, slowing down digitalization.

Suggested Citation

  • Jaume Benseny & Jarno Lahteenmaki & Juuso Toyli & Heikki Hammainen, 2023. "Urban wireless traffic evolution: the role of new devices and the effect of policy," Papers 2310.14406, arXiv.org.
    • Handle: RePEc:arx:papers:2310.14406
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    References listed on IDEAS

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    1. Frias, Zoraida & Pérez Martínez, Jorge, 2018. "5G networks: Will technology and policy collide?," Telecommunications Policy, Elsevier, vol. 42(8), pages 612-621.
    2. Kivi, Antero & Smura, Timo & Töyli, Juuso, 2012. "Technology product evolution and the diffusion of new product features," Technological Forecasting and Social Change, Elsevier, vol. 79(1), pages 107-126.
    3. Rendon Schneir, Juan & Ajibulu, Ade & Konstantinou, Konstantinos & Bradford, Julie & Zimmermann, Gerd & Droste, Heinz & Canto, Rafael, 2019. "A business case for 5G mobile broadband in a dense urban area," Telecommunications Policy, Elsevier, vol. 43(7), pages 1-1.
    4. Abrardi, Laura & Cambini, Carlo, 2019. "Ultra-fast broadband investment and adoption: A survey," Telecommunications Policy, Elsevier, vol. 43(3), pages 183-198.
    5. Caragliu, Andrea & Del Bo, Chiara F., 2019. "Smart innovative cities: The impact of Smart City policies on urban innovation," Technological Forecasting and Social Change, Elsevier, vol. 142(C), pages 373-383.
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