Experimental Demonstration of Delay-Bounded Wireless Network Based on Precise Time Synchronization
Low latency and reliable information transfer are highly demanded in 5G and beyond 5G wireless communications. However, the conventional media access control (MAC) protocol for local wireless networks sometimes unexpectedly yields significant delays due to its stochastic arbitration mechanism, resulting in the incapability of limiting the maximum delay. In the meantime, the latest precise time synchronization technology, especially wireless two-way interferometry (Wi-Wi), paves a new way to overcome such fundamental difficulties. Indeed, Yamasaki et al. proposed a new delay-bounded wireless MAC protocol named Carrier Sense Multiple Access with Arbitration Point (CSMA/AP), exploiting precise time synchronization among all devices in the network. CSMA/AP enables collision-free and delay-bounded communications with a simple autonomous arbitration mechanism, unlike conventional methods such as CSMA/CA. The former study, however, was limited only to numerical examinations. Experimental demonstration and verification in wireless environments are one of the most critical steps. This paper experimentally demonstrates the fundamental principles of CSMA/AP by constructing a star-topology wireless network using software-defined radio terminals combined with precise time synchronization devices. We show that CSMA/AP is successfully operated, including the dynamic change of the spatial position of the terminal or the capability to accommodate mobility, thanks to the real-time adaption to the dynamically changing environment by Wi-Wi. We also experimentally confirm that the proposed CSMA/AP principle cannot be executed without Wi-Wi, which validates the impact of precise time synchronization. This study paves a way toward realizing delay-bounded wireless communications for future low-latency and highly reliable critical applications.
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