Liu, XinleiXinleiLiuBelogaev, AndreyAndreyBelogaevOostvogels, JonathanJonathanOostvogelsFang, BingwuBingwuFangHughes, DannyDannyHughesFamaey, JeroenJeroenFamaey2026-07-082026-07-0820262327-4662https://imec-publications.be/handle/20.500.12860/59771The latency gap between wired and wireless networks poses a challenge in the adoption of wireless technologies in latency-sensitive scenarios. The gap is especially notable in multihop communication typical for industrial sensor networks and robotic swarms. The main reason behind it is that commonly used wireless protocols rely on store-and-forward routing and costly overhead procedures to avoid interference. This article introduces RF-Zero-Wire, an RF-based symbol-synchronous communication protocol. Instead of relaying the whole frame per hop in a store-and-forward manner, nodes concurrently relay the frame symbol by symbol, without the need for tight time synchronization. Based on data collected in real-world experiments, we reveal that the inevitable carrier frequency offsets (CFOs) introduced by imperfect crystal oscillators cause a beating effect under concurrent symbol transmissions. This is characterized by periodic constructive and destructive interference, which significantly affects reliability. Subsequently, a thorough simulation study shows how the beating problem can be overcome with error correction codes. RF-Zero-Wire allows achieving an end-to-end latency of less than 1 ms for a small 4-byte frame transmitted across five hops. Moreover, latency is shown to increase only by 0.16% per extra hop for 16-byte frames, which is negligible compared to the over 100% per-hop latency increase observed in store-and-forward protocols. The tradeoffs between network reliability and CFO range, communication distance, node density, and achievable data rate are studied in large-scale experiments based on simulation.engRF-Zero-Wire: Design and Analysis of Multihop Low-Latency Symbol-Synchronous RF CommunicationJournal article10.1109/jiot.2026.3655182WOS:001723030200014INTERNETCHALLENGESCSMA/CATDMA