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1. Runtime Control of LoRa Spreading Factor for Campus Shuttle Monitoring

   https://doi.org/10.1109/ICNP49622.2020.9259383  

   Mu, Di ; Chen, Yitian ; Shi, Junyang ; Sha, Mo ( October 2020 , IEEE International Conference on Network Protocols (ICNP))
2. Enabling Cross-technology Communication from LoRa to ZigBee via Payload Encoding in Sub-1 GHz Bands

   https://doi.org/10.1145/3470452  

   Shi, Junyang ; Mu, Di ; Sha, Mo ( February 2022 , ACM Transactions on Sensor Networks)

   Low-power wireless mesh networks (LPWMNs) have been widely used in wireless monitoring and control applications. Although LPWMNs work satisfactorily most of the time thanks to decades of research, they are often complex, inelastic to change, and difficult to manage once the networks are deployed. Moreover, the deliveries of control commands, especially those carrying urgent information such as emergency alarms, suffer long delay, since the messages must go through the hop-by-hop transport. Recent studies show that adding low-power wide-area network radios such as LoRa onto the LPWMN devices (e.g., ZigBee) effectively overcomes the limitation. However, users have shown a marked reluctance to embrace the new heterogeneous communication approach because of the cost of hardware modification. In this article, we introduce LoRaBee, a novel LoRa to ZigBee cross-technology communication (CTC) approach, which leverages the energy emission in the Sub-1 GHz bands as the carrier to deliver information. Although LoRa and ZigBee adopt distinct modulation techniques, LoRaBee sends information from LoRa to ZigBee by putting specific bytes in the payload of legitimate LoRa packets. The bytes are selected such that the corresponding LoRa chirps can be recognized by the ZigBee devices through sampling the received signal strength. Experimental results show that our LoRaBeemore »provides reliable CTC communication from LoRa to ZigBee with the throughput of up to 281.61 bps in the Sub-1 GHz bands.« less
3. OwLL: Accurate LoRa Localization using the TV Whitespaces

   https://doi.org/10.1145/3412382.3458263  

   Bansal, Atul ; Gadre, Akshay ; Singh, Vaibhav ; Rowe, Anthony ; Iannucci, Bob ; Kumar, Swarun ( May 2021 , IEEE/ACM IPSN 2021)
4. Improving LoRa Signal Coverage in Urban and Sub-Urban Environments with UAVs

   https://doi.org/10.1109/IWAT.2019.8730598  

   Dambal, Vageesh Anand ; Mohadikar, Sameer ; Kumbhar, Abhaykumar ; Guvenc, Ismail ( March 2019 , IEEE Int. Workshop on Antenna Technology (iWAT))
5. Fingerprinting-based Indoor and Outdoor Localization with LoRa and Deep Learning

   https://doi.org/10.1109/GLOBECOM42002.2020.9322261  

   Purohit, Jait ; Wang, Xuyu ; Mao, Shiwen ; Sun, Xiaoyan ; Yang, Chao ( December 2020 , Proc. IEEE GLOBECOM 2020)