| dc.identifier.citation | Zixiang Han, Lincong Han, Xiaozhou Zhang, Yajuan Wang, Liang Ma, Mengting Lou, Jing Jin, and Guangyi Liu. 2023. Multistatic Integrated Sensing and Communication System in Cellular Networks. arXiv preprint arXiv:2305.12994 (2023).Google Scholar Jesus O. Lacruz, Rafael Ruiz Ortiz, and Joerg Widmer. 2021. A Real-Time Experimentation Platform for Sub-6 GHz and Millimeter-Wave MIMO Systems (MobiSys '21). Association for Computing Machinery, New York, NY, USA, 427--439.Google Scholar Jacopo Pegoraro, Jesus O Lacruz, Tommy Azzino, Marco Mezzavilla, Michele Rossi, Joerg Widmer, and Sundeep Rangan. 2023. JUMP: Joint communication and sensing with Unsynchronized transceivers Made Practical. arXiv preprint arXiv:2304.07766 (2023).Google Scholar J Andrew Zhang, Kai Wu, Xiaojing Huang, Y Jay Guo, Daqing Zhang, and Robert W Heath. 2022. Integration of radar sensing into communications with asynchronous transceivers. IEEE Communications Magazine 60, 11 (2022), 106--112. | es |
| dc.description.abstract | We prototype and validate a multistatic millimeter-wave (mmWave) Integrated Sensing And Communication (ISAC) system based on IEEE 802.11ay. Compensation of the clock asynchrony between each transmitter (TX) and receiver (RX) pair is performed using the sole line-of-sight (LoS) wireless signal propagation. As a result, our system provides concurrent target tracking and micro-Doppler (μD) estimation from multiple points of view, paving the way for practical multistatic data fusion. Our results on human movement sensing, complemented with precise, quantitative ground-truth (GT) data, demonstrate the enhanced sensing capabilities of multistatic ISAC, due to the spatial diversity of the RX nodes. | es |
