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| Sensing Image Data Based Unmanned Aerial Vehicle Channel Path Loss Prediction |
| SUN Mingran1, HUANG Ziwei1, BAI Lu2,3, CHENG Xiang1, ZHANG Hongguang4, FENG Tao4 |
1. School of Electronics, Peking University, Beijing 100871;
2. Shandong Research Institute of Industrial Technology, Jinan 250100;
3. Joint SDU-NTU Centre for Artificial Intelligence Research, Shandong University, Jinan 250101;
4. Institute of System Engineering, Academy of Military Sciences PLA, Beijing 100039 |
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Abstract To facilitate the application and development of 6G unmanned aerial vehicle(UAV)-to-ground wireless communications, improve the theory foundation of UAV-to-ground communication system and meet the safety and efficiency requirements of 6G communications, sensing image data based UAV channel path loss prediction in 6G UAV-to-ground communication scenario is studied. Firstly, based on AirSim and Wireless InSite, sensing data simulation platform and channel data simulation platform, a mixed sensing and communication integration dataset for a dynamic UAV-to-ground communication scenario, is established to explore the mapping relationship between physical space and electromagnetic space. Secondly, based on the established dataset, the mapping relationship between sensing image in physical space and channel path loss in electromagnetic space is built and the 6G UAV-to-ground real-time path loss prediction is achieved. Finally, the prediction result of the proposed model is compared with the test set through the simulation test and the results verify the accuracy of the proposed model.
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Received: 09 October 2023
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| Fund:National Natural Science Foundation of China(No.62125101,62341101,62371273,62001018,62106282), Natural Science Foundation of Shandong Province(No.ZR2023YQ058), New Cornerstone Science Foundation through the XPLORER PRIZE, Young Elite Scientists Sponsorship Program by CAST(No.2023QNRC001), Taishan Scholars Program, Beijing Science and Technology New Star Program(No.20220484139) |
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Corresponding Authors:
BAI Lu, Ph.D., professor. Her research interests include 6G wireless communication network channel mea-surements and modeling.
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| About author:: SUN Mingran, Ph.D. candidate. His research interests include AI-based channel modeling. HUANG Ziwei, Ph.D. candidate. His research interests include complex high-mobility communication channel measurements and mo-deling. CHENG Xiang, Ph.D., professor. His research interests include data-driven intelligent network and networked intelligence. ZHANG Hongguang, Ph.D., assistant professor. His research interests include few-shot learning, meta-learning and transfer-lear-ning.FENG Tao, Ph.D., senior engineer. His research interests include intelligent network, software defined network and network management. |
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CHENG Xiang, ZHANG Haotian, LI Sijiang, HUANG Ziwei, YANG Zonghui, GAO Shijian, BAI Lu, ZHANG Jia'nan, ZHENG Xinhu, YANG Liuqing. Synesthesia of Machines Towards Intelligent Multi-modal Sensing-Communication Integration[J]. Pattern Recognition and Artificial Intelligence, 2023, 36(11): 967-986. |
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2023, Vol. 36 
