|
|
5G通信基站工作特性及其电磁辐射问题研究
|
Abstract:
本文通过与4G通信基站对比,简要介绍了4G和5G通信系统之间的主要相似性和差异,并分析了5G通信基站的工作特性对于测量其电磁辐射值的影响,最后选取某5G通信基站,实地测量了该基站的电磁辐射情况,总结了在不同条件下5G通信基站电磁辐射环境的变化规律。由监测结果得出,与4G通信基站不同,5G通信基站的电磁辐射值分布在空间上有明显差异,且受到多种因素(包括:5G基站工作模式、5G终端的位置、5G终端的网速等)的影响而随动。该研究对于5G通信基站辐射环境监测工作提供了理论帮助,并推动了5G基站选址与建设工作。
Compared with 4G communication base station, the main similarities and differences between 4G and 5G systems are introduced, and the influence of those characteristics of 5G communication base stations on the measurement of the maximum electromagnetic radiation is analyzed. Finally, the electromagnetic radiation of 5G communication base station is measured on the spot, and the change law of electromagnetic radiation environment of 5G communication base stations under different conditions is summarized. Detection results show that the electromagnetic radiation distribution of 5G communication base station is different from that of 4G communication base station in space, and it is affected by many factors, including 5G base station working mode, 5G terminal location, 5G terminal network speed, etc. This study provides theoretical help for the radiation environment monitoring of 5G communication base station, and promotes the location and construction of 5G base station.
| [1] | 戴春伟. 5G基站能耗管控与环境影响[J]. 江苏通信, 2020, 36(4): 29-32. |
| [2] | 王华刚, 罗森文, 陈少川. 5G基站与射频电磁辐射漫谈[J]. 广东通信技术, 2020, 40(8): 70-74. |
| [3] | 王守源, 安少赓, 呼彦朴, 等. 5G基站的电磁特性检测[J]. 安全与电磁兼容, 2020(6): 18-22. |
| [4] | 罗勇, 石丹, 王冠, 等. 5G基站电磁辐射[J/OL]. 太赫兹科学与电子信息学报, 2021: 1-4.
http://kns.cnki.net/kcms/detail/51.1746.TN.20210330.1052.002.html, 2021-06-08. |
| [5] | 李可才. 5G基站电磁辐射探析[J]. 信息通信, 2020(6): 269-271. |
| [6] | Franci, D., Coltellacci, S. and Grillo, E. (2020) An Experimental Investigation on the Impact of Duplexing and Beamforming Techniques in Field Measurements of 5G Signals. Electronics, 9, 223.
https://doi.org/10.3390/electronics9020223 |
| [7] | Keller, H. (2019) On the Assessment of Human Exposure to Electromagnetic Fields Transmitted by 5G NR Base Stations. Health Physics, 117, 541-545. https://doi.org/10.1097/HP.0000000000001089 |
| [8] | Migliore, M.D. (2019) Horse (Electromagnetics) Is More Important than Horseman (Information) for Wireless Transmission. IEEE Transactions on Antennas and Propagation, 67, 2046-2055. https://doi.org/10.1109/TAP.2018.2889158 |
| [9] | Song, C.H., Liu, K. and Yang, Z.Q. (2020) Evaluation of Electromagnetic Radiation Level of a 5G Mobile Communication Base Station in Jinshan, Shanghai. Advances in Environmental Protection, 10, 208-212.
https://doi.org/10.12677/AEP.2020.102024 |
| [10] | Aerts, S., Verloock, L. and Van Den Bossche (2019) In-Situ Measurement Methodology for the Assessment of 5G NR Massive MIMO Base Station Exposure at Sub-6GHz Frequencies. IEEE Access, 7, 184658-184667.
https://doi.org/10.1109/ACCESS.2019.2961225 |
| [11] | 杜岳华. 浅谈5G移动通信基站的电磁辐射环境影响[J]. 科技风, 2020(30): 83-84. |
| [12] | 邓晓钦, 高鹏. 5G移动通信基站电磁辐射监测波束引导必要性研究[J]. 四川环境, 2020, 4(11): 142-145. |
| [13] | 付松. 5G基站电磁辐射评估[J]. 太赫兹科学与电子信息学报, 2020, 5(13): 122-126. |
| [14] | 中华人民共和国生态环境部. 《移动通信基站电磁辐射环境监测方法》(HJ972-2018) [S]. 2018-09-30. |
| [15] | 中华人民共和国生态环境部. 《5G移动通信基站电磁辐射监测方法(试行)》(HJ 1151-2020) [S]. 2020-12-14. |
