Simulation and Modeling of Millimeter-Wave Channel at 60 GHz in Indoor Environment for 5G Wireless Communication System

机译：5G无线通信系统在室内环境下60 GHz毫米波信道的仿真和建模

获取原文

页面导航

摘要
著录项
引文网络
相似文献
相关主题

摘要

This paper presents the propagation characteristics at 60 GHz for fifth generation (5G) millimeter-wave (mmWave) wireless communication systems. The propagation characteristics of mmWave signal in the indoor radio channels are discussed based on the method of shooting and bouncing ray tracing/image (SBR/IM). Omnidirectional path loss models, received power and root-mean-square (RMS) delay spreads statistics are analyzed in terms of line-of-sight (LOS) and non-line-of-sight (NLOS) scenarios. The results show that the path loss exponent (PLE) values in LOS environments vary between 1.56 and 1.78 and the PLE value is 3.87 in NLOS scenario. The RMS delay spreads values vary between 2.1 ns and 6.6 ns. Furthermore, the normal distribution and the Gaussian distribution models best fit the received power and the RMS delay spreads at 60 GHz, respectively.

机译：本文介绍了第五代（5G）毫米波（mmWave）无线通信系统在60 GHz时的传播特性。基于拍摄和反射射线追踪/图像（SBR / IM）的方法，讨论了毫米波信号在室内无线电信道中的传播特性。全向路径损耗模型，接收功率和均方根（RMS）延迟扩展统计数据是根据视线（LOS）和非视线（NLOS）场景进行分析的。结果表明，在NLOS情况下，LOS环境中的路径损耗指数（PLE）值在1.56和1.78之间变化，而PLE值为3.87。 RMS延迟扩展值在2.1 ns和6.6 ns之间变化。此外，正态分布和高斯分布模型分别最适合60 GHz时的接收功率和RMS延迟扩展。

著录项

来源
《International Conference on Computational Electromagnetics》|2018年|1-3|共3页
会议地点 Chengdu(CN)
作者
Shuangde Li; Yuanjian Liu; Leke Lin; Dingming Sun; Shan Yang; Xiangchen Sun;
展开▼
作者单位

College of Electronic and Optical Engineering Nanjing University of Posts and Telecommunications Jiangsu Nanjing 210003 China;

National Key Laboratory of Electromagnetic Environment China Research Institute of Radio wave Propagation Qingdao Shandong 266107 China;

展开▼
会议组织
原文格式 PDF
正文语种
中图分类
关键词
Wireless communication; 5G mobile communication; Delays; Indoor environments; Electron tubes; Mathematical model; Millimeter wave communication;

机译：无线通信; 5G移动通信；延误；室内环境；电子管；数学模型;毫米波通讯;

相似文献

外文文献
中文文献
专利

1. Indoor Corridor Wideband Radio Propagation Measurements and Channel Models for 5G Millimeter Wave Wireless Communications at 19 GHz, 28 GHz, and 38 GHz Bands [J] . Al-samman Ahmed M., Abd Rahman Tharek, Azmi Marwan Hadri Wireless communications & mobile computing . 2018,第1期

机译：适用于19 GHz，28 GHz和38 GHz频段的5G毫米波无线通信的室内走廊宽带无线电传播测量和信道模型
2. 60-GHz Millimeter-Wave Channel Measurements and Modeling for Indoor Office Environments [J] . Xianyue Wu, Cheng-Xiang Wang, Jian Sun, Antennas and Propagation, IEEE Transactions on . 2017,第4期

机译：室内办公环境的60 GHz毫米波通道测量和建模
3. Channel Measurements and Modeling at 6 GHz in the Tunnel Environments for 5G Wireless Systems [J] . Li Shuang-de, Liu Yuan-jian, Lin Le-ke, International journal of antennas and propagation . 2017,第PTa4期

机译：5G无线系统在隧道环境中6 GHz的信道测量和建模
4. Simulation and Modeling of Millimeter-Wave Channel at 60 GHz in Indoor Environment for 5G Wireless Communication System [C] . Shuangde Li, Yuanjian Liu, Leke Lin, IEEE International Conference on Computational Electromagnetics . 2018

机译：60 GHz在室内环境中毫米波通道的仿真与建模5G无线通信系统
5. A simulation traffic study of indoor wireless communications in the (20-60)GHz band. [D] . Thyagarajan, V. R. Manikka. 1993

机译：（20-60）GHz频带内室内无线通信的模拟流量研究。
6. Statistical Modelling and Characterization of Experimental mm-Wave Indoor Channels for Future 5G Wireless Communication Networks [O] . A. M. Al-Samman, T. A. Rahman, M. H. Azmi, -1

机译：未来5G无线通信网络的实验性毫米波室内信道的统计建模和表征
7. Wireless propagation measurements in indoor multipath environments at 1.7 GHz and 60 GHz for small cell systems [O] . Davies, RL, Bensebti, M, Beach, MA, 1991

机译：小型蜂窝系统在1.7 GHz和60 GHz的室内多径环境中进行无线传播测量

Simulation and Modeling of Millimeter-Wave Channel at 60 GHz in Indoor Environment for 5G Wireless Communication System

摘要

著录项

引文网络

相似文献

相关主题

期刊订阅