60 GHz Indoor Propagation Studies for Wireless Communications Based on a Ray-Tracing Method

被引:0
|
作者
C.-P. Lim
M. Lee
R. J. Burkholder
J. L. Volakis
R. J. Marhefka
机构
[1] Ohio State University,ElectroScience Laboratory, Department of Electrical and Computer Engineering
来源
EURASIP Journal on Wireless Communications and Networking | / 2007卷
关键词
Information System; Root Mean Square; Wireless Communication; System Application; Indoor Environment;
D O I
暂无
中图分类号
学科分类号
摘要
This paper demonstrates a ray-tracing method for modeling indoor propagation channels at 60 GHz. A validation of the ray-tracing model with our in-house measurement is also presented. Based on the validated model, the multipath channel parameter such as root mean square (RMS) delay spread and the fading statistics at millimeter wave frequencies are easily extracted. As such, the proposed ray-tracing method can provide vital information pertaining to the fading condition in a site-specific indoor environment.
引用
收藏
相关论文
共 50 条
  • [1] 60 GHz indoor propagation studies for wireless communications based on a ray-tracing method
    Lim, C.-P.
    Lee, M.
    Burkholder, R. J.
    Volakis, J. L.
    Marhefka, R. J.
    EURASIP JOURNAL ON WIRELESS COMMUNICATIONS AND NETWORKING, 2007, 2007 (1)
  • [2] Fast ray-tracing characterisation of indoor propagation channels at 60 GHz
    Dardari, D
    Minelli, L
    Tralli, V
    Andrisano, O
    1997 IEEE 47TH VEHICULAR TECHNOLOGY CONFERENCE PROCEEDINGS, VOLS 1-3: TECHNOLOGY IN MOTION, 1997, : 989 - 993
  • [3] Efficient ray-tracing methods for propagation prediction for indoor wireless communications
    Ji, Z
    Li, BH
    Wang, HX
    Chen, HY
    Sarkar, TK
    IEEE ANTENNAS AND PROPAGATION MAGAZINE, 2001, 43 (02) : 41 - 49
  • [4] Characteristics of the 60 GHz Indoor Wireless Propagation Based on Ray Tracing with Human Body Movement
    Zhao Junhui
    Liu Xu
    2014 9TH INTERNATIONAL CONFERENCE ON COMMUNICATIONS AND NETWORKING IN CHINA (CHINACOM), 2014, : 85 - 89
  • [5] 40 GHz Indoor Propagation Modelling Based on Ray-tracing Simulation and Measurement
    Shen, Yuyan
    Shao, Yu
    Liao, Xi
    Wang, Yang
    Zhang, Jie
    2020 IEEE INTERNATIONAL SYMPOSIUM ON ANTENNAS AND PROPAGATION AND NORTH AMERICAN RADIO SCIENCE MEETING, 2020, : 1279 - 1280
  • [6] Characterization of angle of arrival based on ray-tracing for an indoor wireless communications environment
    Yun, ZQ
    Iskander, MF
    2005 IEEE/ACES INTERNATIONAL CONFERENCE ON WIRELESS COMMUNICATIONS AND APPLIED COMPUTATIONAL ELECTROMAGNETICS, 2005, : 736 - 739
  • [7] Ray-Tracing Analysis of 60 GHz Band Propagation in Vehicle
    Matsui, Kensuke
    Yamakawa, Satoshi
    Kaneko, Yuya
    Kim, Minseok
    Kunitachi, Tadahide
    2020 INTERNATIONAL SYMPOSIUM ON ANTENNAS AND PROPAGATION (ISAP), 2021, : 313 - 314
  • [8] Efficient ray-tracing method for indoor propagation prediction
    Alves, FA
    de Albuquerque, MRML
    da Silva, SG
    d'Assunçao, AG
    2005 SBMO/IEEE MTT-S INTERNATIONAL MICROWAVE AND OPTOELECTRONICS CONFERENCE (IMOC), 2005, : 433 - 436
  • [9] Matrix based ray-tracing model for indoor propagation
    Zrno, D
    Simunic, D
    ICECOM 2003, CONFERENCE PROCEEDINGS, 2003, : 221 - 224
  • [10] A ray-tracing method for modeling indoor wave propagation and penetration
    Yang, CF
    Wu, BC
    Ko, CJ
    IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, 1998, 46 (06) : 907 - 919
12345