Title :
A novel dual-slope mm-Wave channel model based on 3D ray-tracing in urban environments
Author :
Youngbin Chang ; Sangkyu Baek ; Sooyoung Hur ; Youngjoong Mok ; YoungJu Lee
Author_Institution :
DMC R&D Center, Samsung Electron., Co., Ltd., Suwon, South Korea
Abstract :
To solve mobile traffic crunch, the usage of enormous bandwidth in millimeter wave (mm-Wave) is under discussion. In this paper, we investigate radio channel characteristics of mm-Wave frequency in the downtown area of Ottawa using 3D ray-tracing technique. In the results, important parameters of the radio channel model, such as path loss exponent, shadow fading, delay spread and angle spread, are provided. Especially, in case of path loss model in non-line of sight, a novel dual-slope approach is proposed for two conventional deployment scenarios. Comparing to traditional single-slope path loss model, the proposed method has smaller RMS errors in terms of local mean of path loss observations. We believe that the proposed method is appropriate to evaluate performance of the mm-Wave system in dense urban environments.
Keywords :
millimetre waves; mobile radio; ray tracing; telecommunication channels; 3D ray-tracing technique; Ottawa; RMS errors; dual-slope approach; dual-slope mmwave channel model; millimeter wave; mmwave system; mobile traffic crunch; nonline of sight; path loss model; path loss observations; radio channel characteristics; radio channel model; single-slope path loss model; urban environments; Channel models; Delays; Fading; Loss measurement; Ray tracing; Receivers; Three-dimensional displays;
Conference_Titel :
Personal, Indoor, and Mobile Radio Communication (PIMRC), 2014 IEEE 25th Annual International Symposium on
DOI :
10.1109/PIMRC.2014.7136164
