Near-Ground Propagation Channel Modeling and Analysis in Underground Mining Environment at 2.4 GHz

IF 3.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Open Journal of Antennas and Propagation Pub Date : 2025-01-08 DOI:10.1109/OJAP.2025.3527334

Isam Eddine Lamri;Mourad Nedil;Mohamed Nasr Eddine Temmar;Nahi Kandil

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Abstract

This paper presents a detailed measurement and performance analysis of near-ground propagation channels in an underground mine for both Line-of-Sight (LOS) and Non-Line-of-Sight (NLOS) scenarios. The analysis is derived from channel measurements conducted at a frequency of 2.4 GHz with a bandwidth of 200 MHz, utilizing four different combinations of transmitter-receiver (Tx-Rx) antenna heights ranging from 10 cm to 120 cm. Key channel characteristics such as large-scale path loss, time dispersion, and coherence bandwidth are reported and evaluated. The study suggests that a multi-slope (four-slope) path loss model is more effective in predicting path loss across various propagation segments in the mining environment. The path loss coefficient (n) and shadowing variance

$(\sigma)$

show significant sensitivity to both the Tx-Rx distance and the heights of the Tx-Rx antennas, while the root mean square delay spread

$(\tau _{\mathrm { rms}})$

and coherence bandwidth (BC) are less affected by these variables. Moreover, distinct path loss patterns are observed for each combination of Tx-Rx antenna heights, resulting in varying signal attenuation levels. The identification of an optimal height for minimizing signal loss is thus required. These observations provide valuable and crucial insights into the near-ground propagation characteristics within the intricate and scattering-rich conditions of underground mines.

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2.4 GHz 地下采矿环境中的近地传播信道建模与分析

本文对地下矿井近地传播信道在视距（LOS）和非视距（NLOS）情况下的性能进行了详细的测量和分析。该分析来自于在2.4 GHz频率下进行的信道测量，带宽为200 MHz，利用四种不同的发射器-接收器（Tx-Rx）天线组合，高度从10厘米到120厘米。关键信道特性，如大规模路径损耗，时间色散和相干带宽的报告和评估。研究表明，多坡（四坡）路径损失模型能够更有效地预测采矿环境中不同传播段的路径损失。路径损耗系数(n)和阴影方差（$(\sigma)$）对Tx-Rx距离和Tx-Rx天线高度都有显著的敏感性，而均方根延迟扩展$(\tau _{\mathrm { rms}})$和相干带宽（BC）受这些变量的影响较小。此外，对于Tx-Rx天线高度的每种组合，可以观察到不同的路径损耗模式，从而导致不同的信号衰减水平。因此，需要确定使信号损失最小化的最佳高度。这些观测结果为研究地下矿山复杂且多散射条件下的近地传播特性提供了有价值且至关重要的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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