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Empirical millimeter‐wave wideband propagation characteristics of high‐speed train environments
Owing to the difficulties associated with conducting millimeter‐wave (mmWave) field measurements, especially in high‐speed train (HST) environments, most propagation channels for mmWave HST have been studied using methods based on simulation rather than measurement. In this study, considering a line...
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Published in: | ETRI journal 2021, 43(3), , pp.377-388 |
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Main Authors: | , , , , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
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Summary: | Owing to the difficulties associated with conducting millimeter‐wave (mmWave) field measurements, especially in high‐speed train (HST) environments, most propagation channels for mmWave HST have been studied using methods based on simulation rather than measurement. In this study, considering a linear cell layout in which base stations are installed along a railway, measurements were performed at 28 GHz with a speed up to 170 km/h in two prevalent HST scenarios: viaduct and tunnel scenarios. By observing the channel impulse responses, we could identify single‐ and double‐bounced multipath components (MPCs) caused by railway static structures such as overhead line equipment. These MPCs affect the delay spread and Doppler characteristics significantly. Moreover, we observed distinct path loss behaviors for the two scenarios, although both are considered line‐of‐sight (LoS) scenarios. In the tunnel scenario, the path loss exponent (PLE) is 1.3 owing to the waveguide effect, which indicates that the path loss is almost constant with respect to distance. However, the LoS PLE in the viaduct scenario is 2.46, which is slightly higher than the free‐space loss. |
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ISSN: | 1225-6463 2233-7326 |
DOI: | 10.4218/etrij.2020-0239 |