C band transhorizon signal characterisations in evaporation duct propagation environment over Bohai Sea of China

Evaporation duct is an anomalous mechanism of transhorizon propagation in marine and coastal regions. In order to better understand the characteristics of signal fading, a C band signal transhorizon propagation experiment was carried out with a 107 km path length over the Bohai Sea of China. Using a...

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Bibliographic Details
Published in:IET microwaves, antennas & propagation antennas & propagation, 2019-03, Vol.13 (4), p.407-413
Main Authors: Guo, Xiangming, Zhao, Dongliang, Zhang, Lijun, Wang, Hongguang, Kang, Shifeng, Lin, Leke
Format: Article
Language:English
Subjects:
air–sea temperature difference
antenna height
atmospheric electromagnetic wave propagation
Bohai Sea
C band signal transhorizon propagation experiment
C band transhorizon signal characterisations
China
direct diagnostic method
duct layer
ducting communication system
ducts
evaporation
evaporation duct height
evaporation duct propagation environment
fade slope
iron tower
meteorological and oceanographic sensors
METOC sensors
near‐neutral atmospheric conditions
oceanographic equipment
probability
probability density
radiowave propagation
Rayleigh distribution
receiver antennas
receiving antennas
relative humidity
Research Article
sensors
signal fading characteristics
signal strength distribution
stable atmospheric conditions
stronger signal strength
transmitter antennas
transmitting antennas
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Summary:Evaporation duct is an anomalous mechanism of transhorizon propagation in marine and coastal regions. In order to better understand the characteristics of signal fading, a C band signal transhorizon propagation experiment was carried out with a 107 km path length over the Bohai Sea of China. Using an iron tower with meteorological and oceanographic (METOC) sensors at multiple altitudes, a direct diagnostic method of evaporation duct is presented. The dependence of signal strength on evaporation duct height, antenna height, and METOC parameters is analysed. The experimental results indicate that the signal strength tends to be linearly dependent on the evaporation duct height when the transmitter and receiver antennas are submerged within the duct layer. Normally, the signal strength is stronger when the relative humidity is lower. Stronger signal strength tends to occur under near-neutral or stable atmospheric conditions or when the air–sea temperature difference is higher. The results indicate that the signal strength distribution of fast fading is close to Rayleigh distribution, and the probability density of fade slope is symmetric at 0 dB/s. These results have important implications for the design of ducting communications system.
ISSN:1751-8725
1751-8733
1751-8733
DOI:10.1049/iet-map.2018.5040