• Title/Summary/Keyword: Spherical Earth Reflection Model

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Measurement of UHF-Band Propagation Loss for the Long Range Maritime Communication Environment (장거리 해상 통신 환경에서의 UHF 대역 전파 손실 측정)

  • Kim Kyun-Hoi;Tak Youn-Do;Shin Seok-Hyun
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.17 no.5 s.108
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    • pp.490-499
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    • 2006
  • In this paper, we present the newly developed propagation toss model of a long range maritime communication channel, measured by a ground to air flight test, and discuss its validity compared with the predictive value based on the spherical earth reflection model. To measure the propagation loss, actual flight test was performed in the Yellow Sea and the measurement of receiving signal strength was made for overall test range. As far as the test condition is concerned, it is expected that the receiving signal strength must be interfered with the reflected wave by an island existing around the reflection point. Therefore we introduce some modifications on the conventional spherical earth reflection model by including the effect due to the reflected wave from the island. And then, we compare the path loss measured by flight test with that one analyzed by the spherical earth reflection model accounting for reflected wave of the island. As a result of the comparison, it is verified to predict the path loss accurately by the spherical earth reflection model including the effect due to the reflected wave from an island for a long range ground to air communication.

Analysis of UHF-Band Propagation Loss in Long-distance Air-to-Ground Communication Tests (UHF 대역 장거리 항공 통신 시험의 전파 손실 분석)

  • Chang, Min-soo;Kim, Kyoo-hwan;Kim, Jae-hwan;Lee, Jae-moon;Whang, Chan-ho
    • Journal of the Korea Academia-Industrial cooperation Society
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    • v.19 no.8
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    • pp.55-63
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    • 2018
  • In this paper, we measured the propagation path loss by a ground to air flight communication test at UHF band and analyzed the results. The ground receiving terminal was located at 1,100m above sea level in Cheju Island and the airborne transmit terminal flew at an altitude of 3.5km from 150 to 220km from the ground terminal. In this case, the ground terminal and the airborne terminal are on the Line of Sight. Therefore loss in this communications environment can be predicted based on Free Space Loss. However, in this test, the sea level exists between two terminals, and due to the very small angle of incidence on the reflecting surface due to the long-range communication environment, it is not possible to accurately predict the loss of free space only. Therefore, considering that there are no surrounding obstacles and that a line of sight is secured between the end of two terminals, we applied a plane earth reflection model and a spherical earth reflection model to estimate the propagation path loss and compared with the actual test results. As a result of the comparison, the predicted propagation path loss by a spherical earth reflection model were quite similar to the actual test values.

An Analysis of Radio Propagation Range of USV Communication System for Maritime Wireless Environment (해상 환경에서 무인수상정용 통신시스템의 전파 통달거리 분석)

  • Kim, Taehyeon;Park, Hyunsung;Gwak, Sangyell;Lee, Sungho;Jeon, Hoseok
    • Journal of the Korea Institute of Military Science and Technology
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    • v.21 no.6
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    • pp.799-806
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    • 2018
  • In this paper, we analyzed the communication distances in the flat and spherical earth model using the main specifications of the wireless communication device under development to be installed in the unmanned surface vehicle(USV). We installed the wireless communication device on the test ship and the actual communication test was performed in the South Sea of Korea, it compared the experimental result with the simulated results. If the installation altitude of the transmitting and receiving antennas is low, there is not the big difference between the two models. However, when the altitude of one of the two antennas is high, the spherical earth model has similar results to the experimental data. As the altitude of the antenna installation increases, fading occurs in a certain section. We expect that this fading can be overcome through antenna technologies such as space diversity.