THE JOURNAL OF KOREAN INSTITUTE OF ELECTROMAGNETIC ENGINEERING AND SCIENCE. 2019 Mar.; 30(3), 223 228. http://dx.doi.org/10.5515/kjkiees.2019.30.3.223 ISSN 1226-3133 (Print) ISSN 2288-226X (Online) Analysis of Abnormal Path Loss in Jeju Coastal Area Using Duct Map 왕성식 임태흥 정영준 고민호 박용배 추호성 Sungsik Wang Tae-Heung Lim Young Jun Chong* Minho Go** Yong Bae Park*** Hosung Choo 요약 -,.,,. 2018 5 2,,. 167.7 db, 192.3 db 164.4 db, 194.9 db. Abstract This study analyzes the propagation of the path losses between Jeju-do and Jin-do transceivers located in the coastal areas of Korea using the Advanced Refractive Prediction System(AREPS) simulation software based on the actual coastal weather database. The simulated data is used to construct a duct map according to the altitude and thickness of the trap. The duct map is then divided into several regions depending on the altitude parameters of Tx and Rx, which can be used to effectively estimate the abnormal wave propagation characteristics due to duct occurrence in the Jeju-do coastal area. To validate the proposed duct map, two representative atmospheric index samples of the weather database in May 2018 are selected, and the simulated path losses using these atmospheric indices are compared with the measured data. The simulated path losses for abnormal conditions at the Rx point at Jeju-do are 167.7 db and 192.3 db, respectively, which are in good agreement with the measured data of 164.4 db and 194.9 db, respectively. Key words: Jeju Coastal Area, Duct, Propagation Interference, Refractive Index, Trilinear Modeling. 서론 2018 ( ), (No. 2017-0-00066,.. (School of Electronic and Electrical Engineering, Hongik University) * (Electronics and Telecommunications Research Institute) ** ( )(Hanwha Systems Co., Ltd.) *** (School of Electrical and Computer Engineering, Ajou University) Manuscript received January 22, 2019 ; Revised March 12, 2019 ; Accepted March 18, 2019. (ID No. 20190122-009) Corresponding Author: Hosung Choo (e-mail: hschoo@hongik.ac.kr) c Copyright The Korean Institute of Electromagnetic Engineering and Science. All Rights Reserved. 223
THE JOURNAL OF KOREAN INSTITUTE OF ELECTROMAGNETIC ENGINEERING AND SCIENCE. vol. 30, no. 3, Mar. 2019.,, [1].,, [2].,,,, [3].,,,, [4]. (path loss), (propagation factor)., 1 km [5]. [6].,,,, [7].,,,., trilinear model., AREPS(Advanced Refractive Effects Prediction System).. 2018 2018 5 2 DTED(Digital Terrain Elevation Data),.. 본론,. [4],,.,. 1 trilinear model. h 1 그림 1. trilinear model Fig. 1. Duct trilinear modeling for the conventional modified refractive indices. 224
, h 2. trilinear,.. 2. h 1 h 2 h rx, h tx h 1, h 2.. 3. -, 71 m, 479 m. 132 km, 2.58 GHz AREPS. (Rx in duct), (Tx in duct). 2018 5, 71 %, 21 % 그림 3. - Fig. 3. The duct map including the Jeju-Jindo coastal area.,,, 2018 5 9 (Case A) 2018 5 16 (Case B). 4 Case A Case B. Case A, 260 m, Case B. 5 6 Case A Case B 그림 2. Fig. 2. The proposed duct map for the various duct types. 그림 4. Case A Case B Fig. 4. The modified refractive indices for Case A and Case B. 225
THE JOURNAL OF KOREAN INSTITUTE OF ELECTROMAGNETIC ENGINEERING AND SCIENCE. vol. 30, no. 3, Mar. 2019. AREPS. Case A,,. Case B. 7 2018 5 4 20 - AREPS -. Case A 그림 7. Fig. 7. The comparison between the measured and simulated results for the path losses. Case B 167.7 db, 192.3 db 164.4 db, 194.9 db.. 결론 그림 5. Case A Fig. 5. The simulated result of the path loss for Case A.,.. 2018 2018 5 2,. 167.7 db, 192.3 db 164.4 db, 194.9 db. References 그림 6. Case B Fig. 6. The simulated result of the path loss for Case B. [1] J. Y. Kim, D. W. Chun, C. J. Ryu, and H. Y. Lee, "Optimization methodology of multiple air hole effects in substrate integrated waveguide applications," Journal of Electromagnetic Engineering and Science, vol. 18, no. 3, pp. 160-168, Jul. 2018. [2] H. G. Jeon, S. M. Shin, T. Hwang, and C. E. Kang, "Re- 226
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