EUROFIX 導入을 위한 性能評價에 관한 硏究
DC Field | Value | Language |
---|---|---|
dc.contributor.author | 金敏禎 | - |
dc.date.accessioned | 2017-02-22T02:20:38Z | - |
dc.date.available | 2017-02-22T02:20:38Z | - |
dc.date.issued | 2002 | - |
dc.date.submitted | 2005-10-19 | - |
dc.identifier.uri | http://kmou.dcollection.net/jsp/common/DcLoOrgPer.jsp?sItemId=000002173744 | ko_KR |
dc.identifier.uri | http://repository.kmou.ac.kr/handle/2014.oak/8244 | - |
dc.description.abstract | Loran-C was born in the 1950's as a long range position system for strategic weapons such as the nuclear submarine, and was developed primarily as a military system until 1974 when it became the official maritime radio-aid-to-navigation for both the U.S. and Canada. At that time it had one or two thousand users in North America, primarily fishermen and major shipping vessels. The USSR and Eastern Block nations pursued parallel development during this period. Today there are over 1,000,000 users. Originally designed as a maritime system, widespread acceptance has been achieved with applications ranging from civil aviation and fleet management to precise time dissemination. The introduction of satellite navigational technology back in the 1970s(TRANSIT) and the 1980s(GPS) were to be the death knell for Loran-C. Experts touted the benefits of satellite technology in the press as being the only technology anyone would require. A similar argument was made that satellite communications would one day replace all landlines, cellular and wireless systems. The auther too, has been a leading company in radionavigation, particularly in Loran-C. Megapulse encourages and supports policies of provision of positioning, navigation and timing services by at least two independent and hybrid means-specifically GPS and Loran-C. Megapulse substantially disagrees with policies that result in civilian sole dependency upon GPS in safety related transportation processes, and in time synchronization applications. Today, international groups are contributing to a rebirth of Loran as a satellite augmentation adapting the EUROFIX. EUROFIX is an integrated navigation system, which combines Differential GNSS and Loran-C. The Loran-C system is used to transmit messages which contain differential corrections and integrity information for GNSS by additional modulation of the transmitted signals. Beside differential corrections the EUROFIX datalink can also carry other information, such as differential Loran-C information or "short messages" for emergency operations in Europe and the United States. The additional modulation should not degrade normal Loran-C operations. Restrictions on the allied modulation are imposed on the datalink design by the Loran-C user community. As data transmission is hindered by the aggressive Loran-C signal environment, special modulation patterns and Forward Error Correcting codes are designed to fulfill the requirements. While recognizing that Loran-C is very important as a back-up for satellite systems, the introduction of EUROFIX, which uses Loran-C system, was proposed and admitted at 9th FERNS(Far East Radio Navigation System) Meeting. But, the FERNS countries should consider whether the cost-effectiveness of the system could be improved by making use of its communication facilities to integrate more closely with satellite systems. And, the members were requested to give this proposal consideration before the 10th session of the Council. For this matter, Korea planned to demonstrate transmitting EUROFIX signals from Pohang Loran-C station (Master of 9930 Chain) during the 10th FERNS Meetings. Therefore, in this thesis, the introduction of EUROFIX is evaluated whether EUROFIX is suitable for reliable data transmission of DGPS signals to FERNS countries as well as South Korea, after demonstration of EUROFIX. The demonstration result showed satisfactory enough for introduction to the FERNS member countries. | - |
dc.description.tableofcontents | 목차 표목차 = iv 그림목차 = v Abstract = vii 제1장 서론 = 1 1.1 연구의 배경과 목적 = 1 1.2 선행연구 고찰 = 1 1.3 연구의 방법 및 논문의 구성 = 3 제2장 EUROFIX의 개요 = 5 2.1 EUROFIX의 개요 = 5 2.1.1 EUROFIX의 정의 = 5 2.1.2 개발과정 = 7 2.1.3 EUROFIX 시스템의 장점 및 단점 = 7 2.2 EUROFIX 시스템의 데이터 변조과정 = 10 2.2.1 EUROFIX의 패턴 변조 조합과정 = 10 2.2.2 순방향 에러 정정[11] = 15 2.2.3 CRC = 19 2.2.4 Reed-Solomon 코드의 인코딩 및 디코딩 = 22 2.2.5 메시지의 구조 = 26 2.2.6 DGNSS 보정코드 발생기 = 29 2.3 EUROFIX 도입시의 비용 효율성 = 30 제 3 장 RS 부호를 이용한 데이터링크의 분석 = 31 3.1 Reed-Solomon(RS) 코드[4] = 31 3.1.1 RS 부호의 부호화(Encoding) = 31 3.2 EUROFIX에서 RS Code 부호화 = 32 3.3 Euclid 알고리즘을 이용한 RS부호의 복호법 = 38 3.3.1 RS부호를 복호하기 위한 Euclid 알고리즘[19] = 38 3.3.2 Euclid 알고리즘과 변??복호법을 이용한 (14, 9) RS부호의 복호 = 46 3.4 RS 부호기 및 복호기의 실험 결과 = 52 3.4.1 RS 부호/복호기의 설계 및 구현 = 52 3.4.2 RS 부호/복호기의 시뮬레이션 결과 = 56 제 4 장 Loran-C 전파 전파의 모델링 = 61 4.1 모델링 고려사항 = 61 4.1.1 지표파 = 61 4.1.2 Loran-C 전파의 전계강도 = 62 4.2 전파전파의 모델링 = 63 4.2.1 거리변화에 따른 전계강도 예측 = 63 4.3 Loran-C 전파의 전계강도 측정 결과 및 분석 = 67 4.3.1 측정시스템 구성 및 측정방법 = 67 4.4 Loran-C 전파의 전계강도 실측 및 모델링 결과 = 71 4.4.1 해상경로 실측 및 모델링 결과 = 71 4.4.2 육상경로 실측 및 모델링 결과 = 74 4.4.3 해상 및 육상경로의 SNR 실측 결과 = 77 제 5 장 EUROFIX 모의실험 = 79 5.1 송신 시스템 구성 = 79 5.2 수신 시스템의 구성 = 82 5.3 모의 실험 결과 = 83 제6장 결론 = 84 | - |
dc.publisher | 한국해양대학교 | - |
dc.title | EUROFIX 導入을 위한 性能評價에 관한 硏究 | - |
dc.title.alternative | A Study on the Performance Evaluation for Introduction of EUROFIX. | - |
dc.type | Thesis | - |
Items in Repository are protected by copyright, with all rights reserved, unless otherwise indicated.