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Jeom-Hun Lee,Seung-hyeub Oh 한국항공우주학회 2004 International Journal of Aeronautical and Space Sc Vol.5 No.2
This paper describes the antenna analysis of the multi-beam for communication satellite. The design core parameters of the antenna system are optimal antenna diameter, feed horn type and horn size, F/D, and the coordinate of offset horns. The paper deals with the method to determine design core parameters of optimal antenna diameter, feed horn type and horn size. F/D. and the coordinate of offset horns, and the performances of design result
Design of the COMS Satellite Ground Control System
Lee, Byoung-Sun,Jung, Won-Chan,Lee, Sang-Uk,Lee, Jeom-Hun,Kim, Jae-Hoon 통신위성우주산업연구회 2006 Joint Conference on Satellite Communications Vol.2006 No.-
복합임무를 갖는 정지궤도 위성인 통신해양기상위성은 항공우주연구원, 전자통신연구원, 해양연구원, 기상청과 국내외 기업이 공동으로 개발을 수행하고 있다. 통신해양기상위성의 주 계약자는 EADS Astrium이며 전자통신연구원은 정보통신부의 재원으로 Ka 대역 통신탑재체와 지상 관제시스템을 개발하고 있다. 통신해양기상위성의 관제시스템은 궤도상의 위성을 감시하고 제어할 수 있는 유일한 시스템이다. 통신해양기상위성에 탑재되어 있는 세개의 탑재체와 위성체 버스에 대한 임무운용을 위해서 지상 관제시스템은 원격측정 신호의 수신과 처리, 위성의 추적과 거리측정, 원격명령의 생성 및 송출, 위성의 임무계획, 비행역학데이터 처리, 그리고 위성 시뮬레이션을 수행한다. 이와 같은 기능을 적절히 할당해서 통신해양기상위성의 관제시스템은 TTC, 실시간운영, 임무계획, 비행역학, 그리고 위성시뮬레이터와 같은 5개의 서브시스템으로 구성되었다. 본 논문에서는 통신해양기상위성 관제시스템을 구성하는 5 개의 서브시스템에 대한 기능 설계와 인터페이스를 기술한다. As a multi-mission GEO satellite, COMS system is being developed jointly by KARl, ETRI, KORDI, KMA, and industries from both abroad and domestic. EADS ASTRIUM is the prime contractor for manufacturing the COMS. ETRI is developing the COMS Ka-band payload and SGCS with the fund from MIC. COMS Satellite Ground Control System (SGCS) will be the only system for monitor and control of the satellite in orbit. In order to fulfill the mission operations of the three payloads and spacecraft bus, COMS SGCS performs telemetry reception and processing, satellite tracking and ranging, command generation and transmission, satellite mission planning, flight dynamics operations, and satellite simulation. By the proper functional allocations, COMS SGCS is divided into five subsystems such as TTC, ROS, MPS, FDS, and CSS. In this paper, functional design of the COMS SGCS is described as five subsystems and the interfaces among the subsystems.
Antenna Alignment Method for Low Angular Error of 3-axis Tracking System
Lee, Jeom Hun,Kim, Young Wan,Kim, Nae Soo,Lee, Ho Jin The Korean Society for Aeronautical and Space Scie 2001 International Journal of Aeronautical and Space Sc Vol. No.
This paper describes the antenna alignment method of the tracking antenna system for LEO satellite. The purpose of the antenna alignment is to reduce the angular error due to the structural alignment and the monopulse null point alignment error. The angular error of 3 axis tracking system is the key performance parameter that should be minimized to accurately track satellite movement. The angular error is analyzed via a simulation and boresight measurement. The simulation is done with formulas to be derived from vector concept for 3-axis movement. The formulas of the structural alignment are verified by comparing the formula result with the field measurement. Also, the angular error due to monopulse null shift is obtained via boresight measurement. Based on the analyzed and measured results, the antenna alignment was performed and was verified via tracking test of operating LEO satellite.
Lee, Jeom-Hun,Oh, Seung-Hyeub The Korean Society for Aeronautical and Space Scie 2004 International Journal of Aeronautical and Space Sc Vol.5 No.2
This paper describes the antenna analysis of the multi-beam for communicationsatellite. The design core parameters of the antenna system are optimal antennadiameter, feed horn type and hom size, F/D, and the coordinate of offset horns. Thepaper deals with the method to determine design core parameters of optimal antennadiameter, feed horn type and horn size. F/D, and the coordinate of offset horns, andthe performances of design result.