• 한국측량학회지
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• 제27권2호
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• pp.129-138
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• 2009

달 중력장은 달의 내부구조와 이분성 및 마그마 바다의 분화 진화과정을 이해하고, 더 나아가 달의 기원과 진화를 규명하기 위한 중요한 자료이다. 본 연구에서는 달 탐사의 역사와 달의 중력장 탐지 및 중력장모델의 발전과정을 고찰하였으며, 최근에 임무를 종료한 일본의 SELENE위성의 관측방식을 소개하고, SELENE위성의 궤도추적자료를 처리하여 개발된 달 중력장모델 SGM90d(SELENE Gravity Model)를 이용해 달 전체의 중력이상을 결정하였으며, 기존의 달 중력장 모델인 LP165P모델과 비교분석을 수행하였다. SGM90d를 분석해 본 결과, SELENE위성의 4중 도플러 관측방식은 달 뒷면의 중력장 직접 관측에 매우 효과적이었으며, 달 뒷면 중력장의 최초 결정은 달의 메스콘과 같은 중력이상의 상세한 분포를 확인하고 달의 이분성을 이해하는데 큰 도움이 되었다.

• Journal of Astronomy and Space Sciences
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• 제27권2호
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• pp.97-106
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• 2010

To prepare for a Korean lunar orbiter mission, a precise lunar orbit propagator; Yonsei precise lunar orbit propagator (YSPLOP) is developed. In the propagator, accelerations due to the Moon's non-spherical gravity, the point masses of the Earth, Moon, Sun, Mars, Jupiter and also, solar radiation pressures can be included. The developed propagator's performance is validated and propagation errors between YSPOLP and STK/Astrogator are found to have about maximum 4-m, in along-track direction during 30 days (Earth's time) of propagation. Also, it is found that the lifetime of a lunar polar orbiter is strongly affected by the different degrees and orders of the lunar gravity model, by a third body's gravitational attractions (especially the Earth), and by the different orbital inclinations. The reliable lifetime of circular lunar polar orbiter at about 100 km altitude is estimated to have about 160 days (Earth's time). However, to estimate the reasonable lifetime of circular lunar polar orbiter at about 100 km altitude, it is strongly recommended to consider at least $50\;{\times}\;50$ degrees and orders of the lunar gravity field. The results provided in this paper are expected to make further progress in the design fields of Korea's lunar orbiter missions.

• Journal of Astronomy and Space Sciences
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• 제37권1호
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• pp.1-9
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• 2020

Frozen orbit is an attractive option for orbital design owing to its characteristics (its argument of pericenter and eccentricity are kept constant on an average). Solar sails are attractive solutions for massive and expensive missions. However, the solar radiation pressure effect represents an additional force on the solar sail that may greatly affect its orbital behavior in the long run. Thus, this force must be included as a perturbation force in the dynamical model for more accuracy. This study shows the calculations of initial conditions for a lunar solar sail frozen orbit. The disturbing function of the problem was developed to include the lunar gravitational field that is characterized by uneven mass distribution, third body perturbation, and the effect of solar radiation. An averaging technique was used to reduce the dynamical problem to a long period system. Lagrange planetary equations were utilized to formulate the rate of change of the argument of pericenter and eccentricity. Using the reduced system, frozen orbits for the Moon sail orbiter were constructed. The resulting frozen orbits are shown by two 3Dsurface (semi-major, eccentricity, inclination) figures. To simplify the analysis, we showed inclination-eccentricity contours for different values of semi-major axis, argument of pericenter, and values of sail lightness number.