• Journal of Astronomy and Space Sciences
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• 제10권2호
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• pp.189-196
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• 1993

상해 천문대 Sheshan 관측소의 레이저 위성거리 측정기기를 이용하여 LAGEOS II위성에 대한 레이저 관측을 수행하여 총 1,838점을 얻었다. 관측된 거리 자료를 지상목표물 관측에 의한 관측기기 지연보정, 대기굴절 보정, 위성의 질량중심거리 보정, 일반 상대론적 보정과 지구 고형체 조석, 극 조석, 대양 조석을 포함한 조석보정을 통해 지연값을 결정하였는데 거리보정의 평균값은 19.12m이다. 결국 다항식 fitting 과 최소 자승법을 이용하여 계산한 관측값의 내부 정밀도 평균은 $\pm$7cm이다. 잡음을 제거하고 보정된 최종 관측점은 1,340점으로 관측점 총수에 대한 잡음비율은 27.1%이다.

• Bulletin of the Korean Chemical Society
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• 제35권5호
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• pp.1397-1402
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• 2014

The complete active space self-consist field method followed by the internally contracted multireference configuration interaction method has been used to compute the potential energy curves of $X^2\prod_g$, $a^4\prod_u$, $A^2\prod_u$, $b^4\sum_{g}^{-}$, and $B^2\sum_{g}^{-}$ states of $S{_2}^+$ cation with large correlation-consistent basis sets. Utilizing the potential energy curves computed with different basis sets, the spectroscopic parameters of these states were evaluated. Finally, the transition dipole moment and the Franck-Condon factors of the transition from $A^2\prod_u$ to $X^2\prod_g$ were evaluated. The radiative lifetime of $A^2\prod_u$ is calculated to be 887 ns, which is in good agreement with experimental value of $805{\pm}10$ ns.

• Journal of Positioning, Navigation, and Timing
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• 제3권4호
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• pp.155-161
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• 2014

The purpose of this study is to develop precise point positioning (PPP) algorithms based on GLONASS code-pseudorange, verify their performance and present their utility. As the basic correction models of PPP, we applied Inter Frequency Bias (IFB), relativistic effect, satellite antenna phase center offset, and satellite orbit and satellite clock errors, ionospheric errors, and tropospheric errors that must be provided on a real-time basis. The satellite orbit and satellite clock errors provided by Information-Analytical Centre (IAC) are interpolated at each observation epoch by applying the Lagrange polynomial method and linear interpolation method. We applied Global Ionosphere Maps (GIM) provided by International GNSS Service (IGS) for ionospheric errors, and increased the positioning accuracy by applying the true value calculated with GIPSY for tropospheric errors. As a result of testing the developed GLONASS PPP algorithms for four days, the horizontal error was approximately 1.4 ~ 1.5 m and the vertical error was approximately 2.5 ~ 2.8 m, showing that the accuracy is similar to that of GPS PPP.