扁率

The accuracy of the measurements of the geocentric vector plays a key role in satellite navigation,but it is affected by the earth oblateness.

卫星利用紫外敏感器和星敏感器进行自主导航的方法中地心矢量的测量精度是影响导航精度的重要因素之一，而地心矢量的测量又受到地球扁率的影响。

In this chapter, based on six integral of hyperbolic motion, we gave the analytical solution for the satellite's motion perturbed by the oblateness of the primary and numerical examples were also given to prove the accuracy.

文中给出了无摄情况下双曲线轨道的基本关系式，受摄情况下双曲线运动对应的摄动运动方程，以及在目标天体扁率摄动影响下双曲线轨道变化的分析解。

Its values, determined from different kinds of observations and models are reviewed. Moreover, its relation to precession and its effect on nutation computation are discussed.

介绍了由不同的观测方法和模型给出的地球动力学扁率值，并讨论了它与岁差的关系和对章动计算的影响。

The increasing accuracy of modern observations requires to take into account its influence on the nutation amplitudes at the level of a few microarcseconds.

随着观测和计算精度的提高，地球动力学扁率值的不一致将影响章动振幅的计算。

In order to improve the amplitudes of the rigid Earth nutation series, it become necessary to revise the IAU 1976 value of the general precession in longitude.

非刚体地球章动的转换函数中所采用的简正模频率和常数都直接或间接地依赖地球动力学扁率值。

The interpretation and selection for different values of the Earth dynamical flattening will have to be approached in the construction of the future nutation theory of a non-rigid Earth.

在建立非刚体地球章动理论中，如何解释地球动力学扁率值的差异，如何选取地球动力学扁率值，还有待进一步的研究。

The oblateness tends to decrease since the formation of the earth.

地球的扁率自形成以来总体趋势在减小。

The change of oblateness in individual geological periods is needed to determine the change of the earth's shape.

为了确定地球形状的变化需要了解各个地质历史时期其扁率的变化。

The earth is a ellipsoid consisted of both solid and liquid, so the true value in each geological time should be less than the calculated oblateness.

地球是个固液混合的椭球体，在各个地质历史时期中地球扁率的真实值应该小于计算的扁率值。

We 〓 braking inaex also as the function of only oblateness.

另外，我们也可导出脉冲星制动系数亦完全决定于扁率，当扁率趋向于零时，制动系数趋向于3，而这正是标准模型下所具有的制动系数。

Obligate anaerobe：专性嫌气微生物

oblateness of the earth 地球扁率 | obligate anaerobe 专性嫌气微生物 | oblique aerial photography 倾斜航空摄影

oblateness in circular orbit：圆形轨道扁率

扁率 oblateness | 圆形轨道扁率 oblateness in circular orbit | 地球扁率 oblateness of the earth

oblateness：扁率

oblate spherold 扁球体 | oblateness 扁率 | obligatory point 约束体

oblateness：扁率;扁圆形

oblate 扁圆形的 | oblateness 扁率;扁圆形 | Oblatinella 扁球粉属

polar oblateness：极向扁率

polar night 极夜 | polar oblateness 极向扁率 | polar path [地]极轨线

dynamical oblateness：动态扁率

dynamical halo model 动态晕模型(宇宙线) | dynamical oblateness 动态扁率 | dynamical parallax 动力视差

earth oblateness：地球扁率

工程机械:Earth-moving machinery | 地球扁率:Earth oblateness | 土石坝:Earth and rockfill dams

planetary oblateness：行星扁率

planetary impact - 行星碰撞 | planetary oblateness - 行星扁率 | planetology - 行星学

dynamic oblateness：力学扁率

dynamic noise suppressor 动态噪声抑制器,动噪声抑制器 | dynamic oblateness 力学扁率 | dynamic oceanography 动力海洋学

flattening：扁率

后者面积广大而月海(Mare)区内反照率为 5%.这现象使人联想到它具有小行星的构造,因有7800万公里).次近的是阿波罗(Apollo)及亚当尼斯(Adonis),都是大而又扁率(flattening)特小,其他类地行星也同样由于这种原因而无光月(朔)开始到第二次新月(朔),