共查询到19条相似文献,搜索用时 156 毫秒
1.
研究了在高空电离层中运动的带电荷的卫星受电感应阻力后对轨道根数产生的摄动影响。研究结果表明 ,电感应阻力对带电卫星的轨道半长轴、轨道偏心率、近地点赤经、历元平赤经均有周期摄动影响 ,但除对半长轴有长期摄动效应外对其它轨道根数均无长期摄动。轨道倾角和升交点赤经不受摄动影响。文中以飞行在高度 1 50 0km的电离层中的导体卫星作为算例。计算结果显示 :带电导体卫星在高空电离层中带有一定电量时电感应阻力对轨道半长轴的缩短产生显著效应 相似文献
2.
在电离中电感应阻力对带电卫星轨道根数的摄动影响 总被引:2,自引:0,他引:2
研究了在高空电离层中运动的带电荷的卫星受电感应阻力后对轨道根数产生的摄动影响。研究结果表明,电感应阻力对带电卫星的轨道半长轴、轨道偏心率、近地点赤经、历元平赤经均有周期摄动影响,但除对半生长轴有长期摄动效应外对其它轨道根数均无长期摄动。轨道倾角和升交点赤经不受摄动影响。文中以飞行在高度1500km的电离层中的导体卫星作为算例。计算结果显示:带电导体卫星在高空电离层中带有一定电量时电感应阻力对轨道半长轴的缩短产生显著效应。 相似文献
3.
研究了地球磁场对带电的非赤道卫星的轨道根数的摄动影响。理论结果表明,地球磁场对带电卫星的轨道半长轴没有摄动影响,既无周期摄动,也无长期摄动,但对轨道偏心率、轨道倾角、升交点赤经、近地点经度和历元平近点角均有周期摄动,且对升交点和近地点经度还有长期摄动效应。通过算例表明,当卫星带有大量电荷时,地球磁场对卫星轨道的摄动影响必须加以考虑。 相似文献
4.
地球磁场对带电人造卫星轨道根数的摄动影响 总被引:2,自引:0,他引:2
研究了地球磁场对带电的非赤道卫星的轨道根数的摄动影响,理论结果表明,地球磁场对带电卫星的轨道半长轴没有摄动影响,既无周期摄动,也无长期摄动,但对轨道偏心率、轨道倾角、升交点赤经、近地点经度和历元平近点角均有周期摄动,且对升交点和近地点经度还有长期摄动效应,通过算例表明,当卫星带有大量电菏时,地球磁场对卫星轨道的摄动影响必须加以考虑。 相似文献
5.
本文提出一种近地卫星联合摄动的计算方法,给出近地卫星轨道在地球形状摄动和大气阻力摄动同量级时的计算公式。它适用于近地点地面高度在160公里≤z_0≤250公里,轨道偏心率在0≤e≤0.01的近地卫星。 相似文献
6.
中心体自转对天体轨道要素变化的后牛顿效应 总被引:2,自引:1,他引:1
本文给出了在三种引力理论为中心自转对天体轨道要素变化产生的后牛顿摄动效应的研究结果。研究结果表明:六个轨道要素除长钾不受摄动影响外其它五个要素均有周期摄动,特别升交点经度和近星点经度还有长期摄动效应。最后将文中的理论结论同前人的工作做了比较还应用于行星自转对卫星轨道要素变化的摄动效应计算上。作者在文[1]中研究了天体轨道要素变化的后牛顿效应,但在该文中并没有考虑中心体自转的影响。本文研究了三种引力理论(Einstein,Brans-Dick和Nordtvedt)中的这方面效应,并给出理论和数值的研究结果。 相似文献
7.
本文从阻力系数的理论计算、风洞实验和卫星轨道资料的反测结果,得出卫星在自由分子流和过渡流区域运动时,阻力系数的变化趋势,并给出适合计算卫星大气阻力摄动的阻力系数公式。 相似文献
8.
在对卫星所受的非保守摄动力研究中,对太阳辐射压摄动建模的研究发展迅速,而对地球辐射压摄动的研究相对缺乏,特别是其对中高轨卫星轨道影响的研究。在高精度人造卫星轨道确定中,地球辐射压摄动对于具有大面质比的导航卫星的影响越来越不可忽略。针对中国北斗导航卫星,基于地球辐射压的原理和影响机制,探讨了地球辐射压摄动建模的方法。针对北斗导航系统特点,利用地球表层的反照率和红外发射率的分布格网数据,建立了精确的地球辐射压模型,并利用全球MGEX站观测数据和中国区域监测站数据,进行了对北斗卫星引入地球辐射压模型的验证试验,分析了其定轨精度,检验了模型的正确性和可靠性。试验表明,对北斗卫星来说,在加入地球辐射压模型ERPM2(Earth radiation pressure model 2)后,轨道精度比不加入地球辐射压模型提高约4 mm;加入ERPM1模型则相应提高约2 mm。对部分卫星,加入地球辐射压模型后,其轨道精度修正量可达5~10 mm。通过卫星激光测距(satellite laser ranging,SLR)检核发现,加入ERPM2模型后,北斗中轨道地球卫星正常姿态时的轨道径向精度提高3.1 cm,GPS 036卫星轨道径向精度改善0.8~1.4 cm。因此,地球辐射压摄动模型在北斗导航卫星高精度轨道确定研究中具有一定的意义。 相似文献
9.
10.
本文选择1976年10月到1977年7月期间,全球对卫星STARLETTE激光测距的连续300天的观测资料,分析了海潮对该卫星轨道的摄动。1.在力学模型计及地球形状、大气阻力、日月引力、太阳辐射压和固体潮的摄动情形下,应用最大熵功率谱和周期图解法分析了所得STARLETTE的轨道倾角的残差。从中可明显地看出,海潮的4个主要分潮波K_1、P_1、K_2和S_2所产生的长周期(长于20天)摄动。2.以计及上述所有摄动并还包括海潮摄动在内的力学模型为基础产生模拟资料(即参考轨迹),然后应用计及上述所有摄动但海潮摄动却除外的力学模型数值积分所得的轨迹去拟合这些模拟资料的方法,估计了海潮对STARLETTE在5天弧段内的位置影响的数量级。 相似文献
11.
Lin-Sen Li 《Journal of Astrophysics and Astronomy》2014,35(2):189-200
The influence of the gravitational radiation damping on the evolution of the orbital elements of compact binary stars is examined by using the method of perturbation. The perturbation equations with the true anomaly as an independent variable are given. This effect results in both the secular and periodic variation of the semi-major axis, the eccentricity, the mean longitude at the epoch and the mean longitude. However, the longitude of periastron exhibits no secular variation, but only periodic variation. The effect of secular variation of the orbit would lead to collapse of the system of binary stars. The deduced formulae are applied to the calculation of secular variation of the orbital elements for three compact binary stars: PSR19 13 + 16, PSR J0737-3039 and M33X-7. The results obtained are discussed. 相似文献
12.
本文利用天体力学中的摄动理论和天体物理学中的气体星多方模型理论研究了太阳多方模型对行星轨道要素变化的长期摄动影响。文中给出了太阳日多方指数n=3的模型由于自转、扁度和内部密度分布等因素对行星轨道要素变化的长期摄动效应的理论结果。研究结果表明:行星轨道要素除长轴、偏心率和轨道倾角不受长期摄动外升交点经度、近日点经度以及平近点角均受长期摄动的影响。最后利用理论结果对行星轨道要素的长期投动效应做了数值计算,数值结果在表1中给出。 相似文献
13.
The first aim of the present work is to compute a more accurate and recent model for the Earth’s magnetic field. The second
aim is to determine the effects of the Earth’s magnetic field on the motion of a charged artificial satellite to evaluate
the variations of the orbital elements of the satellite due to these effects. The magnetic field and its variation with time
have been studied at different heights, longitudes and latitudes. The geomagnetic field is considered as a multiple potential
field and the electrical charge of the satellite is assumed to be constant. A new computer code has been constructed to follow
the components of the magnetic field in spherical harmonic models. The Gauss equations are solved numerically. The results
concentrate on the computation of the numerical values of orbital perturbation for the case of a low Earth satellite. RS-1
satellite and space craft gravity probe B (GPB) are chosen as cases of studies for a detailed numerical analysis. 相似文献
14.
David Vokrouhlický 《Celestial Mechanics and Dynamical Astronomy》1989,46(1):85-104
The orbital effects of the Lorentz force on the motion of an electrically charged artificial satellite moving in the Earth's
magnetic field are determined. The geomagnetic field is considered as a multipole potential field and the satellite electrical
charge is supposed to be constant. The relativistic perturbations of the main geomagnetic field are discussed briefly. The
results are concentrated on the determination of the secular changes, and numerical values are computed for the case of the
LAGEOS satellite. The results are discussed in the context of a possible detection of the Lense-Thirring effect analyzing
the orbital perturbations of the LAGEOS and LAGEOS X satellites. 相似文献
15.
16.
David Parry Rubincam 《Celestial Mechanics and Dynamical Astronomy》1982,26(4):361-382
The semimajor axis of the Lageos satellite's orbit is decreasing secularly at the rate of 1.1 mm day–1. Ten possible mechanisms are investigated to discover which one (s), if any, might be causing the orbit to decay. Six of the mechanisms, resonance with the Earth's gravitational field, gravitational radiation, the Poynting-Robertson effect, transfer of spin angular momentum to the orbital angular momentum, drag from near-earth dust, and atmospheric drag by neutral hydrogen are ruled out because they are too small or require unacceptable assumptions to account for the observed rate of decay. Three other mechanisms, the Yarkovsky effect, the Schach effect, and terrestrial radiation pressure give perturbations whose characteristic signatures do not agree with the observed secular decrease (terrestrial radiation pressure appears to be too small in any case); hence they are also ruled out. Charged particle drag with the ions at Lageos's altitude is probably the principal cause of the orbital decay. An estimate of charged particle drag based upon laboratory experiments and satellite measurements of ion number densities accounts for 60 percent of the observed rate of decrease in the semimajor axis, assuming a satellite potential of –1V. This figure is in good agreement with other estimates based on charge drag theory. A satellite potential of –1.5V will explain the entire decay rate. Atmospheric drag from neutral hydrogen appears to be the next largest effect, explaining about 10 percent of the observed orbital decay rate. 相似文献
17.
Fabienne Delhaise 《Celestial Mechanics and Dynamical Astronomy》1991,52(1):85-103
A development of an analytical solution for the motion of an artificial Earth satellite subject to the combined effects of Earth gravity and air drag is presented. The atmospheric model takes into account a linear variation of the density scale height with altitude, the rotation and the oblateness of the atmosphere. The perturbation theory is based upon Lie transforms. The secular and long-periodic terms as well as the short-periodic effects are included in the theory which is valid for small to moderate eccentricities and for all values of the inclination.Belgian National Fund for Scientific Research 相似文献
18.
We investigated the motion of the Earth's artificial satellite Interball‐1 by using a method suitable for the computation of large eccentricity orbits. Though the measured and the computed orbital elements differ from each other within the measured error bound, we found a slight tendency for secular decreasing in the semi‐major axis, caused probably by electromagnetic drag. We analysed the dominant role of the Moon in the variations of the orbital eccentricity, leading to zero perigee height and the end of the lifetime of the satellite. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
19.
Hiroshi Kinoshita 《Celestial Mechanics and Dynamical Astronomy》1993,57(1-2):359-368
At the present state the rotational axes of Uranus and Pluto are nearly perpendicular to their orbital planes and each satellite moves in the vicinity of the equatorial plane of its mother planet. We assume that in the past a planet's equatorial plane was nearly coincident with its orbital plane and then the inclination of the equatorial plane with respect to the orbital plane began to increase secularly. Here we discuss whether a satellite that moves in its mother's equatorial plane continues to move in the equatorial plane or not. When the direct solar perturbation is neglected, the satellite continues to stay in the equatorial plane under the condition that the secular rate of change of the obliquity is slower than the precessional speed of the satellite orbital plane with respect to the equator. 相似文献