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Orbit Determination (Seeber, 3.3), sat05_42.ppt,

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1 Orbit Determination (Seeber, 3.3), sat05_42.ppt, 2005-11-22
Find state-vector (position and velocity) at time t=t0 Determine orbit from all types of observations Gives Kepler elements and time derivatives from J2=-C20 (2) –Short arcs very precise (3.3.1) -Long arcs for ”prediction” (3.3.2)

2 Kepler orbits (Kaula and Seeber)

3 Linearisation using Kepler elem.
Start values: a,e,f+ω,Ω,i .

4 General orbit determination (Seeber, 3.3.2)
Analytic orbit determination uses knowledge of Cij to compute More difficult for drag, solar pressure etc. Start values describe reference Kepler orbit: Truncated series are used, so limited precision. 500 terms give 1 m.

5 Numerical integration (Seeber, 3.3.2.2)
Cartesian coordinates not optimal. Spherical better (r,θ,Φ).Steps of numerical integration smaller. Cowell (1910) method. Encke, 1857: use Kepler orbit as reference: Osculating orbit.

6 Enckes method .

7 Orbit determination using GPS
POD= Precise Orbit Determination Dynamic: (a) orbit determined using integration of qeuations of motion (b) adjusted to GPS measurements Kinematic: From GPS measurements Reduced Dynamic, like Dynamic byt GPS data adjusted using Kalman filter GPS Dynamic

8 Orbit representation (1) Kepler elements and linear pertubations Transit (Doppler) Corrections: every minute, along track, cross-track and radially GPS: Every hour: (2) Polynomial representation: (only 1 – 2 revolutions

9 Chebychev:

10 Simplified short-arc repr.

11 How frequently must the satellite cross Equator ?
Orbit selection How frequently must the satellite cross Equator ? Where is the ground-track ? (spherical earth) . δ α

12 Sun-syncroneous, or geostationary
.

13 Bringing the satellite in orbit: Transfer orbit
.

14 Transfer orbit, velocity requirement

15 Lagrange points Stable points in Sun, Earth, Moon system: .Figure 3.29

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