Satellite orbit determination  

Course Contents Course contents 1 Dynamics Introduction to dynamics o Planetary Gravity field o Tides and the three-body problem o Hill radius and Roche limit o Relation to planetary sciences and astrodynamics Solving Equations of motion o reformulate orbit problem as a system of ordinary differential equations o efficiency and accuracy of numerical integration methods o implementation of numerical integration methods 2 Observations techniques and reference systems Observation techniques o Laser, Doppler and Camera observations o Refraction, Electromagnetism, radio- and optical technology o Tropospheric and ionospheric refraction o Relativity and the definition of time, o Classification of time systems (UTC, TAI, etc) o Light-time effect o Quality of clocks (Allan Variance behaviour of clocks) Reference systems o Local and global coordinate systems o Definition of geoid and reference ellipsoid, height systems o Precession and nutation, polar motion, polar wander. o Newton or Einstein, consequences for reference systems 3 Statistics Random variables, probability density functions, moments, hypothesis testing Least squares minimisation o unconstrained linear parameter estimation, o data weighting o nonlinear parameter estimation. Rank deficient equation systems o compatibility conditions o general and homogeneous solutions o constrained linear parameter estimation Mechanisation of parameter estimation algorithms o Choice of algorithms 4 Orbit determination Perturbation analysis and variational problems o state transition matrix for initial state vector problems o partial derivatives for dynamical parameters Parameter estimation o Identification of parameters o batch least squares o Kalman filter, theory and implementation 5 Applications Global Navigation Satellite Systems: o Technology and terminology, o various data processing strategies and available software o Modelling deformation of the solid Earth, o the Earths gravity field and thermospheric density Satellite laser ranging and Doppler tracking via DORIS o technology and terminology, results and applications Observing changes in the cryosphere with satellites Hydrology and Oceanography observed with satellites 6 Homework assignments An exercise related to dynamics, observation systems or reference systems An exercise related to GNSS applied to orbit determination An exercise related to Kalman filtering Exercises with the Ghost software, typical examples are to solve: o initial value problems (state vector estimation) o problems with parameters in a dynamic model (drag parameter estimation) o problems with time bias parameters Study Goals The candidate should be able to: 1) Explain the physical and mathematical aspects of orbit determination (OD), the topics are 1.1) Solar system dynamics 1.2) Equations of motion and variational equations 1.3) Parameter estimation 2) Construct transformations between various coordinate and time systems that play a role in OD 3) Examine error sources in satellite tracking data and implement error mitigation strategies 4) Make use of parameter estimation methods in the context of tracking data for OD 5) Apply relevant statistical techniques within the framework of OD 6) Discuss scientific applications of satellite missions that depend on precise OD 6.1) GNSS techniques to model the deformation of the Earth 6.2) Satellite gravimetry to model the gravity field of the Earth 6.3) Satellite altimetry to model the ocean topography 6.4) Satellite altimeter missions to measure variations of land and sea ice 7) Apply OD with state-of-the-art software
Presential
English
Satellite orbit determination
English

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