Satellite geodesy and navigation  

Reference systems and reference frames, geodetic datum. Inertial (celestial) and terrestrial reference systems and frames. The hierarchy of celestial and terrestrial reference systems. Artificial Earth satellites for surveying; methods of satellite geodesy. Fundamentals of the theory of time; sidereal time, solar time (universal time), dynamic time, atomic time, coordinated time, own specific time. ethods of global geodesy: VLBI, SLR, LLR, DORIS, GNSS. Solving interdisciplinary tasks by using modern satellite techniques. Basis of kinematic and dynamic motion of satellites. Object (point) movement in the central field of force, conservation laws. Satellite transfer into orbit and relativistic problem compliance. Movement of artificial Earth satellites, Kepler's laws, derivation, orbits. Undisturbed and disturbed movement of satellites. Keplerian elements. Perturbing forces. Protocols and formats in GNSS. Effects on satellite observations, modelling impacts, use of models by solving inverse problems: GNSS meteorology, GNSS reflectometry, GNSS for monitoring the Earth's atmosphere. GNSS observations and linear combinations, satellite position computation using different ephemerides. Absolute point positioning from code and carrier- phase measurements, differential GNSS. GNSS application in navigation. Navigation in problematic conditions for GNSS. Intended LO: knowledge and understanding of basic satellite geodesy methods, understanding of artificial Earth satellites motion • Perception of complexity of contemporary interdisciplinary problems tied to the planet Earth, involving geodetic satellite techniques • ability of solving practical problems related to artificial Earth satellites’ movement • student acquires the necessary knowledge for the integration of theory into practice and theoretical basis for participation in interdisciplinary geo-projects related to the problems of the planet Earth.
Presential
English
Satellite geodesy and navigation
English

Funded by the European Union. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or HaDEA. Neither the European Union nor the granting authority can be held responsible for them. The statements made herein do not necessarily have the consent or agreement of the ASTRAIOS Consortium. These represent the opinion and findings of the author(s).