Infopaket

Satellite Geodesy

ОК 25

Обов’язкова дисципліна для ОП

First

2022/2023

8 Semester

4

Apply the conceptual knowledge of natural and socio-economic sciences in the performance of tasks of geodesy and land management. Participate in the creation of state geodetic and special engineering geodetic networks, organize and carry out topographic and cadastral surveys, geodetic measurements, engineering and geodetic surveys for the design, construction and operation of construction projects. Collect, evaluate, interpret and use geospatial data, metadata on objects of natural and man-made origin, apply statistical methods for their analysis to solve specialized problems in the field of geodesy and land management. Select and apply the tools, equipment and software required for remote, ground, field and office research in the field of geodesy and land management. Organize and carry out remote, ground, field and cameral work in the field of geodesy and land management, draw up the results of the work.

Full-time form

the student must have knowledge of the course "Higher Mathematics", "Higher Geodesy", the basics of mathematical processing of the results of geodetic measurements, skills in working with a personal computer (Excel).

As a result of studying the discipline the student must know: coordinate systems and time, the theory of undisturbed and perturbed motion of the satellite, general principles the use of artificial satellites of the Earth (SSS) for geodetic purposes, the basics of using satellite methods to study the shape, size and external gravitational field of the Earth, creation of geodetic networks by methods of satellite geodesy, functioning of the global satellite navigation system GNSS. Be able to: solve problems of determining the position of the satellite (direct problem), determining the coordinates of the observation point (inverse problem); to carry out field measurements by GNSS receivers in static and kinematic modes; use software products to calculate the results of field GNSS measurements, perform coordinate transformation.

1. Marchenko O.M. Reference systems in geodesy: heading help / O.M. Marchenko, K.R. Tretyak, N.P. Yarema - Lviv: Publishing House of the Lviv Polytechnic, 2013, 202 p. 2. Chernyaga P.G., Bialik I.M., Yanchuk R.M. Suputnikova Geodesy Manual / Chernyaga P.G., Byalik I.M., Yanchuk R.M., Rivne: NUVGP, 2013. 222 p. 3. Shumakov F.T. Abstract of lectures on the discipline of Suputnikov geodesy. Kharkiv. KhNAMG, 2009. - 88 p. 4. Bürgmann R., Rosen P. A., Fielding E. J. Synthetic Aperture Radar Interferometry to Measure Earth’s Surface Topography and Its Deformation // Annual Review of Earth and Planetary Sciences. 2000. № 1 (28). C. 169–209. 5. Hanssen R. F. Radar interferometry: data interpretation and error analysis / R. F. Hanssen, Dordrecht ; Boston: Kluwer Academic, 2001. 308 c. 6. Kazmierski K., Zajdel R., Sośnica K. Evolution of orbit and clock quality for real-time multiGNSS solutions // GPS Solutions. 2020. № 4 (24). C. 111.

Lectures, laboratory work, self-study

The control is carried out according to the module-rating system and includes: performance of 10 laboratory works (where students have to demonstrate the quality of acquired knowledge and solve problems using the methods and tools outlined by the teacher), performance of 3 independent practical works students must demonstrate the quality of acquired knowledge and solve problems without limiting the tools and techniques of problem solving) and conducting 2 written modular tests. The final assessment is conducted in the form of an exam.

ukrainian