Ability to use and implement new technologies, participate in the modernization and renovation of equipment, devices, systems and complexes, in particular to improve their efficiency and accuracy.
Ability to demonstrate in-depth knowledge of domestic and foreign scientific achievements and theoretical and applied principles of geodesy, namely, in global navigation satellite systems.
Ability to demonstrate knowledge of the latest technologies, formulate and refine an important research problem, to solve it to gather the necessary information and formulate conclusions that can be protected in a scientific context.

Geodesy,
Positioning and navigation systems,
Monitoring and forecasting of the stress-strain state of territories, buildings and structures,
Active GNSS Networks,
Creating local geodetic networks.

The use of GNSS technologies in engineering geodesy is aimed at exploring aspects of the use of GNSS for solving geodetic engineering problems. Theoretical aspects of GNSS observations processing. GNSS data processing by precision engineering and geodetic networks with application software. GNSS data processing in precision engineering and geodetic networks with scientific software Bernese GNSS V 5.2. Use of online services and databases to process GNSS observations. Active base station networks. Network structure of active base stations. Methods for the calculating corrections in the active base station networks. Formats of data transmission in networks of active base stations. NTRIP Data Transfer Protocol. Aspects of using RTK method for solving geodetic engineering problems. Overview of global GNSS satellite exact ephemeris databases. Ephemeris types. Download the exact ephemeris files. Conversion of received point coordinates to the corresponding coordinate system using online services. Calculation of displacement vectors of points of the processed network. Construction of maps the distribution of displacement vectors.

1. Seeber, Gunter (2003). Satellite geodesy. Berlin New York: Walter de Gruyter. p. 2. ISBN 978-3-11-017549-3.
2. Rolf Dach, Simon Lutz, Peter Walser, Pierre FridezBernese GNSS Software Version 5.2. Astronomical Institute, University of Bern. 2015.
3. Steigenberger, Peter; Lutz, Simon; Dach, Rolf; Schaer, Stefan; Jaggi, Adrian (2014). CODE repro2 product series for the IGS. Published by Astronomical Institute, University of Bern. URL: http://www.aiub.unibe.ch/download/REPRO_2013; DOI: 10.7892/boris.75680.
4. sopac.ucsd.edu Scripps Orbit and Permanent Array Center.
5. www.igs.org. International GNSS Service.
6. https://www.unavco.org/ University NAVSTAR Consortium (UNAVCO).
7. https://www.ngs.noaa.gov/. National Geodetic Survey.

Selective questionnairing before lections;
testing for 5-10 minutes,
assessment of the activity of the graduate student in the learning process, suggestions, original decisions, clarifications and definitions, additions to previous answers, etc.
The control questions are divided into:
test tasks - choose the right answers;
problematic - creating problematic situations;
question-replica - identify causation;
the question of reproductive nature is the determination of practical significance. The final control is based on the results of the current control and the written examination component.
Ongoing examination and examinations together for discipline
practical works (20 points).
individual homeworks (20 points).
Together for the written and oral components
40 + 60 = 100