| Course Unit Code | 544-0095/06 |
|---|
| Number of ECTS Credits Allocated | 5 ECTS credits |
|---|
| Type of Course Unit * | Compulsory |
|---|
| Level of Course Unit * | Second Cycle |
|---|
| Year of Study * | First Year |
|---|
| Semester when the Course Unit is delivered | Winter Semester |
|---|
| Mode of Delivery | Face-to-face |
|---|
| Language of Instruction | Czech |
|---|
| Prerequisites and Co-Requisites | There are no prerequisites or co-requisites for this course unit |
|---|
| Name of Lecturer(s) | Personal ID | Name |
|---|
| POS0188 | doc. RNDr. Lubomil Pospíšil, CSc. |
| KOS0259 | doc. Ing. Jakub Kostelecký, Ph.D. |
| Summary |
|---|
The course includes the science of the physical fields of the Earth, especially the gravitational field, its mathematical description and its influence on geodetic quantities. Current methods of physical geodesy require an understanding of the role of geopotential models in modern geodesy and knowledge of their practical applications. With this in mind, the basics of gravitational, gravity and tidal potentials are discussed using the mathematical apparatus of spherical harmonics and Legendre functions. Practical applications of this issue are discussed and practiced in the issues of altitude systems, fault potential, methods for determining the area and dimensions of geoids and quasi-geoids and obtaining global data of various geophysical quantities using modern geopotential models.
Furthermore, some geophysical methods and their use in engineering geodesy and mining surveying are discussed. The analysis of the physical fields of the Earth's body, in order to solve the problem of its shape and structure (internal structure of the Earth - especially the structure of the earth's crust and upper mantle, etc.) is part of the connection of both methods.
The importance of both methods is in the use and possibility of solving problems in the field of general, structural and deposit geology (tectonophysics; exploration of mineral deposits; localization of faults, etc.), solving problems in the field of engineering geology, environmental geology, hydrogeology, etc. At the same time, new satellite geophysical and geodetic methods enable global applications and forecasting of raw material potential, risks and threats.
With regard to the physical principle and character of the field, which we measure and analyze, the following geophysical methods are included in the subject: - gravimetry (gravity field), - geomagnetics (Earth's geomagnetic field), - geoelectrical methods (both natural and artificial geoelectric fields), - seismic survey and seismology (wave field), - radionuclide methods (radioactive field), - geothermal energy (thermal field).
|
| Learning Outcomes of the Course Unit |
|---|
Master the content of the subject according to the annotation. To learn to apply especially gravimetric methods and selected geophysical methods in geodesy and mining surveying. To improve in the knowledge of the laws of motion and shape of the Earth, its deformations and changes. Most geophysical methods currently include applications in the form of aerial, ground, mining, drilling variants, including modifications for marine applications. However, satellite geodetic and geophysical technologies are experiencing the greatest expansion, which are becoming part of everyday practice. Their foundations are part of Physical Geodesy. Each of the methods differs in its application by the used mathematical solution, global data sources, instrumentation, methodology of approach to solving the relevant problem, and in terms of interpretation.
|
| Course Contents |
|---|
1. Gravitational potential theory. Spherical harmonic functions and Legendre functions.
2. Earth's gravitational field. Gravitational potential. Level surfaces of gravity potential.
3. Theory of heights. Stokes parameters and their determination.
4. Earth's normal gravitational field. Measurement of basic gravity field parameters.
5. Tidal phenomena, local and regional geodynamics. Earth's magnetic field - models.
6. Practical applications of physical geodesy methods.
7. Position of geophysics in geodetic disciplines and mining.
8. Earth's gravitational field. Weight measurements and their processing. Anomalous gravity field.
9. Earth's wave field. Seismology and seismic methods and their use.
10. Earth's magnetic field. Magnetic measurements in geodesy and mine surveying.
11. Earth's electric field. Geoelectrical methods (resistivity, SP, GPR, MT) and their use.
12. Radiometry and radionuclide methods. Radon risk.
13. Earth's thermal field. Thermal measurements and their use in geotechnics and mining.
|
| Recommended or Required Reading |
|---|
| Required Reading: |
|---|
HEISKANEN, W.A., MORITZ, H.: Physical Geodesy. W.H.Freeman and Co., 1967.
TELFORD, W. M., GELDART, L., P., SHERIFF, R., E.: Applied Geophysics Second Edition, Published by The Press, 2001. |
ZEMAN, A. Fyzikální geodézie. Skripta ČVUT, Praha 1998
MERVART, L., CIMBALNÍK, M. Vyšší geodézie 2. Skripta ČVUT, Praha 1997
BURŠA, M., 2004: Geopotenciál. Díl I. Teoretické základy a modely. Ministerstvo obrany ČR, Praha, 2004.
TELFORD, W. M., GELDART, L., P., SHERIFF, R., E.: Applied Geophysics Second Edition, Published by The Press, 2001 |
| Recommended Reading: |
|---|
MORITZ, H.: Advanced physical geodesy. Abarcus Press., 1980.
WAHR, J., Geodesy and Gravity. Syndicate of the University of Cambridge, United Kingdom,. Class Notes, Department of Physics University of Colorado, Samizdat Press, 491p, 1999. |
MULLER, K., OKÁL, M., HOFRICHTEROVÁ, L. Základy hornické geofyziky. SNTL, Alfa Praha 1985
MAREŠ, S. a kol., 1990. Úvod do užité geofyziky, SNTL/ALFA Praha, 672s.
HEISKANEN, W.A., MORITZ, H.: Physical Geodesy. W.H. Freeman and Co., 1967.
MORITZ, H.: Advanced physical geodesy. Abarcus Press., 1980. |
| Planned learning activities and teaching methods |
|---|
| Lectures, Tutorials |
| Assesment methods and criteria |
|---|
| Task Title | Task Type | Maximum Number of Points
(Act. for Subtasks) | Minimum Number of Points for Task Passing |
|---|
| Credit and Examination | Credit and Examination | 100 (100) | 51 |
| Credit | Credit | 33 | 17 |
| Examination | Examination | 67 | 34 |