Navigation

OGD08FG - Physical geodesy

Course specification
Type of study Bachelor academic studies
Study programme
Course title Physical geodesy
Acronym Status Semester Number of classes ECTS
OGD08FG mandatory 6 3L + 1E 5.0
Lecturers
Lecturer
    Lecturer/Associate (practicals)
    Prerequisite Form of prerequisites
    Mathematics for geodesy and Geodetic astronomy. Completed classes for attending classes, and none for final exam.
    Learning objectives
    Introducing students to the theoretical and practical aspects of physical geodesy, the problems of boundary values of the theory of Earth's gravitational potential and mathematical models used in determining the reference geodetic surfaces.
    Learning outcomes
    The student should be able to: 1) describe and explain the influence of the Earth's gravitational field and its importance in modeling reference geodetic surfaces, 2) define and use different height systems, 3) model and apply datum transformation parameters, 4) model the gravitational influence of topographic masses of the Earth's crust, 5) understand the basics of Molodensky's theory, 6) creates and applies the collocation model in predicting / estimating the functionals of the anomalous potential of the Earth's gravitational field, etc.
    Content
    Lectures. Introduction. Gravitational force. Gravitational potential. Spherically harmonics development of gravitational potential. Boundary value problems of the theory of gravitational potential. Laplace and Poisson differential equations. Earth's gravity. The potential of a Earth's gravity. The gravity of the so-called Normal Earth and normal potential. Spherically harmonics development of normal potential. Anomalous potential. Functionals of anomalous potential. The integral formulas of Stokes and Wenning-Meines. Reduction of the acceleration of the Earth's gravity. Molodensky's theory. Statistical methods in physical geodesy. Exercises. Height systems. Determining the potential of a body of regular geometric shape of uniform / homogeneous density. Coordinate transformation (natural, geodetic, geocentric, spherical). Reduction of the Earth's gravity acceleration. Determining the geoid undulation using the Stokes equation. Astrogeodetic determination of geoid.
    Teaching Methods
    Classes are conducted through lectures. Lectures are accompanied by exercises of appropriate content.
    Literature
    1. Heiskanen Weiko, H. Moritz: Physical geodesy, Faculty of Civil engineering, University of Belgrade, 2000.
    2. P. Vaniček, E. Krakivsky: Geodesy, the concepts, Serbian geodetic association, 2005.
    3. H. Moritz: Advanced Phisical Geodesy, Karlsruhe, Wichmann; Tunbridge, Eng.: Abacus Press, 1980. (Original title)
    4. W. Torge: Geodesy, Walter de Gruyter, Berlin-New York, 2001. (Original title)
    5. Višnjić, I. R., Digital relief model - application in geoid determination by gravimetric method, master 's thesis, Faculty of Civil Engineering, University of Belgrade, Belgrade, 1999.
    Evaluation and grading
    Class attendance Activity in classes, Exercises Colloquium 1 Colloquium 2
    Specific remarks
    None.