| Type of course: |
Compulsory |
| Language of instruction: |
Romanian |
| Erasmus Language of instruction: |
English |
| Name of lecturer: |
Andreea Ramona Begov Ungur |
| Seminar tutor: |
Andreea Ramona Begov Ungur |
| Form of education |
Full-time |
| Form of instruction: |
Lecture |
| Number of teaching hours per semester: |
56 |
| Number of teaching hours per week: |
4 |
| Semester: |
Summer |
| Form of receiving a credit for a course: |
Grade |
| Number of ECTS credits allocated |
4 |
Course aims:
- knowing, understanding and a correct using of fundamental ideas concerning concepts specific to the processing and optimization of a geodetic networks;
- knowing how to design a geodetic network;
- knowing the categories and criteria of optimization and applying them in the design of a geodetic networks.
Course Entry Requirements:
Ellipsoidal Geodesy, National and Local Geodetic Networks 1+2, Satellite geodesy
Course contents:
1. Generalities
2. Geodetic network design. Principles for develop the geodetic networks
3. The component parts of geodetic network project.
4. Methods to design a geodetic networks
5. The materialisation of geodetic networks on the field
6. The processing of a geodetic networks. Generalities.
7. The processing of a geodetic networks. Methods
8. Optimization generalities. The matrix form of linear programming problem
The problem of subdimesionate linear systems
The problem of supradimesionate linear systems
9. Scope functions and restrictions to geodetic network optimization
Local precision indicators. Global precision indicators. Economic indicators
10. Categories and criteria of optimization. Classification of optimization criteria
11. Optimizing the initial data
12. Optimizing the configuration of geodetic networks
13. Optimizing the measurements related to the geodetic networks
14. Examples of optimal elements in a geodetic networks
Teaching methods:
Lecture, conversation, exemplification, practical application.
Learning outcomes:
• to accustom students with terminology, methods, equipment and instruments specific of this discipline;
• to give students the basics concepts needed to design and optimization of a geodetic networks;
• understanding of issues they will encounter in their future profession.
Learning outcomes verification and assessment criteria:
Written exam – 60%; Portfolio of practical work – 40%.
Recommended reading:
Federal Geodetic Control Committee,
Standards and Specifications for Geodetic Control Networks,
, Rockville, Maryland
, 1984
David A. Conner,
The Use and Improvement of the National Spatial Reference System in Ohio, Columbus, Ohio, USA , https://www.ngs.noaa.gov/PUBS_LIB/NSRSinOhio.pdf
, Ohio
Ungur Andreea,
Considerations on the Development of Geodetic Network by Classical and GPS Methods, , Revista AGRICULTURA, AGRICULTURE Science and Practice Iournal, Vol. 77, No. 1-2/2011, AcademicPres
, Cluj Napoca
, 2011
, 230-234
https://www.fgdc.gov/standards/projects/framework-data-standard/GI_FrameworkDataStandard_Part4_GeodeticControl.pdf