Программа обучения "Geodesy and Geoinformatics Engineering" в University of Stuttgart
Geodäsie und Geoinformatik
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Университет
University of Stuttgart
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Степень
Бакалавриат
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Специализация
Computer Science, Geography
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Стоимость
0 € / Семестр
Geodesy is everywhere: in highly topical projects such as "autonomous driving", in the digital maps of Navis, in earth system research, where conclusions about the climate are drawn from satellite data, or in fascinating projects such as Google Earth and OpenStreetMap. p>
Geodesy is an engineering science with a strong interdisciplinary character, which moves in the field of activity between applied mathematics, computer science, physics and geosciences on the one hand and civil engineering, electrical engineering and mechanical engineering on the other.
Общая Информация по Программе обучения "Geodesy and Geoinformatics Engineering"
- Уровень: Бакалавриат
- Диплом: Bachelor of Science (B.Sc.)
- Язык обучения: Немецкий
- Начало обучения: Зимний семестр
- Срок обучения: 6 семестров
- Форма обучения: Полная
- Учебные кредиты: 180 ECTS
- Стоимость: € 0 / Семестр
- Семестровый взнос: € 188.40 / семестр
- Правила приема: Без конкурса
- Минимальный уровень немецкого: C1
Описание программы обучения "Geodesy and Geoinformatics Engineering"
GPS satellites
In modern geodesy, satellites are often used, for example for navigation systems such as GPS, but also for observing global phenomena on earth such as the rise in sea level or the melting of the polar ice caps.
Navigation sensors
In autonomous driving, the exact position and movement behavior of the vehicle must always be known. For example, satellite-based methods and inertial sensors are used for determination. The picture shows a test drive with a remote-controlled model car with built-in navigation sensors.
Excavator Control
The control of moving objects is used, for example, for the automated operation of construction machinery. The fully automatic execution of charging processes is implemented here. A model crawler loader on a scale of 1:14 is used as the object of investigation.
Deformation measurements
The observance of dimensions plays an important role in the construction of new buildings and objects. After production, this pavilion on the Stadtmitte campus was measured with a laser scanner and the result compared with the planned dimensions. From this it is derived which processes in construction need to be improved.
Change in ice mass in Antarctica
Geodesy deals with natural phenomena, e.g. in connection with climate change. The figure shows the change in ice mass in Antarctica. It was measured with satellites. Blue areas show mass loss, red areas mass increase.
Photogrammetry
In photogrammetry, geodesy is concerned with the generation of three-dimensional data from multiple overlapping images. In order for the calculated 3D coordinates to be accurate, the geometry of the camera used must be determined very precisely. This camera calibration is done here with our calibration field.
3D Data
An example of the result of a photogrammetric reconstruction is the shown 3D mesh of Stuttgart's Schlossplatz. For this purpose, photos were taken from an airplane. Such data is used, among other things, to create 3D city models.
Earth's gravitational field
The picture shows a superconducting gravimeter in an observatory in the Black Forest. The gravimeter is used to measure temporal changes in gravity with high precision. Even the influence of heavy rainfall on the Earth's gravity can be seen in the instrument's data.
Карьерные перспективы по завершению программы обучения "Geodesy and Geoinformatics Engineering"
The increasing need for specially trained specialists offers excellent future prospects for graduates of geodesy and geoinformatics: The varied training means that the range of employment opportunities is very wide and varied. It includes, for example, areas of the automotive industry, robotics, software development as well as activities in planning and surveying offices.
Учебный план программы обучения "Geodesy and Geoinformatics Engineering"
In the first and second semester, the focus is on the basic modules of mathematics, physics and computer science. The basic modules provide the basics for the following (subject-specific) modules.
The core modules are primarily located in the middle of the course. On the one hand, they provide an overview of the diverse fields of activity in geodesy and geoinformatics. On the other hand, they contain fundamental specialist knowledge.
The second half of the course is characterized by the supplementary modules. You deepen the subject-specific knowledge acquired within the framework of the core modules. In a 2-week integrated field project (integrated field project 2006, integrated field project 2017), the entire spectrum of the learned measuring methods and evaluation methods of geodesy and geoinformatics will be applied to a project to be carried out independently. Both subject-related and interdisciplinary key qualifications round off this block.
The preparation of the bachelor thesis is scheduled for the sixth semester. She completes the bachelor's degree in geodesy and geoinformatics. After passing the exam, the University of Stuttgart awards the academic degree "Bachelor of Science" (B.Sc.).
https://www.uni-stuttgart.de/bologna/modulhandbuecher
http://stundenplan.gis.uni-stuttgart.de/
Факультет
Faculty 6: Aerospace Engineering and Geodesy
University of StuttgartThe faculty for Aerospace Engineering and Geodesy at the University of Stuttgart is in an internationally outstanding position because of the way it connects fundamental aviation technologies, space travel, and geodesy. It is nationally the only aviation and aerospace engineering faculty at a public university; the combination with geodesy is also nationally unique. Its strong focus on teaching fundamental principles, combined with targeted, practice-oriented areas of specialization, creates a distinctive profile that counts as a mark of quality in Stuttgart’s research and industry sectors.
The approximately 2000 students of aerospace engineering and geodesy also learn about the interdisciplinary research areas of aviation technology, aircraft development, propulsion systems, avionics, spacecraft ascent and re-entry, satellite technology, and earth observation. The theses developed in these areas cover a wide range of topics, including mission analysis, flight control, aerodynamics, thermodynamics, material development, structural development, construction design, system development, and the operation and combustion of air-breathing propulsion systems.
Полезные ссылки по программе обучения "Geodesy and Geoinformatics Engineering"
- Сайт программы: https://www.uni-stuttgart.de/studium/bachelor/geodaesie-und-geoinformatik-b.sc./
- Брошюра / инфо-материалы: https://www.f06.uni-stuttgart.de/files/gug/Flyer_BSc_Geodaesie_2021.pdf<br />https://www.f06.uni-stuttgart.de/studium/studium_gug/<br />https://www.f06.uni-stuttgart.de/studium/studium_gug/bachelor_gug/
- Учебный план / модули: https://www.f06.uni-stuttgart.de/files/gug/Studienverlaufsplan_BSc.pdf<br />https://www.uni-stuttgart.de/bologna/modulhandbuecher<br />http://stundenplan.gis.uni-stuttgart.de/
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Geodesy and Geoinformatics Engineering