Books and Papers
all
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2024
Seckiner, Dilan; Ebert, L.; Mallett, Xanthé; Berry, Rachel; Green, Hayley; Franckenberg, Sabine; Thali, Michael; Sieberth, T. (2022):
A technical protocol for 3D observation and documentation of human decomposition. Australian Journal of Forensic Sciences
, doi: https://doi.org/10.1080/00450618.2022.2146189
Nietiedt, S.; Wester, T.; Langidis, A.; Kröger, L.; Rofallski, R.; Göring, M.; Kühn, M.; Gülker, G.; Luhmann, T. (2022):
A Wind Tunnel Setup for Fluid-Structure Interaction Measurements Using Optical Methods. Sensors 2022, 22(13), 5014
, doi: https://doi.org/10.3390/s22135014
Kalinowski, P.; Hindmarch, J.; Luhmann, T. (2022):
Accuracy investigations of hand-held scanning system using different dumbbell artefacts. Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci., XLIII-B2-2022, 401–407
, doi: 10.5194/isprs-archives-XLIII-B2-2022-401-2022 , Weblink
Rofallski, R.; Menna, F.; Nocerino, E.; Luhmann, T. (2022):
An efficient solution to ray tracing problems for hemispherical refractive interfaces. ISPRS Ann. Photogramm. Remote Sens. Spatial Inf. Sci., V-2-2022, 333–342
, doi: 10.5194/isprs-annals-V-2-2022-333-2022 , Weblink
Rofallski, R.; Luhmann, T. (2022):
An Efficient Solution to Ray Tracing Problems in Multimedia Photogrammetry for Flat Refractive Interfaces. PFG – Journal of Photogrammetry, Remote Sensing and Geoinformation Science, Vol. 90, Issue 1, pp. 37-54
, doi: 10.1007/s41064-022-00192-1
Presentations
Luhmann, T.
:
Development of a simulator for terrestrial laser scanning as a powerful tool for distance learning.
Ukraine Tage in Niedersachsen, Hannover,
September 2022
Luhmann, T.
:
Introduction to Close-Range Photogrammetry.
DAAD VRscan3D Projektwoche, Universität Bamberg,
September 2022
Koch, S.
:
WärmewendeNordwest - Digitalisierter Experimentalcampus Bauphysik.
9. Oldenburger BIMTag,
September 2022
Weblink
Kahmen, O.
:
Digitale Sichtprüfung von Schweißverbindungen unter Wasser durch photogrammetrische Verfahren.
9. BIM-Tag / 20. Oldenburger 3D-Tage,
September 2022
Projects
funded by: German Research Foundation
Classical methods of photogrammetric deformation analysis are essentially a two-step process of spatio-temporal image matching (STM) followed by the calculation of deformation parameters. In many close-range applications, further kinematic in... more
funded by: Niedersächsisches Vorab
Transformation and structural change in rural areas mean changes in space and time. Such spatiotemporal data is to be managed and processed by our “Geo-Toolbox”. It uses digital technologies such as databases and geographic information systems ... more
people
Prof. Dr. Thomas Brinkhoff (head) Prof. Dr. rer. nat. habil. Roland Pesch (head) Prof. Dr. rer. nat. Frank Schüssler (head) Tobias Werner, M.Sc. (10.2022-) Jonas Schoo, M.Sc. (06.2022-) Maren Leiz, M.Sc. (08.2022-) Dr. Amirmohammad Ghavimi (08.2022-)
Prof. Dr. Thomas Brinkhoff (head) Prof. Dr. rer. nat. habil. Roland Pesch (head) Prof. Dr. rer. nat. Frank Schüssler (head) Tobias Werner, M.Sc. (10.2022-) Jonas Schoo, M.Sc. (06.2022-) Maren Leiz, M.Sc. (08.2022-) Dr. Amirmohammad Ghavimi (08.2022-)
funded by: Bundesministerium für Bildung und Forschung
The Project – „CoSAIR – Collaborative Spatial Artificial Intelligence in Realtime“ is funded by the Federal Ministry of Education and Research within the program „Research at Universities of Applied Sciences“ in order to create, consolida... more
people
Prof. Dr. Sascha Koch (head) Tobias Neiß-Theuerkauff, M.Sc. (-03.2024) Oliver Kahmen, M.Sc. (04.2022-07.2022) Prof. Dr.-Ing. habil. Dr. h.c. Thomas Luhmann Mareike Fincken, M.Sc. (09.2023-)
Prof. Dr. Sascha Koch (head) Tobias Neiß-Theuerkauff, M.Sc. (-03.2024) Oliver Kahmen, M.Sc. (04.2022-07.2022) Prof. Dr.-Ing. habil. Dr. h.c. Thomas Luhmann Mareike Fincken, M.Sc. (09.2023-)
Bachelor & Master Theses
Untersuchung zur Georeferenzierung und Nutzung von Urkarten des Liegenschaftskatasters (2024/2)
Analyse und Vergleich der geometrischen Eigenschaften von Referenzdaten und KI-Ergebnissen für die automatische Gebäudeerkennung in Luftbildern (2024/2)
Maschinelles Lernen für die Identifikation von baulichen Erweiterungen an Gebäuden anhand geometrischer Merkmale von ALKIS- und durch KI bestimmten Hausumringen (2024/2)
Integration und Verteilung von ALKIS-Grunddaten und Fortführungsdaten in Echtzeit mittels Open-Source-Technologien (2024/2)
Design und prototypische Implementierung einer Georeferenzierung im Web-Browser mittels Javascript und dem Open-Source-Geoportal „Masterportal“ (2024/2)