Dr.-Ing. Berit Jost

2023

• Dreier, A., Jost, B., Kuhlmann, H. & Klingbeil, L.  (2023) Investigations of the scan characteristics with special focus on multi-target capability for the 2D laser scanner RIEGL miniVUX-2UAV, Journal of Applied Geodesy, ahead of print. https://doi.org/10.1515/jag-2022-0029
• Jost, B. (2023) Strategies for the Empirical Determination of the Stochastic Properties of Terrestrial Laser Scans. Dissertation, Rheinische Friedrich-Wilhelms-Universität Bonn. Online-Ausgabe in bonndoc: https://nbn-resolving.org/urn:nbn:de:hbz:5-71297
• Jost, B., Coopmann, D., Holst, C. & Kuhlmann, H. (2023). How to be more accurate than a single laser scan: Creating the reference geometry of a large wall. In A. Wieser (Ed.), Beiträge zum 20. Internationalen Ingenieurvermessungskurs, 11.-14. April 2023, Zurich, Switzerland (pp. 131–144).: Wichmann, Berlin, Offenbach.
• Jost, B., Coopmann, D., Holst, C., & Kuhlmann, H. (2023). Real movement or systematic errors? – TLS-based deformation analysis of a concrete wall. Journal of Applied Geodesy, 17(2), 139–149.

2022

• Koller, E., Jost, B., Wieser, A., Holst, C. & Kuhlmann, H. (2022). Bestimmung einer Referenzgeometrie zur Prüfung terrestrischer Laserscanner. In: DVW e.V. (Hrsg.): Terrestrisches Laserscanning 2022 (TLS 2022). DVW-Schriftenreihe, Band 104, Wißner Verlag, Augsburg, S. 9-22.
• Wieser, A., Balangé, L., Bauer, P., Gehrmann, T., Hartmann, J., Holst, C., Jost, B., Kuhlmann, H., Lienhart, W., Maboudi, M., Mawas, K., Medic, T., Paffenholz, J., Pollinger, F., Rafeld, E., Schill, F. & Schwieger, V. (2022) Erfahrungen aus einem koordinierten Vergleich aktueller Scanner. In: DVW e.V. (Hrsg.): Terrestrisches Laserscanning 2022 (TLS 2022). DVW-Schriftenreihe, Band 104, Wißner Verlag, Augsburg, S. 23-38

2021

• Holst, C., Janßen, J., Schmitz, B., Blome, M., Dercks, M., Schoch-Baumann, A., Blöthe, J., Schrott, L., Kuhlmann, H., Medic, T. (2021) Increasing the Spatio-Temporal Resolution at Monitoring Alpine Solifluction Using Terrestrial Laser Scanners and 3D Vector Fields, Remote Sens. 13(6), 1192. https://doi.org/10.3390/rs13061192
• Schmitz, B., Kuhlmann, H., Holst, C. (2021) Deformation analysis of a reference wall towards the uncertainty investigation of terrestrial laser scanners, J. Appl. Geodesy, 15(3), pp. 189-206. https://doi.org/10.1515/jag-2020-0025
• Schmitz, B.,  Coopmann, D., Kuhlmann, H., Holst, C. (2021) Using the Resolution Capability and the Effective Number of Measurements to Select the "Right" Terrestrial Laser Scanner,  In: Kopáčik, A., Kyrinovič, P., Erdélyi, J., Paar, R., Marendić, A. (Eds.): Contributions to International Conferences on Engineering Surveying, INGEO & SIG 2020, Dubrovnik, Croatia. Springer Proceedings in Earth and Environmental Sciences. Springer, Cham, 85-97. Preprint: online
• Schmitz, B., Kuhlmann, H., Holst, C. (2021) Towards the empirical determination of correlations in terrestrial laser scanner range observations and the comparison of the correlation structure of different scanners, ISPRS J. Photogramm. Remote Sens. (182), 228-241, https://doi.org/10.1016/j.isprsjprs.2021.10.012

2020

• Schmitz, B., Kuhlmann, H., Holst, C. (2020) Investigating the resolution capability of terrestrial laser scanners and its impact on the effective number of measurements, ISPRS J. Photogramm. Remote Sens. (159), 41-52, https://doi.org/10.1016/j.isprsjprs.2019.11.002

2019

• Schmitz, B., Holst, C., Medic, T., Lichti D. D., Kuhlmann, H. (2019) How to Efficiently Determine the Range Precision of 3D Terrestrial Laser Scanners, Sensors, 19 (6), 1466, doi:10.3390/s19061466
• Zimmermann, F., Schmitz, B., Klingbeil, L., Kuhlmann, H. (2019) GPS-Multipath Analysis using Fresnel-Zones, Sensors 2019, 19(1), 25, https://doi.org/10.3390/s19010025

2017

• Holst, C., Schmitz, B., Kuhlmann, H. (2017) Investigating the applicability of standard software packages for laser scanner based deformation analyses, FIG Working Week 2017, May 29 - June 02, Helsinki, Finland
• Holst, C., Schmitz, B., Schraven, A., Kuhlmann, H. (2017) Eignen sich in Standardsoftware implementierte Punktwolkenvergleiche zur flächenhaften Deformationsanalyse von Bauwerken? Eine Fallstudie anhand von Laserscans einer Holzplatte und einer Staumauer, zfv - Zeitschrift für Geodäsie, Geoinformation und Landmanagement, 2/2017, S. 98-110, doi:10.12902/zfv-0158-2017

2016

• Holst, C., Schmitz, B., Kuhlmann, H. (2016) TLS-basierte Deformationsanalyse unter Nutzung von Standardsoftware, In: Schriftenreihe DVW, Band 85, „Terrestrisches Laserscanning 2016 (TLS 2016)“, Wißner Verlag, S. 39-58, online verfügbar unter geodaesie.info

2023

• Jost, B. (2023) Strategies for the Empirical Determination of the Stochastic Properties of Terrestrial Laser Scans. Rigorosum, University of Bonn.
• Jost, B., Coopmann, D., Holst, C. & Kuhlmann, H. (2023). How to be more accurate than a single laser scan: Creating the reference geometry of a large wall. 20. Internationaler Ingenieurvermessungskurs, 11.-14. April 2023, Zurich, Switzerland

2022

• Jost, B., Coopmann, D., Holst, C., & Kuhlmann, H. (2022). Real movement or systematic errors? – TLS-based deformation analysis of a concrete wall. In 5th Joint International Symposium on Deformation Monitoring (JISDM), 20-22 June 2022, Valencia, Spain.

2020

• Schmitz, B., Coopmann, C., Kuhlmann, H., Holst, C. (2020). Welche Objektdetails "sieht" mein Laserscanner?, 194. DVW-Seminar "Terrestrisches Laserscanning 2020 (TLS 2020)", 04. Dezember 2020, digital.

2018

• Schmitz, B., Holst, C., Kuhlmann, H. (2018) Untersuchung des Auflösungsvermögens terrestrischer Laserscanner und seiner Auswirkung auf das stochastische Modell der Punktwolke, Präsentation, Geodätische Woche, 16-18 Oktober 2018, Frankfurt