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Bernhard Höfle
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- affiliation: University of Heidelberg, Institute of Geography, Germany
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2020 – today
- 2024
- [d11]Hannah Weiser
, Veit Ulrich
Manually labeled terrestrial laser scanning point clouds of individual trees for leaf-wood separation. heiDATA, 2024 - [i4]Stefano Puliti, Emily R. Lines, Jana Müllerová, Julian Frey, Zoe Schindler, Adrian Straker, Matt Allen, Lukas Winiwarter, Nataliia Rehush
Benchmarking tree species classification from proximally-sensed laser scanning data: introducing the FOR-species20K dataset. CoRR abs/2408.06507 (2024) - 2023
- [j30]Vivien Zahs
Classification of structural building damage grades from multi-temporal photogrammetric point clouds using a machine learning model trained on virtual laser scanning data. Int. J. Appl. Earth Obs. Geoinformation 122: 103406 (2023) - [d10]Maria Shinoto
3D Point Cloud from Nakadake Sanroku Kiln Site Center, Japan: Sample Data for the Application of Adaptive Filtering with the AFwizard. 2.1. heiDATA, 2023 [all versions] - [d9]Lukas Winiwarter
UAV laser scanning and terrestrial laser scanning point clouds of snow-on and snow-off conditions of a forest plot in the black forest at Hundseck, Baden-Württemberg, Germany [data]. 1.0. heiDATA, 2023 [all versions] - [d8]Lukas Winiwarter
UAV laser scanning and terrestrial laser scanning point clouds of snow-on and snow-off conditions of a forest plot in the black forest at Hundseck, Baden-Württemberg, Germany [data]. 1.1. heiDATA, 2023 [all versions] - [d7]Vivien Zahs
Classification of structural building damage grades from multi-temporal photogrammetric point clouds using a machine learning model trained on virtual laser scanning data [Data and Source Code]. heiDATA, 2023 - [i3]Vivien Zahs, Katharina Anders, Julia Kohns, Alexander Stark
Classification of structural building damage grades from multi-temporal photogrammetric point clouds using a machine learning model trained on virtual laser scanning data. CoRR abs/2302.12591 (2023) - 2022
- [j29]Alberto Manuel Esmorís Pena
Virtual LiDAR Simulation as a High Performance Computing Challenge: Toward HPC HELIOS++. IEEE Access 10: 105052-105073 (2022) - [j28]Katharina Anders
Improving Change Analysis From Near-Continuous 3D Time Series by Considering Full Temporal Information. IEEE Geosci. Remote. Sens. Lett. 19: 1-5 (2022) - [d6]Manuel Herzog
Capturing complex star dune dynamics - Repeated highly accurate surveys combining multitemporal 3D topographic measurements and local wind data [Data]. heiDATA, 2022 - [d5]Maria Shinoto
3D Point Cloud from Nakadake Sanroku Kiln Site Center, Japan: Sample Data for the Application of Adaptive Filtering with the AFwizard. 1.0. heiDATA, 2022 [all versions] - [d4]Maria Shinoto
3D Point Cloud from Nakadake Sanroku Kiln Site Center, Japan: Sample Data for the Application of Adaptive Filtering with the AFwizard. 2.0. heiDATA, 2022 [all versions] - 2021
- [j27]Miguel Vallejo Orti
Use of TanDEM-X and Sentinel Products to Derive Gully Activity Maps in Kunene Region (Namibia) Based on Automatic Iterative Random Forest Approach. IEEE J. Sel. Top. Appl. Earth Obs. Remote. Sens. 14: 607-623 (2021) - [d3]Hannah Weiser
Opaque Voxel-based Tree Models for Virtual Laser Scanning in Forestry Applications [Research Data and Source Code]. heiDATA, 2021 - [d2]Lukas Winiwarter
M3C2-EP: Pushing the limits of 3D topographic point cloud change detection by error propagation [Data and Source Code]. 1.0. heiDATA, 2021 [all versions] - [d1]Lukas Winiwarter
M3C2-EP: Pushing the limits of 3D topographic point cloud change detection by error propagation [Data and Source Code]. 1.1. heiDATA, 2021 [all versions] - [i2]Lukas Winiwarter, Alberto Manuel Esmorís Pena, Hannah Weiser, Katharina Anders, Jorge Martínez Sánchez, Mark Searle, Bernhard Höfle:
Virtual laser scanning with HELIOS++: A novel take on ray tracing-based simulation of topographic 3D laser scanning. CoRR abs/2101.09154 (2021) - 2020
- [j26]René Westerholt
Behavioural Effects of Spatially Structured Scoring Systems in Location-Based Serious Games - A Case Study in the Context of OpenStreetMap. ISPRS Int. J. Geo Inf. 9(2): 129 (2020)
2010 – 2019
- 2019
- [j25]Miguel Vallejo Orti
Comparison of Three Algorithms for the Evaluation of TanDEM-X Data for Gully Detection in Krumhuk Farm (Namibia). Remote. Sens. 11(11): 1327 (2019) - 2018
- [j24]Carolin Klonner
Capturing Flood Risk Perception via Sketch Maps. ISPRS Int. J. Geo Inf. 7(9): 359 (2018) - [i1]Pedram Ghamisi, Behnood Rasti, Naoto Yokoya, Qunming Wang, Bernhard Höfle, Lorenzo Bruzzone, Francesca Bovolo, Mingmin Chi, Katharina Anders, Richard Gloaguen, Peter M. Atkinson, Jón Atli Benediktsson:
Multisource and Multitemporal Data Fusion in Remote Sensing. CoRR abs/1812.08287 (2018) - 2017
- [j23]Hone-Jay Chu
Historic Low Wall Detection via Topographic Parameter Images Derived from Fine-Resolution DEM. ISPRS Int. J. Geo Inf. 6(11): 346 (2017) - [j22]Pedram Ghamisi
LiDAR Data Classification Using Extinction Profiles and a Composite Kernel Support Vector Machine. IEEE Geosci. Remote. Sens. Lett. 14(5): 659-663 (2017) - [j21]Florian Klopfer
Assessing the Potential of a Low-Cost 3-D Sensor in Shallow-Water Bathymetry. IEEE Geosci. Remote. Sens. Lett. 14(8): 1388-1392 (2017) - [j20]Pedram Ghamisi, Bernhard Höfle
Hyperspectral and LiDAR Data Fusion Using Extinction Profiles and Deep Convolutional Neural Network. IEEE J. Sel. Top. Appl. Earth Obs. Remote. Sens. 10(6): 3011-3024 (2017) - [c5]Carolin Klonner, Melanie Eckle, Tomás Usón, Bernhard Höfle:
Quality Improvement of Remotely Volunteered Geographic Information via Country-Specific Mapping Instructions. ISCRAM 2017 - 2016
- [j19]Florian Hillen, Mario Gerdes, Benjamin Herfort, Bernhard Höfle
3D-MicroMapping - Crowdsourcing zur Klassifikation von 3D-Geodaten. AGIT Journal Angew. Geoinformatik 2: 156-161 (2016) - [j18]Carolin Klonner
Volunteered Geographic Information in Natural Hazard Analysis: A Systematic Literature Review of Current Approaches with a Focus on Preparedness and Mitigation. ISPRS Int. J. Geo Inf. 5(7): 103 (2016) - [j17]Sophie Crommelinck
Simulating an Autonomously Operating Low-Cost Static Terrestrial LiDAR for Multitemporal Maize Crop Height Measurements. Remote. Sens. 8(3): 205 (2016) - [c4]Aaron Charles Pattee, Bernhard Höfle, Christian Seitz:
Integrative 3D Recording Methods of Historic Architecture: Burg Hohenecken from Southwest Germany. DH 2016: 858-859 - [c3]Carolin Klonner, Sabrina Marx, Tomás Usón, Bernhard Höfle:
Risk Awareness Maps of Urban Flooding via OSM Field Papers- Case Study Santiago de Chile. ISCRAM 2016 - 2015
- [j16]Florian Hillen, Bernhard Höfle
Geo-reCAPTCHA: Crowdsourcing large amounts of geographic information from earth observation data. Int. J. Appl. Earth Obs. Geoinformation 40: 29-38 (2015) - [j15]Carolin Klonner
Updating digital elevation models via change detection and fusion of human and remote sensor data in urban environments. Int. J. Digit. Earth 8(2): 151-169 (2015) - [j14]Florian Hillen, Oliver Meynberg
Routing in Dense Human Crowds Using Smartphone Movement Data and Optical Aerial Imagery. ISPRS Int. J. Geo Inf. 4(2): 974-988 (2015) - [j13]Ivan Tomljenovic
Building Extraction from Airborne Laser Scanning Data: An Analysis of the State of the Art. Remote. Sens. 7(4): 3826-3862 (2015) - [c2]Aaron Charles Pattee, Bernhard Höfle
Integrative 3D recording methods of historic architecture Burg Hohenecken castle from southwest Germany. DigitalHERITAGE (1) 2015: 95-98 - 2014
- [j12]Bernhard Höfle
Radiometric Correction of Terrestrial LiDAR Point Cloud Data for Individual Maize Plant Detection. IEEE Geosci. Remote. Sens. Lett. 11(1): 94-98 (2014) - [j11]Martin Hämmerle
Comparison of Kinect and Terrestrial LiDAR Capturing Natural Karst Cave 3-D Objects. IEEE Geosci. Remote. Sens. Lett. 11(11): 1896-1900 (2014) - [j10]Mariana Belgiu
Ontology-Based Classification of Building Types Detected from Airborne Laser Scanning Data. Remote. Sens. 6(2): 1347-1366 (2014) - [j9]Helen Dorn, Michael Vetter, Bernhard Höfle
GIS-Based Roughness Derivation for Flood Simulations: A Comparison of Orthophotos, LiDAR and Crowdsourced Geodata. Remote. Sens. 6(2): 1739-1759 (2014) - [j8]Martin Hämmerle
Effects of Reduced Terrestrial LiDAR Point Density on High-Resolution Grain Crop Surface Models in Precision Agriculture. Sensors 14(12): 24212-24230 (2014) - 2013
- [j7]Bernhard Höfle
GIS-Based Detection of Gullies in Terrestrial LiDAR Data of the Cerro Llamoca Peatland (Peru). Remote. Sens. 5(11): 5851-5870 (2013) - [j6]Marco Helbich, Andreas Jochem, Werner Mücke, Bernhard Höfle
Boosting the predictive accuracy of urban hedonic house price models through airborne laser scanning. Comput. Environ. Urban Syst. 39: 81-92 (2013) - 2012
- [j5]Andreas Jochem, Bernhard Höfle
Area-wide roof plane segmentation in airborne LiDAR point clouds. Comput. Environ. Urban Syst. 36(1): 54-64 (2012) - 2011
- [j4]Markus Hollaus
Roughness Mapping on Various Vertical Scales Based on Full-Waveform Airborne Laser Scanning Data. Remote. Sens. 3(3): 503-523 (2011) - [j3]Andreas Jochem, Bernhard Höfle
Extraction of Vertical Walls from Mobile Laser Scanning Data for Solar Potential Assessment. Remote. Sens. 3(4): 650-667 (2011) - [j2]Andreas Jochem, Markus Hollaus
Estimation of Aboveground Biomass in Alpine Forests: A Semi-Empirical Approach Considering Canopy Transparency Derived from Airborne LiDAR Data. Sensors 11(1): 278-295 (2011) - [c1]Sandra Lanig, Arne Schilling, Michael Auer, Bernhard Höfle, Nicolas Billen, Alexander Zipf:
Interoperable integration of high precision 3D laser data and large scale geoanalysis in a SDI for Sutra inscriptions in Sichuan (China). Geoinformatik 2011: 79-84
2000 – 2009
- 2009
- [j1]Andreas Jochem, Bernhard Höfle
Automatic Roof Plane Detection and Analysis in Airborne Lidar Point Clouds for Solar Potential Assessment. Sensors 9(7): 5241-5262 (2009)
Coauthor Index
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