eprintid: 36930 rev_number: 11 eprint_status: archive userid: 5878 dir: disk0/00/03/69/30 datestamp: 2025-07-22 15:11:36 lastmod: 2025-07-24 07:32:23 status_changed: 2025-07-22 15:11:36 type: doctoralThesis metadata_visibility: show creators_name: Höfle, Bernhard title: Detection and utilization of the information potential of airborne laser scanning point cloud and intensity data by developing a management and analysis system title_de: Detektion und Anwendung des Informationspotenzials von flugzeuggestützten Laserscanner Punktwolken- und Intensitätsdaten durch die Entwicklung eines Verwaltungs- und Analysesystems subjects: ddc-550 divisions: i-120700 abstract: In recent years Airborne Laser Scanning (ALS) evolved to the state-of-the-art technique for topographic data acquisition. High resolution and highly accurate digital elevation models can be produced with a high degree of automation. Especially in vegetated areas and in areas with low surface texture this active remote sensing technique surpasses traditional aerial imagery in acquiring terrain information. Until now, primarily the rasterized elevation models (Digital Terrain and Surface Models) were used due to the simple data model (regular grid) and the multitude of existing image/raster analysis methods. The original measurements – the ALS point cloud – are generally delivered to end-users but not often used because of the lack of management and analysis strategies that can handle the incidental data volume (>1 pt/m2 multiplied by scanned area). The point cloud – tuples of 3D coordinates, a value for received signal intensity and a timestamp – contains the highest degree of information as it represents the three-dimensional, ungeneralized result of ALS data acquisition. This thesis aims to utilize the full information inherent in the ALS point cloud and the intensity value. Therefore, a new concept for spatial data management of laser points and their additional information (e.g. intensity, timestamp, scanner positions) is introduced. The Geographic Information System (GIS) is used to bridge existing raster processing methods and novel point cloud management and analysis methods. The developed information system “LISA” (LIdar Surface Analysis) integrates existing Open Source software (e.g. GRASS GIS) allowing a fast and easy implementation of new processing tools, which can make use of both, ALS elevation models and the original point cloud. Point cloud management is performed in an external spatial database management system (PostgreSQL/PostGIS). A new ALS data model was developed and the existing spatial index was extended to improve performance. Previous research studies working with signal intensity of pulsed ALS systems stated that there is a large potential for supporting surface classification and object detection. Before making use of the intensity value, it has to be corrected for known influences (e.g. emitted power, spherical loss, topographic and atmospheric effects), which are derived from the radar equation. This thesis introduces, implements and evaluates two fully automatic approaches for intensity correction to derive a value proportional to surface reflectance, which is well suited for surface classification. The first method, the data-driven approach, empir- ically determines a correction function accounting for influences correlating with range (distance scanner-target). The second method, the model-driven approach, derives individual correction factors for each laser point by applying the radar equation. The “disturbing” effects could be successfully reduced (90% and a delineation accuracy <2 m could be achieved. The second application introduces a novel procedure for building detection and roof facet modeling and classification by combining object-based image and point cloud analysis. This thesis contributes the framework (LISA system) for point cloud analysis put on top of the building detection algorithm. The final roof modeling originates from a hierarchical, multi-resolution object detection. Firstly, the building polygons are derived from a fill sinks segmentation on the inverted Digital Surface Model. Secondly, these building objects are used to extract the corresponding laser points for each building. Finally, a point cloud segmentation task (region growing) using the normal vectors in each laser point (derived by plane fitting in a defined neighborhood) is applied to identify planar objects (roof patches). The 3D roof facets are further classified by their slope. This result can be used as input for a multitude of applications, such as snow load capacity modeling or photovoltaics site analysis. This thesis concludes that efficient ALS data management integrated in a GIS environment allows moving some steps forward to the major goal of the “detection and utilization of the the full information potential”. Without additional costs added value can be generated out of existing ALS datasets (e.g. intensity correction). Future research should incorporate state-of-the-art ALS data (full-waveform) as well as terrestrial laser scanning data. abstract_translated_text: Flugzeuggestütztes Laserscanning (auch Airborne Laser Scanning oder kurz ALS) entwickelte sich in den letzten Jahren zu einer operationell einsetzbaren Methode zur topographischen Erfassung der Erdoberfläche. Vor allem in Gebieten mit hoher Vegetation und schwacher Oberflächentextur übertrifft diese aktive Fernerkundungsmethode traditionelle optische Verfahren (z.B. Luftbildphotographie) in der Erfassung des Geländes (Boden). Bis zum jetzigen Zeitpunkt wurden vor allem die hoch auflösenden und hoch genauen digitalen Gelände- und Oberflächenmodelle für weitere Analysen herangezogen, da es dafür bereits eine Vielzahl von Bild- bzw. Rasteranalysewerkzeugen gibt. Das eigentliche Messergebnis, die originäre Punktwolke, wird zwar oft mitausgeliefert, aber meistens nicht verwendet, da es an Verwaltungs- und Analysetools für diese große Datenmenge mangelt (>1 Punkt/m2 multipliziert mit der gescannten Fläche). Diese Punktwolke setzt sich aus vielen Einzelmessungen zusammen, bestehend aus den 3D-Koordinaten, einem Wert für die Intensität des reflektierten Laserimpulses und einem Zeitstempel. Das Ziel dieser Arbeit ist, den vollen Informationsgehalt der ALS Punktwolke zu nutzen, indem ein neues Konzept für die Verwaltung dieser räumlichen Daten eingeführt wird. Das Geographische Informationssystem (GIS) wird dazu als Mittler zwischen bestehenden rasterbasierten Algorithmen und der neu entwickelten Punktwolkenverwaltung herangezogen. Das entwickelte Informationssystem “LISA” (LIdar Surface Analysis) verwendet ausschließlich bestehende Open Source Software (z.B. GRASS GIS), wodurch eine schnelle und einfache Implementierung neuer Auswertestrategien, die GIS- und Punktwolkenfunktionalität nützen, möglich wird. Die Punktwolkenverwaltung wird unter Verwendung des Datenbankmanagementsystems PostgreSQL/PostGIS umgesetzt. Hierfür wird ein spezielles Datenmodell für ALS Daten entworfen sowie der bestehende räumliche Index verbessert. ... abstract_translated_lang: ger date: 2007 id_scheme: DOI id_number: 10.11588/heidok.00036930 ppn_swb: 1931690642 own_urn: urn:nbn:de:bsz:16-heidok-369305 advisor: HASH(0x55bdeac98248) language: eng bibsort: HOFLEBERNHDETECTIONA2007 full_text_status: public place_of_pub: Innsbruck citation: Höfle, Bernhard (2007) Detection and utilization of the information potential of airborne laser scanning point cloud and intensity data by developing a management and analysis system. [Dissertation] document_url: https://archiv.ub.uni-heidelberg.de/volltextserver/36930/1/hoefle_dissertation_2007.pdf