%0 Conference Paper %1 Golovinskiy2010 %A Golovinskiy, A. %A Kim, VG %A Funkhouser, T. %B IEEE 12th International Conference on Computer Vision, 2009 %D 2010 %K urban 3DPointCloud %P 2154--2161 %T Shape-based recognition of 3d point clouds in urban environments %X This paper investigates the design of a system for recognizing objects in 3D point clouds of urban environments. The system is decomposed into four steps: locating, segmenting, characterizing, and classifying clusters of 3D points. Specifically, we first cluster nearby points to form a set of potential object locations (with hierarchical clustering). Then, we segment points near those locations into foreground and background sets (with a graph-cut algorithm). Next, we build a feature vector for each point cluster (based on both its shape and its context). Finally, we label the feature vectors using a classifier trained on a set of manually labeled objects. The paper presents several alternative methods for each step. We quantitatively evaluate the system and tradeoffs of different alternatives in a truthed part of a scan of Ottawa that contains approximately 100 million points and 1000 objects of interest. Then, we use this truth data as a training set to recognize objects amidst approximately 1 billion points of the remainder of the Ottawa scan.

@inproceedings{Golovinskiy2010, abstract = {This paper investigates the design of a system for recognizing objects in 3D point clouds of urban environments. The system is decomposed into four steps: locating, segmenting, characterizing, and classifying clusters of 3D points. Specifically, we first cluster nearby points to form a set of potential object locations (with hierarchical clustering). Then, we segment points near those locations into foreground and background sets (with a graph-cut algorithm). Next, we build a feature vector for each point cluster (based on both its shape and its context). Finally, we label the feature vectors using a classifier trained on a set of manually labeled objects. The paper presents several alternative methods for each step. We quantitatively evaluate the system and tradeoffs of different alternatives in a truthed part of a scan of Ottawa that contains approximately 100 million points and 1000 objects of interest. Then, we use this truth data as a training set to recognize objects amidst approximately 1 billion points of the remainder of the Ottawa scan.}, added-at = {2010-12-09T16:35:41.000+0100}, author = {Golovinskiy, A. and Kim, VG and Funkhouser, T.}, biburl = {https://www.bibsonomy.org/bibtex/20d7dbbb1b18e1db906545be33291eccf/ipi_jn}, booktitle = {IEEE 12th International Conference on Computer Vision, 2009}, file = {:E\:\\Literatursammlung\\Proceedings\\Sonstige\\Golovinskiy (2009) - Shape based recognition of 3d point clouds in urban environments.pdf:PDF}, interhash = {1a272e853f25eff5cbb54f6a47acd525}, intrahash = {0d7dbbb1b18e1db906545be33291eccf}, issn = {1550-5499}, keywords = {urban 3DPointCloud}, organization = {IEEE}, pages = {2154--2161}, timestamp = {2010-12-09T16:35:41.000+0100}, title = {Shape-based recognition of 3d point clouds in urban environments}, year = 2010 }