An architecture for online semantic labeling on UGVS
We describe an architecture to provide online semantic labeling capabilities to field robots operating in urban environments. At the core of our system is the stacked hierarchical classifier developed by Munoz et al.,1 which classifies regions in monocular color images using models derived from hand...
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2013
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sg-smu-ink.sis_research-92352023-10-26T03:30:49Z An architecture for online semantic labeling on UGVS SUPPE, Arne NAVARRO-SERMENT, Luis MUNOZ, Daniel BAGNELL, Drew HEBERT, Martial We describe an architecture to provide online semantic labeling capabilities to field robots operating in urban environments. At the core of our system is the stacked hierarchical classifier developed by Munoz et al.,1 which classifies regions in monocular color images using models derived from hand labeled training data. The classifier is trained to identify buildings, several kinds of hard surfaces, grass, trees, and sky. When taking this algorithm into the real world, practical concerns with difficult and varying lighting conditions require careful control of the imaging process. First, camera exposure is controlled by software, examining all of the image’s pixels, to compensate for the poorly performing, simplistic algorithm used on the camera. Second, by merging multiple images taken with different exposure times, we are able to synthesize images with higher dynamic range than the ones produced by the sensor itself. The sensor’s limited dynamic range makes it difficult to, at the same time, properly expose areas in shadow along with high albedo surfaces that are directly illuminated by the sun. Texture is a key feature used by the classifier, and under/over exposed regions lacking texture are a leading cause of misclassifications. The results of the classifier are shared with higher-lev elements operating in the UGV in order to perform tasks such as building identification from a distance and finding traversable surfaces. 2013-05-01T07:00:00Z text application/pdf https://ink.library.smu.edu.sg/sis_research/8232 info:doi/10.1117/12.2015806 https://ink.library.smu.edu.sg/context/sis_research/article/9235/viewcontent/an_architecture.pdf http://creativecommons.org/licenses/by-nc-nd/4.0/ Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University Semantic labeling scene understanding unmanned vehicles computer vision Graphics and Human Computer Interfaces |
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Semantic labeling scene understanding unmanned vehicles computer vision Graphics and Human Computer Interfaces |
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Semantic labeling scene understanding unmanned vehicles computer vision Graphics and Human Computer Interfaces SUPPE, Arne NAVARRO-SERMENT, Luis MUNOZ, Daniel BAGNELL, Drew HEBERT, Martial An architecture for online semantic labeling on UGVS |
| description |
We describe an architecture to provide online semantic labeling capabilities to field robots operating in urban environments. At the core of our system is the stacked hierarchical classifier developed by Munoz et al.,1 which classifies regions in monocular color images using models derived from hand labeled training data. The classifier is trained to identify buildings, several kinds of hard surfaces, grass, trees, and sky. When taking this algorithm into the real world, practical concerns with difficult and varying lighting conditions require careful control of the imaging process. First, camera exposure is controlled by software, examining all of the image’s pixels, to compensate for the poorly performing, simplistic algorithm used on the camera. Second, by merging multiple images taken with different exposure times, we are able to synthesize images with higher dynamic range than the ones produced by the sensor itself. The sensor’s limited dynamic range makes it difficult to, at the same time, properly expose areas in shadow along with high albedo surfaces that are directly illuminated by the sun. Texture is a key feature used by the classifier, and under/over exposed regions lacking texture are a leading cause of misclassifications. The results of the classifier are shared with higher-lev elements operating in the UGV in order to perform tasks such as building identification from a distance and finding traversable surfaces. |
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text |
| author |
SUPPE, Arne NAVARRO-SERMENT, Luis MUNOZ, Daniel BAGNELL, Drew HEBERT, Martial |
| author_facet |
SUPPE, Arne NAVARRO-SERMENT, Luis MUNOZ, Daniel BAGNELL, Drew HEBERT, Martial |
| author_sort |
SUPPE, Arne |
| title |
An architecture for online semantic labeling on UGVS |
| title_short |
An architecture for online semantic labeling on UGVS |
| title_full |
An architecture for online semantic labeling on UGVS |
| title_fullStr |
An architecture for online semantic labeling on UGVS |
| title_full_unstemmed |
An architecture for online semantic labeling on UGVS |
| title_sort |
architecture for online semantic labeling on ugvs |
| publisher |
Institutional Knowledge at Singapore Management University |
| publishDate |
2013 |
| url |
https://ink.library.smu.edu.sg/sis_research/8232 https://ink.library.smu.edu.sg/context/sis_research/article/9235/viewcontent/an_architecture.pdf |
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