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== Abstract == | == Abstract == | ||
− | The modern emergence of automation in many industries has given impetus to extensive research into mobile robotics. Novel perception technologies now enable cars to drive autonomously, tractors to till a field automatically and underwater robots to construct pipelines. An essential requirement to facilitate both perception and autonomous navigation is the analysis of the 3D environment using sensors like laser scanners or stereo cameras. 3D sensors generate a very large number of 3D data points when sampling object shapes within an environment, but crucially do not provide any intrinsic information about the environment which the robots operate within. | + | The modern emergence of automation in many industries has given impetus to extensive research into mobile robotics. Novel perception technologies now enable cars to drive autonomously, tractors to till a field automatically and underwater robots to construct pipelines. An essential requirement to facilitate both perception and autonomous navigation is the analysis of the 3D environment using sensors like laser scanners or stereo cameras. 3D sensors generate a very large number of 3D data points when sampling object shapes within an environment, but crucially do not provide any intrinsic information about the environment which the robots operate within. This work focuses on the fundamental task of 3D shape reconstruction and modelling from 3D point clouds. The novelty lies in the representation of surfaces by algebraic functions having limited support, which enables the extraction of smooth consistent implicit shapes from noisy samples with a heterogeneous density. The minimization of total variation of second differential degree makes it possible to enforce planar surfaces which often occur in man-made environments. Applying the new technique means that less accurate, low-cost 3D sensors can be employed without sacrificing the 3D shape reconstruction accuracy. |
Document type: Part of book or chapter of book | Document type: Part of book or chapter of book | ||
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== Original document == | == Original document == | ||
+ | <pdf>Media:Funk_et_al_2016a_3121_Springer_Eugen_Paper_Feb 2016.pdf</pdf> | ||
The different versions of the original document can be found in: | The different versions of the original document can be found in: | ||
* [http://oro.open.ac.uk/45399/1/Springer_Eugen_Paper_Feb%202016.pdf http://oro.open.ac.uk/45399/1/Springer_Eugen_Paper_Feb%202016.pdf] | * [http://oro.open.ac.uk/45399/1/Springer_Eugen_Paper_Feb%202016.pdf http://oro.open.ac.uk/45399/1/Springer_Eugen_Paper_Feb%202016.pdf] |
The modern emergence of automation in many industries has given impetus to extensive research into mobile robotics. Novel perception technologies now enable cars to drive autonomously, tractors to till a field automatically and underwater robots to construct pipelines. An essential requirement to facilitate both perception and autonomous navigation is the analysis of the 3D environment using sensors like laser scanners or stereo cameras. 3D sensors generate a very large number of 3D data points when sampling object shapes within an environment, but crucially do not provide any intrinsic information about the environment which the robots operate within. This work focuses on the fundamental task of 3D shape reconstruction and modelling from 3D point clouds. The novelty lies in the representation of surfaces by algebraic functions having limited support, which enables the extraction of smooth consistent implicit shapes from noisy samples with a heterogeneous density. The minimization of total variation of second differential degree makes it possible to enforce planar surfaces which often occur in man-made environments. Applying the new technique means that less accurate, low-cost 3D sensors can be employed without sacrificing the 3D shape reconstruction accuracy.
Document type: Part of book or chapter of book
Published on 11/02/16
Accepted on 11/02/16
Submitted on 11/02/16
Volume 2016, 2016
DOI: 10.1007/978-3-319-29971-6_15
Licence: CC BY-NC-SA license
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