Abstract
Three-dimensional space perception is one of the most important capabilities for an autonomous mobile robot in order to operate a task in an unknown environment adaptively since the autonomous robot needs to detect the target object and estimate the 3D pose of the target object for performing given tasks efficiently. After the 3D point cloud is measured by an RGB-D camera, the autonomous robot needs to reconstruct a structure from the 3D point cloud with color information according to the given tasks since the point cloud is unstructured data. For reconstructing the unstructured point cloud, growing neural gas (GNG) based methods have been utilized in many research studies since GNG can learn the data distribution of the point cloud appropriately. However, the conventional GNG based methods have unsolved problems about the scalability and multi-viewpoint clustering. In this paper, therefore, we propose growing neural gas with different topologies (GNG-DT) as a new topological structure learning method for solving the problems. GNG-DT has multiple topologies of each property, while the conventional GNG method has a single topology of the input vector. In addition, the distance measurement in the winner node selection uses only the position information for preserving the environmental space of the point cloud. Next, we show several experimental results of the proposed method using simulation and RGB-D datasets measured by Kinect. In these experiments, we verified that our proposed method almost outperforms the other methods from the viewpoint of the quantization and clustering errors. Finally, we summarize our proposed method and discuss the future direction on this research.
Highlights
Three-dimensional space perception is one of the most important capabilities for an autonomous mobile robot in order to operate a task in an unknown environment adaptively since the autonomous robot needs to detect the target object and estimate the 3D pose of the target object for performing given tasks efficiently [1,2,3,4,5,6,7]
We propose growing neural gas with different topologies (GNG-DT) as a new topological structure learning method for addressing all of these issues, which were not incorporated in the previous work
This paper proposed growing neural gas with different topologies (GNG-DT) for perceiving the 3D environmental space from unknown 3D point cloud data
Summary
Three-dimensional space perception is one of the most important capabilities for an autonomous mobile robot in order to operate a task in an unknown environment adaptively since the autonomous robot needs to detect the target object and estimate the 3D pose of the target object for performing given tasks efficiently [1,2,3,4,5,6,7]. The other is to apply a weighted distance measurement in the winner node selection according to the importance of each property [47,48] In the former approach, Angelopoulou, et al proposed a background detection method based on mixture Gaussian distribution and CIE lab color space for generating topological structure of the human face and arm [45]. The weighted distance-based methods need a cutting algorithm of the edges for clustering the 2D/3D point cloud data according to the property after generating the topological structure In this way, the learning method of the 2D/3D point cloud with additional information that can generate the topological structure composed of the multiple properties and preserve the position space simultaneously is not realized. We summarize this paper and discuss the future direction to realize the 3D space perception
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