Mesh Convolutional Restricted Boltzmann Machines for Unsupervised Learning of Features With Structure Preservation on 3-D Meshes
Discriminative features of 3-D meshes are significant to many 3-D shape analysis tasks. However, handcrafted descriptors and traditional unsupervised 3-D feature learning methods suffer from several significant weaknesses: 1) the extensive human intervention is involved; 2) the local and global stru...
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| creator | Zhizhong Han Zhenbao Liu Junwei Han Chi-Man Vong Shuhui Bu Chen, Chun Lung Philip |
| description | Discriminative features of 3-D meshes are significant to many 3-D shape analysis tasks. However, handcrafted descriptors and traditional unsupervised 3-D feature learning methods suffer from several significant weaknesses: 1) the extensive human intervention is involved; 2) the local and global structure information of 3-D meshes cannot be preserved, which is in fact an important source of discriminability; 3) the irregular vertex topology and arbitrary resolution of 3-D meshes do not allow the direct application of the popular deep learning models; 4) the orientation is ambiguous on the mesh surface; and 5) the effect of rigid and nonrigid transformations on 3-D meshes cannot be eliminated. As a remedy, we propose a deep learning model with a novel irregular model structure, called mesh convolutional restricted Boltzmann machines (MCRBMs). MCRBM aims to simultaneously learn structure-preserving local and global features from a novel raw representation, local function energy distribution. In addition, multiple MCRBMs can be stacked into a deeper model, called mesh convolutional deep belief networks (MCDBNs). MCDBN employs a novel local structure preserving convolution (LSPC) strategy to convolve the geometry and the local structure learned by the lower MCRBM to the upper MCRBM. LSPC facilitates resolving the challenging issue of the orientation ambiguity on the mesh surface in MCDBN. Experiments using the proposed MCRBM and MCDBN were conducted on three common aspects: global shape retrieval, partial shape retrieval, and shape correspondence. Results show that the features learned by the proposed methods outperform the other state-of-the-art 3-D shape features. |
| doi_str_mv | 10.1109/TNNLS.2016.2582532 |
| format | Article |
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However, handcrafted descriptors and traditional unsupervised 3-D feature learning methods suffer from several significant weaknesses: 1) the extensive human intervention is involved; 2) the local and global structure information of 3-D meshes cannot be preserved, which is in fact an important source of discriminability; 3) the irregular vertex topology and arbitrary resolution of 3-D meshes do not allow the direct application of the popular deep learning models; 4) the orientation is ambiguous on the mesh surface; and 5) the effect of rigid and nonrigid transformations on 3-D meshes cannot be eliminated. As a remedy, we propose a deep learning model with a novel irregular model structure, called mesh convolutional restricted Boltzmann machines (MCRBMs). MCRBM aims to simultaneously learn structure-preserving local and global features from a novel raw representation, local function energy distribution. In addition, multiple MCRBMs can be stacked into a deeper model, called mesh convolutional deep belief networks (MCDBNs). MCDBN employs a novel local structure preserving convolution (LSPC) strategy to convolve the geometry and the local structure learned by the lower MCRBM to the upper MCRBM. LSPC facilitates resolving the challenging issue of the orientation ambiguity on the mesh surface in MCDBN. Experiments using the proposed MCRBM and MCDBN were conducted on three common aspects: global shape retrieval, partial shape retrieval, and shape correspondence. Results show that the features learned by the proposed methods outperform the other state-of-the-art 3-D shape features.</description><identifier>ISSN: 2162-237X</identifier><identifier>EISSN: 2162-2388</identifier><identifier>DOI: 10.1109/TNNLS.2016.2582532</identifier><identifier>PMID: 28113522</identifier><identifier>CODEN: ITNNAL</identifier><language>eng</language><publisher>United States: IEEE</publisher><subject>3-D mesh ; Belief networks ; Convolution ; Energy distribution ; Feature extraction ; Finite element method ; Laplace–Beltrami operator ; Machine learning ; mesh convolutional deep belief networks (MCDBNs) ; mesh convolutional restricted Boltzmann machines (MCRBMs) ; Preservation ; Retrieval ; Shape ; Shape recognition ; Solid modeling ; State of the art ; Topology ; Unsupervised learning</subject><ispartof>IEEE transaction on neural networks and learning systems, 2017-10, Vol.28 (10), p.2268-2281</ispartof><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. 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However, handcrafted descriptors and traditional unsupervised 3-D feature learning methods suffer from several significant weaknesses: 1) the extensive human intervention is involved; 2) the local and global structure information of 3-D meshes cannot be preserved, which is in fact an important source of discriminability; 3) the irregular vertex topology and arbitrary resolution of 3-D meshes do not allow the direct application of the popular deep learning models; 4) the orientation is ambiguous on the mesh surface; and 5) the effect of rigid and nonrigid transformations on 3-D meshes cannot be eliminated. As a remedy, we propose a deep learning model with a novel irregular model structure, called mesh convolutional restricted Boltzmann machines (MCRBMs). MCRBM aims to simultaneously learn structure-preserving local and global features from a novel raw representation, local function energy distribution. In addition, multiple MCRBMs can be stacked into a deeper model, called mesh convolutional deep belief networks (MCDBNs). MCDBN employs a novel local structure preserving convolution (LSPC) strategy to convolve the geometry and the local structure learned by the lower MCRBM to the upper MCRBM. LSPC facilitates resolving the challenging issue of the orientation ambiguity on the mesh surface in MCDBN. Experiments using the proposed MCRBM and MCDBN were conducted on three common aspects: global shape retrieval, partial shape retrieval, and shape correspondence. Results show that the features learned by the proposed methods outperform the other state-of-the-art 3-D shape features.</description><subject>3-D mesh</subject><subject>Belief networks</subject><subject>Convolution</subject><subject>Energy distribution</subject><subject>Feature extraction</subject><subject>Finite element method</subject><subject>Laplace–Beltrami operator</subject><subject>Machine learning</subject><subject>mesh convolutional deep belief networks (MCDBNs)</subject><subject>mesh convolutional restricted Boltzmann machines (MCRBMs)</subject><subject>Preservation</subject><subject>Retrieval</subject><subject>Shape</subject><subject>Shape recognition</subject><subject>Solid modeling</subject><subject>State of the art</subject><subject>Topology</subject><subject>Unsupervised learning</subject><issn>2162-237X</issn><issn>2162-2388</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNpdkUtv1DAUhS0EolXpHwAJWWLDJoOvH4mzhIFCpWmLaCvYWU5yw7jK2IOdVIIVPx2nM8yiliW_vnuujg8hL4EtAFj97ubycnW94AzKBVeaK8GfkGMOJS-40PrpYV_9OCKnKd2xPEqmSlk_J0dcAwjF-TH5e4FpTZfB34dhGl3wdqDfMI3RtSN29EMYxj8b6z29sO3aeUy0D5He-jRtMd67lJkV2uid_0lDT8_QjlPM1Hc3run1GKd2PtOv-S7zdu5A8xTFRzp3xvSCPOvtkPB0v56Q27NPN8svxerq8_ny_apohYKx6GohVNspqbOvtm6aDlQjBK8sWMlsXTGpSturmnPV17y3orFKSCy10rrvQJyQtzvdbQy_puzQbFxqcRisxzAlA7qEEqSuZEbfPELvwhTzzyTDoZJScQmzIN9RbQwpRezNNrqNjb8NMDNHZB4iMnNEZh9RLnq9l56aDXaHkv-BZODVDnCIeHiuFMu2QfwDHAqVfQ</recordid><startdate>20171001</startdate><enddate>20171001</enddate><creator>Zhizhong Han</creator><creator>Zhenbao Liu</creator><creator>Junwei Han</creator><creator>Chi-Man Vong</creator><creator>Shuhui Bu</creator><creator>Chen, Chun Lung Philip</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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In addition, multiple MCRBMs can be stacked into a deeper model, called mesh convolutional deep belief networks (MCDBNs). MCDBN employs a novel local structure preserving convolution (LSPC) strategy to convolve the geometry and the local structure learned by the lower MCRBM to the upper MCRBM. LSPC facilitates resolving the challenging issue of the orientation ambiguity on the mesh surface in MCDBN. Experiments using the proposed MCRBM and MCDBN were conducted on three common aspects: global shape retrieval, partial shape retrieval, and shape correspondence. Results show that the features learned by the proposed methods outperform the other state-of-the-art 3-D shape features.</abstract><cop>United States</cop><pub>IEEE</pub><pmid>28113522</pmid><doi>10.1109/TNNLS.2016.2582532</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0002-0030-275X</orcidid></addata></record> |
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| subjects | 3-D mesh Belief networks Convolution Energy distribution Feature extraction Finite element method Laplace–Beltrami operator Machine learning mesh convolutional deep belief networks (MCDBNs) mesh convolutional restricted Boltzmann machines (MCRBMs) Preservation Retrieval Shape Shape recognition Solid modeling State of the art Topology Unsupervised learning |
| title | Mesh Convolutional Restricted Boltzmann Machines for Unsupervised Learning of Features With Structure Preservation on 3-D Meshes |
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