TY - GEN
T1 - Accelerating the computation of canonical forms for 3D nonrigid objects using Multidimensional Scaling
AU - Shamai, Gil
AU - Zibulevsky, Michael
AU - Kimmel, Ron
N1 - Publisher Copyright: © The Eurographics Association 2015.
PY - 2015
Y1 - 2015
N2 - The analysis of 3D nonrigid objects usually involves the need to deal with a large number of degrees of freedom. When trying to match two such objects, one approach is to map the surfaces into a domain in which the matching process is simple to execute. Limiting the discussion to almost isometric mappings, which describe most natural deformations in nature, one could resort to Canonical forms. Such forms translate the surface's intrinsic geometry into an extrinsic one in a Euclidean space, thus eliminating the effect of deformations at the expense of (hopefully) minor embedding errors. Multidimensional Scaling (MDS) is a dimensionality reduction technique that can be used to compute canonical forms of 3D-objects, by first evaluating the pairwise geodesic distances between surface points, and then embedding the distances in a lower dimensional Euclidean space. The native computational and space complexities involved in describing such inter-geodesic distances is quadratic in the number of surface points, a property that could be prohibiting in various scenarios. We present an acceleration framework for multidimensional scaling, by accurately approximating the pairwise distance maps. We show how the proposed Nyström Multidimensional Scaling (NMDS) framework can be used to compute canonical forms in quasi-linear time and linear space complexities in the number of data points. It allows us to efficiently deal with high resolution structures without giving up the embedding accuracy.
AB - The analysis of 3D nonrigid objects usually involves the need to deal with a large number of degrees of freedom. When trying to match two such objects, one approach is to map the surfaces into a domain in which the matching process is simple to execute. Limiting the discussion to almost isometric mappings, which describe most natural deformations in nature, one could resort to Canonical forms. Such forms translate the surface's intrinsic geometry into an extrinsic one in a Euclidean space, thus eliminating the effect of deformations at the expense of (hopefully) minor embedding errors. Multidimensional Scaling (MDS) is a dimensionality reduction technique that can be used to compute canonical forms of 3D-objects, by first evaluating the pairwise geodesic distances between surface points, and then embedding the distances in a lower dimensional Euclidean space. The native computational and space complexities involved in describing such inter-geodesic distances is quadratic in the number of surface points, a property that could be prohibiting in various scenarios. We present an acceleration framework for multidimensional scaling, by accurately approximating the pairwise distance maps. We show how the proposed Nyström Multidimensional Scaling (NMDS) framework can be used to compute canonical forms in quasi-linear time and linear space complexities in the number of data points. It allows us to efficiently deal with high resolution structures without giving up the embedding accuracy.
UR - http://www.scopus.com/inward/record.url?scp=85018187630&partnerID=8YFLogxK
U2 - 10.2312/3DOR.20151057
DO - 10.2312/3DOR.20151057
M3 - منشور من مؤتمر
T3 - Eurographics Workshop on 3D Object Retrieval, EG 3DOR
SP - 71
EP - 78
BT - EG 3DOR 2015 - Eurographics 2015 Workshop on 3D Object Retrieval
A2 - Spagnuolo, Michela
A2 - Van Gool, Luc
A2 - Pratikakis, Ioannis
A2 - Theoharis, Theoharis
A2 - Veltkamp, Remco
PB - Eurographics Association
T2 - 8th Eurographics Workshop on 3D Object Retrieval, 3DOR 2015
Y2 - 2 May 2015 through 3 May 2015
ER -