12.3.3 Surface Matching, Deformable Surface Matching

Merickel, M.,
3D Reconstruction: The Registration Problem,
CVGIP(42), No. 2, May 1988, pp. 206-219. BibRef 8805

Goshtasby, A., Stockman, G.C., and Page, C.,
A Region-Based Approach to Digital Image Registration with Subpixel Accuracy,
GeoEl(24), No. 3, 1986, pp. 390-399. BibRef 8600

Radack, G.M., and Badler, N.I.,
Local Matching of Surfaces Using a Boundary-Centered Radial Decomposition,
CVGIP(45), No. 3, March 1989, pp. 380-396.
WWW Version. The 3-D version of See also Jigsaw Puzzle Matching Using a Boundary-Centered Polar Encoding. BibRef 8903

Kim, W.Y., and Kak, A.C.,
3-D Object Recognition Using Bipartite Matching Embedded in Discrete Relaxation,
PAMI(13), No. 3, March 1991, pp. 224-251.
IEEE Abstract. IEEE Top Reference.
WWW Version. Relaxation, Matching. Use the Bipartite (yes/no) matching to eliminate many bad matches and discrete relaxation for the hard part. Matching based on 3-D surfaces. The relaxation requires only a few (2) iterations for 30 surfaces. BibRef 9103

Chen, C.H., and Kak, A.C.,
A Robot Vision for Recovering 3-D Objects in Low-Order Polynomial Time,
SMC(19), No. 6, November/December 1989, pp. 1535-1563. BibRef 8911
And:
3D-POLY: A Robot Vision System for Recognizing Objects in Occluded Environments,
TR-EE 88-48, School of Electrical Engineering, PurdueUniversity, December 1988. Matching, Tree Search. Recognize Three-Dimensional Objects. Region extraction, surface normals for representation, model driven tree search for recognition. BibRef

Yuille, A.L.,
Generalized Deformable Models, Statistical Physics and Matching Problems,
NeurComp(2), No. 1, 1990, pp. 1-24. Problems arise with hill-climbing techniques. Mean-Field annealing. BibRef 9000

Moshfeghi, M., Ranganath, S., and Nawyn, K.,
Three-Dimensional Elastic Matching of Volumes,
IP(3), No. 2, March 1994, pp. 128-138.
WWW Version. BibRef 9403

Chuang, J.H.,
A Potential-Based Approach for Shape-Matching and Recognition,
PR(29), No. 3, March 1996, pp. 463-470.
WWW Version. BibRef 9603

Feldmar, J.[Jacques], Ayache, N.J.[Nicholas J.], Betting, F.[Fabienne],
3D-2D Projective Registration of Free-Form Curves and Surfaces,
CVIU(65), No. 3, March 1997, pp. 403-424. 9705
WWW Version. BibRef
Earlier: ICCV95(549-556).
WWW Version.
WWW Version. 3-D curves or surfaces. BibRef

Yamany, S.M.[Sameh M.], Ahmed, M.N.[Mohamed N.], Farag, A.A.[Aly A.],
A new genetic-based technique for matching 3-D curves and surfaces,
PR(32), No. 10, October 1999, pp. 1817-1820.
WWW Version. BibRef 9910

Brett, A.D., Hill, A., Taylor, C.J.,
A method of 3D surface correspondence and interpolation for merging shape examples,
IVC(17), No. 8, June 1999, pp. 635-642.
WWW Version. BibRef 9906

Pedersini, F.[Federico], Pigazzini, P.[Pasquale], Sarti, A.[Augusto], Tubaro, S.[Stefano],
3D area matching with arbitrary multiview geometry,
SP:IC(14), No. 1-2, November 1998, pp. 71-94.
WWW Version. BibRef 9811

Younes, L.[Laurent],
Optimal matching between shapes via elastic deformations,
IVC(17), No. 5/6, April 1999, pp. 381-389.
WWW Version. BibRef 9904

Thompson, P.M., Toga, A.W.,
A surface-based technique for warping three-dimensional images of the brain,
MedImg(15), No. 4, August 1996, pp. 402-417.
IEEE Top Reference. 0203 Brain. BibRef

Toga, A.W., Thompson, P.M.,
The role of image registration in brain mapping,
IVC(19), No. 1-2, January 2001, pp. 3-24.
WWW Version. 0101 BibRef

Wang, Y.[Yalin], Chiang, M.C.[Ming-Chang], Thompson, P.M.[Paul M.],
Mutual Information-Based 3D Surface Matching with Applications to Face Recognition and Brain Mapping,
ICCV05(I: 527-534).
WWW Version. 0510 BibRef

Wang, Y.[Yalin], Lui, L.M., Gu, X.F.[Xian-Feng], Hayashi, K.M.[Kiralee M.], Chan, T.F.[Tony F.], Toga, A.W., Thompson, P.M.[Paul M.], Yau, S.T.[Shing-Tung],
Brain Surface Conformal Parameterization Using Riemann Surface Structure,
MedImg(26), No. 6, June 2007, pp. 853-865.
WWW Version. 0706 BibRef

Wang, Y.[Yalin], Gu, X.F.[Xian-Feng], Hayashi, K.M.[Kiralee M.], Chan, T.F.[Tony F.], Thompson, P.M.[Paul M.], Yau, S.T.[Shing-Tung],
Surface Parameterization Using Riemann Surface Structure,
ICCV05(II: 1061-1066).
WWW Version. 0510To allow complex topology (and changes in topology). BibRef

Li, Z.L.[Zhi-Lin], Xu, Z.[Zhu], Cen, M.[Minyi], Ding, X.L.[Xiao-Li],
Robust Surface Matching for Automated Detection of Local Deformations Using Least-Median-of-Squares Estimator,
PhEngRS(67), No. 11, November 2001, pp. 1283-1292. The least-median-of-squares estimator with the least height difference method produce the best results.
WWW Version. 0201 BibRef

Huot, E.[Etienne], Yahia, H.[Hussein], Cohen, I.[Isaac], Herlin, I.[Isabelle],
Matching Structures by Computing Minimal Paths on a Manifold,
JVCIR(13), No. 1/2, March/June 2002, pp. 302-312.
WWW Version. 0204 BibRef
Earlier:
Surface Matching with Large Deformations and Arbitrary Topology: A Geodesic Distance Evolution Scheme on a 3-Manifold,
ECCV00(I: 769-783).
WWW Version. 0003
PDF Version. BibRef

Yahia, H., Huot, E., Herlin, I., Cohen, I.,
Geodesic Distance Evolution of Surfaces: A New Method for Matching Surfaces,
CVPR00(I: 663-668).
IEEE Abstract. IEEE Top Reference.
WWW Version. 0005
PDF Version. BibRef

Hellier, P.[Pierre], Barillot, C.[Christian],
Coupling Dense and Landmark-Based Approaches for Non Rigid Registration,
MedImg(22), No. 2, February 2003, pp. 217-227.
IEEE Top Reference. 0304 BibRef
Earlier: INRIARR-4076, November 2000.
HTML Version.
Postscript Version.
PDF Version. 0105 BibRef

Barillot, C.[Christian], Hellier, P.[Pierre],
Cooperation Between Level Set Techniques and Dense 3d Registration for the Segmentation of Brain Structures,
ICPR00(Vol I: 991-994).
WWW Version.
HTML Version. 0009 BibRef

Barillot, C., Hellier, P., Pratikakis, I.E.,
Robust multi-scale non-rigid registration of 3D ultrasound images,
ScaleSpace01(xx-yy). 0106 BibRef

Hellier, P.[Pierre], Barillot, C.[Christian], Mémin, É.[Étienne], Pérez, P.[Patrick],
An Energy-based Framework for Dense 3D Registration of Volumetric Brain Images,
CVPR00(II: 270-275).
IEEE Abstract. IEEE Top Reference.
WWW Version. 0005 See also Dense Estimation of Fluid Flows. BibRef

Huang, X.L.[Xiao-Lei], Paragios, N.[Nikos], Metaxas, D.N.[Dimitris N.],
Shape Registration in Implicit Spaces Using Information Theory and Free Form Deformations,
PAMI(28), No. 8, August 2006, pp. 1303-1318.
WWW Version. 0606Apply to medical and to face registration. BibRef

Vasa, L.[Libor], Skala, V.[Vaclav],
CODDYAC: Connectivity Driven Dynamic Mesh Compression,
3DTV07(1-4).
WWW Version. 0705 BibRef
Earlier:
A Spatio-temporal Metric for Dynamic Mesh Comparison,
AMDO06(29-37).
WWW Version. 0607 BibRef

Mizuta, S.[Shinobu], Matsuda, T.[Tetsuya],
Description of Digital Images by Region-Based Contour Trees,
ICIAR05(549-558).
WWW Version. 0509Describe by iso-surfaces. BibRef

Vergeest, J.S.M., Spanjaard, S., Song, Y.,
Direct 3D Pattern Matching in the Domain of Freeform Shapes,
WSCG02(469).
PDF Version.
HTML Version. 0209 BibRef

Sun, Y.Y.[Yi-Yong], Abidi, M.A.[Mongi A.],
Surface Matching by 3D Point's Fingerprint,
ICCV01(II: 263-269).
WWW Version. 0106 BibRef

Chen, G.Q.[G. Qian], Medioni, G.[Gerard],
A Volumetric Stereo Matching Method: Application to Image-Based Modeling,
CVPR99(I: 29-34).
IEEE Abstract. IEEE Top Reference.
WWW Version. BibRef 9900 USC Computer VisionStereo is a surface matching problem. BibRef

Basri, R., Costa, L., Geiger, D., Jacobs, D.W.,
Determining the Similarity of Deformable Shapes,
PBMCV95(SESSION 5) BibRef 9500

Mullick, R.[Rakesh],
Automatic Orientation Determination of Three-Dimensional Objects from Three-Dimensional Data,
Ph.D.Georgia Institute of Technology, 1994, 204p. BibRef 9400

Gupta, A., and Liang, C.C.,
3-D Model-Data Correspondence and Nonrigid Deformation,
CVPR93(756-757).
IEEE Abstract. IEEE Top Reference. BibRef 9300

Shvaytser, H.[Haim],
A Surface Matching Algorithm for Two Perspective Views,
CVPR93(742-743).
IEEE Abstract. IEEE Top Reference. BibRef 9300

Gourdon, A., Ayache, N.J.,
Registration of a Curve on a Surface Using Differential Properties,
ECCV94(B:187-192).
WWW Version. BibRef 9400

Chapter on Registration, Matching and Recognition Using Points, Lines, Regions, Areas, Surfaces continues in
Surfaces and Range Data Matching .