11.3.3.1 Discontinuity Analysis in Surface Reconstruction

Grimson, W.E.L., and Pavlidis, T.,
Discontinuity Detection for Visual Surface Reconstruction,
CVGIP(30), No. 3, June 1985, pp. 316-330.
WWW Version. (Bell Labs work) An algorithm to detect disparity discontinuities from sparse data and fit a surface to the points. BibRef 8506

Terzopoulos, D.[Demetri],
The Computation of Visible-Surface Representations,
PAMI(10), No. 4, July 1988, pp. 417-438.
IEEE Abstract.
IEEE DOI Link BibRef 8807

Terzopoulos, D.[Demetri],
Multilevel Computational Processes for Visual Surface Reconstruction,
CVGIP(24), No. 1, October 1983, pp. 52-96.
WWW Version. BibRef 8310
Earlier:
Multiresolution Computation of Visible-Surface Representations,
Ph.D.Thesis (MIT EECS), January 1984. BibRef
And:
The Role of Constraints and Discontinuities in Visible Surface Reconstruction,
IJCAI83(1019-1022). Relaxation. This paper uses the multi-grid relaxation technique given earlier to derive a technique for surface reconstruction that considers discontinuities. See also Multiresolution Algorithms in Computational Vision. BibRef

Terzopoulos, D.[Demetri],
Computing Visible Surface Representations,
MIT AI Memo-800, March 1985.
WWW Version. BibRef 8503

Terzopoulos, D.[Demetri],
Multi-Level Reconstruction of Visual Surfaces: Variational Principles and Finite Element Representations,
MIT AI Memo-671, April 1982.
WWW Version. BibRef 8204

Terzopoulos, D.,
Efficient Multiresolution Algorithms for Computing Lightness, Shape from Shading, and Optical Flow,
AAAI-84(314-317). BibRef 8400

Vasilescu, M.A.O., and Terzopoulos, D.,
Adaptive Meshes and Shells: Irregular Triangulation, Discontinuities, and Hierarchical Subdivisions,
CVPR92(829-832).
IEEE Abstract. Follow-up to the following paper. BibRef 9200

Terzopoulos, D., and Vasilescu, M.A.O.,
Sampling and Reconstruction with Adaptive Meshes,
CVPR91(70-75).
IEEE Abstract. Cut the surface at the detected edges. BibRef 9100

Blake, A.,
Comparison of the Efficiency of Deterministic and Stochastic Algorithms for Visual Reconstruction,
PAMI(11), No. 1, January 1989, pp. 2-12.
IEEE Abstract.
IEEE DOI Link BibRef 8901
Earlier:
Reconstructing a Visible Surface,
AAAI-84(23-26). Graduated nonconvexity is better than simulated annealing both in efficiency and in problem-solving power. BibRef

Blake, A., and Zisserman, A.,
Visual Reconstruction,
Cambridge: MIT Press1987. ISBN 0262022710.
PDF Version. A complete discussion of continuity constraints. Graduated nonconvexity. BibRef 8700

Blake, A., Zisserman, A.,
Localizing Discontinuities Using Weak Continuity Constraints,
PRL(6), 1987, pp. 51-59. BibRef 8700

Blake, A., and Zisserman, A.,
Invariant Surface Reconstruction Using Weak Continuity Constraints,
CVPR86(62-67). Explicitly include discontinuities. BibRef 8600

Yi, J.H., Chelberg, D.M.,
Discontinuity-Preserving and Viewpoint Invariant Reconstruction of Visible Surfaces Using a First-Order Regularization,
PAMI(17), No. 6, June 1995, pp. 624-629.
IEEE Abstract.
IEEE DOI Link Regularization. BibRef 9506

Jou, J.Y.[Jinn-Yeu], and Bovik, A.C.[Alan C.],
Improved Initial Approximation and Intensity-Guided Discontinuity Detection in Visible-Surface Reconstruction,
CVGIP(47), No. 3, September 1989, pp. 292-326.
WWW Version. BibRef 8909
Earlier:
Improving Visible-Surface Reconstruction,
CVPR88(138-143).
IEEE Abstract. By using edges it is possible to improve the speed and accuracy of the reconstruction. BibRef

March, R.,
Visual Reconstruction with Discontinuities Using Variational Methods,
IVC(10), No. 1, January-February 1992, pp. 30-38.
WWW Version. BibRef 9201

Sparr, G., Hansson, A., Nielsen, L.,
Discontinuity Preserving Visual Reconstruction by Means of Potential Theory,
PRL(11), 1990, pp. 117-122. BibRef 9000

Qian, W., Titterington, D.M.,
Bayesian Image Restoration: An Application to Edge-Preserving Surface Recovery,
PAMI(15), No. 7, July 1993, pp. 748-752.
IEEE Abstract.
IEEE DOI Link 0401
See also On Some Bayesian/Regularization Methods for Image Restoration. BibRef

Vaidya, N.M., Boyer, K.L.,
Discontinuity-Preserving Surface Reconstruction Using Stochastic Differential Equations,
CVIU(72), No. 3, December 1998, pp. 257-270.
WWW Version. BibRef 9812

Pedersini, F.[Federico], Sarti, A., Tubaro, S.,
Visible Surface Reconstruction with Accurate Localization of Object Boundaries,
CirSysVideo(10), No. 2, March 2000, pp. 278.
IEEE Top Reference. 0003
BibRef
Earlier:
Combined surface interpolation and object segmentation for automatic 3D scene reconstruction,
ICIP98(II: 963-966).
IEEE DOI Link 9810
BibRef
Earlier:
Combined Motion and Edge Analysis for a Layer-Based Representation of Image Sequences,
ICIP96(I: 921-924).
IEEE DOI Link BibRef
Earlier:
Synthesis of virtual views using non-Lambertian reflectivity models and stereo matching,
ICIP95(II: 358-361).
IEEE DOI Link 9510
BibRef

Kim, J.H.[Jae-Hak], Han, J.H.[Joon H.],
A corner preserving surface inference algorithm using 3D convolution,
PRL(22), No. 3-4, March 2001, pp. 259-269.
Elsevier DOI Link 0105
BibRef

Law, N.F., Chung, R.,
Multiresolution discontinuity-preserving surface reconstruction,
PR(34), No. 11, November 2001, pp. 2133-2144.
WWW Version. 0108
BibRef
Earlier:
Surface Reconstruction with Multiresolution Discontinuity Analysis,
ECCV98(II: 202).
WWW Version. BibRef

Lin, M.H.[Michael H.], Tomasi, C.[Carlo],
Surfaces with Occlusions from Layered Stereo,
PAMI(26), No. 8, August 2004, pp. 1073-1078.
IEEE Abstract. 0407
BibRef
Earlier: CVPR03(I: 710-717).
IEEE Abstract.
WWW Version. 0307
Estimate scene structure as a set of smooth surface patches. The disparities within each patch are modeled by a spline, while the extent of each patch is represented by a pixelwise labeling of the source images. Disparities and extents are alternately estimated in an iterative, energy minimization framework. BibRef

Li, K.[Kang], Wu, X.D.[Xiao-Dong], Chen, D.Z.[Danny Z.], Sonka, M.[Milan],
Optimal Surface Segmentation in Volumetric Images: A Graph-Theoretic Approach,
PAMI(28), No. 1, January 2006, pp. 119-134.
IEEE DOI Link 0512
BibRef
Earlier:
Globally optimal segmentation of interacting surfaces with geometric constraints,
CVPR04(I: 394-399).
IEEE Abstract. 0408
Surfaces in CT images. BibRef

Song, Q.[Qi], Wu, X.D.[Xiao-Dong], Liu, Y.L.[Yun-Long], Sonka, M.[Milan], Garvin, M.[Mona],
Simultaneous searching of globally optimal interacting surfaces with shape priors,
CVPR10(2879-2886).
IEEE DOI Link 1006
BibRef

Han, D.F.[Dong-Feng], Sonka, M.[Milan], Bayouth, J.[John], Wu, X.D.[Xiao-Dong],
Optimal multiple-seams search for image resizing with smoothness and shape prior,
VC(26), No. 6-8, June 2010, pp. 749-759.
WWW Version. 1101
BibRef
Earlier: A1, A4, A2, Only:
Optimal multiple surfaces searching for video/image resizing: A graph-theoretic approach,
ICCV09(1026-1033).
IEEE DOI Link 0909
BibRef

Dou, X.[Xin], Wu, X.D.[Xiao-Dong], Wahle, A.[Andreas], Sonka, M.[Milan],
Globally optimal surface segmentation using regional properties of segmented objects,
CVPR08(1-8).
IEEE DOI Link 0806
BibRef

Ecker, A.[Ady], Jepson, A.D.[Allan D.], Kutulakos, K.N.[Kiriakos N.],
Semidefinite Programming Heuristics for Surface Reconstruction Ambiguities,
ECCV08(I: 127-140).
Springer DOI Link 0810
BibRef

Goepfert, J., Soergel, U., Heipke, C., Brzank, A.,
An Approach for Filtering LIDAR Data in Coastal Vegetated Areas Using Intensity Information and Multiple Echoes,
ISPRS08(B3b: 219 ff).
PDF Version. 0807
BibRef

Lui, L.M.[Lok Ming], Zeng, W.[Wei], Yau, S.T.[Shing-Tung], Gu, X.F.[Xian-Feng],
Shape Analysis of Planar Objects with Arbitrary Topologies Using Conformal Geometry,
ECCV10(V: 672-686).
Springer DOI Link 1009
BibRef

Yin, X.T.[Xiao-Tian], Dai, J.F.[Jun-Fei], Yau, S.T.[Shing-Tung], Gu, X.F.[Xian-Feng],
Slit Map: Conformal Parameterization for Multiply Connected Surfaces,
GMP08(xx-yy).
Springer DOI Link 0804
itting with multiple connected surfaces BibRef

Gu, X.F.[Xian-Feng], Yau, S.T.[Shing-Tung],
Surface classification using conformal structures,
ICCV03(701-708).
IEEE DOI Link 0311
Conformal equivalent classes are between topological and isometric classes. BibRef

Shimizu, M.[Masao], Okutomi, M.[Masatoshi],
Microscopic Surface Shape Estimation of a Transparent Plate Using a Complex Image,
ACCV07(II: 176-185).
Springer DOI Link 0711
BibRef

Fanany, M.I.[Mohamad Ivan], Kumazawa, I.[Itsuo],
Analytic Reconstruction of Transparent and Opaque Surfaces from Texture Images,
IbPRIA07(II: 380-387).
Springer DOI Link 0706
BibRef
Earlier:
A Neural Network for Simultaneously Reconstructing Transparent and Opaque Surfaces,
ICIAR06(II: 157-168).
Springer DOI Link 0610
BibRef

Fanany, M.I.[Mohamad Ivan], Kobayashi, K.[Kiichi], Kumazawa, I.[Itsuo],
A Combinatorial Transparent Surface Modeling from Polarization Images,
IWCIA04(65-76).
WWW Version. 0505
BibRef

Wu, T.P.[Tai-Pang], Tang, C.K.[Chi-Keung],
Visible Surface Reconstruction from Normals with Discontinuity Consideration,
CVPR06(II: 1793-1800).
IEEE DOI Link 0606
BibRef

Yang, J.[Jing], Duncan, J.S.,
Joint prior models of neighboring objects for 3D image segmentation,
CVPR04(I: 314-319).
IEEE Abstract. 0408
BibRef

Wallace, A.M., Csakany, P., Buller, G., Walker, A.,
3D Imaging of Transparent Objects,
BMVC00(xx-yy).
PDF Version. 0009
BibRef

Borga, M., Knutsson, H.,
Estimating Multiple Depths in Semi-transparent Stereo Images,
SCIA99(Computer Vision III). BibRef 9900

Mathur, S., Ferrie, F.P.,
Edge Localization in Surface Reconstruction Using Optimal Estimation Theory,
CVPR97(833-838).
IEEE Abstract.
IEEE DOI Link 9704
BibRef

Vaidya, N.M., Boyer, K.L.,
Discontinuity Preserving Surface Reconstruction Through Global Optimization,
SCV95(115-120).
IEEE Top Reference. Ohio State University. BibRef 9500

Shizawa, M.,
Reconstruction of multiple overlapping surfaces via standard regularization techniques,
ICPR94(A:321-325).
IEEE DOI Link 9410
BibRef

Figueiredo, M.A.T., and Leitao, J.M.N.,
Simulated Tearing: An Algorithm for Discontinuity-Preserving Visual Surface Reconstruction,
CVPR93(28-33).
IEEE Abstract. BibRef 9300

Gunsel, B., Jain, A.K.,
Visual surface reconstruction and boundary detection using stochastic models,
ICPR92(III:343-346).
IEEE DOI Link 9208
BibRef

Pawlak, M.,
On the detection and measurement of discontinuities,
ICPR92(III:378-381).
IEEE DOI Link 9208
BibRef

Marroquin, J.L.[Jose L.],
Surface Reconstruction Preserving Discontinuities,
MIT AI Memo-792, August 1984.
WWW Version. BibRef 8408

Chapter on 3-D Object Description and Computation Techniques, Surfaces, Deformable, View Generation, Video Conferencing continues in
Fitting Curved Surfaces .