10.9 Shape from Two or More Properties

Chapter Contents (Back)
Fusion, Shape. Shape from Multiple Cues. Multi-Modal Shape.

Bulthoff, H.H.[Heinrich H.], Mallot, H.A.[Hanspeter A.],
Integration of Depth Modules: Stereo and Shading,
JOSA-A(5), October 1988, pp. 1749-1758. BibRef 8810
Earlier:
Interaction of Different Modules in Depth Perception,
ICCV87(295-305). BibRef
And: MIT AI Memo-965, May 1987. BibRef

Bulthoff, H.H.[Heinrich H.], Fahle, M.[Manfred],
Disparity Gradients and Depth Scaling,
MIT AI Memo-1175, September 1989. BibRef 8909

Yuille, A.L., Geiger, D., Bülthoff, H.H.,
Stereo integration, mean field theory and psychophysics,
ECCV90(71-82).
Springer DOI 9004
BibRef

Kanatani, K.I.,
3D Euclidean Versus 2D Non-Euclidean: Two Approaches to 3D Recovery from Images,
PAMI(11), No. 3, March 1989, pp. 329-332.
IEEE Abstract.
IEEE DOI BibRef 8903

Fua, P.V., and Leclerc, Y.G.,
Object-Centered Surface Reconstruction: Combining Multi-Image Stereo and Shading,
IJCV(16), No. 1, September 1995, pp. 35-56.
Springer DOI
PS File. BibRef 9509
Earlier: DARPA93(1097-1120). BibRef
And: SRI-TN-535, September 1993. Stereo for the initial shape and refinement using the shading information. It could use anything for the initial shape (DTM).
See also From Multiple Stereo Views to Multiple 3-D Surfaces. BibRef

Fua, P.V.[Pascal V.], Leclerc, Y.G.[Yvan G.],
Combining Stereo, Shading, and Geometric Constraints for Surface Reconstruction from Multiple Views,
SPIE(2031), 1993, pp. 112-123.
See also From Multiple Stereo Views to Multiple 3-D Surfaces. BibRef 9300

Fua, P.V., Leclerc, Y.G.,
Taking Advantage of Image-Based and Geometry-Based Constraints to Recover 3-D Surfaces,
CVIU(64), No. 1, July 1996, pp. 111-127. 9608

DOI Link
PS File. BibRef
Earlier:
Using 3-Dimensional Meshes to Combine Image-Based and Geometry-Based Constraints,
ECCV94(B:281-291).
Springer DOI BibRef

Fua, P.V., and Leclerc, Y.G.,
A Unified Framework to Recover 3-D Surfaces by Combining Image-Based and Externally-Supplied Constraints,
ARPA94(II:1469-1480). BibRef 9400

Fua, P.V.,
Combining Stereo and Monocular Information to Compute Dense Depth Maps That Preserve Depth Discontinuities,
IJCAI91(1292-1298). Correlation followed by interpolation. BibRef 9100

Lengagne, R.[Richard], Fua, P.V.[Pascal V.], Monga, O.[Olivier],
3D stereo reconstruction of human faces driven by differential constraints,
IVC(18), No. 4, March 2000, pp. 337-343.
Elsevier DOI 0003
BibRef

Lengagne, R.[Richard], Fua, P.V.[Pascal V.], Monga, O.[Olivier],
3D Face Modeling from Stereo and Differential Constraints,
AFGR98(148-153).
IEEE DOI BibRef 9800
And:
Using differential constraints to generate a 3D face model from stereo,
ICPR98(Vol I: 637-639).
IEEE DOI 9808
BibRef

Lengagne, R.[Richard], Monga, O.[Olivier], and Fua, P.V.[Pascal V.],
Using Differential Constraints to Reconstruct Complex Surfaces from Stereo,
CVPR97(1081-1086).
IEEE Abstract.
IEEE DOI 9704
BibRef
And:
Using Differential Properties for Stereo Reconstruction of Complex Surfaces,
SCIA97(xx-yy) 9705
For complex surfaces stereo is not enough. differential properties of the image provides constraints.
HTML Version. BibRef

Lengagne, R.[Richard], Tarel, J.P.[Jean-Philippe], Monga, O.[Olivier],
From 2D Images to 3D Face Geometry,
AFGR96(301-306).
IEEE DOI
PS File. BibRef 9600

Lengagne, R.[Richard], Fua, P.V.[Pascal V.],
Incorporating Differential Constraints in a 3D Reconstruction Process. Application to Stereo,
ICCV01(I: 573-580).
IEEE DOI 0106
BibRef

Lengagne, R.[Richard], Monga, O., Fua, P.V.,
Using Crest Lines to Guide Surface Reconstruction from Stereo,
ICIP96(II: 847-850).
IEEE DOI BibRef 9600
And: ICPR96(I: 9-13).
IEEE DOI 9608
(INRIA, F) BibRef

Gilliland, M.T.[Malcolm T.],
Method and apparatus for determining the configuration of a workpiece,
US_Patent5,999,642, Dec 7, 1999
WWW Link. BibRef 9912
And: US_Patent6,101,268, Aug 8, 2000
WWW Link. move camera across object. BibRef

Samaras, D.[Dimitris], Metaxas, D.N.[Dimitris N.],
Incorporating illumination constraints in deformable models for shape from shading and light direction estimation,
PAMI(25), No. 2, February 2003, pp. 247-264.
IEEE Abstract.
IEEE DOI 0301
BibRef
Earlier:
Coupled Lighting Direction and Shape Estimation from Single Images,
ICCV99(868-874).
IEEE DOI BibRef
Earlier:
Incorporating Illumination Constraints in Deformable Models,
CVPR98(322-329).
IEEE DOI BibRef

Duan, Y.[Ye], Yang, L.[Liu], Qin, H.[Hong], Samaras, D.[Dimitris],
Shape Reconstruction from 3D and 2D Data Using PDE-Based Deformable Surfaces,
ECCV04(Vol III: 238-251).
Springer DOI 0405
BibRef

Wang, Y.[Yang], Samaras, D.[Dimitris],
Estimation of Multiple Illuminants from a Single Image of Arbitrary Known Geometry,
ECCV02(III: 272 ff.).
Springer DOI 0205
Lambertian, any shape. BibRef

Samaras, D.[Dimitris], Metaxas, D.N.[Dimitris N.], Fua, P.V.[Pascal V.], Leclerc, Y.G.[Yvan G.],
Variable Albedo Surface Reconstruction from Stereo and Shape from Shading,
CVPR00(I: 480-487).
IEEE Abstract.
IEEE DOI 0005
Applied to faces. Integration of SfS and Stereo. BibRef

Lie, W.N.[Wen-Nung], Yu, C.W.[Ching-Wen], Chen, Y.C.[Yung-Chang],
Model-Based Recognition and Positioning of Polyhedra Using Intensity-Guided Range Sensing and Interpretation in 3-D Space,
PR(23), No. 9, 1990, pp. 983-997.
Elsevier DOI BibRef 9000

Lie, W.N.[Wen-Nung], Yu, C.W.[Ching-Wen], Chen, Y.C.[Yung-Chang],
Integrating Intensity and Range Sensing to Construct 3-D Polyhedra Representations,
CVIP92(517-536). BibRef 9200

Chen, C.S.[Chu-Song], Hung, Y.P.[Yi-Ping], Chiang, C.C.[Chiann-Chu], Wu, J.L.[Ja-Ling],
Range Data-Acquisition Using Color Structured Lighting and Stereo Vision,
IVC(15), No. 6, June 1997, pp. 445-456.
Elsevier DOI 9708
BibRef
Earlier: A1, A2, A4, Only:
Model-Based Object Recognition Using Range Images by Combining Morphological Feature Extraction and Geometric Hashing,
ICPR96(I: 565-569).
IEEE DOI 9608
(Academia Sinica, ROC) BibRef

Kobayashi, F., Fukuda, T., Shimojima, K.,
Shape Reconstruction System Integrating Stereo Vision and Shape from Shading with Evolutionary Programming,
JEI(7), No. 1, January 1998, pp. 8-15. 9807
BibRef

Schrater, P.R.[Paul R.], Kersten, D.[Daniel],
How Optimal Depth Cue Integration Depends on the Task,
IJCV(40), No. 1, October 2000, pp. 71-89.
DOI Link 0101
BibRef

Fanany, M.I.[Mohamad Ivan], Kumazawa, I.[Itsuo],
A neural network for recovering 3D shape from erroneous and few depth maps of shaded images,
PRL(25), No. 4, March 2004, pp. 377-389.
Elsevier DOI 0402
Refine polyhedral model using SfS computations. BibRef

Hernández Esteban, C.[Carlos], Schmitt, F.[Francis],
Silhouette and stereo fusion for 3D object modeling,
CVIU(96), No. 3, December 2004, pp. 367-392.
Elsevier DOI 0411
BibRef
Earlier: 3DIM03(46-53).
IEEE DOI 0311
BibRef
Earlier:
Multi-stereo 3D object reconstruction,
3DPVT02(159-166).
IEEE DOI 0206
BibRef

Cobzas, D.[Dana], Jagersand, M.[Martin], Sturm, P.F.[Peter F.],
3D SSD Tracking with Estimated 3D Planes,
IVC(27), No. 1-2, January 2009, pp. 69-79.
Elsevier DOI
PDF File. 0811
BibRef
Earlier: A1, A3, Only: CRV05(129-134).
IEEE DOI 0505
Visual tracking; SSD tracking; Image registration; Plane tracking; 3D model estimation BibRef

Cobzas, D.[Dana], Jagersand, M.[Martin],
3D SSD Tracking from Uncalibrated Video,
SCVMA04(25-37).
Springer DOI 0405
BibRef
Earlier:
Tracking and Rendering Using Dynamic Textures on Geometric Structure from Motion,
ECCV02(II: 415 ff.).
Springer DOI 0205
Encode motion of the texture for reconstruction of the scene. BibRef

Upright, C.[Cameron], Cobzas, D.[Dana], Jagersand, M.[Martin],
Wavelet-based Light Reconstruction from a Single Image,
CRV07(305-312).
IEEE DOI 0705
BibRef

Lovi, D.[David], Birkbeck, N.[Neil], Cobzas, D.[Dana], Jagersand, M.[Martin],
Incremental Free-Space Carving for Real-Time 3D Reconstruction,
3DPVT10(xx-yy).
WWW Link. 1005
BibRef

Rachmielowski, A.[Adam], Birkbeck, N.[Neil], Jägersand, M.[Martin], Cobzas, D.[Dana],
Realtime Visualization of Monocular Data for 3D Reconstruction,
CRV08(196-202).
IEEE DOI 0805
BibRef

Birkbeck, N.[Neil], Cobzas, D.[Dana], Sturm, P.F.[Peter F.], Jagersand, M.[Martin],
Variational Shape and Reflectance Estimation Under Changing Light and Viewpoints,
ECCV06(I: 536-549).
Springer DOI 0608
Surface evolution interleaved with reflectance estimation. BibRef

Birkbeck, N.[Neil], Cobzas, D.[Dana], Jagersand, M.[Martin],
Object Centered Stereo: Displacement Map Estimation Using Texture and Shading,
3DPVT06(790-797).
IEEE DOI 0606
BibRef

Rachmielowski, A., Cobzas, D.[Dana], Jagersand, M.[Martin],
Robust SSD tracking with incremental 3D structure estimation,
CRV06(12-12).
IEEE DOI 0607
BibRef

Lin, H.Y.[Huei-Yung], Lie, W.N.[Wen-Nung], Wang, M.L.[Min-Liang],
A Framework of View-Dependent Planar Scene Active Camouflage,
IJIST(19), No. 3, September 2009, pp. 167-174.
DOI Link 0909
BibRef
Earlier: CRV08(319-325).
IEEE DOI 0805
BibRef


Bae, G.[Gwangbin], Budvytis, I.[Ignas], Cipolla, R.[Roberto],
Multi-View Depth Estimation by Fusing Single-View Depth Probability with Multi-View Geometry,
CVPR22(2832-2841)
IEEE DOI 2210
Geometry, Estimation, Sensor fusion, Probabilistic logic, Robustness, Probability distribution, 3D from multi-view and sensors, 3D from single images BibRef

Xu, Y.H.[Yu-Hua], Yang, X.L.[Xiao-Li], Yu, Y.S.[Yu-Shan], Jia, W.[Wei], Chu, Z.[Zhaobi], Guo, Y.L.[Yu-Lan],
Depth Estimation by Combining Binocular Stereo and Monocular Structured-Light,
CVPR22(1736-1745)
IEEE DOI 2210
Estimation, Prototypes, Speckle, Cameras, Pattern recognition, Indoor environment, RGBD sensors and analytics BibRef

Agrafiotis, P.[Panagiotis], Georgopoulos, A.[Andreas], Doulamis, A.D.[Anastasios D.], Doulamis, N.D.[Nikolaos D.],
Precise 3D Measurements for Tracked Objects from Synchronized Stereo-Video Sequences,
ISVC14(II: 757-769).
Springer DOI 1501
BibRef

Jia, Z.Y.[Zhao-Yin], Gallagher, A.C.[Andrew C.], Chen, T.H.[Tsu-Han],
Cameras and gravity: Estimating planar object orientation,
ICIP13(3642-3646)
IEEE DOI 1402
Image detection; Image motion analysis; Image processing BibRef

Kowdle, A.[Adarsh], Gallagher, A.C.[Andrew C.], Chen, T.H.[Tsu-Han],
Combining Monocular Geometric Cues with Traditional Stereo Cues for Consumer Camera Stereo,
UnOptFlow12(II: 103-113).
Springer DOI 1210
BibRef

Lin, H.Y.[Huei-Yung], Wu, J.R.[Jing-Ren],
3D reconstruction by combining shape from silhouette with stereo,
ICPR08(1-4).
IEEE DOI 0812
BibRef

Haines, T.S.F.[Tom S. F.], Wilson, R.C.[Richard C.],
Combining shape-from-shading and stereo using Gaussian-Markov random fields,
ICPR08(1-4).
IEEE DOI 0812
BibRef

Haines, T.S.F.[Tom S. F.], Wilson, R.C.[Richard C.],
Belief Propagation with Directional Statistics for Solving the Shape-from-Shading Problem,
ECCV08(III: 780-791).
Springer DOI 0810
BibRef
Earlier:
Integrating Stereo with Shape-from-Shading derived Orientation Information,
BMVC07(xx-yy).
PDF File. 0709

See also Combining Probabilistic Shape-from-Shading and Statistical Facial Shape Models. BibRef

Balossino, N.[Nello], Lucenteforte, M.[Maurizio], Piovano, L.[Luca], Pettiti, G.[Giuseppe], Spertino, M.[Massimiliano],
A New Stereo Algorithm Integrating Luminance, Gradient and Segmentation Informations in a Belief-Propagation Framework,
CIAP07(757-762).
IEEE DOI 0709
BibRef

Ballan, L.[Luca], Cortelazzo, G.M.[Guido Maria],
Multimodal 3D Shape Recovery from Texture, Silhouette and Shadow Information,
3DPVT06(924-930).
IEEE DOI 0606
Shape from Texture. Shape from Shadows. Shape from Contours. BibRef

Bayerl, P.[Pierre], Neumann, H.[Heiko],
A Model of Motion, Stereo, and Monocular Depth Perception,
DAGM04(95).
Springer DOI 0505
BibRef

Basri, R.[Ronen], Frolova, D.[Darya],
A two-frame theory of motion, lighting and shape,
CVPR08(1-7).
IEEE DOI 0806
BibRef

Simakov, D., Frolova, D., Basri, R.,
Dense shape reconstruction of a moving object under arbitrary, unknown lighting,
ICCV03(1202-1207).
IEEE DOI 0311
Known motion, Lambertian assumption. Exploit changes in illumination. BibRef

Tu, P., Mendonca, P.R.S.,
Surface reconstruction via Helmholtz reciprocity with a single image pair,
CVPR03(I: 541-547).
IEEE DOI 0307
takes advantage of the symmetry resulting from alternating the positions of a camera and a light source. BibRef

Zickler, T.E., Belhumeur, P.N., Kriegman, D.J.,
Toward a stratification of Helmholtz stereopsis,
CVPR03(I: 548-555).
IEEE DOI 0307
uncalibrated Helmholtz stereopsis. use of multiple cameras and light sources. BibRef

Zickler, T.E., Ho, J., Kriegman, D.J., Ponce, J., Belhumeur, P.N.,
Binocular Helmholtz Stereopsis,
ICCV03(1411-1417).
IEEE DOI 0311
BibRef

Kohlberger, T.[Timo], Mémin, É.[Étienne], Schnörr, C.[Christoph],
Variational Dense Motion Estimation Using the Helmholtz Decomposition,
ScaleSpace03(432-448).
Springer DOI 0310
BibRef

Dedieu, S., Guitton, P., Schlick, C., Reuter, P.,
Reality: An Interactive Reconstruction Tool of 3-D Objects from Photographs,
VMV01(xx-yy).
PDF File. 0209
BibRef

Subbarao, M.[Muralidhara],
Method and apparatus for determining the distances between surface-patches of a three-dimensional spatial scene and a camera system,
US_Patent4,965,840, Oct 23, 1990
WWW Link. BibRef 9010

Lin, H.Y.[Huei-Yung], and Subbarao, M.[Murali],
A Vision System for Fast 3D Model Reconstruction,
CVPR01(II:663-668).
IEEE DOI 0110
Rotational stereo and shape from focus. BibRef

Roussel, D., Bourdot, P., Gherbi, R.,
Curve and surface models to drive 3D reconstruction using stereo and shading,
3DIM99(84-90).
IEEE DOI 9910
BibRef

Zhou, L.X.[Ling-Xiang], Gu, W.K.[Wei-Kang],
3D Model Reconstruction by Fusing Multiple Visual Cues,
ICPR98(Vol I: 640-642).
IEEE DOI 9808
BibRef

Benzougar, A., Simon, T., Bernard, J.,
Monocular Stereovision : Depth Map from two Blurred Images,
ConferenceInternational Workshop on Stereoscopic and Three Dimensional Imaging, Santorini, Greece, 1995, pp. xx-yy.
PS File. BibRef 9500

Hoshino, J., Uemura, T., Masuda, I.,
Recognition-Based Reconstruction of an Indoor Scene Using an Integration of Active and Passive Sensing Techniques,
ICCV90(568-572).
IEEE DOI BibRef 9000

Henderson, T.C., Dekhil, M., Bruderlin, B., Schenkat, L., Veigel, L.,
Flat Surface Reconstruction Using Minimal Sonar Readings,
ARPA96(995-1000). Shape from Sonar. BibRef 9600

Pankanti, S., Jain, A.K.,
A Uniform Bayesian Framework for Integration,
SCV95(497-502).
IEEE DOI Michigan State University. Integrate depth from stereo, perceptual grouping, shape from shading or texture BibRef 9500

Mancini, T.A., and Wolf, L.B.[Lior B.],
3D Shape and Light Source Location from Depth and Reflectance,
CVPR92(707-709).
IEEE DOI BibRef 9200

Zheng, J.Y., and Kishino, F.,
Verifying and Combining Different Visual Cues into a 3D Model,
CVPR92(777-780).
IEEE DOI BibRef 9200

Banerjee, S., Sastry, P.S., Venkatesh, Y.V.,
Surface Reconstruction from Disparate Shading: An Integration of Shape-from-Shading and Stereopsis,
ICPR92(I:141-144).
IEEE DOI Shading and Stereo. BibRef 9200

Thompson, C.M.[Clay Matthew],
Robust Photo-Topography by Fusing Shape-from-Shading and Stereo,
MIT AI-TR-1411, February 1993.
WWW Link. BibRef 9302

Chapter on Stereo: Three Dimensional Descriptions from Two or More Views, Binocular, Trinocular continues in
Integration of Different Shape-from-X Cues .


Last update:Mar 16, 2024 at 20:36:19