11.3.4 Projective Reconstructions

Chapter Contents (Back)
Surface Reconstruction.

Chou, H.L., Chen, Z.,
A novel 3D planar object reconstruction from multiple uncalibrated images using the plane-induced homographies,
PRL(25), No. 12, September 2004, pp. 1399-1410.
Elsevier DOI 0409
Projective reconstruction of all planes in images. BibRef

Nistér, D.[David],
Untwisting a Projective Reconstruction,
IJCV(60), No. 2, November 2004, pp. 165-183.
DOI Link 0406
BibRef
Earlier:
Calibration with Robust Use of Cheirality by Quasi-Affine Reconstruction of the Set of Camera Projection Centres,
ICCV01(II: 116-123).
IEEE DOI 0106
Projective reconstruction to metric reconstruction. Transform projective reconstruction to metric. First transform so that no twisted pairs. Then local perturbation to get the model. BibRef

Reyes, L.[Leo], Bayro-Corrochano, E.[Eduardo],
The projective reconstruction of points, lines, quadrics, plane conics and degenerate quadrics using uncalibrated cameras,
IVC(23), No. 8, 1 August 2005, pp. 693-706.
Elsevier DOI 0508
BibRef
Earlier:
Geometric approach for simultaneous projective reconstruction of points, lines, planes, quadrics, plane conics and degenerate quadrics,
ICPR04(IV: 60-63).
IEEE DOI 0409
Noise can break the limits of the cost function. See also Geometric Approach for the Theory and Applications of 3D Projective Invariants, A. BibRef

Reyes, L.[Leo], Bayro-Corrochano, E.[Eduardo],
Projective reconstruction of all visual primitives,
PR(38), No. 12, December 2005, pp. 2301-2313.
Elsevier DOI 0510
Bunle Adjustment to refine. N uncalibrated views. BibRef

Tang, W.K., Hung, Y.S.,
A column-space approach to projective reconstruction,
CVIU(101), No. 3, March 2006, pp. 166-176.
Elsevier DOI 0601
Structure from motion, factorization. BibRef

Hung, Y.S., Tang, A.W.K.,
Projective Reconstruction from Multiple Views with Minimization of 2D Reprojection Error,
IJCV(66), No. 3, March 2006, pp. 305-317.
Springer DOI 0604
BibRef
Earlier: A2, A1:
A Factorization-Based Method for Projective Reconstruction with Minimization of 2-D Reprojection Errors,
DAGM02(387 ff.).
Springer DOI 0303
BibRef

Tang, A.W.K., Hung, Y.S.,
A Self-calibration Algorithm Based on a Unified Framework for Constraints on Multiple Views,
JMIV(44), No. 3, November 2012, pp. 432-448.
WWW Link. 1209
BibRef

Li, Y., Tang, W.K., Hung, Y.S.,
A factorization-based projective reconstruction algorithm with circular motion constraint,
ICIP04(III: 1959-1962).
IEEE DOI 0505
BibRef

Zhong, H., Hung, Y.S.,
Factorization-based Hierarchical Reconstruction for Circular Motion,
BMVC04(xx-yy).
HTML Version. 0508
BibRef

Tang, A.W.K., Ng, T.P., Hung, Y.S., Leung, C.H.,
Projective reconstruction from line-correspondences in multiple uncalibrated images,
PR(39), No. 5, May 2006, pp. 889-896.
Elsevier DOI 0604
Projective reconstruction; Line reconstruction; Line correspondence BibRef

Mai, F., Hung, Y.S., Chesi, G.,
Projective reconstruction of ellipses from multiple images,
PR(43), No. 3, March 2010, pp. 545-556.
Elsevier DOI 1001
Multiple views; Projective reconstruction; Ellipse reconstruction; Conic correspondence BibRef

Zhang, J.[Jian], Mai, F.[Fei], Hung, Y.S., Chesi, G.,
3D Model Reconstruction from Turntable Sequence with Multiple-View Triangulation,
ISVC09(II: 470-479).
Springer DOI 0911
BibRef

Mai, F., Hung, Y.S.,
Three-dimensional curve reconstruction from multiple images,
IET-CV(6), No. 4, 2012, pp. 273-284.
DOI Link 1209
BibRef
Earlier:
3D Curves Reconstruction from Multiple Images,
DICTA10(462-467).
IEEE DOI 1012
BibRef
Earlier:
Augmented Lagrangian Approach for Projective Reconstruction from Multiple Views,
ICPR06(I: 634-637).
IEEE DOI 0609
BibRef

Tang, W.K., Hung, Y.S.,
A subspace method for projective reconstruction from multiple images with missing data,
IVC(24), No. 5, 1 May 2006, pp. 515-524.
Elsevier DOI 0606
Multiple views; Subspace method; Factorization method; Structure from motion BibRef

Bertolini, M.[Marina], Turrini, C.[Cristina],
Critical Configurations for 1-View in Projections from Pk -> P2,
JMIV(27), No. 3, April 2007, pp. 277-287.
Springer DOI 0704
For set of points in one view. See also On Projection Matrices P^k, -> P^2, k=,3..., 6, and their Applications in Computer Vision. BibRef

Bertolini, M.[Marina], Besana, G.M.[Gian-Mario], Turrini, C.[Cristina],
Reconstruction of Some Segmented and Dynamic Scenes: Trifocal Tensors in P4 Theoretical Set Up for Critical Loci, and Instability,
ISVC08(II: 1125-1136).
Springer DOI 0812
BibRef

Bertolini, M.[Marina], Turrini, C.[Cristina], Besana, G.M.[Gian-Mario],
Instability of Projective Reconstruction of Dynamic Scenes near Critical Configurations,
ICCV07(1-7).
IEEE DOI 0710
BibRef

Alzati, A.[Alberto], Bertolini, M.[Marina], Borghese, N.A.[N. Alberto], Turrini, C.[Cristina],
Tracking 3D Orientation through Corresponding Conics,
ACIVS09(456-461).
Springer DOI 0909
BibRef

Lee, J.H.[Joo-Haeng],
A New Solution for Projective Reconstruction Based on Coupled Line Cameras,
ETRI Journal(35), No. 5, October 2013, pp. 939.
WWW Link.
WWW Link. 1310
See also Camera calibration from a single image based on coupled line cameras and rectangle constraint. BibRef

Lee, J.H.[Joo-Haeng],
New Geometric Interpretation and Analytic Solution for Quadrilateral Reconstruction,
ICPR14(4015-4020)
IEEE DOI 1412
Cameras BibRef

Nasihatkon, B.[Behrooz], Hartley, R.I.[Richard I.], Trumpf, J.[Jochen],
A Generalized Projective Reconstruction Theorem and Depth Constraints for Projective Factorization,
IJCV(115), No. 2, November 2015, pp. 87-114.
Springer DOI 1511
BibRef
Earlier:
On Projective Reconstruction in Arbitrary Dimensions,
CVPR14(477-484)
IEEE DOI 1409
BibRef


Kannala, J.H.[Ju-Ho], Salo, M.[Mikko], Heikkila, J.[Janne],
Algorithms for computing a planar homography from conics in correspondence,
BMVC06(I:77).
PDF File. 0609
BibRef

Ponce, J.[Jean],
On Computing Metric Upgrades of Projective Reconstructions Under the Rectangular Pixel Assumption,
SMILE00(52 ff.).
Springer DOI
PS File. 0209
BibRef

Buchanan, T.[Thomas],
Critical sets for 3D reconstruction using lines,
ECCV92(730-738).
Springer DOI 9205
BibRef

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


Last update:Nov 17, 2018 at 09:12:27