12.3.2.1 Partial Contour Matching, Piecewise Segments

Bhanu, B., and Ming, J.,
Recognition of Occluded Objects: A Cluster-Structure Algorithm,
PR(20), No. 2, 1987, pp. 199-211.
WWW Version. Improve on the technique of Price above by applying a clustering technique to limit the set of possible matches. BibRef 8700

Liu, H.C., and Srinath, M.D.,
Partial Shape Classification Using Contour Matching in Distance Transformation,
PAMI(12), No. 11, November 1990, pp. 1072-1079.
IEEE Abstract. IEEE Top Reference.
WWW Version. Chamfer matching of contours using control points (corners). ( See also Distance Transformations in Digital Images. ) BibRef 9011

Liu, H.C., Srinath, M.D.,
A String Descriptor for Matching Partial Shapes,
CVIP92(575-592). BibRef 9200

Hwang, V.,
Recognizing and Locating Partially Occluded 2-D Objects: Symbolic Clustering Method,
SMC(19), No. 6, Nov/Dec 1989, pp. 1644-1656. BibRef 8900
Earlier:
Recognition of Two-Dimensional Objects Using Hypothesis Integration Techniques,
CVWS87(106-111). Recognize Two-Dimensional Objects. This is similar to other methods. BibRef

Bhanu, B.[Bir], and Faugeras, O.D.[Olivier D.],
Shape Matching of Two-Dimensional Objects,
PAMI(6), No. 2, March 1984, pp. 137-155. BibRef 8403
Earlier: A1 Only:
Recognition of Occluded Objects,
IJCAI83(1136-1138). BibRef
Earlier: A1, A2:
Recognition of Occluded Two Dimensional Objects,
SCIA81(72-77). Recognize Two-Dimensional Objects. Relaxation. Segment matching and relaxation using occluded objects from his thesis, matching the occluded parts using segments as the basis. BibRef

Horaud, R., and Skordas, T.,
Model-Based Strategy Planning for Recognizing Partially Occluded Parts,
Computer(20), No. 8, August 1987, pp. 58-65. BibRef 8708
Earlier: A2, A1:
Planning A Strategy for Recognizing Partially Occluded Parts,
ICPR86(1080-1083). Recognize Two-Dimensional Objects. A search strategy based on what to look for is generated based on the distinguishing features of the given object. The system determines the correct orientation for the single type of part (top and bottom may be different). BibRef

Rutkowski, W.S.,
Shape Completion,
CGIP(9), No. 1, January 1979, pp. 89-101. BibRef 7901

Rutkowski, W.S.,
Recognition of Occluded Shapes Using Relaxation,
CGIP(19), No. 2, June 1982, pp. 111-128.
WWW Version. Recognize Two-Dimensional Objects. Relaxation. The description is based on selecting high curvature points and extending to sample points a fixed distance on either side. If necessary straight (or slightly curved) segments are used to connect these end points. Because feature values are used in the relaxation step no initial assignments are made. BibRef 8206

Koch, M.W., and Kashyap, R.L.,
Using Polygons to Recognize and Locate Partially Occluded Objects,
PAMI(9), No. 4, July 1987, pp. 483-494. BibRef 8707
Earlier: A2, A1:
Computer Vision Algorithms Used in Recognition of Occluded Objects,
CAIA84(150-155). Recognize Two-Dimensional Objects. This one hurts. Polygon means linear segment representation of the boundary. It uses clusters of matches to find the best rotation and translation for the match. It is too much of a copy for me. BibRef

Ansari, N., and Delp, E.J.,
Partial Shape Recognition: A Landmark-Based Approach,
PAMI(12), No. 5, May 1990, pp. 470-483.
IEEE Abstract. IEEE Top Reference.
WWW Version. BibRef 9005
Earlier:
A Note on Two-Dimensional Landmark-Based Object Recognition,
CVPR86(622-624). Shape matching based on landmarks (important features) using a dynamic programming approach. BibRef

Ansari, N.,
Shape Recognition: A Landmark-Based Approach,
PurdueTR-EE-88-31, July 1988, BibRef 8807 Ph.D.Thesis (EE). The thesis form of the above paper. BibRef

Ansari, N., Li, K.,
Landmark-Based Shape Recognition by a Modified Hopfield Neural Network,
PR(26), No. 4, April 1993, pp. 531-542.
WWW Version. Uses a three point based shape measure and major curvature points on the contour to match rotated and scaled and partially occluded objects to models. Requires 4 landmark points (corners) to appear in the scene. BibRef 9304

Ullmann, J.R.,
Analysis of 2-D Occlusion by Subtracting Out,
PAMI(14), No. 4, April 1992, pp. 485-489.
IEEE Abstract. IEEE Top Reference.
WWW Version. Matching and analysis of occlusions. One-D occlusion: See also Investigation of Occlusion in One Dimension, An. BibRef 9204

Ullmann, J.R.,
Edge Replacement in the Recognition of Occluded Objects,
PR(26), No. 12, December 1993, pp. 1771-1784.
WWW Version. BibRef 9312

Tsai, D.M., Tsai, R.Y.,
Use Neural Networks to Determine Matching Order for Recognizing Overlapping Objects,
PRL(17), No. 10, September 2 1996, pp. 1077-1088. Neural Networks. Hough Transform. BibRef 9609

Han, M.H., Jang, D.,
The Use of Maximum Curvature Points for the Recognition of Partially Occluded Objects,
PR(23), No. 1-2, 1990, pp. 21-33.
WWW Version. BibRef 9000

Salari, E., Balaji, S.,
Recognition of Partially Occluded Objects Using B-Spline Representation,
PR(24), No. 7, 1991, pp. 653-660.
WWW Version. BibRef 9100

Pikaz, A., Dinstein, I.H.,
Matching of Partially Occluded Planar Curves,
PR(28), No. 2, February 1995, pp. 199-209.
WWW Version. BibRef 9502

Dinstein, I., and Silberberg, T.,
Shape Discrimination with Walsh Descriptors,
ICPR80(1055-1061). BibRef 8000

Kim, J.H., Yoon, S.H., Sohn, K.H.,
A Robust Boundary-Based Object Recognition in Occlusion Environment by Hybrid Hopfield Neural Networks,
PR(29), No. 12, December 1996, pp. 2047-2060.
WWW Version. 9701 Hopfield Networks. BibRef

Illing, D.P., Fairney, P.T.,
Reconstructing Partially Occluded Object Boundaries,
PRL(12), 1991, pp. 31-38. BibRef 9100

Koch, M.W., Kashyap, R.L.,
Matching Polygon Fragments,
PRL(10), 1989, pp. 297-308. BibRef 8900

Ray, K.S., Dutta Majumder, D.,
Application of Differential Geometry to Recognize and Locate Partially Occluded Objects,
PRL(9), 1989, pp. 351-360. See also Recognition and Positioning of Partially Occluded 3-D Objects. BibRef 8900

Ray, K.S., Majumder, D.D.,
Application of Hopfield Neural Networks and Canonical Perspectives to Recognize and Locate Partially Occluded 3-D Objects,
PRL(15), No. 8, August 1994, pp. 815-824. BibRef 9408

Chen, J.M., Ventura, J.A.,
Optimization Models for Shape-Matching of Nonconvex Polygons,
PR(28), No. 6, June 1995, pp. 863-877.
WWW Version. See also Optimization Algorithm for Shape Analysis of Regular Polygons, An. BibRef 9506

Ventura, J.A., Chen, J.M.,
A Structural Model For Shape-Recognition Using Neural Nets,
JIM(7), No. 1, February 1996, pp. 1-11. BibRef 9602

Gewali, L.P.,
Recognizing S-Star Polygons,
PR(28), No. 7, July 1995, pp. 1019-1032.
WWW Version. BibRef 9507

Tsang, P.W.M.,
A Genetic Algorithm for Aligning Object Shapes,
IVC(15), No. 11, November 1997, pp. 819-831.
WWW Version. 9712 BibRef

Tsang, P.W.M.,
A Genetic Algorithm for Affine Invariant Recognition of Object Shapes from Broken Boundaries,
PRL(18), No. 7, July 1997, pp. 631-639. 9711 BibRef

Tsang, P.W.M., Yu, Z.,
Genetic algorithm for model-based matching of projected images of three-dimensional objects,
VISP(150), No. 6, December 2003, pp. 351-359.
IEEE Abstract. IEEE Top Reference. 0402 BibRef

Park, J.S., Han, J.H.,
Contour Matching: A Curvature-Based Approach,
IVC(16), No. 3, March 16 1998, pp. 181-189.
WWW Version. 9804 See also Estimating Optical Flow by Tracking Contours. BibRef

Han, J.H., Park, J.S.,
Contour Matching Using Epipolar Geometry,
PAMI(22), No. 4, April 2000, pp. 358-370.
IEEE Abstract. IEEE Top Reference.
WWW Version. 0006Using the epipolar constraint in matching through a sequence helps eliminate mis-matches. BibRef

Kupeev, K.Y., Brailovsky, V.L.,
A Reinforced Random Algorithm for a Partial Contour Perceptual Similarity Problem,
PRL(19), No. 3-4, March 1998, pp. 287-297. 9807
Postscript Version. BibRef

Bunke, H.[Horst], Zumbuhl, M.[Marcel],
Acquisition of 2D Shape Models from Scenes with Overlapping Objects using String matching,
PAA(2), No. 1, 1999, pp. 2-9. BibRef 9900

Bunke, H., Kaufmann, G.,
Jigsaw puzzle solving using approximate string matching and best-first search,
CAIP93(299-308).
WWW Version. 9309 BibRef

Saber, E.[Eli], Xu, Y.[Yaowu], Tekalp, A.M.[A. Murat],
Partial shape recognition by sub-matrix matching for partial matching guided image labeling,
PR(38), No. 10, October 2005, pp. 1560-1573.
WWW Version. 0508 BibRef

Zhu, L.J.[Liang-Jia], Zhou, Z.T.[Zong-Tan], Hu, D.[Dewen],
Globally Consistent Reconstruction of Ripped-Up Documents,
PAMI(30), No. 1, January 2008, pp. 1-13.
WWW Version. 0711First curve matching, then disambiguate using relaxation process. BibRef

Marcenaro, L., Gandetto, M., Regazzoni, C.S.,
Localization and classification of partially overlapped objects using self-organizing trees,
ICIP03(III: 137-140).
IEEE Abstract. IEEE Top Reference. 0312 BibRef

Kawaguchi, T.[Tsuyoshi], Nagao, M.[Makoto],
Recognition of Occluded Objects by a Genetic Algorithm,
ICPR98(Vol I: 233-237).
WWW Version. 9808 BibRef

Vergnet, R.L., Saint-Marc, P., and Ayache, N.J.,
Robustness of Model-Based Recognition in Cluttered Images,
CVPR93(713-714).
IEEE Abstract. IEEE Top Reference. BibRef 9300

Lee, C.H., Quek, G.P.,
Partial Matching of two Dimensional Shapes Using Random Coding,
ICPR88(I: 64-68).
WWW Version.
IEEE Top Reference. BibRef 8800

Li, J.C., Yuan, B.Z.,
Using Stereo Vision Analysis to Recognize Partially Obscured Objects,
ICPR88(II: 758-760).
WWW Version.
IEEE Top Reference. BibRef 8800

Singer, P.F.[Paul Frank], and Chellappa, R.,
Machine Perception of Partially Obscured Planar Shapes,
CVPR85(497-502). BibRef 8500
Earlier:
Classification of Boundaries on the Plane Using Stochastic Models,
CVPR83(146-147). Uses a circular auto-regressive model. Not the real model for the noise that is expected. BibRef

Chapter on Registration, Matching and Recognition Using Points, Lines, Regions, Areas, Surfaces continues in
Contours Through a Sequence .