Top

International Journal of Computer Vision

Published in:

01-08-2013

SLEDGE: Sequential Labeling of Image Edges for Boundary Detection

Authors: Nadia Payet, Sinisa Todorovic

Published in: International Journal of Computer Vision | Issue 1/2013

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Our goal is to detect boundaries of objects or surfaces occurring in an arbitrary image. We present a new approach that discovers boundaries by sequential labeling of a given set of image edges. A visited edge is labeled as on or off a boundary, based on the edge’s photometric and geometric properties, and evidence of its perceptual grouping with already identified boundaries. We use both local Gestalt cues (e.g., proximity and good continuation), and the global Helmholtz principle of non-accidental grouping. A new formulation of the Helmholtz principle is specified as the entropy of a layout of image edges. For boundary discovery, we formulate a new, policy iteration algorithm, called SLEDGE. Training of SLEDGE is iterative. In each training image, SLEDGE labels a sequence of edges, which induces loss with respect to the ground truth. These sequences are then used as training examples for learning SLEDGE in the next iteration, such that the total loss is minimized. For extracting image edges that are input to SLEDGE, we use our new, low-level detector. It finds salient pixel sequences that separate distinct textures within the image. On the benchmark Berkeley Segmentation Datasets 300 and 500, our approach proves robust and effective. We outperform the state of the art both in recall and precision for different input sets of image edges.

previous article Linearized Alternating Direction Method with Adaptive Penalty and Warm Starts for Fast Solving Transform Invariant Low-Rank Textures

next article Recovering Relative Depth from Low-Level Features Without Explicit T-junction Detection and Interpretation

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Ahuja, N., & Todorovic, S. (2007). Learning the taxonomy and models of categories present in arbitrary images. In ICCV, Rio de Janeiro.

Ahuja, N., & Todorovic, S. (2008). Connected segmentation tree—A joint representation of region layout and hierarchy. In CVPR.

Arbelaez, P. (2006). Boundary extraction in natural images using ultrametric contour maps. In POCV (p. 182).

Arbelaez, P., Maire, M., Fowlkes, C., & Malik, J. (2010). Contour detection and hierarchical image segmentation. In TPAMI, 99(RapidPosts).

Belongie, S., Malik, J., & Puzicha, J. (2002). Shape matching and object recognition using shape contexts. TPAMI, 24(4), 509–522.CrossRef

Biederman, I. (1988). Surface versus edge-based determinants of visual recognition. Cognitive Psychology, 20(1), 38–64.CrossRef

Borenstein, E., & Ullman, S. (2002). Class-specific, top-down segmentation. In ECCV, Copenhagen (vol. 2, pp. 109–124).

Borgefors, G. (1988). Hierarchical Chamfer matching: A parametric edge matching algorithm. TPAMI, 10(6), 849–865.CrossRef

Brice, C. R., & Fennema, C. L. (1970). Scene analysis using regions. Artificial Intelligence, 1, 205–226.CrossRef

Brin, S., & Page, L. (1998). The anatomy of a large-scale hypertextual web search engine. In Seventh international world-wide web conference (WWW : 1998).

Canny, J. (1986). A computational approach to edge detection. TPAMI, 8(6), 679–698.CrossRef

Coughlan, J. M., & Yuille, A. L. (2002). Bayesian A* tree search with expected o(n) node expansions: Applications to road tracking. Neural Computation, 14(8), 1929–1958.MATHCrossRef

Daume, H., III, Langford, J., & Marcu, D. (2009). Search-based structured prediction. Machine Learning Journal.

Deng, Y., & Manjunath, B. S. (2001). Unsupervised segmentation of color-texture regions in images and videos. TPAMI, 23(8), 800–810.CrossRef

Desolneux, A., Moisan, L., & Morel, J. (2001). Edge detection by Helmholtz principle. Journal of Mathematical Imaging and Vision, 14(3), 271–284.MATHCrossRef

Desolneux, A., Moisan, L., & Morel, J.-M. (2000). Meaningful alignments. IJCV, 40(1), 7–23.MATHCrossRef

Desolneux, A., Moisan, L., & Morel, J. -M. (2003). A grouping principle and four applications. TPAMI, 25(4), 508–513.

Dietterich, T. G. (2000). Ensemble methods in machine learning. In Lecture Notes in Computer Science (pp. 1–15).

Dollar, P., Tu Z., Belongie, S. (2006). Supervised learning of edges and object boundaries. In CVPR (pp. 1964–1971).

Donoser, M., Riemenschneider, H., & Bischof, H. (2010). Linked edges as stable region boundaries. In CVPR.

Drummond, C., & Holte, R. C. (2003). C4.5, class imbalance, and cost sensitivity: Why under-sampling beats over-sampling. In Workshop on learning from imbalanced datasets II.

Felzenszwalb, P., & McAllester, D. (2006). A min-cover approach for finding salient curves. In POCV.

Ferrari, V., Jurie, F., & Schmid, C. (2010). From images to shape models for object detection. IJCV, 87(3), 284–303.CrossRef

Freund, Y., Mansour, Y., & Schapire, R. E. (2001) Why averaging classifiers can protect against overfitting. In Proceedings of the 8th international workshop on artificial intelligence and statistics.

Fridman, A. (2003). Mixed markov models. Proceedings of the National Academy of Sciences, 100(14), 8092–8096.MathSciNetMATHCrossRef

Galun, M., Basri, R., & Brandt, A. (2007). Multiscale edge detection and fiber enhancement using differences of oriented means. In ICCV (pp. 1–8).

Geman, D., & Jedynak, B. (1996). An active testing model for tracking roads in satellite images. TPAMI, 18(1), 1–14.CrossRef

Greminger, M. A., & Nelson, B. J. (2008). A deformable object tracking algorithm based on the boundary element method that is robust to occlusions and spurious edges. IJCV, 78(1), 29–45.CrossRef

Guy, G., & Medioni, G. (1996). Inferring global perceptual contours from local features. IJCV, 20(1–2), 113–133.CrossRef

Helmholtz, H. (1962). Treatise on physiological optics (first published in 1867). New York: Dover.

Hochberg, J. E. (1957). Effects of the Gestalt revolution: The Cornell symposium on perception. Psychological Review, 64(2), 73–84.CrossRef

Itti, L., & Koch, C. (2001). Computational modeling of visual attention. Nature Reviews Neuroscience, 2(3), 194–203.CrossRef

Jain, A., Gupta, A., & Davis, L. S. (2010). Learning what and how of contextual models for scene labeling. ECCV, 4, 199–212.

Jermyn, I. H., & Ishikawa, H. (2001). Globally optimal regions and boundaries as minimum ratio weight cycles. TPAMI, 23(10), 1075–1088.CrossRef

Kaelbling, L. P., Littman, M. L., & Moore, A. W. (1996). Reinforcement learning: A survey. JAIR, 4, 237–285.

Kim, G., Faloutsos, C., & Hebert, M. (2008). Unsupervised modeling of object categories using link analysis techniques. In CVPR.

Kittler, J., Hatef, M., Duin, R. P. W., & Matas, J. (1998). On combining classifiers. TPAMI, 20, 226–239.CrossRef

Koffka, K. (1935). Principles of Gestalt psychology. London: Routledge.

Kokkinos, I. (2010). Boundary detection using F-measure-, Filter- and Feature- (\({F}^3\)) boost. In ECCV.

Kokkinos, I. (2010). Highly accurate boundary detection and grouping. In CVPR.

Konishi, S., Yuille, A., Coughlan, J., & Zhu, S.-C. (1999). Fundamental bounds on edge detection: An information theoretic evaluation of different edge cues. In CVPR.

Konishi, S., Yuille, A. L., Coughlan, J. M., & Zhu, S. C. (2003). Statistical edge detection: Learning and evaluating edge cues. TPAMI, 25, 57–74.CrossRef

Lafferty, J., McCallum, A., & Pereira, F. (2001). Conditional random fields: Probabilistic models for segmenting and labeling sequence data. In ICML, Williamstown (pp. 282–289).

Lee, Y., & Grauman, K. (2009). Shape discovery from unlabeled image collections. In CVPR.

Lindeberg, T. (1998). Edge detection and ridge detection with automatic scale selection. IJCV, 30(2), 117–156.CrossRef

Lowe, D. G. (1985). Perceptual organization and visual recognition. Norwell: Kluwer Academic Publishers.CrossRef

Mahamud, S., Williams, L. R., Thornber, K. K., & Xu, K. (2003). Segmentation of multiple salient closed contours from real images. TPAMI, 25(4), 433–444.CrossRef

Mairal, J., Leordeanu, M., Bach, F., Hebert, M., & Ponce, J. (2008). Discriminative sparse image models for class-specific edge detection and image interpretation. In ECCV (pp. 43–56).

Maire, M., Arbelaez, P., Fowlkes, C., & Malik, J. (2008). Using contours to detect and localize junctions in natural images. In CVPR (pp. 1–8).

Martin, D., Fowlkes, C., Tal, D., & Malik, J. (2001). A database of human segmented natural images and its application to evaluating segmentation algorithms and measuring ecological statistics. In ICCV, Vancouver.

Martin, D. R., Fowlkes, C. C., & Malik, J. (2004). Learning to detect natural image boundaries using local brightness, color, and texture cues. PAMI, 26, 530–549.CrossRef

Morrone, M. C., & Owens, R. A. (1987). Feature detection from local energy. Pattern Recognition Letters, 6(5), 303–313.CrossRef

Palmer, S. (1999). Vision science: Photons to phenomenology. Cambridge: MIT Press.

Perona, P., & Malik, J. (1990). Detecting and localizing edges composed of steps, peaks and roofs. In ICCV.

Porrill, J., & Pollard, S. (1991). Curve matching and stereo calibration. IVC, 9(1), 45–50.CrossRef

Ren, X. (2008). Multi-scale improves boundary detection in natural images. In ECCV, Marseille.

Ren, X., Fowlkes, C., & Malik, J. (2008). Learning probabilistic models for contour completion in natural images. IJCV, 77(1–3), 47–63.CrossRef

Rubner Y., & Tomasi C., (1996). Coalescing texture descriptors. In ARPA image understanding, Workshop (pp. 927–935).

Russell, B. C., Torralba, A., Murphy, K. P., & Freeman, W. T. (2008). Labelme: A database and web-based tool for image annotation. IJCV, 77(1–3), 157–173.CrossRef

Sharon, E., Br ,A., & Basri, R. (2001). Segmentation and boundary detection using multiscale intensity measurements. In CVPR (pp. 469–476).

Shashua, A., & Ullman, S. (1988). Structural saliency: The detection of globally salient structures using a locally connected network. In ICCV, Tampa.

Taskar, B., Guestrin, C., & Koller, D. (2004). Max-margin Markov networks. In NIPS, Vancouver.

Teh, C. H., & Chin, R. T. (1989). On the detection of dominant points on digital curves. IEEE Transactions on Pattern Analysis and Machine Intelligence, 11(8), 859–872.CrossRef

Tsochantaridis, I., Joachims, T., Hofmann, T., & Altun, Y. (2005). Large margin methods for structured and interdependent output variables. Journal of Machine Learning Research, 6, 1453–1484.MathSciNetMATH

Varma, M., & Zisserman, A. (2003). Texture classification: Are filter banks necessary? CVPR, 2, 691.

Wang, S., Kubota, T., Siskind, J. M., & Wang, J. (2005). Salient closed boundary extraction with ratio contour. TPAMI, 27(4), 546–561.CrossRef

Will, S., Hermes, L., Buhmann, J. M., Puzicha, & J. (2000). On learning texture edge detectors. In ICIP (pp. 877–880).

Williams, L., & Jacobs, D. (1995). Stochastic completion fields: A neural model of illusory contour shape and salience. In ICCV (pp. 408–415).

Williams, L. R., & Thornber, K. K. (1999). A comparison of measures for detecting natural shapes in cluttered backgrounds. IJCV, 34(2–3), 81–96.CrossRef

Xiong, W., & Jia, J. (2007). Stereo matching on objects with fractional boundary. In CVPR.

Yu, S. (2005). Segmentation induced by scale invariance. In CVPR.

Zhu, Q., Song, G., & Shi, J. (2007). Untangling cycles for contour grouping. In ICCV (pp. 1–8).

Zhu, S.-C. (1999). Embedding Gestalt laws in Markov random fields. TPAMI, 21(11), 1170–1187.CrossRef

Title: SLEDGE: Sequential Labeling of Image Edges for Boundary Detection
Authors: Nadia Payet
Sinisa Todorovic
Publication date: 01-08-2013
Publisher: Springer US
Published in: International Journal of Computer Vision / Issue 1/2013
Print ISSN: 0920-5691
Electronic ISSN: 1573-1405
DOI: https://doi.org/10.1007/s11263-013-0612-5

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Wirtschaft"

Springer Professional "Technik"

Other articles of this Issue 1/2013

Recovering Relative Depth from Low-Level Features Without Explicit T-junction Detection and Interpretation

Linearized Alternating Direction Method with Adaptive Penalty and Warm Starts for Fast Solving Transform Invariant Low-Rank Textures

3D Scene Reconstruction from Multiple Spherical Stereo Pairs

Coupling Image Restoration and Segmentation: A Generalized Linear Model/Bregman Perspective

Premium Partner