Efficient Boosting-Based Active Learning for Specific Object Detection Problems
In this work, we present a novel active learning approach
for learning a visual object detection system. Our system
is composed of an active learning mechanism as wrapper around
a sub-algorithm which implement an online boosting-based learning
object detector. In the core is a combination of a bootstrap procedure
and a semi automatic learning process based on the online boosting
procedure. The idea is to exploit the availability of classifier during
learning to automatically label training samples and increasingly
improves the classifier. This addresses the issue of reducing labeling
effort meanwhile obtain better performance. In addition, we propose
a verification process for further improvement of the classifier.
The idea is to allow re-update on seen data during learning for
stabilizing the detector. The main contribution of this empirical study
is a demonstration that active learning based on an online boosting
approach trained in this manner can achieve results comparable or
even outperform a framework trained in conventional manner using
much more labeling effort. Empirical experiments on challenging data
set for specific object deteciton problems show the effectiveness of
our approach.
[1] Y. Abramson and Y. Freund. SEmi-automatic VIsual LEarning
(SEVILLE): Tutorial on active learning for visual object recognition.
Technical report, UCSD, 2005.
[2] S. Agarwal, A. Awan, and D. Roth. Learning to detect objects in images
via a sparse, part-based representation. Transactions on Pattern Analysis
and Machine Intelligence, 26(11):1475-1490, 2004.
[3] L. Anton-Canalis and E. Sanchez-Nielsen. Hand posture dataset creation
for gesture recognition. In International Conference on Computer Vision
Theory and Applications (VISAPP06), 2006.
[4] H. Francke, J. Ruiz del Solar, and R. Verschae. Real-time hand gesture
detection and recognition using boosted classifiers and active learning.
pages 533-547, 2007.
[5] H. Grabner and H. Bischof. On-line boosting and vision. In Proceedings
CVPR, volume 1, pages 260-267, New York, NY, USA, 2006. IEEE
Computer Society.
[6] R. Hewitt and S. Belongie. Active learning in face recognition: Using
tracking to build a face model. CVPR Workshop, pages 157-157, 2006.
[7] C. Huang, H. Ai, Y. Li, and S. Lao. Vector boosting for rotation invariant
multi-view face detection. ICCV, 2005, IEEE, 1:446-453 Vol. 1, 2005.
[8] O. Javed, S. Ali, and M. Shah. Online detection and classification of
moving objects using progressively improving detectors. In Proceedings
CVPR, pages 695-700, San Diego, CA, USA, 2005. IEEE.
[9] M. Kolsch and M. Turk. Robust hand detection. Proceedings, FG04,
IEEE, pages 614-619, 2004.
[10] A. Levin, P. Viola, and Y. Freund. Unsupervised improvement of visual
detectors using co-training. In Proceedings ICCV, volume 2, pages 626-
633, Nice, France, 2003. IEEE.
[11] Tong Luo, K. Kramer, S. Samson, and A. Remsen. Active learning to
recognize multiple types of plankton. Proceedings ICPR 2004, 3:478-
481 Vol.3, 2004.
[12] C. Monteleoni and M. Kaariainen. Practical online active learning for
classification. CVPR -07, IEEE, pages 1-8, 2007.
[13] Thuy Thi Nguyen, Helmut Grabner, Horst Bischof, and Barbara Gruber.
On-line boosting for car detection from aerial images. RIVF-07, IEEE,
pages 87-95, 2007.
[14] A. Opelt, M. Fussenegger, A. Pinz, and P. Auer. Weak hypotheses and
boosting for generic object detection and recognition. In ECCV, pages
Vol II: 71-84, 2004.
[15] N. Oza and S. Russell. Online bagging and boosting. In Proceedings AI
and Statistics, pages 105-112, Florida, USA, 2001. Morgan Kaufmann.
[16] M.-Tri Pham and T.-J. Cham. Online learning asymmetric boosted
classifiers for object detection. In CVPR-07, IEEE, 2007.
[17] C. Rosenberg, M. Hebert, and H. Schneiderman. Semi-supervised selftraining
of object detection models. In Proceedings WACV. IEEE,
January 2005.
[18] P. Roth and H. Bischof. On-line learning a person model from video
data. In Video Proc. CVPR, IEEE, 2006.
[19] P.M. Roth, H. Grabner, D. Skoˇcaj, H. Bischof, and A. Leonardis. Online
conservative learning for person detection. In Proceedings VS-PETS,
pages 223-230, Beijing, China, 2005. IEEE.
[20] K. Sung and P. Niyogi. A formulation for active learning with
applications to object detection. Technical Report AIM-1438, 1995.
[21] A. Torralba, K.P. Murphy, and W.T. Freeman. Sharing features: Efficient
boosting procedures for multiclass object detection. volume 2, pages
762-769, 2005.
[22] R. Verschae, J. Ruiz del Solar, and M. Correa. A unified learning
framework for object detection and classification using nested cascades
of boosted classifiers. Mach. Vision Appl., 19(2):85-103, 2008.
[23] P. Viola and M. Jones. Rapid object detection using a boosted cascade
of simple features. In CVPR, volume 1, pages 511-518, Kauai, HI,
USA, 2001. IEEE Computer Society.
[24] Paul A. Viola and Michael J. Jones. Robust real-time face detection.
IJCV, 57:137-154, 2004.
[25] T. Yang, J. Li, Q. Pan, C. Zhao, and Y. Zhu. Active learning
based pedestrian detection in real scenes. In ICPR, pages 904-907,
Washington, DC, USA, 2006. IEEE.
[1] Y. Abramson and Y. Freund. SEmi-automatic VIsual LEarning
(SEVILLE): Tutorial on active learning for visual object recognition.
Technical report, UCSD, 2005.
[2] S. Agarwal, A. Awan, and D. Roth. Learning to detect objects in images
via a sparse, part-based representation. Transactions on Pattern Analysis
and Machine Intelligence, 26(11):1475-1490, 2004.
[3] L. Anton-Canalis and E. Sanchez-Nielsen. Hand posture dataset creation
for gesture recognition. In International Conference on Computer Vision
Theory and Applications (VISAPP06), 2006.
[4] H. Francke, J. Ruiz del Solar, and R. Verschae. Real-time hand gesture
detection and recognition using boosted classifiers and active learning.
pages 533-547, 2007.
[5] H. Grabner and H. Bischof. On-line boosting and vision. In Proceedings
CVPR, volume 1, pages 260-267, New York, NY, USA, 2006. IEEE
Computer Society.
[6] R. Hewitt and S. Belongie. Active learning in face recognition: Using
tracking to build a face model. CVPR Workshop, pages 157-157, 2006.
[7] C. Huang, H. Ai, Y. Li, and S. Lao. Vector boosting for rotation invariant
multi-view face detection. ICCV, 2005, IEEE, 1:446-453 Vol. 1, 2005.
[8] O. Javed, S. Ali, and M. Shah. Online detection and classification of
moving objects using progressively improving detectors. In Proceedings
CVPR, pages 695-700, San Diego, CA, USA, 2005. IEEE.
[9] M. Kolsch and M. Turk. Robust hand detection. Proceedings, FG04,
IEEE, pages 614-619, 2004.
[10] A. Levin, P. Viola, and Y. Freund. Unsupervised improvement of visual
detectors using co-training. In Proceedings ICCV, volume 2, pages 626-
633, Nice, France, 2003. IEEE.
[11] Tong Luo, K. Kramer, S. Samson, and A. Remsen. Active learning to
recognize multiple types of plankton. Proceedings ICPR 2004, 3:478-
481 Vol.3, 2004.
[12] C. Monteleoni and M. Kaariainen. Practical online active learning for
classification. CVPR -07, IEEE, pages 1-8, 2007.
[13] Thuy Thi Nguyen, Helmut Grabner, Horst Bischof, and Barbara Gruber.
On-line boosting for car detection from aerial images. RIVF-07, IEEE,
pages 87-95, 2007.
[14] A. Opelt, M. Fussenegger, A. Pinz, and P. Auer. Weak hypotheses and
boosting for generic object detection and recognition. In ECCV, pages
Vol II: 71-84, 2004.
[15] N. Oza and S. Russell. Online bagging and boosting. In Proceedings AI
and Statistics, pages 105-112, Florida, USA, 2001. Morgan Kaufmann.
[16] M.-Tri Pham and T.-J. Cham. Online learning asymmetric boosted
classifiers for object detection. In CVPR-07, IEEE, 2007.
[17] C. Rosenberg, M. Hebert, and H. Schneiderman. Semi-supervised selftraining
of object detection models. In Proceedings WACV. IEEE,
January 2005.
[18] P. Roth and H. Bischof. On-line learning a person model from video
data. In Video Proc. CVPR, IEEE, 2006.
[19] P.M. Roth, H. Grabner, D. Skoˇcaj, H. Bischof, and A. Leonardis. Online
conservative learning for person detection. In Proceedings VS-PETS,
pages 223-230, Beijing, China, 2005. IEEE.
[20] K. Sung and P. Niyogi. A formulation for active learning with
applications to object detection. Technical Report AIM-1438, 1995.
[21] A. Torralba, K.P. Murphy, and W.T. Freeman. Sharing features: Efficient
boosting procedures for multiclass object detection. volume 2, pages
762-769, 2005.
[22] R. Verschae, J. Ruiz del Solar, and M. Correa. A unified learning
framework for object detection and classification using nested cascades
of boosted classifiers. Mach. Vision Appl., 19(2):85-103, 2008.
[23] P. Viola and M. Jones. Rapid object detection using a boosted cascade
of simple features. In CVPR, volume 1, pages 511-518, Kauai, HI,
USA, 2001. IEEE Computer Society.
[24] Paul A. Viola and Michael J. Jones. Robust real-time face detection.
IJCV, 57:137-154, 2004.
[25] T. Yang, J. Li, Q. Pan, C. Zhao, and Y. Zhu. Active learning
based pedestrian detection in real scenes. In ICPR, pages 904-907,
Washington, DC, USA, 2006. IEEE.
@article{"International Journal of Information, Control and Computer Sciences:58639", author = "Thuy Thi Nguyen and Nguyen Dang Binh and Horst Bischof", title = "Efficient Boosting-Based Active Learning for Specific Object Detection Problems", abstract = "In this work, we present a novel active learning approach
for learning a visual object detection system. Our system
is composed of an active learning mechanism as wrapper around
a sub-algorithm which implement an online boosting-based learning
object detector. In the core is a combination of a bootstrap procedure
and a semi automatic learning process based on the online boosting
procedure. The idea is to exploit the availability of classifier during
learning to automatically label training samples and increasingly
improves the classifier. This addresses the issue of reducing labeling
effort meanwhile obtain better performance. In addition, we propose
a verification process for further improvement of the classifier.
The idea is to allow re-update on seen data during learning for
stabilizing the detector. The main contribution of this empirical study
is a demonstration that active learning based on an online boosting
approach trained in this manner can achieve results comparable or
even outperform a framework trained in conventional manner using
much more labeling effort. Empirical experiments on challenging data
set for specific object deteciton problems show the effectiveness of
our approach.", keywords = "Computer vision, object detection, online boosting,
active learning, labeling complexity.", volume = "2", number = "5", pages = "1600-6", }
