ABNORMAL CROWD BEHAVIOUR DETECTION BASED ON DEEP LEARNING AND SPARSE REPRESENTATION, 322-331.

Zhendi Gai, Dongmei Liu, Faliang Chang, and Nanjun Li

References

1. [1] S.H. Cho and H.B. Kang, Integrated multiple behavior models for abnormal crowd behavior detection, IEEE Southwest Symposium on Image Analysis and Interpretation, Santa Fe, NM, 2012, 113–116.
2. [2] Y.H. Zhang, L. Qin, H.Y. Yao, and Q. Huang, Abnormal crowd behavior detection based on social attribute-aware force model, IEEE International Conf. on Image Processing, Orlando, Florida, USA, 2012, 2689–2692.
3. [3] N. Suriani, A. Hussain, and M. Zulkifley, Sudden event recognition: A survey, Sensors, 13(8), 2013, 9966–9998.
4. [4] J. Yuan, Z. Liu, and Y. Wu, Discriminative video pattern search for efficient action detection, IEEE Transactions on Pattern Analysis and Machine Intelligence, 33(9), 2011, 1728–1743.
5. [5] Y. Cong, J. Yuan, and J. Liu, Abnormal event detection in crowded scenes using sparse representation, Pattern Recognition, 46(7), 2013, 1851–1864.
6. [6] M. Li, K. Chen, C.M. Guo, and F. Li, Abnormal crowd event detection by fusing saliency information and social force model, Opto-Electronic Engineering, 43(12), 2016, 193–199.
7. [7] C. Wang, X.Y. Wu, N.N. Li, and Y.L. Chen, Abnormal detection based on gait analysis, Intelligent Control and Automation, China, Beijing, 2012, 4859–4864.
8. [8] T. Fernando, S. Denman, S. Sridharan, and C. Fookes, Soft+ hardwired attention: An LSTM framework for human trajectory prediction and abnormal event detection, Neural Networks, 108, 2018, 466–478.
9. [9] T. Fernando, S. Sridharan, C. Fookes, and S. Denman, Deep decision trees for discriminative dictionary learning with adversarial multi-agent trajectories, IEEE Conf. on Computer Vision and Pattern Recognition Workshops, Salt Lake City, UT, 2018, 1722–1731.
10. [10] F. Ding, J. Wang, J. Ge, and W. Li, Anomaly detection in large-scale trajectories using hybrid grid-based hierarchical clustering, International Journal of Robotics and Automation, 33(5), 2018, 474–480.
11. [11] K. Kang, W.B. Liu, and W.W. Xong, Motion pattern study and analysis from video monitoring trajectory, IEICE Transactions on Information and Systems, E97.D(6), 2014, 1574–1582.
12. [12] D.G. Lee, H.I. Suk, and S.W. Lee, Crowd behavior representation using motion influence matrix for anomaly detection, Pattern Recognition, Japan, Okinawa, 2013, 110–114.
13. [13] S. Zaidenberg, P. Bilinski, and F. Bremond, Towards unsupervised sudden group movement discovery for video surveillance, International Conf. on Computer Vision Theory and Applications, Portugal, 2015, 388–395.
14. [14] E. Cermeno, S. Mallor, and J.A. Siguenza, Learning crowd behavior for event recognition, IEEE International Workshop on Performance Evaluation of Tracking and Surveillance, Clearwater Beach, Florida, USA, 2013, 1–5.
15. [15] B. Wang, M. Ye, X. Li, and J. Ding, Abnormal crowd behavior detection using high-frequency and spatio-temporal features, Machine Vision & Applications, 23(3), 2012, 501–511.
16. [16] K. Grm, V. Struc, A. Artiges, et al., Strengths and weaknesses of deep learning models for face recognition against image degradations, IET Biometrics, 7(1), 2018, 81–89.
17. [17] R. Polishetty, M. Roopaei, and P. Rad, A next-generation secure cloud-based deep learning license plate recognition for smart cities, IEEE International Conf. on Machine Learning and Applications, Anaheim, CA, USA, 2016, 286–293.
18. [18] S. Zhou, W. Shen, D. Zeng, et al., Spatial-temporal convolutional neural networks for anomaly detection and localization in crowded scenes, Signal Processing: Image Communication, 47, 2016, 358–368.
19. [19] D. Xu and E. Ricci, Learning deep representations of and motion for anomalous event detection, British Machine Vision Conf., Swansea, 2015, 1–12.
20. [20] M. Sabokrou, M. Fayyaz, M. Fathy, and R. Klette, Deep-cascade: Cascading 3D deep neural networks for fast anomaly detection and localization in crowded scenes, IEEE Transactions on Image Processing, 26(4), 2017, 1992–2004.
21. [21] Q. Wang, Q. Ma, C.H. Luo, et al., Hybrid histogram of oriented optical flow for abnormal behavior detection in crowd scenes, International Journal of Pattern Recognition and Artificial Intelligence, 30(02), 2016, 14.
22. [22] R.C. Cai, W.H. Xie, and Z.H. Hao, Abnormal crowd detection based on multi-scale recurrent neural network, Journal of Software, 26(11), 2015, 2884–2896.
23. [23] B.K.P. Horn and B.G. Schunck, Determining optical flow, Artificial Intelligence, 17(1–3), 1980, 185–203.
24. [24] H.B. Liu and F.L. Chang, Moving object detection by optical flow method based on adaptive weight coefficient, Optics and Precision Engineering, 24(2), 2016, 460–468.
25. [25] B. Guo, H. Dai, and Z. Li, Visual saliency-based motion detection technique for mobile robots, International Journal of Robotics and Automation, 32(2), 2017, 4636–4670.
26. [26] H. Abidi, M. Chtourou, K. Kaaniche, et al., Saliency-based robust features for global visual servoing, International Journal of Robotics and Automation, 31(5), 2016, 206–214.
27. [27] Z. Fang, F. Fei, Y. Fang, et al., Abnormal event detection in crowded scenes based on deep learning, Multimedia Tools and Applications, 75(22), 2016, 14617–14639.
28. [28] T.H. Chan, K. Jia, S. Gao, et al., PCANet: A simple deep learning baseline for image classification, IEEE Transactions on Image Processing, 24(12), 2014, 5017–5032.
29. [29] G. Tolias, R. Sicre, and H. Jegou, Particular object retrieval with integral max-pooling of CNN activations, 2015, arXiv preprint arXiv:1511.05879.
30. [30] Y. Nesterov, Gradient methods for minimizing composite functions, Mathematical Programming, 140(1), 2013, 125–161.
31. [31] UMN dataset [Online], available: http://mha.cs.umn.edu/ Movies/Crowd-Activity-All.avi, January 11, 2012.
32. [32] B. Zhou, X. Tang, H. Zhang, and X. Wang, Measuring crowd collectiveness, IEEE Transactions on Pattern Analysis and Machine Intelligence, 36(8), 2014, 1586–1599.
33. [33] R. Mehran, A. Oyama, and M. Shah, Abnormal crowd behavior detection using social force model, IEEE Conf. on Computer Vision and Pattern Recognition, Miami, Florida, USA, 2009, 935–942.
34. [34] S. Wu, H.S. Wong, and Z. Yu, A Bayesian model for crowd escape behavior detection, IEEE Transactions on Circuits & Systems for Video Technology, 24(1), 2014, 85–98. 330
35. [35] G.G. Xiong, J. Cheng, X.Y. Wu, et al., An energy model approach to people counting for abnormal crowd behavior detection, Neurocomputing, 83(7), 2012, 121–135.
36. [36] C. Direkoglu, M. Sah, and N.E. O’Connor, Abnormal crowd behavior detection using novel optical flow-based features, IEEE International Conf. on Advanced Video and Signal Based Surveillance, Lecce, Italy, 2017, 1–6.
37. [37] H. Fradi, B. Luvison, and Q.C. Pham, Crowd behavior analysis using local mid-level visual descriptors, IEEE Transactions on Circuits and Systems for Video Technology, 27(3), 2016, 589–602.

Important Links:

• Abstract
• DOI: 10.2316/J.2020.206-0325
• From Journal (206) International Journal of Robotics and Automation - 2020

Go Back