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GaitSet: regarding gait as a set for cross-view gait recognition

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Jianfeng FengAuthors Info & Claims

AAAI'19/IAAI'19/EAAI'19: Proceedings of the Thirty-Third AAAI Conference on Artificial Intelligence and Thirty-First Innovative Applications of Artificial Intelligence Conference and Ninth AAAI Symposium on Educational Advances in Artificial Intelligence

Article No.: 996, Pages 8126 - 8133

https://doi.org/10.1609/aaai.v33i01.33018126

Published: 27 January 2019 Publication History

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Abstract

As a unique biometric feature that can be recognized at a distance, gait has broad applications in crime prevention, forensic identification and social security. To portray a gait, existing gait recognition methods utilize either a gait template, where temporal information is hard to preserve, or a gait sequence, which must keep unnecessary sequential constraints and thus loses the flexibility of gait recognition. In this paper we present a novel perspective, where a gait is regarded as a set consisting of independent frames. We propose a new network named GaitSet to learn identity information from the set. Based on the set perspective, our method is immune to permutation of frames, and can naturally integrate frames from different videos which have been filmed under different scenarios, such as diverse viewing angles, different clothes/carrying conditions. Experiments show that under normal walking conditions, our single-model method achieves an average rank-1 accuracy of 95.0% on the CASIA-B gait dataset and an 87.1% accuracy on the OU-MVLP gait dataset. These results represent new state-of-the-art recognition accuracy. On various complex scenarios, our model exhibits a significant level of robustness. It achieves accuracies of 87.2% and 70.4% on CASIA-B under bag-carrying and coat-wearing walking conditions, respectively. These outperform the existing best methods by a large margin. The method presented can also achieve a satisfactory accuracy with a small number of frames in a test sample, e.g., 82.5% on CASIA-B with only 7 frames.

References

[1]

Bashir, K.; Xiang, T.; and Gong, S. 2010. Gait recognition without subject cooperation. Pattern Recognition Letters 31(13):2052–2060.

Digital Library

[2]

Charles, R. Q.; Su, H.; Kaichun, M.; and Guibas, L. J. 2017. Pointnet: Deep learning on point sets for 3D classification and segmentation. In CVPR, 77–85.

[3]

Fu, Y.; Wei, Y.; Zhou, Y.; Shi, H.; Huang, G.; Wang, X.; Yao, Z.; and Huang, T. 2018. Horizontal pyramid matching for person re-identification. ArXiv:1804.05275.

[4]

Hamilton, W.; Ying, Z.; and Leskovec, J. 2017. Inductive representation learning on large graphs. In NIPS, 1024–1034.

[5]

Han, J., and Bhanu, B. 2006. Individual recognition using gait energy image. IEEE TPAMI 28(2):316–322.

Digital Library

[6]

He, Y.; Zhang, J.; Shan, H.; and Wang, L. 2019. Multi-task GANs for view-specific feature learning in gait recognition. IEEE TIFS 14(1):102–113.

[7]

Hermans, A.; Beyer, L.; and Leibe, B. 2017. In defense of the triplet loss for person re-identification. ArXiv:1703.07737.

[8]

Hu, M.; Wang, Y.; Zhang, Z.; Little, J. J.; and Huang, D. 2013. View-invariant discriminative projection for multi-view gait-based human identification. IEEE TIFS 8(12):2034–2045.

[9]

Kingma, D. P., and Ba, J. 2015. Adam: A method for stochastic optimization. ICLR.

[10]

Krause, J.; Johnson, J.; Krishna, R.; and Fei-Fei, L. 2017. A hierarchical approach for generating descriptive image paragraphs. In CVPR, 3337–3345.

[11]

Kusakunniran, W.; Wu, Q.; Zhang, J.; Li, H.; and Wang, L. 2014. Recognizing gaits across views through correlated motion co-clustering. IEEE TIP 23(2):696–709.

[12]

Li, W.; Zhu, X.; and Gong, S. 2018. Harmonious attention network for person re-identification. In CVPR.

[13]

Liao, R.; Cao, C.; Garcia, E. B.; Yu, S.; and Huang, Y. 2017. Pose-based temporal-spatial network (ptsn) for gait recognition with carrying and clothing variations. In Chinese Conference on Biometric Recognition, 474–483. Springer.

[14]

Makihara, Y.; Sagawa, R.; Mukaigawa, Y.; Echigo, T.; and Yagi, Y. 2006. Gait recognition using a view transformation model in the frequency domain. In ECCV, 151–163. Springer.

[15]

Qi, C. R.; Yi, L.; Su, H.; and Guibas, L. J. 2017. PointNet++: Deep hierarchical feature learning on point sets in a metric space. In NIPS, 5099–5108.

[16]

Shiraga, K.; Makihara, Y.; Muramatsu, D.; Echigo, T.; and Yagi, Y. 2016. GEINet: View-invariant gait recognition using a convolutional neural network. In ICB, 1–8.

[17]

Takemura, N.; Makihara, Y.; Muramatsu, D.; Echigo, T.; and Yagi, Y. 2018a. On input/output architectures for convolutional neural network-based cross-view gait recognition. IEEE TCSVT 28(1):1–13.

[18]

Takemura, N.; Makihara, Y.; Muramatsu, D.; Echigo, T.; and Yagi, Y. 2018b. Multi-view large population gait dataset and its performance evaluation for cross-view gait recognition. IPSJ TCVA 10(4):1–14.

[19]

Wang, C.; Zhang, J.; Wang, L.; Pu, J.; and Yuan, X. 2012. Human identification using temporal information preserving gait template. IEEE TPAMI 34(11):2164–2176.

Digital Library

[20]

Wang, G.; Yuan, Y.; Chen, X.; Li, J.; and Zhou, X. 2018a. Learning discriminative features with multiple granularities for person re-identification. ArXiv:1804.01438.

[21]

Wang, X.; Girshick, R.; Gupta, A.; and He, K. 2018b. Nonlocal neural networks. In CVPR.

[22]

Wang, Y.; Sun, Y.; Liu, Z.; Sarma, S. E.; Bronstein, M. M.; and Solomon, J. M. 2018c. Dynamic graph CNN for learning on point clouds. ArXiv:1801.07829.

[23]

Wolf, T.; Babaee, M.; and Rigoll, G. 2016. Multi-view gait recognition using 3D convolutional neural networks. In ICIP, 4165–4169.

[24]

Wu, Z.; Huang, Y.; Wang, L.; Wang, X.; and Tan, T. 2017. A comprehensive study on cross-view gait based human identification with deep CNNs. IEEE TPAMI 39(2):209–226.

Digital Library

[25]

Xing, X.; Wang, K.; Yan, T.; and Lv, Z. 2016. Complete canonical correlation analysis with application to multi-view gait recognition. Pattern Recognition 50:107–117.

Digital Library

[26]

Xu, K.; Ba, J.; Kiros, R.; Cho, K.; Courville, A.; Salakhudinov, R.; Zemel, R.; and Bengio, Y. 2015. Show, attend and tell: Neural image caption generation with visual attention. In ICML, 2048–2057.

[27]

Yu, S.; Chen, H.; Reyes, E. B. G.; and Poh, N. 2017a. GaitGAN: Invariant gait feature extraction using generative adversarial networks. In CVPR Workshops, 532–539.

[28]

Yu, S.; Chen, H.; Wang, Q.; Shen, L.; and Huang, Y. 2017b. Invariant feature extraction for gait recognition using only one uniform model. Neurocomputing 239:81–93.

Digital Library

[29]

Yu, S.; Tan, D.; and Tan, T. 2006. A framework for evaluating the effect of view angle, clothing and carrying condition on gait recognition. In ICPR, volume 4, 441–444.

[30]

Zaheer, M.; Kottur, S.; Ravanbakhsh, S.; Poczos, B.; Salakhutdinov, R. R.; and Smola, A. J. 2017. Deep sets. In NIPS, 3391–3401.

[31]

Zhou, Y., and Tuzel, O. 2018. Voxelnet: End-to-end learning for point cloud based 3D object detection. CVPR.

Cited By

Wang ZHou SZhang MLiu XCao CHuang YLi PXu SWooldridge MDy JNatarajan S(2024)QAGaitProceedings of the Thirty-Eighth AAAI Conference on Artificial Intelligence and Thirty-Sixth Conference on Innovative Applications of Artificial Intelligence and Fourteenth Symposium on Educational Advances in Artificial Intelligence10.1609/aaai.v38i6.28391(5785-5793)Online publication date: 20-Feb-2024
https://dl.acm.org/doi/10.1609/aaai.v38i6.28391
Shakeel MLiu KLiao XKang W(2024)MRGait: A Multi-range feature learning framework for Cross-View Gait RecognitionProceedings of the 6th ACM International Conference on Multimedia in Asia10.1145/3696409.3700247(1-7)Online publication date: 3-Dec-2024
https://dl.acm.org/doi/10.1145/3696409.3700247
Han XRen YCong PSun YWang JXu LMa YCai JKankanhalli MPrabhakaran BBoll SSubramanian RZheng LSingh VCesar PXie LXu D(2024)Gait Recognition in Large-scale Free Environment via Single LiDARProceedings of the 32nd ACM International Conference on Multimedia10.1145/3664647.3681166(380-389)Online publication date: 28-Oct-2024
https://dl.acm.org/doi/10.1145/3664647.3681166
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Index Terms

GaitSet: regarding gait as a set for cross-view gait recognition
1. Computing methodologies
  1. Artificial intelligence
    1. Computer vision
      1. Computer vision problems
  2. Machine learning
    1. Learning paradigms
      1. Supervised learning
    2. Machine learning approaches

Index terms have been assigned to the content through auto-classification.

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AAAI'19/IAAI'19/EAAI'19: Proceedings of the Thirty-Third AAAI Conference on Artificial Intelligence and Thirty-First Innovative Applications of Artificial Intelligence Conference and Ninth AAAI Symposium on Educational Advances in Artificial Intelligence

January 2019

10088 pages

ISBN:978-1-57735-809-1

Copyright © 2019 Association for the Advancement of Artificial Intelligence.

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Published: 27 January 2019

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Cited By

Wang ZHou SZhang MLiu XCao CHuang YLi PXu SWooldridge MDy JNatarajan S(2024)QAGaitProceedings of the Thirty-Eighth AAAI Conference on Artificial Intelligence and Thirty-Sixth Conference on Innovative Applications of Artificial Intelligence and Fourteenth Symposium on Educational Advances in Artificial Intelligence10.1609/aaai.v38i6.28391(5785-5793)Online publication date: 20-Feb-2024
https://dl.acm.org/doi/10.1609/aaai.v38i6.28391
Shakeel MLiu KLiao XKang W(2024)MRGait: A Multi-range feature learning framework for Cross-View Gait RecognitionProceedings of the 6th ACM International Conference on Multimedia in Asia10.1145/3696409.3700247(1-7)Online publication date: 3-Dec-2024
https://dl.acm.org/doi/10.1145/3696409.3700247
Han XRen YCong PSun YWang JXu LMa YCai JKankanhalli MPrabhakaran BBoll SSubramanian RZheng LSingh VCesar PXie LXu D(2024)Gait Recognition in Large-scale Free Environment via Single LiDARProceedings of the 32nd ACM International Conference on Multimedia10.1145/3664647.3681166(380-389)Online publication date: 28-Oct-2024
https://dl.acm.org/doi/10.1145/3664647.3681166
Peng GWang YZhao YZhang SLi ACai JKankanhalli MPrabhakaran BBoll SSubramanian RZheng LSingh VCesar PXie LXu D(2024)GLGait: A Global-Local Temporal Receptive Field Network for Gait Recognition in the WildProceedings of the 32nd ACM International Conference on Multimedia10.1145/3664647.3680812(826-835)Online publication date: 28-Oct-2024
https://dl.acm.org/doi/10.1145/3664647.3680812
An QReza Pavel HRoy AMakedon F(2024)Residual Graph Network for Assessing Cognitive Fatigue from Gait Cycle AnalysisProceedings of the 17th International Conference on PErvasive Technologies Related to Assistive Environments10.1145/3652037.3652065(228-232)Online publication date: 26-Jun-2024
https://dl.acm.org/doi/10.1145/3652037.3652065
Wang ZWang LShi ZZhang MGeng QJiang N(2024)A survey on person and vehicle re‐identificationIET Computer Vision10.1049/cvi2.1231618:8(1235-1268)Online publication date: 28-Dec-2024
https://dl.acm.org/doi/10.1049/cvi2.12316
Lu YJin M(2023)Dual-Branch Network Fused With Two-Level Attention Mechanism for Clothes-Changing Person Re-IdentificationInternational Journal of Web Services Research10.4018/IJWSR.32202120:1(1-14)Online publication date: 20-Apr-2023
https://dl.acm.org/doi/10.4018/IJWSR.322021
Chen HXiang JLuo FZhao LMa L(2023)Research on Construction of Dual Channel Model Based on Elderly GaitProceedings of the 2023 4th International Conference on Machine Learning and Computer Application10.1145/3650215.3650399(1042-1046)Online publication date: 27-Oct-2023
https://dl.acm.org/doi/10.1145/3650215.3650399
Wang ZHou SZhang MLiu XCao CHuang YXu SEl Saddik AMei TCucchiara RBertini MTobon Vallejo DAtrey PHossain M(2023)LandmarkGait: Intrinsic Human Parsing for Gait RecognitionProceedings of the 31st ACM International Conference on Multimedia10.1145/3581783.3611840(2305-2314)Online publication date: 26-Oct-2023
https://dl.acm.org/doi/10.1145/3581783.3611840
Zhang PDou HZhang WZhao YQin ZHu DFang YLi X(2023)A Large-Scale Synthetic Gait Dataset Towards in-the-Wild Simulation and Comparison StudyACM Transactions on Multimedia Computing, Communications, and Applications10.1145/351719919:1(1-23)Online publication date: 5-Jan-2023
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