논문상세정보
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- 저자 장한별
- 형태사항 83: 26 cm
- 일반주기 지도교수: 이칠우
- 학위논문사항 2022. 2, 학위논문(박사)-, 전남대학교, 전자컴퓨터공학과 컴퓨터정보통신
- DDC 621.381
- 발행지 광주
- 언어 kor
- 출판년 2022
- 발행사항 전남대학교
- 주제어 Graph convolutional network Image gradient Optical flow Humanactionrecognition
인간 행동 인식을 위한 다중 영역 기반 방사형 레이어 GCN 알고리즘 = Multi region based radial layer GCN algorithm for human action recognition
장한별
2022년
'
인간 행동 인식을 위한 다중 영역 기반 방사형 레이어 GCN 알고리즘 = Multi region based radial layer GCN algorithm for human action recognition' 의 주제별 논문영향력
| 주제 |
|
|
|---|---|---|
| 동일주제 총논문수 | 논문피인용 총횟수 | 주제별 논문영향력의 평균 |
| 928 | 0 |
0.0% |
주제별 논문영향력
' 인간 행동 인식을 위한 다중 영역 기반 방사형 레이어 GCN 알고리즘 = Multi region based radial layer GCN algorithm for human action recognition' 의 참고문헌
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[9] Laptev, Ivan, On space-time interest points, International journal of computer vision 64.2, pp. 107-123, 2005.[2005]
-
[8] Efros, Alexei A., et al. Recognizing action at a distance, Computer Vision, IEEE International Conference on. Vol. 3. IEEE Computer Society, 2003.[2003]
-
[7] Weinland, Daniel, Remi Ronfard, and Edmond Boyer, Free viewpoint action recognition using motion history volumes, Computer vision and image understanding 104.2-3, pp. 249-257, 2006.[2006]
-
[5] Kong, Yu, and Yun Fu, Human action recognition and prediction: A survey, arXiv preprint arXiv:1806.11230, 2018.[2018]
-
[4] Shahroudy, Amir, et al. Ntu rgb+ d: A large scale dataset for 3d human activity analysis, Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 1010- 1019, 2016.[2016]
-
[43] Ke, Qiuhong, et al. A new representation of skeleton sequences for 3d action recognition, Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 4570-4579, 2017.[2017]
-
[42] Hou, Jingxuan, Tae Soo Kim, and Austin Reiter, Train, Diagnose and Fix: Interpretable Approach for Fine-grained Action Recognition, arXiv preprint arXiv:1711.08502, 2017.[2017]
-
[41] Jang, Han-Byul, and Chil-Woo Lee, ST-GCN Based Human Action Recognition with Abstracted Three Features of Optical Flow and Image Gradient, International Workshop on Frontiers of Computer Vision. Springer, Cham, pp. 203-217, 2021.
-
[40] Jang, Han-Byul, and Chil-Woo Lee, A human action recognition based on MRGCN using overlapped data acquisition regions, The 10th International Conference on Smart Media and Applications, pp. 10-15, 2021.
-
[39] Jang, Han-Byul, Dae-Jin Kim, and Chil-Woo Lee, Human Action Recognition based on ST-GCN using Opticalflow and Image Gradient, The 9th International Conference on Smart Media and Applications, pp. 255-260, 2020.[2020]
-
[38] Dalal, Navneet, and Bill Triggs, Histograms of oriented gradients for human detection, 2005 IEEE computer society conference on computer vision and pattern recognition (CVPR'05), IEEE, Vol. 1, 2005.[2005]
-
[37] Lucas, Bruce D., and Takeo Kanade, An iterative image registration technique with an application to stereo vision, 1981.[1981]
-
[36] Wikipedia, “https://en.wikipedia.org/wiki/Optical_flow,“ Nov. 2021.
-
[33] Li, Maosen, et al. Actional-structural graph convolutional networks for skeleton-based action recognition, Proceedings of the IEEE/CVF conference on computer vision and pattern recognition, pp. 3590-3598, 2019.[2019]
-
[32] Thakkar, Kalpit, and P. J. Narayanan, Part-based graph convolutional network for action recognition, arXiv preprint arXiv:1809.04983, 2018.[2018]
-
[30] Defferrard, Michaël, Xavier Bresson, and Pierre Vandergheynst, Convolutional neural networks on graphs with fast localized spectral filtering, Advances in neural information processing systems 29, pp. 3844-3852, 2016.[2016]
-
[2] Wikipedia, “https://en.wikipedia.org/wiki/Kinect,” Nov. 2021.
-
[29] Carreira, Joao, and Andrew Zisserman, Quo vadis, action recognition? a new model and the kinetics dataset, proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 4724-4733, 2017.[2017]
-
[28] Kim, Tae Soo, and Austin Reiter, Interpretable 3d human action analysis with temporal convolutional networks, 2017 IEEE conference on computer vision and pattern recognition workshops (CVPRW), IEEE, pp. 1623-1631, 2017.[2017]
-
[27] Liu, Jun, et al. Spatio-temporal lstm with trust gates for 3d human action recognition, European conference on computer vision, Springer, Cham, 2016.[2016]
-
[26] Du, Yong, Wei Wang, and Liang Wang, Hierarchical recurrent neural network for skeleton based action recognition, Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 1110-1118, 2015.[2015]
-
[25] Li, Chuankun, et al. Skeleton-based action recognition using LSTM and CNN, 2017 IEEE International Conference on Multimedia & Expo Workshops (ICMEW), IEEE, pp. 585-590, 2017.[2017]
-
[24] Valueva, Maria V., et al. Application of the residue number system to reduce hardware costs of the convolutional neural network implementation, Mathematics and Computers in Simulation 177, pp. 232-243, 2020.[2020]
-
[23] Rumelhart, David E., Geoffrey E. Hinton, and Ronald J. Williams, Learning representations by back-propagating errors, nature 323.6088, pp. 533-536, 1986.[1986]
-
[22] Brownlee, Jason. A gentle introduction to the rectified linear unit (ReLU), Machine learning mastery 6, 2019.[2019]
-
[20] Bengio, Yoshua, Learning deep architectures for AI, Now Publishers Inc, 2009.[2009]
-
[19] Chaaraoui, Alexandros, Jose Padilla-Lopez, and Francisco Florez-Revuelta, Fusion of skeletal and silhouette-based features for human action recognition with rgb-d devices, Proceedings of the IEEE international conference on computer vision workshops, pp. 91-97, 2013.[2013]
-
[17] Boiman, Oren, Eli Shechtman, and Michal Irani, In defense of nearest-neighbor based image classification, 2008 IEEE Conference on Computer Vision and Pattern Recognition, IEEE, 2008.[2008]
-
[16] Weng, Junwu, Chaoqun Weng, and Junsong Yuan, Spatio-temporal naive-bayes nearest-neighbor (st-nbnn) for skeleton-based action recognition, Proceedings of the IEEE Conference on computer vision and pattern recognition, pp. 445-454, 2017.[2017]
-
[14] Vemulapalli, Raviteja, Felipe Arrate, and Rama Chellappa, Human action recognition by representing 3d skeletons as points in a lie group, Proceedings of the IEEE conference on computer vision and pattern recognition, 2014.[2014]
-
[13] Raptis, Michalis, and Leonid Sigal, Poselet key-framing: A model for human activity recognition, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pp. 2050-2657, 2013.[2013]
-
[12] Duong, Thi V., et al. Activity recognition and abnormality detection with the switching hidden semi-markov model, 2005 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR'05), IEEE, Vol. 1, 2005.[2005]
-
[11] Laptev, Ivan, et al. Learning realistic human actions from movies, 2008 IEEE Conference on Computer Vision and Pattern Recognition, IEEE, 2008.[2008]
-
[10] Schuldt, Christian, Ivan Laptev, and Barbara Caputo, Recognizing human actions: a local SVM approach, Proceedings of the 17th International Conference on Pattern Recognition, IEEE, ICPR 2004, Vol. 3, 2004.[2004]
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Where does AlphaGo go : From church-turing thesis to AlphaGo thesis and beyond
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The recognition of human movement using temporal templates
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Spatio-temporal graph routing for skeleton-based action recognition
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Spatial temporal graph convolutional networks for skeleton-based action recognition
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Optimized skeleton-based action recognition via sparsified graph regression
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OpenPose : realtime multi-person 2D pose estimation using Part Affinity Fields ,
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Human action recognition using a temporal hierarchy of covariance descriptors on 3d joint locations
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3-d human action recognition by shape analysis of motion trajectories on riemannian manifold