[1] Andriluka M, Roth S, Schiele B. Pictorial structures revisited: people detection and articulated pose estimation. [C]∥2009 IEEE Conference on Computer Vision and Pattern Recognition, June 20-25, 2009, Miami, FL, USA. New York: IEEE, 1014-1021(2009).
[2] Ladicky L. Torr P H S, Zisserman A. Human pose estimation using a joint pixel-wise and part-wise formulation. [C]∥2013 IEEE Conference on Computer Vision and Pattern Recognition, June 23-28, 2013, Portland, OR, USA. New York: IEEE, 3578-3585(2013).
[4] Newell A, Yang K Y, Deng J. Stacked hourglass networks for human pose estimation[M]. ∥Leibe B, Matas J, Sebe N, et al. Computer Vision-ECCV 2016. Lecture Notes in Computer Science. Cham: Springer, 9912, 483-499(2016).
[5] Luo J Y, Xu Y, Tang C W et al. Learning inverse mapping by autoencoder based generative adversarial nets[M]. ∥ Liu D, Xie S, Li Y, et al. Neural Information Processing. ICONIP 2017. Lecture Notes in Computer Science. Cham: Springer, 10635, 207-216(2017).
[9] Wang X L, Shrivastava A, Gupta A. A-fast-RCNN: hard positive generation via adversary for object detection. [C]∥2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), July 21-26, 2017, Honolulu, HI, USA. New York: IEEE, 3039-3048(2017).
[10] Peng X, Tang Z Q, Yang F et al. Jointly optimize data augmentation and network training: adversarial data augmentation in human pose estimation. [C]∥2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition, June 18-23, 2018, Salt Lake City, UT, USA. New York: IEEE, 2226-2234(2018).
[11] Chou C J, Chien J T, Chen H T[2020-01-02]. Self adversarial training for human pose estimation [2020-01-02].https:∥arxiv., org/abs/1707, 02439.
[12] Chen Y, Shen C H, Wei X S et al. Adversarial PoseNet: a structure-aware convolutional network for human pose estimation. [C]∥2017 IEEE International Conference on Computer Vision (ICCV), October 22-29, 2017, Venice, Italy. New York: IEEE, 1221-1230(2017).
[13] Szegedy C, Ioffe S, Vanhoucke V et al[2019-12-28]. Inception-v4, inception-ResNet and the impact of residual connections on learning [2019-12-28].http:∥arxiv., org/abs/1602, 07261.
[14] Tompson J, Jain A, Lecun Y et al[2020-01-01]. Joint training of a convolutional network and a graphical model for human pose estimation [2020-01-01].https:∥arxiv., org/abs/1406, 2984.
[15] Berthelot D, Schumm T, Metz L[2019-12-30]. BEGAN: boundary equilibrium generative adversarial networks [2019-12-30].https:∥www.arxiv., org/abs/1703, 10717.
[16] Johnson S, Everingham M. Clustered pose and nonlinear appearance models for human pose estimation. [C]∥Procedings of the British Machine Vision Conference, BMVC 2010, August 31-September 3, 2010, Aberystwyth, UK. UK: BMVA, 1-11(2010).
[17] Andriluka M, Pishchulin L, Gehler P et al. 2D human pose estimation: new benchmark and state of the art analysis. [C]∥2014 IEEE Conference on Computer Vision and Pattern Recognition, June 23-28, 2014, Columbus, OH, USA. New York: IEEE, 3686-3693(2014).
[18] Sze V, Chen Y H, Yang T J et al. Efficient processing of deep neural networks: a tutorial and survey[J]. Proceedings of the IEEE, 105, 2295-2329(2017).
[19] Tieleman T, Hinton G. Lecture 6.5-rmsprop: divide the gradient by a running average of its recent magnitude[J]. COURSERA: Neural Networks for Machine Learning, 4, 26-31(2012).
[20] Yang Y, Ramanan D. Articulated pose estimation with flexible mixtures-of-parts. [C]∥CVPR 2011, June 20-25, 2011, Providence, RI, USA. New York: IEEE, 1385-1392(2011).
[21] Wei S H, Ramakrishna V, Kanade T et al. Convolutional pose machines. [C]∥2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), June 27-30, 2016, Las Vegas, NV, USA. New York: IEEE, 4724-4732(2016).
