This work is licensed under the Creative Commons Attribution 4.0 International License.
Spencer, M., Eickholt, J., & Cheng, J. (2014). A deep learning network approach to ab initio protein secondary structure prediction. IEEE/ACM transactions on computational biology and bioinformatics, 12(1), 103-112.SpencerM.EickholtJ.ChengJ. (2014). A deep learning network approach to ab initio protein secondary structure prediction. IEEE/ACM transactions on computational biology and bioinformatics, 12(1), 103-112.Search in Google Scholar
Shawahna, A., Sait, S. M., & El-Maleh, A. (2018). FPGA-based accelerators of deep learning networks for learning and classification: A review. ieee Access, 7, 7823-7859.ShawahnaA.SaitS. M.El-MalehA. (2018). FPGA-based accelerators of deep learning networks for learning and classification: A review. ieee Access, 7, 7823-7859.Search in Google Scholar
Wang, J., Qiu, K., Peng, H., Fu, J., & Zhu, J. (2019, October). Ai coach: Deep human pose estimation and analysis for personalized athletic training assistance. In Proceedings of the 27th ACM international conference on multimedia (pp. 374-382).WangJ.QiuK.PengH.FuJ.ZhuJ. (2019, October). Ai coach: Deep human pose estimation and analysis for personalized athletic training assistance. In Proceedings of the 27th ACM international conference on multimedia (pp. 374-382).Search in Google Scholar
Díaz-Pereira, M. P., Gomez-Conde, I., Escalona, M., & Olivieri, D. N. (2014). Automatic recognition and scoring of olympic rhythmic gymnastic movements. Human movement science, 34, 63-80.Díaz-PereiraM. P.Gomez-CondeI.EscalonaM.OlivieriD. N. (2014). Automatic recognition and scoring of olympic rhythmic gymnastic movements. Human movement science, 34, 63-80.Search in Google Scholar
Zhao, Y., Meng, X., Ren, X., Lian, C., Sun, J., Sha, X., ... & Li, W. J. (2021). Quantitative evaluation of gymnastics based on multiple MEMS sensors. IEEE Sensors Journal, 21(21), 24531-24539.ZhaoY.MengX.RenX.LianC.SunJ.ShaX.LiW. J. (2021). Quantitative evaluation of gymnastics based on multiple MEMS sensors. IEEE Sensors Journal, 21(21), 24531-24539.Search in Google Scholar
Wu, F., Wang, Q., Bian, J., Ding, N., Lu, F., Cheng, J., ... & Xiong, H. (2022). A survey on video action recognition in sports: Datasets, methods and applications. IEEE Transactions on Multimedia, 25, 7943-7966.WuF.WangQ.BianJ.DingN.LuF.ChengJ.XiongH. (2022). A survey on video action recognition in sports: Datasets, methods and applications. IEEE Transactions on Multimedia, 25, 7943-7966.Search in Google Scholar
Chen, Y. (2024). 3D Convolutional Neural Networks based Movement Evaluation System for Gymnasts in Computer Vision Applications. Journal of Electrical Systems, 20(3s), 880-898.ChenY. (2024). 3D Convolutional Neural Networks based Movement Evaluation System for Gymnasts in Computer Vision Applications. Journal of Electrical Systems, 20(3s), 880-898.Search in Google Scholar
Domingo, J. D., Gomez-Garcia-Bermejo, J., & Zalama, E. (2021). Visual recognition of gymnastic exercise sequences. Application to supervision and robot learning by demonstration. Robotics and Autonomous Systems, 143, 103830.DomingoJ. D.Gomez-Garcia-BermejoJ.ZalamaE. (2021). Visual recognition of gymnastic exercise sequences. Application to supervision and robot learning by demonstration. Robotics and Autonomous Systems, 143, 103830.Search in Google Scholar
Liu, Q. (2022). Aerobics posture recognition based on neural network and sensors. Neural Computing and Applications, 34(5), 3337-3348.LiuQ. (2022). Aerobics posture recognition based on neural network and sensors. Neural Computing and Applications, 34(5), 3337-3348.Search in Google Scholar
Zhao, Y., Dong, F., Sun, T., Ju, Z., Yang, L., Shan, P., ... & Lian, C. (2024). Image expression of time series data of wearable IMU sensor and fusion classification of gymnastics action. Expert Systems with Applications, 238, 121978.ZhaoY.DongF.SunT.JuZ.YangL.ShanP.LianC. (2024). Image expression of time series data of wearable IMU sensor and fusion classification of gymnastics action. Expert Systems with Applications, 238, 121978.Search in Google Scholar
Alsaif, K. I., & Abdullah, A. S. (2024, January). Deep Learning Technique for Gymnastics Movements Evaluation Based on Pose Estimation. In International Conference on Forthcoming Networks and Sustainability in the AIoT Era (pp. 236-245). Cham: Springer Nature Switzerland.AlsaifK. I.AbdullahA. S. (2024, January). Deep Learning Technique for Gymnastics Movements Evaluation Based on Pose Estimation. In International Conference on Forthcoming Networks and Sustainability in the AIoT Era (pp. 236-245). Cham: Springer Nature Switzerland.Search in Google Scholar
Liu, Y., Dong, H., & Wang, L. (2021). Trampoline motion decomposition method based on deep learning image recognition. Scientific Programming, 2021(1), 1215065.LiuY.DongH.WangL. (2021). Trampoline motion decomposition method based on deep learning image recognition. Scientific Programming, 2021(1), 1215065.Search in Google Scholar
Yihan, M. (2024). Design and optimization of an aerobics movement recognition system based on high-dimensional biotechnological data using neural networks. Journal of Visual Communication and Image Representation, 103, 104227.YihanM. (2024). Design and optimization of an aerobics movement recognition system based on high-dimensional biotechnological data using neural networks. Journal of Visual Communication and Image Representation, 103, 104227.Search in Google Scholar
Ren, Y., & Sun, K. (2024). Application Effect of Human-Computer Interactive Gymnastic Sports Action Recognition System Based on PTP-CNN Algorithm. International Journal of Advanced Computer Science & Applications, 15(1).RenY.SunK. (2024). Application Effect of Human-Computer Interactive Gymnastic Sports Action Recognition System Based on PTP-CNN Algorithm. International Journal of Advanced Computer Science & Applications, 15(1.Search in Google Scholar
Zhang, X., Shan, G., Wang, Y., Wan, B., & Li, H. (2019). Wearables, biomechanical feedback, and human motor-skills’ learning & optimization. Applied Sciences, 9(2), 226.ZhangX.ShanG.WangY.WanB.LiH. (2019). Wearables, biomechanical feedback, and human motor-skills’ learning & optimization. Applied Sciences, 9(2), 226.Search in Google Scholar
Wang, L., Xu, Y., Cheng, J., Xia, H., Yin, J., & Wu, J. (2018). Human action recognition by learning spatio-temporal features with deep neural networks. IEEE access, 6, 17913-17922.WangL.XuY.ChengJ.XiaH.YinJ.WuJ. (2018). Human action recognition by learning spatio-temporal features with deep neural networks. IEEE access, 6, 17913-17922.Search in Google Scholar
Zhang Siqi,Jin Jie,Wang Chaofang,Dong Wenlong & Fan Bin. (2022). Quality Evaluation Algorithm for Chest Compressions Based on OpenPose Model. Applied Sciences(10),4847-4847.SiqiZhangJieJinChaofangWangWenlongDongBinFan (2022). Quality Evaluation Algorithm for Chest Compressions Based on OpenPose Model. Applied Sciences(10),4847-4847.Search in Google Scholar
Huimin Han,Bouba oumarou Aboubakar,Mughair Bhatti,Bandeh Ali Talpur,Yasser A. Ali,Muna Al Razgan & Yazeed Yasid Ghadi. (2024). Optimizing image captioning: The effectiveness of vision transformers and VGG networks for remote sensing. Big Data Research100477-100477.HanHuiminAboubakarBouba oumarouBhattiMughairTalpurBandeh AliAliYasser A.RazganMuna AlGhadiYazeed Yasid (2024). Optimizing image captioning: The effectiveness of vision transformers and VGG networks for remote sensing. Big Data Research100477-100477.Search in Google Scholar
Huang Jin,Mei Liye,Long Mengping,Liu Yiqiang,Sun Wei,Li Xiaoxiao... & Lei Cheng. (2022). BM-Net: CNN-Based MobileNet-V3 and Bilinear Structure for Breast Cancer Detection in Whole Slide Images. Bioengineering(6),261-261.JinHuangLiyeMeiMengpingLongYiqiangLiuWeiSunXiaoxiaoLiChengLei (2022). BM-Net: CNN-Based MobileNet-V3 and Bilinear Structure for Breast Cancer Detection in Whole Slide Images. Bioengineering(6),261-261.Search in Google Scholar
