Automatic Construction and Extraction of Sports Moment Feature Variables Using Artificial Intelligence

In this paper, we study the automatic construction and extraction of feature variables of sports moments and construct the extraction of the specific variables by artificial intelligence. In this paper, support vector machines, which have better performance in the case of small samples, are selected as classifiers, and multiclass classifiers are constructed in a one-to-one manner to achieve the classification and recognition of human sports postures. The classifier for a single decomposed action is constructed to transform the automatic description problem of free gymnastic movements into a multilabel classification problem. With the increase in the depth of the feature extraction network, the experimental effect is enhanced; however, the two-dimensional convolutional neural network loses temporal information when extracting features, so the three-dimensional convolutional network is used in this paper for spatial-temporal feature extraction of the video. The extracted features are binary classified several times to achieve the goal of multilabel classification. To form a comparison experiment, the results of the classification are randomly combined into a sentence and compared with the results of the automatic description method to verify the effectiveness of the method. The multiclass classifier constructed in this paper is used for human motion pose classification and recognition tests, and the experimental results show that the human motion pose recognition algorithm based on multifeature fusion can effectively improve the recognition accuracy and perform well in practical applications.

[1]  Hossein Babajanian Bisheh,et al.  Damage detection of a cable-stayed bridge using feature extraction and selection methods , 2019 .

[2]  Derek C Angus,et al.  Randomized Clinical Trials of Artificial Intelligence. , 2020, JAMA.

[3]  Nathaniel A. Bates,et al.  Linear Discriminant Analysis Successfully Predicts Knee Injury Outcome From Biomechanical Variables , 2020, The American journal of sports medicine.

[4]  Lieven De Marez,et al.  (What) Can Journalism Studies Learn from Supervised Machine Learning? , 2020, Journalism Studies.

[5]  Yang Lu,et al.  Artificial intelligence: a survey on evolution, models, applications and future trends , 2019, Journal of Management Analytics.

[6]  A. Jayanthiladevi,et al.  Optimal Nonparametric Bayesian Model-Based Multimodal BoVW Creation Using Multilayer pLSA , 2019, Circuits, Systems, and Signal Processing.

[7]  Fei Kong,et al.  Design of computer interactive system for sports training based on artificial intelligence and improved support vector , 2019, J. Intell. Fuzzy Syst..

[8]  Ting Liu,et al.  Research on emotional model of sports arena based on artificial intelligence emotion calculation , 2018, Cluster Computing.

[9]  Namita Mittal,et al.  Recent developments in human gait research: parameters, approaches, applications, machine learning techniques, datasets and challenges , 2016, Artificial Intelligence Review.

[10]  Takeshi Nishida,et al.  Deep recurrent neural network for mobile human activity recognition with high throughput , 2017, Artificial Life and Robotics.

[11]  H. J. Escalante,et al.  Barley yield and fertilization analysis from UAV imagery: a deep learning approach , 2019, International Journal of Remote Sensing.

[12]  Jaber Alwidian,et al.  Data Streams Curation for Better Machine Learning Functionality and Result to Serve IoT and other Applications: A Survey , 2019 .

[13]  Simon Fong,et al.  Histogram of oriented gradient based plantar pressure image feature extraction and classification employing fuzzy support vector machine , 2018 .

[14]  Berkman Sahiner,et al.  Evaluation of Combined Artificial Intelligence and Radiologist Assessment to Interpret Screening Mammograms , 2020, JAMA network open.

[15]  Liye Ma,et al.  Machine learning and AI in marketing – Connecting computing power to human insights , 2020, International Journal of Research in Marketing.

[16]  Igor Kononenko,et al.  Automatic attribute construction for basketball modelling , 2019, Knowledge and Information Systems.

[17]  Majid Ali Khan Quaid,et al.  Wearable sensors based human behavioral pattern recognition using statistical features and reweighted genetic algorithm , 2019, Multimedia Tools and Applications.

[18]  Takashi Kamachi,et al.  Machine Learning for Catalysis Informatics: Recent Applications and Prospects , 2020 .

[19]  Lisa Jeffrey,et al.  More human than human? Artificial intelligence in the archive , 2018, Archives and Manuscripts.

[20]  Samuel D. Gosling,et al.  Personality Research and Assessment in the Era of Machine Learning , 2020 .

[21]  H. Çelik,et al.  Predicting air permeability and porosity of nonwovens with image processing and artificial intelligence methods , 2020 .

[22]  M. Boucher,et al.  Using artificial neural networks to estimate snow water equivalent from snow depth , 2020, Canadian Water Resources Journal / Revue canadienne des ressources hydriques.