Learning cricket strokes from spatial and motion visual word sequences

There are a number of challenges involved in recognizing actions from Cricket telecast videos, mainly, due to the rapid camera motion, camera switching, and variations in background/foreground, scale, position and viewpoint. Our work deals with the task of trimmed Cricket stroke classification. We u...

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Veröffentlicht in:	Multimedia tools and applications 2023, Vol.82 (1), p.1237-1259
Hauptverfasser:	Gupta, Arpan, Muthiah, Sakthi Balan
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Sprache:	eng
Schlagworte:	Cameras Categories Computer Communication Networks Computer Science Data Structures and Information Theory Datasets Feature extraction Histograms Multimedia Multimedia Information Systems Optical flow (image analysis) Sequences Special Purpose and Application-Based Systems Tennis Three dimensional models Training Two dimensional flow
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description	There are a number of challenges involved in recognizing actions from Cricket telecast videos, mainly, due to the rapid camera motion, camera switching, and variations in background/foreground, scale, position and viewpoint. Our work deals with the task of trimmed Cricket stroke classification. We used the Cricket Highlights dataset of Gupta and Balan ( 2020 ) and manually labeled the 562 trimmed strokes into 5 categories based on the direction of stroke play. These categories are independent of the batsman pose orientations (or handedness) and are useful in determining the outcome of a Cricket stroke. Models trained on our proposed categories can have applications in building player profiles, automated extraction of direction dependent strokes and highlights generation. The Gated Recurrent Unit (GRU) based models were trained on sequences of spatial and motion visual words, obtained by hard (HA) and soft assignment (SA). Extensive set of experiments were carried out on the frame-level dense optical flow grid(OF Grid) features, histogram of oriented optical flow(HOOF), pretrained 2D ResNet and pretrained 3D ResNet extracted features. The training on visual word sequences gives better results as compared to the training on raw feature sequences. Moreover, the soft assignment based word sequences perform better than the hard assignment based sequences of OF Grid features. We present strong baseline results for this new dataset, with the best accuracy of 8 1 . 1 3 % on the test set, using soft assignment on optical flow based grid features. We compare our results with Transformer and 2-stream GRU models trained on HA/SA visual words, and 3D convolutional models (C3D/I3D) trained on raw frame sequences.
doi_str_mv	10.1007/s11042-022-13307-y
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Our work deals with the task of trimmed Cricket stroke classification. We used the Cricket Highlights dataset of Gupta and Balan ( 2020 ) and manually labeled the 562 trimmed strokes into 5 categories based on the direction of stroke play. These categories are independent of the batsman pose orientations (or handedness) and are useful in determining the outcome of a Cricket stroke. Models trained on our proposed categories can have applications in building player profiles, automated extraction of direction dependent strokes and highlights generation. The Gated Recurrent Unit (GRU) based models were trained on sequences of spatial and motion visual words, obtained by hard (HA) and soft assignment (SA). Extensive set of experiments were carried out on the frame-level dense optical flow grid(OF Grid) features, histogram of oriented optical flow(HOOF), pretrained 2D ResNet and pretrained 3D ResNet extracted features. 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Our work deals with the task of trimmed Cricket stroke classification. We used the Cricket Highlights dataset of Gupta and Balan ( 2020 ) and manually labeled the 562 trimmed strokes into 5 categories based on the direction of stroke play. These categories are independent of the batsman pose orientations (or handedness) and are useful in determining the outcome of a Cricket stroke. Models trained on our proposed categories can have applications in building player profiles, automated extraction of direction dependent strokes and highlights generation. The Gated Recurrent Unit (GRU) based models were trained on sequences of spatial and motion visual words, obtained by hard (HA) and soft assignment (SA). Extensive set of experiments were carried out on the frame-level dense optical flow grid(OF Grid) features, histogram of oriented optical flow(HOOF), pretrained 2D ResNet and pretrained 3D ResNet extracted features. 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subjects	Cameras Categories Computer Communication Networks Computer Science Data Structures and Information Theory Datasets Feature extraction Histograms Multimedia Multimedia Information Systems Optical flow (image analysis) Sequences Special Purpose and Application-Based Systems Tennis Three dimensional models Training Two dimensional flow
title	Learning cricket strokes from spatial and motion visual word sequences
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