Zhenyue Qin scite author profile

Skeleton sequences are lightweight and compact and thus are ideal candidates for action recognition on edge devices. Recent skeleton-based action recognition methods extract features from 3-D joint coordinates as spatial-temporal cues, using these representations in a graph neural network for feature fusion to boost recognition performance. The use of first-and second-order features, that is, joint and bone representations, has led to high accuracy. Nonetheless, many models are still confused by actions that have similar motion trajectories. To address these issues, we propose fusing higher-order features in the form of angular encoding (AGE) into modern architectures to robustly capture the relationships between joints and body parts. This simple fusion with popular spatial-temporal graph neural networks achieves new state-of-the-art accuracy in two large benchmarks, including NTU60 and NTU120, while employing fewer parameters and reduced run time. Our source code is publicly available at: https://github.com/ZhenyueQin/Angular-Skeleton-Encoding.

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Are Deep Neural Architectures Losing Information? Invertibility is Indispensable

Liu

Qin

Anwar

et al. 2020

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Fusing Higher-Order Features in Graph Neural Networks for Skeleton-Based Action Recognition

Qin¹,

Liu²,

Pan³

et al. 2021

Preprint

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Skeleton sequences are light-weight and compact, and thus ideal candidates for action recognition on edge devices. Recent skeleton-based action recognition methods extract features from 3D joint coordinates as spatial-temporal cues, using these representations in a graph neural network for feature fusion, to boost recognition performance. The use of first-and second-order features, i.e., joint and bone representations has led to high accuracy, but many models are still confused by actions that have similar motion trajectories. To address these issues, we propose fusing third-order features in the form of angles into modern architectures, to robustly capture the relationships between joints and body parts. This simple fusion with popular spatial-temporal graph neural networks achieves new state-of-the-art accuracy in two large benchmarks, including NTU60 and NTU120, while employing fewer parameters and reduced run time. Our sourcecode is publicly available at: https://github.com/ZhenyueQin/Angular-Skeleton-Encoding.

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Zhenyue Qin

Invertible Denoising Network: A Light Solution for Real Noise Removal

Rethinking Softmax with Cross-Entropy: Neural Network Classifier as Mutual Information Estimator

Fusing Higher-Order Features in Graph Neural Networks for Skeleton-Based Action Recognition

Are Deep Neural Architectures Losing Information? Invertibility is Indispensable

Fusing Higher-Order Features in Graph Neural Networks for Skeleton-Based Action Recognition

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