AI Article Synopsis
- Skeleton-based human interaction recognition is complex due to challenges in effectively utilizing various skeletal modalities and constraints in capturing two-person interactions.
- The new multi-modal enhancement transformer (ME-Former) network addresses these issues by incorporating a multi-modal enhancement module and a context progressive fusion block to improve feature extraction and interaction modeling.
- Experimental results on the NTU-RGB+D datasets show that ME-Former significantly outperforms existing GCN-based methods, proving its effectiveness in recognizing human interactions.
Article Abstract
Skeleton-based human interaction recognition is a challenging task in the field of vision and image processing. Graph Convolutional Networks (GCNs) achieved remarkable performance by modeling the human skeleton as a topology. However, existing GCN-based methods have two problems: (1) Existing frameworks cannot effectively take advantage of the complementary features of different skeletal modalities. There is no information transfer channel between various specific modalities. (2) Limited by the structure of the skeleton topology, it is hard to capture and learn the information about two-person interactions. To solve these problems, inspired by the human visual neural network, we propose a multi-modal enhancement transformer (ME-Former) network for skeleton-based human interaction recognition. ME-Former includes a multi-modal enhancement module (ME) and a context progressive fusion block (CPF). More specifically, each ME module consists of a multi-head cross-modal attention block (MH-CA) and a two-person hypergraph self-attention block (TH-SA), which are responsible for enhancing the skeleton features of a specific modality from other skeletal modalities and modeling spatial dependencies between joints using the specific modality, respectively. In addition, we propose a two-person skeleton topology and a two-person hypergraph representation. The TH-SA block can embed their structural information into the self-attention to better learn two-person interaction. The CPF block is capable of progressively transforming the features of different skeletal modalities from low-level features to higher-order global contexts, making the enhancement process more efficient. Extensive experiments on benchmark NTU-RGB+D 60 and NTU-RGB+D 120 datasets consistently verify the effectiveness of our proposed ME-Former by outperforming state-of-the-art methods.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10968049 | PMC |
| http://dx.doi.org/10.3390/biomimetics9030123 | DOI Listing |
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