M2AST:MLP-mixer-based adaptive spatial-temporal graph learning for human motion prediction

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-07-12 DOI:10.1007/s00530-024-01351-7
Junyi Tang, Simin An, Yuanwei Liu, Yong Su, Jin Chen
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Abstract

Human motion prediction is a challenging task in human-centric computer vision, involving forecasting future poses based on historical sequences. Despite recent progress in modeling spatial-temporal relationships of motion sequences using complex structured graphs, few approaches have provided an adaptive and lightweight representation for varying graph structures of human motion. Taking inspiration from the advantages of MLP-Mixer, a lightweight architecture designed for learning complex interactions in multi-dimensional data, we explore its potential as a backbone for motion prediction. To this end, we propose a novel MLP-Mixer-based adaptive spatial-temporal pattern learning framework (M\(^2\)AST). Our framework includes an adaptive spatial mixer to model the spatial relationships between joints, an adaptive temporal mixer to learn temporal smoothness, and a local dynamic mixer to capture fine-grained cross-dependencies between joints of adjacent poses. The final method achieves a compact representation of human motion dynamics by adaptively considering spatial-temporal dependencies from coarse to fine. Unlike the trivial spatial-temporal MLP-Mixer, our proposed approach can more effectively capture both local and global spatial-temporal relationships simultaneously. We extensively evaluated our proposed framework on three commonly used benchmarks (Human3.6M, AMASS, 3DPW MoCap), demonstrating comparable or better performance than existing state-of-the-art methods in both short and long-term predictions, despite having significantly fewer parameters. Overall, our proposed framework provides a novel and efficient solution for human motion prediction with adaptive graph learning.

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M2AST:基于 MLP 混合器的自适应时空图学习,用于人体运动预测
人体运动预测是以人为中心的计算机视觉中一项具有挑战性的任务,它涉及根据历史序列预测未来姿势。尽管最近在使用复杂结构图对运动序列的时空关系建模方面取得了进展,但很少有方法能为人类运动的不同图结构提供自适应的轻量级表示。MLP-Mixer 是一种专为学习多维数据中的复杂交互而设计的轻量级架构,我们从 MLP-Mixer 的优势中汲取灵感,探索其作为运动预测骨干的潜力。为此,我们提出了一种新颖的基于 MLP-Mixer 的自适应时空模式学习框架 (M(^2\)AST)。我们的框架包括一个自适应空间混合器,用于模拟关节之间的空间关系;一个自适应时间混合器,用于学习时间平滑性;以及一个局部动态混合器,用于捕捉相邻姿势的关节之间的细粒度交叉依赖关系。最终的方法通过自适应地考虑从粗到细的空间-时间依赖关系,实现了对人体运动动态的紧凑表示。与微不足道的时空 MLP-Mixer 不同,我们提出的方法能更有效地同时捕捉局部和全局时空关系。我们在三个常用基准(Human3.6M、AMASS、3DPW MoCap)上对我们提出的框架进行了广泛评估,结果表明,尽管参数少得多,但在短期和长期预测方面,我们提出的框架的性能与现有的先进方法相当,甚至更好。总之,我们提出的框架为利用自适应图学习进行人体运动预测提供了一种新颖、高效的解决方案。
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7.20
自引率
4.30%
发文量
567
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