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Multi-level Motion Attention for Human Motion Prediction

Abstract

Human motion prediction aims to forecast future human poses given a historical motion. Whether based on recurrent or feed-forward neural networks, existing learning based methods fail to model the observation that human motion tends to repeat itself, even for complex sports actions and cooking activities. Here, we introduce an attention based feed-forward network that explicitly leverages this observation. In particular, instead of modeling frame-wise attention via pose similarity, we propose to extract motion attention to capture the similarity between the current motion context and the historical motion sub-sequences. In this context, we study the use of different types of attention, computed at joint, body part, and full pose levels. Aggregating the relevant past motions and processing the result with a graph convolutional network allows us to effectively exploit motion patterns from the long-term history to predict the future poses. Our experiments on Human3.6M, AMASS and 3DPW validate the benefits of our approach for both periodical and non-periodical actions. Thanks to our attention model, it yields state-of-the-art results on all three datasets. Our code is available at https://github.com/wei-mao-2019/HisRepItself.

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Fig. 1: Human motion prediction
Fig. 2: Overview of our motion attention pipeline.
Fig. 3: Predictor.
Fig. 4: Different fusion model.
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Notes

  1. 1.

    Described at https://github.com/nghorbani/amass

  2. 2.

    Available at https://amass.is.tue.mpg.de/dataset.

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Acknowledgements

This research was supported in part by the Australia Research Council DECRA Fellowship (DE180100628) and ARC Discovery Grant (DP200102274). The authors would like to thank NVIDIA for the donated GPU (Titan V).

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Correspondence to Wei Mao.

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Communicated by Javier Romero.

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Mao, W., Liu, M., Salzmann, M. et al. Multi-level Motion Attention for Human Motion Prediction. Int J Comput Vis 129, 2513–2535 (2021). https://doi.org/10.1007/s11263-021-01483-7

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Keywords

  • Human motion prediction
  • Motion attention
  • Deep learning