IKOL: Inverse Kinematics Optimization Layer for 3D Human Pose and Shape Estimation via Gauss-Newton Differentiation

Authors

  • Juze Zhang ShanghaiTech University Shanghai Advanced Research Institute, Chinese Academy of Sciences University of Chinese Academy of Sciences Shanghai Engineering Research Center of Intelligent Vision and Imaging
  • Ye Shi ShanghaiTech University Shanghai Engineering Research Center of Intelligent Vision and Imaging
  • Yuexin Ma ShanghaiTech University Shanghai Engineering Research Center of Intelligent Vision and Imaging
  • Lan Xu ShanghaiTech University Shanghai Engineering Research Center of Intelligent Vision and Imaging
  • Jingyi Yu ShanghaiTech University Shanghai Engineering Research Center of Intelligent Vision and Imaging
  • Jingya Wang ShanghaiTech University Shanghai Engineering Research Center of Intelligent Vision and Imaging

DOI:

https://doi.org/10.1609/aaai.v37i3.25454

Keywords:

CV: 3D Computer Vision, CV: Biometrics, Face, Gesture & Pose

Abstract

This paper presents an inverse kinematic optimization layer (IKOL) for 3D human pose and shape estimation that leverages the strength of both optimization- and regression-based methods within an end-to-end framework. IKOL involves a nonconvex optimization that establishes an implicit mapping from an image’s 3D keypoints and body shapes to the relative body-part rotations. The 3D keypoints and the body shapes are the inputs and the relative body-part rotations are the solutions. However, this procedure is implicit and hard to make differentiable. So, to overcome this issue, we designed a Gauss-Newton differentiation (GN-Diff) procedure to differentiate IKOL. GN-Diff iteratively linearizes the nonconvex objective function to obtain Gauss-Newton directions with closed form solutions. Then, an automatic differentiation procedure is directly applied to generate a Jacobian matrix for end-to-end training. Notably, the GN-Diff procedure works fast because it does not rely on a time-consuming implicit differentiation procedure. The twist rotation and shape parameters are learned from the neural networks and, as a result, IKOL has a much lower computational overhead than most existing optimization-based methods. Additionally, compared to existing regression-based methods, IKOL provides a more accurate mesh-image correspondence. This is because it iteratively reduces the distance between the keypoints and also enhances the reliability of the pose structures. Extensive experiments demonstrate the superiority of our proposed framework over a wide range of 3D human pose and shape estimation methods. Code is available at https://github.com/Juzezhang/IKOL

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Published

2023-06-26

How to Cite

Zhang, J., Shi, Y., Ma, Y., Xu, L., Yu, J., & Wang, J. (2023). IKOL: Inverse Kinematics Optimization Layer for 3D Human Pose and Shape Estimation via Gauss-Newton Differentiation. Proceedings of the AAAI Conference on Artificial Intelligence, 37(3), 3454-3462. https://doi.org/10.1609/aaai.v37i3.25454

Issue

Section

AAAI Technical Track on Computer Vision III