鲁棒密集人体估计的学习可见性

Chunfeng Yao, Jimei Yang, Duygu Ceylan, Yi Zhou, Yang Zhou, Ming-Hsuan Yang
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引用次数: 7

摘要

从2D图像中估计3D人体姿势和形状是一项至关重要但具有挑战性的任务。虽然先前的基于模型表示的方法可以在全身图像上表现得相当好,但当身体的某些部分被遮挡或在帧外时,它们往往会失败。此外,由于可变形模型的表现能力有限(例如,仅代表裸体),这些结果通常不能忠实地捕捉人体轮廓。另一种方法是估计图像空间中预定义模板体的密集顶点。这种表示在定位图像中的顶点时是有效的,但不能处理帧外的身体部分。在这项工作中,我们学习了对部分观测稳健的密集人体估计。我们分别在x、y和z轴上对人体关节和顶点的可见性进行了显式建模。x轴和y轴的可见性有助于区分帧外情况,深度轴的可见性对应于遮挡(自身遮挡或其他物体遮挡)。我们从密集的UV对应中获得可见性标签的伪真地,并训练神经网络与3D坐标一起预测可见性。我们表明,可见性可以作为1)一个额外的信号来解决自遮挡顶点的深度排序歧义,以及2)在将人体模型拟合到预测时的正则化项。在多个三维人体数据集上进行的大量实验表明,能见度建模显著提高了人体估计的准确性,特别是在部分人体情况下。我们的项目代码页面在:https://github.com/chhankyao/visdb。
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Learning Visibility for Robust Dense Human Body Estimation
Estimating 3D human pose and shape from 2D images is a crucial yet challenging task. While prior methods with model-based representations can perform reasonably well on whole-body images, they often fail when parts of the body are occluded or outside the frame. Moreover, these results usually do not faithfully capture the human silhouettes due to their limited representation power of deformable models (e.g., representing only the naked body). An alternative approach is to estimate dense vertices of a predefined template body in the image space. Such representations are effective in localizing vertices within an image but cannot handle out-of-frame body parts. In this work, we learn dense human body estimation that is robust to partial observations. We explicitly model the visibility of human joints and vertices in the x, y, and z axes separately. The visibility in x and y axes help distinguishing out-of-frame cases, and the visibility in depth axis corresponds to occlusions (either self-occlusions or occlusions by other objects). We obtain pseudo ground-truths of visibility labels from dense UV correspondences and train a neural network to predict visibility along with 3D coordinates. We show that visibility can serve as 1) an additional signal to resolve depth ordering ambiguities of self-occluded vertices and 2) a regularization term when fitting a human body model to the predictions. Extensive experiments on multiple 3D human datasets demonstrate that visibility modeling significantly improves the accuracy of human body estimation, especially for partial-body cases. Our project page with code is at: https://github.com/chhankyao/visdb.
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