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Main Authors: Huang, Jing, Wen, Hao, Zhou, Tianyi, Lin, Haozhe, Lai, Yu-kun, Li, Kun
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.06232
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author Huang, Jing
Wen, Hao
Zhou, Tianyi
Lin, Haozhe
Lai, Yu-kun
Li, Kun
author_facet Huang, Jing
Wen, Hao
Zhou, Tianyi
Lin, Haozhe
Lai, Yu-kun
Li, Kun
contents This paper focuses on spatially consistent hundreds of human pose and shape reconstruction from a single large-scene image with various human scales under arbitrary camera FoVs (Fields of View). Due to the small and highly varying 2D human scales, depth ambiguity, and perspective distortion, no existing methods can achieve globally consistent reconstruction with correct reprojection. To address these challenges, we first propose a new concept, Human-scene Virtual Interaction Point (HVIP), to convert the complex 3D human localization into 2D-pixel localization. We then extend it to RCR (Robust Crowd Reconstruction), which achieves globally consistent reconstruction and stable generalization on different camera FoVs without test-time optimization. To perceive humans in varying pixel sizes, we propose an Iterative Ground-aware Cropping to automatically crop the image and then merge the results. To eliminate the influence of the camera and cropping process during the reconstruction, we introduce a canonical Upright 3D Space and the corresponding Upright 2D Space. To link the canonical space and the camera space, we propose the Upright Normalization, which transforms the local crop input into the Upright 2D Space, and transforms the output from the Upright 3D Space into the unified camera space. Besides, we contribute two benchmark datasets, LargeCrowd and SynCrowd, for evaluating crowd reconstruction in large scenes. Experimental results demonstrate the effectiveness of the proposed method. The source code and data will be publicly available for research purposes.
format Preprint
id arxiv_https___arxiv_org_abs_2411_06232
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle RCR: Robust Crowd Reconstruction with Upright Space from a Single Large-scene Image
Huang, Jing
Wen, Hao
Zhou, Tianyi
Lin, Haozhe
Lai, Yu-kun
Li, Kun
Computer Vision and Pattern Recognition
This paper focuses on spatially consistent hundreds of human pose and shape reconstruction from a single large-scene image with various human scales under arbitrary camera FoVs (Fields of View). Due to the small and highly varying 2D human scales, depth ambiguity, and perspective distortion, no existing methods can achieve globally consistent reconstruction with correct reprojection. To address these challenges, we first propose a new concept, Human-scene Virtual Interaction Point (HVIP), to convert the complex 3D human localization into 2D-pixel localization. We then extend it to RCR (Robust Crowd Reconstruction), which achieves globally consistent reconstruction and stable generalization on different camera FoVs without test-time optimization. To perceive humans in varying pixel sizes, we propose an Iterative Ground-aware Cropping to automatically crop the image and then merge the results. To eliminate the influence of the camera and cropping process during the reconstruction, we introduce a canonical Upright 3D Space and the corresponding Upright 2D Space. To link the canonical space and the camera space, we propose the Upright Normalization, which transforms the local crop input into the Upright 2D Space, and transforms the output from the Upright 3D Space into the unified camera space. Besides, we contribute two benchmark datasets, LargeCrowd and SynCrowd, for evaluating crowd reconstruction in large scenes. Experimental results demonstrate the effectiveness of the proposed method. The source code and data will be publicly available for research purposes.
title RCR: Robust Crowd Reconstruction with Upright Space from a Single Large-scene Image
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2411.06232