An End-To-End Framework For Pose Estimation Of Occluded Pedestrians

Pose estimation in the wild is a challenging problem, particularly in situations of(i) occlusions of varying degrees, and (ii) crowded outdoor scenes. Most of the existing studies of pose estimation did not report the performance in similar situations. Moreover, pose annotations for occluded parts o...

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Bibliographic Details
Main Authors: Das, Sudip, Kishore, Perla Sai Raj, Bhattacharya, Ujjwal
Format: Conference Proceeding
Language:English
Subjects:
Adversarial Learning
Benchmark testing
Detectors
Feature extraction
Image segmentation
Multi-task Learning
Pose estimation
Training
Unsupervised Domain Adaptation
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Summary:Pose estimation in the wild is a challenging problem, particularly in situations of(i) occlusions of varying degrees, and (ii) crowded outdoor scenes. Most of the existing studies of pose estimation did not report the performance in similar situations. Moreover, pose annotations for occluded parts of the human figures have not been provided in any of the relevant standard datasets, which in turn creates further difficulties to the required studies for pose estimation of the entire Figure for occluded humans. Well known pedestrian detection datasets such as CityPersons contains samples of outdoor scenes but it does not include pose annotations. Here we propose a novel multi-task framework for end-to-end training towards the entire pose estimation of pedestrians including in situations of any kind of occlusion. To tackle this problem, we make use of a pose estimation dataset, MS-COCO, and employ unsupervised adversarial instance-level domain adaptation for estimating the entire pose of occluded pedestrians. The experimental studies show that the proposed framework outperforms the SOTA results for pose estimation, instance segmentation and pedestrian detection in cases of heavy occlusions (HO) and reasonable + heavy occlusions (R+HO) on the two benchmark datasets.
ISSN:2381-8549
DOI:10.1109/ICIP40778.2020.9191147