Learning disentangled representation implicitly via transformer for occluded person re-identification

Learning disentangled representation implicitly via transformer for occluded person re-identification

Person re-IDentification (re-ID) under various occlusions has been a long-standing challenge as person images with different types of occlusions often suffer from misalignment in image matching and ranking. Most existing methods tackle this challenge by aligning spatial features of body parts accord...

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Bibliographic Details
Main Authors: Jia, Mengxi, Cheng, Xinhua, Lu, Shijian, Zhang, Jian
Other Authors: School of Computer Science and Engineering
Format: Article
Language:English
Published: 2022
Subjects:
Engineering::Computer science and engineering
Person Re-Identification
Representation Learning
Online Access:https://hdl.handle.net/10356/162960
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Institution: Nanyang Technological University
Language: English
Description
Summary:Person re-IDentification (re-ID) under various occlusions has been a long-standing challenge as person images with different types of occlusions often suffer from misalignment in image matching and ranking. Most existing methods tackle this challenge by aligning spatial features of body parts according to external semantic cues or feature similarities but this alignment approach is complicated and sensitive to noises. We design DRL-Net, a disentangled representation learning network that handles occluded re-ID without requiring strict person image alignment or any additional supervision. Leveraging transformer architectures, DRL-Net achieves alignment-free re-ID via global reasoning of local features of occluded person images. It measures image similarity by automatically disentangling the representation of undefined semantic components, e.g., human body parts or obstacles, under the guidance of semantic preference object queries in the transformer. In addition, we design a decorrelation constraint in the transformer decoder and impose it over object queries for better focus on different semantic components. To better eliminate interference from occlusions, we design a contrast feature learning technique (CFL) for better separation of occlusion features and discriminative ID features. Extensive experiments over occluded and holistic reID benchmarks show that the DRL-Net achieves superior re-ID performance consistently and outperforms the state-of-the-art by large margins for occluded re-ID dataset.

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