DCG ReID: Disentangling Collaboration and Guidance Fusion Representations for Multi-modal Vehicle Re-Identification
Aihua Zheng, Ya Gao, Shihao Li, Chenglong Li, Jin Tang
TL;DR
This paper introduces DCG-ReID, a novel multi-modal vehicle Re-Identification framework that disentangles and optimizes fusion strategies for balanced and unbalanced modality quality distributions, improving retrieval accuracy.
Contribution
The paper proposes a dynamic confidence-based disentangling mechanism and two scenario-specific fusion modules, advancing multi-modal fusion by addressing modality quality disparities.
Findings
Effective in handling balanced and unbalanced modality quality distributions
Significant performance improvements on three benchmark datasets
Validated through extensive experiments
Abstract
Multi-modal vehicle Re-Identification (ReID) aims to leverage complementary information from RGB, Near Infrared (NIR), and Thermal Infrared (TIR) modalities to retrieve the same vehicle. The challenges of multi-modal vehicle ReID arise from the uncertainty of modality quality distribution induced by inherent discrepancies across modalities, resulting in distinct conflicting fusion requirements for data with balanced and unbalanced quality distributions. Existing methods handle all multi-modal data within a single fusion model, overlooking the different needs of the two data types and making it difficult to decouple the conflict between intra-class consistency and inter-modal heterogeneity. To this end, we propose Disentangle Collaboration and Guidance Fusion Representations for Multi-modal Vehicle ReID (DCG-ReID). Specifically, to disentangle heterogeneous quality-distributed modal data…
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Taxonomy
TopicsVideo Surveillance and Tracking Methods · Adversarial Robustness in Machine Learning · Autonomous Vehicle Technology and Safety