Detection-Identification Balancing Margin Loss for One-Stage Multi-Object Tracking

2022 IEEE International Conference on Image Processing (ICIP) Pub Date : 2022-10-16 DOI:10.1109/ICIP46576.2022.9898030

Heansung Lee, Suhwan Cho, Sungjun Jang, Jungho Lee, Sungmin Woo, Sangyoun Lee

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Abstract

In recent years, one-stage multi-object tracking (MOT) methods, which jointly learn detection and identification in a single network, have attracted extensive attention, due to their efficiency. However, the negative transfer effects caused by the two conflicting objectives of detection and identification have rarely been explored. In this paper, we propose a Detection-Identification Balancing Margin (DIM) loss for minimizing the adverse effects caused by these two different objectives. The proposed DIM loss consists of Detection Margin (DM) loss and Identification Margin (IM) loss. DM loss forces features that are farther from the center of the foreground features than the defined margin due to identification learning to be converged to ensure accurate detection. IM loss enables the various feature representations that are essential for identification by intentionally spreading features that become overly clustered due to detection learning. The proposed DIM loss demonstrates competitive and balanced performance for MOT by providing a positive transfer for features that had a strong negative impact on detection and identification, respectively. (HOTA 61.5, MOTA 75.3, IDF1 75.6 on MOT16, and real-time rates of 25.9 fps were achieved)

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单阶段多目标跟踪的检测-识别平衡裕度损失

近年来，在单个网络中共同学习检测和识别的单阶段多目标跟踪(MOT)方法因其高效性而受到广泛关注。然而，由于检测和识别这两个相互冲突的目标所造成的负迁移效应却很少被探讨。在本文中，我们提出了一种检测-识别平衡裕度(DIM)损失，以最大限度地减少这两个不同目标所造成的不利影响。提出的DIM损失包括检测裕量(DM)损失和识别裕量(IM)损失。DM loss迫使由于识别学习而离前景特征中心较远的特征收敛，以确保准确检测。IM损失通过有意地传播由于检测学习而变得过度聚类的特征，实现了识别所必需的各种特征表示。所提出的DIM损失通过为分别对检测和识别产生强烈负面影响的特征提供正转移，展示了MOT的竞争性和平衡性能。(HOTA 61.5, MOTA 75.3, IDF1 75.6在MOTA 16上，实时速率达到25.9 fps)

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2022 IEEE International Conference on Image Processing (ICIP)

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