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Main Authors: Tan, Yuedong, Wu, Zongwei, Fu, Yuqian, Zhou, Zhuyun, Sun, Guolei, Zamfi, Eduard, Ma, Chao, Paudel, Danda Pani, Van Gool, Luc, Timofte, Radu
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.17773
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author Tan, Yuedong
Wu, Zongwei
Fu, Yuqian
Zhou, Zhuyun
Sun, Guolei
Zamfi, Eduard
Ma, Chao
Paudel, Danda Pani
Van Gool, Luc
Timofte, Radu
author_facet Tan, Yuedong
Wu, Zongwei
Fu, Yuqian
Zhou, Zhuyun
Sun, Guolei
Zamfi, Eduard
Ma, Chao
Paudel, Danda Pani
Van Gool, Luc
Timofte, Radu
contents Multimodal sensing has proven valuable for visual tracking, as different sensor types offer unique strengths in handling one specific challenging scene where object appearance varies. While a generalist model capable of leveraging all modalities would be ideal, development is hindered by data sparsity, typically in practice, only one modality is available at a time. Therefore, it is crucial to ensure and achieve that knowledge gained from multimodal sensing -- such as identifying relevant features and regions -- is effectively shared, even when certain modalities are unavailable at inference. We venture with a simple assumption: similar samples across different modalities have more knowledge to share than otherwise. To implement this, we employ a ``weak" classifier tasked with distinguishing between modalities. More specifically, if the classifier ``fails" to accurately identify the modality of the given sample, this signals an opportunity for cross-modal knowledge sharing. Intuitively, knowledge transfer is facilitated whenever a sample from one modality is sufficiently close and aligned with another. Technically, we achieve this by routing samples from one modality to the expert of the others, within a mixture-of-experts framework designed for multimodal video object tracking. During the inference, the expert of the respective modality is chosen, which we show to benefit from the multimodal knowledge available during training, thanks to the proposed method. Through the exhaustive experiments that use only paired RGB-E, RGB-D, and RGB-T during training, we showcase the benefit of the proposed method for RGB-X tracker during inference, with an average +3\% precision improvement over the current SOTA. Our source code is publicly available at https://github.com/supertyd/XTrack/tree/main.
format Preprint
id arxiv_https___arxiv_org_abs_2405_17773
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle XTrack: Multimodal Training Boosts RGB-X Video Object Trackers
Tan, Yuedong
Wu, Zongwei
Fu, Yuqian
Zhou, Zhuyun
Sun, Guolei
Zamfi, Eduard
Ma, Chao
Paudel, Danda Pani
Van Gool, Luc
Timofte, Radu
Computer Vision and Pattern Recognition
Multimodal sensing has proven valuable for visual tracking, as different sensor types offer unique strengths in handling one specific challenging scene where object appearance varies. While a generalist model capable of leveraging all modalities would be ideal, development is hindered by data sparsity, typically in practice, only one modality is available at a time. Therefore, it is crucial to ensure and achieve that knowledge gained from multimodal sensing -- such as identifying relevant features and regions -- is effectively shared, even when certain modalities are unavailable at inference. We venture with a simple assumption: similar samples across different modalities have more knowledge to share than otherwise. To implement this, we employ a ``weak" classifier tasked with distinguishing between modalities. More specifically, if the classifier ``fails" to accurately identify the modality of the given sample, this signals an opportunity for cross-modal knowledge sharing. Intuitively, knowledge transfer is facilitated whenever a sample from one modality is sufficiently close and aligned with another. Technically, we achieve this by routing samples from one modality to the expert of the others, within a mixture-of-experts framework designed for multimodal video object tracking. During the inference, the expert of the respective modality is chosen, which we show to benefit from the multimodal knowledge available during training, thanks to the proposed method. Through the exhaustive experiments that use only paired RGB-E, RGB-D, and RGB-T during training, we showcase the benefit of the proposed method for RGB-X tracker during inference, with an average +3\% precision improvement over the current SOTA. Our source code is publicly available at https://github.com/supertyd/XTrack/tree/main.
title XTrack: Multimodal Training Boosts RGB-X Video Object Trackers
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2405.17773