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Main Authors: Lin, Ronghao, He, Qiaolin, Mai, Sijie, Zeng, Ying, Xiong, Aolin, Huang, Li, Tan, Yap-Peng, Hu, Haifeng
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.04920
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author Lin, Ronghao
He, Qiaolin
Mai, Sijie
Zeng, Ying
Xiong, Aolin
Huang, Li
Tan, Yap-Peng
Hu, Haifeng
author_facet Lin, Ronghao
He, Qiaolin
Mai, Sijie
Zeng, Ying
Xiong, Aolin
Huang, Li
Tan, Yap-Peng
Hu, Haifeng
contents Multimodal machine learning, mimicking the human brain's ability to integrate various modalities has seen rapid growth. Most previous multimodal models are trained on perfectly paired multimodal input to reach optimal performance. In real-world deployments, however, the presence of modality is highly variable and unpredictable, causing the pre-trained models in suffering significant performance drops and fail to remain robust with dynamic missing modalities circumstances. In this paper, we present a novel Cyclic INformative Learning framework (CyIN) to bridge the gap between complete and incomplete multimodal learning. Specifically, we firstly build an informative latent space by adopting token- and label-level Information Bottleneck (IB) cyclically among various modalities. Capturing task-related features with variational approximation, the informative bottleneck latents are purified for more efficient cross-modal interaction and multimodal fusion. Moreover, to supplement the missing information caused by incomplete multimodal input, we propose cross-modal cyclic translation by reconstruct the missing modalities with the remained ones through forward and reverse propagation process. With the help of the extracted and reconstructed informative latents, CyIN succeeds in jointly optimizing complete and incomplete multimodal learning in one unified model. Extensive experiments on 4 multimodal datasets demonstrate the superior performance of our method in both complete and diverse incomplete scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2602_04920
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CyIN: Cyclic Informative Latent Space for Bridging Complete and Incomplete Multimodal Learning
Lin, Ronghao
He, Qiaolin
Mai, Sijie
Zeng, Ying
Xiong, Aolin
Huang, Li
Tan, Yap-Peng
Hu, Haifeng
Machine Learning
Sound
Multimodal machine learning, mimicking the human brain's ability to integrate various modalities has seen rapid growth. Most previous multimodal models are trained on perfectly paired multimodal input to reach optimal performance. In real-world deployments, however, the presence of modality is highly variable and unpredictable, causing the pre-trained models in suffering significant performance drops and fail to remain robust with dynamic missing modalities circumstances. In this paper, we present a novel Cyclic INformative Learning framework (CyIN) to bridge the gap between complete and incomplete multimodal learning. Specifically, we firstly build an informative latent space by adopting token- and label-level Information Bottleneck (IB) cyclically among various modalities. Capturing task-related features with variational approximation, the informative bottleneck latents are purified for more efficient cross-modal interaction and multimodal fusion. Moreover, to supplement the missing information caused by incomplete multimodal input, we propose cross-modal cyclic translation by reconstruct the missing modalities with the remained ones through forward and reverse propagation process. With the help of the extracted and reconstructed informative latents, CyIN succeeds in jointly optimizing complete and incomplete multimodal learning in one unified model. Extensive experiments on 4 multimodal datasets demonstrate the superior performance of our method in both complete and diverse incomplete scenarios.
title CyIN: Cyclic Informative Latent Space for Bridging Complete and Incomplete Multimodal Learning
topic Machine Learning
Sound
url https://arxiv.org/abs/2602.04920