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Main Authors: Sun, Yuwei, Mi, Lu, Fujisawa, Ippei, Mei, Ruiqiao, Chen, Jimin, Zhu, Siyu, Kanai, Ryota
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.00266
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author Sun, Yuwei
Mi, Lu
Fujisawa, Ippei
Mei, Ruiqiao
Chen, Jimin
Zhu, Siyu
Kanai, Ryota
author_facet Sun, Yuwei
Mi, Lu
Fujisawa, Ippei
Mei, Ruiqiao
Chen, Jimin
Zhu, Siyu
Kanai, Ryota
contents Masking strategies commonly employed in natural language processing are still underexplored in vision tasks such as concept learning, where conventional methods typically rely on full images. However, using masked images diversifies perceptual inputs, potentially offering significant advantages in concept learning with large-scale Transformer models. To this end, we propose Multi-layer Concept Map (MCM), the first work to devise an efficient concept learning method based on masked images. In particular, we introduce an asymmetric concept learning architecture by establishing correlations between different encoder and decoder layers, updating concept tokens using backward gradients from reconstruction tasks. The learned concept tokens at various levels of granularity help either reconstruct the masked image patches by filling in gaps or guide the reconstruction results in a direction that reflects specific concepts. Moreover, we present both quantitative and qualitative results across a wide range of metrics, demonstrating that MCM significantly reduces computational costs by training on fewer than 75% of the total image patches while enhancing concept prediction performance. Additionally, editing specific concept tokens in the latent space enables targeted image generation from masked images, aligning both the visible contextual patches and the provided concepts. By further adjusting the testing time mask ratio, we could produce a range of reconstructions that blend the visible patches with the provided concepts, proportional to the chosen ratios.
format Preprint
id arxiv_https___arxiv_org_abs_2502_00266
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MCM: Multi-layer Concept Map for Efficient Concept Learning from Masked Images
Sun, Yuwei
Mi, Lu
Fujisawa, Ippei
Mei, Ruiqiao
Chen, Jimin
Zhu, Siyu
Kanai, Ryota
Computer Vision and Pattern Recognition
Machine Learning
Masking strategies commonly employed in natural language processing are still underexplored in vision tasks such as concept learning, where conventional methods typically rely on full images. However, using masked images diversifies perceptual inputs, potentially offering significant advantages in concept learning with large-scale Transformer models. To this end, we propose Multi-layer Concept Map (MCM), the first work to devise an efficient concept learning method based on masked images. In particular, we introduce an asymmetric concept learning architecture by establishing correlations between different encoder and decoder layers, updating concept tokens using backward gradients from reconstruction tasks. The learned concept tokens at various levels of granularity help either reconstruct the masked image patches by filling in gaps or guide the reconstruction results in a direction that reflects specific concepts. Moreover, we present both quantitative and qualitative results across a wide range of metrics, demonstrating that MCM significantly reduces computational costs by training on fewer than 75% of the total image patches while enhancing concept prediction performance. Additionally, editing specific concept tokens in the latent space enables targeted image generation from masked images, aligning both the visible contextual patches and the provided concepts. By further adjusting the testing time mask ratio, we could produce a range of reconstructions that blend the visible patches with the provided concepts, proportional to the chosen ratios.
title MCM: Multi-layer Concept Map for Efficient Concept Learning from Masked Images
topic Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2502.00266