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Main Authors: Ma, Hongxu, Li, Guang, Wang, Shijie, Zhou, Dongzhan, Sun, Baoli, Ogawa, Takahiro, Haseyama, Miki, Wang, Zhihui
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.25144
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author Ma, Hongxu
Li, Guang
Wang, Shijie
Zhou, Dongzhan
Sun, Baoli
Ogawa, Takahiro
Haseyama, Miki
Wang, Zhihui
author_facet Ma, Hongxu
Li, Guang
Wang, Shijie
Zhou, Dongzhan
Sun, Baoli
Ogawa, Takahiro
Haseyama, Miki
Wang, Zhihui
contents Dataset distillation (DD) compresses a large training set into a small synthetic set, reducing storage and training cost, and has shown strong results on general benchmarks. Decoupled DD further improves efficiency by splitting the pipeline into pretraining, sample distillation, and soft-label generation. However, existing decoupled methods largely rely on coarse class-label supervision and optimize samples within each class in a nearly identical manner. On fine-grained datasets, this often yields distilled samples that (i) retain large intra-class variation with subtle inter-class differences and (ii) become overly similar within the same class, limiting localized discriminative cues and hurting recognition. To solve the above-mentioned problems, we propose FD$^{2}$, a dedicated framework for Fine-grained Dataset Distillation. FD$^{2}$ localizes discriminative regions and constructs fine-grained representations for distillation. During pretraining, counterfactual attention learning aggregates discriminative representations to update class prototypes. During distillation, a fine-grained characteristic constraint aligns each sample with its class prototype while repelling others, and a similarity constraint diversifies attention across same-class samples. Experiments on multiple fine-grained and general datasets show that FD$^{2}$ integrates seamlessly with decoupled DD and improves performance in most settings, indicating strong transferability.
format Preprint
id arxiv_https___arxiv_org_abs_2603_25144
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle FD$^2$: A Dedicated Framework for Fine-Grained Dataset Distillation
Ma, Hongxu
Li, Guang
Wang, Shijie
Zhou, Dongzhan
Sun, Baoli
Ogawa, Takahiro
Haseyama, Miki
Wang, Zhihui
Computer Vision and Pattern Recognition
Artificial Intelligence
Dataset distillation (DD) compresses a large training set into a small synthetic set, reducing storage and training cost, and has shown strong results on general benchmarks. Decoupled DD further improves efficiency by splitting the pipeline into pretraining, sample distillation, and soft-label generation. However, existing decoupled methods largely rely on coarse class-label supervision and optimize samples within each class in a nearly identical manner. On fine-grained datasets, this often yields distilled samples that (i) retain large intra-class variation with subtle inter-class differences and (ii) become overly similar within the same class, limiting localized discriminative cues and hurting recognition. To solve the above-mentioned problems, we propose FD$^{2}$, a dedicated framework for Fine-grained Dataset Distillation. FD$^{2}$ localizes discriminative regions and constructs fine-grained representations for distillation. During pretraining, counterfactual attention learning aggregates discriminative representations to update class prototypes. During distillation, a fine-grained characteristic constraint aligns each sample with its class prototype while repelling others, and a similarity constraint diversifies attention across same-class samples. Experiments on multiple fine-grained and general datasets show that FD$^{2}$ integrates seamlessly with decoupled DD and improves performance in most settings, indicating strong transferability.
title FD$^2$: A Dedicated Framework for Fine-Grained Dataset Distillation
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2603.25144