基于扩散模型数据增广的域泛化方法

doi:10.11959/j.issn.2096-6652.202334

Abstract

Abstract:

Domain generalization is an important and challenging problem in computer vision, arising from the distribution shift of real-world data.In practical applications, it is common to encounter training and testing data from different domains, and the difference in data distribution can lead to performance degradation during testing.In this paper, we propose a domain generalization method based on latent space data augmentation.Unlike traditional image-level data augmentation approaches, the method introduces a diffusion model in the latent space to achieve fine control and diversity generation of features, thereby achieving feature level data augmentation and enhancing the model's generalization ability in the target domain.Specifically, the classifier-based implicit diffusion model, trained within the latent space, can conditionally generate accurate and rich source domain features.It leverages efficient sampling techniques to expedite the generation of augmented features.Experimental results show that the method has achieved significant performance improvement in various domain generalization tasks, and has good effectiveness and robustness in real scenarios.The key innovation of this paper lies in shifting data augmentation to the latent space level and introducing the diffusion model for augmentation, providing a novel approach to address the domain generalization problem.

Key words: domain generalization, diffusion model, data augmentation

CLC Number:

TP39

Yujun TONG, Heqing WANG, Yueheng LUO, et al. Data augmentation method based on diffusion model for domain generalization[J]. Chinese Journal of Intelligent Science and Technology, 2023, 5(3): 380-388.

Figures/Tables 8

References 37

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方法	A	C	P	S	平均
ERM	78.6	74.4	96.3	72.4	80.4
Jigen	79.4	75.3	96.0	71.6	80.5
SFA-A	81.2	77.8	93.9	73.7	81.7
MMLD	81.3	77.2	96.1	72.3	81.7
DADG	79.9	76.3	94.9	70.5	80.4
BNE	78.8	78.9	94.8	79.7	83.1
本文方法（50步+2阶）	81.9	73.7	96.6	74.8	81.7
本文方法（100步+2阶）	81.8	75.4	96.6	75.1	82.2
本文方法+MMD	82.5	76.6	96.4	77.4	83.2

方法	A	C	P	S	平均
无分类器引导	81.0	73.3	96.7	73.3	81.1
本文方法	81.8	73.7	96.6	74.8	81.7

步数	阶数	A	C	P	S	平均
20	2	80.8	73.7	96.7	75.1	81.6
50	2	81.8	73.7	96.6	74.8	81.7
20	1	80.4	73.3	96.5	75.0	81.3
50	1	81.3	73.4	96.4	74.7	81.5

Data augmentation method based on diffusion model for domain generalization

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References 37

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