核心概念
Diffusion-based image augmentation methods often struggle to balance faithfulness (preserving original image characteristics) and diversity (creating varied synthetic images), limiting their effectiveness in data-scarce scenarios. This paper introduces Diff-II, a novel method using inversion circle interpolation and two-stage denoising to generate both faithful and diverse augmented images, improving classification performance across various tasks.
要約
Bibliographic Information:
Wang, Y., & Chen, L. (2024). Inversion Circle Interpolation: Diffusion-based Image Augmentation for Data-scarce Classification. arXiv preprint arXiv:2408.16266v2.
Research Objective:
This paper addresses the limitations of existing diffusion-based image augmentation methods in balancing faithfulness and diversity when generating synthetic images for data-scarce image classification tasks. The authors propose a novel method, Diff-II, to improve augmentation quality and downstream classification performance.
Methodology:
Diff-II consists of three main steps: 1) Category Concepts Learning: Learnable token embeddings and low-rank matrices are incorporated into a pre-trained diffusion U-Net to learn accurate concept representations for each image category. 2) Inversion Interpolation: DDIM inversion is applied to each training image conditioned on learned concepts. Random pairs of inversions within the same category undergo circle interpolation to generate new latent representations. 3) Two-stage Denoising: Interpolation results are denoised in two stages using different prompts. The first stage utilizes a prompt containing the learned concept and a randomly sampled suffix summarizing high-frequency context patterns. The second stage refines details using a prompt with only the learned concept.
Key Findings:
- Experiments on few-shot, long-tailed, and out-of-distribution classification tasks demonstrate Diff-II's effectiveness.
- Diff-II consistently outperforms existing diffusion-based augmentation methods, achieving significant accuracy improvements.
- Ablation studies confirm the contribution of each component (concept learning, interpolation, two-stage denoising) to performance.
Main Conclusions:
Diff-II effectively addresses the faithfulness-diversity trade-off in diffusion-based image augmentation. By leveraging inversion circle interpolation and two-stage denoising, it generates high-quality synthetic images that improve the generalization ability of classifiers, particularly in data-scarce scenarios.
Significance:
This research contributes a novel and effective method for data augmentation in image classification, particularly beneficial for fine-grained datasets and challenging scenarios with limited training data.
Limitations and Future Research:
- The method's effectiveness is limited when categories have only one training image, hindering interpolation.
- Future research could explore removing the dependency on external captioning models and solely utilize LLMs for prompt diversification.
- Extending the method to other computer vision tasks like object detection and segmentation is a promising direction.
統計
Average accuracy improvement of 3.56% to 10.05% on few-shot classification tasks.
Outperforms state-of-the-art Diff-Mix by 3.6% on CUB-LT long-tailed classification.
Achieves an 11.39% improvement in accuracy on out-of-distribution classification compared to no augmentation.
引用
"current state-of-the-art diffusion-based DA methods cannot take account of both faithfulness and diversity, which results in limited improvements on the generalization ability of downstream classifiers."
"we propose a simple yet effective Diffusion-based Inversion Interpolation method: Diff-II, which can generate both faithful and diverse augmented images."