Diffusion Epistemic Uncertainty with Asymmetric Learning for Diffusion-Generated Image Detection
- URL: http://arxiv.org/abs/2601.14625v1
- Date: Wed, 21 Jan 2026 03:57:15 GMT
- Title: Diffusion Epistemic Uncertainty with Asymmetric Learning for Diffusion-Generated Image Detection
- Authors: Yingsong Huang, Hui Guo, Jing Huang, Bing Bai, Qi Xiong,
- Abstract summary: We propose a novel framework, Diffusion Epistemic Uncertainty with Asymmetric Learning(DEUA), for detecting generated images.<n>We introduce Diffusion Epistemic Uncertainty(DEU) estimation via the Laplace approximation to assess the proximity of data to the manifold of diffusion-generated samples.
- Score: 10.061197311881287
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: The rapid progress of diffusion models highlights the growing need for detecting generated images. Previous research demonstrates that incorporating diffusion-based measurements, such as reconstruction error, can enhance the generalizability of detectors. However, ignoring the differing impacts of aleatoric and epistemic uncertainty on reconstruction error can undermine detection performance. Aleatoric uncertainty, arising from inherent data noise, creates ambiguity that impedes accurate detection of generated images. As it reflects random variations within the data (e.g., noise in natural textures), it does not help distinguish generated images. In contrast, epistemic uncertainty, which represents the model's lack of knowledge about unfamiliar patterns, supports detection. In this paper, we propose a novel framework, Diffusion Epistemic Uncertainty with Asymmetric Learning~(DEUA), for detecting diffusion-generated images. We introduce Diffusion Epistemic Uncertainty~(DEU) estimation via the Laplace approximation to assess the proximity of data to the manifold of diffusion-generated samples. Additionally, an asymmetric loss function is introduced to train a balanced classifier with larger margins, further enhancing generalizability. Extensive experiments on large-scale benchmarks validate the state-of-the-art performance of our method.
Related papers
- Explainable Synthetic Image Detection through Diffusion Timestep Ensembling [30.298198387824275]
We propose a novel synthetic image detection method that directly utilizes features of intermediately noised images by training an ensemble on multiple noised timesteps.<n>To enhance human comprehension, we introduce a metric-grounded explanation generation and refinement module.<n>Our method achieves state-of-the-art performance with 98.91% and 95.89% detection accuracy on regular and challenging samples respectively.
arXiv Detail & Related papers (2025-03-08T13:04:20Z) - One-for-More: Continual Diffusion Model for Anomaly Detection [63.50488826645681]
Anomaly detection methods utilize diffusion models to generate or reconstruct normal samples when given arbitrary anomaly images.<n>Our study found that the diffusion model suffers from severe faithfulness hallucination'' and catastrophic forgetting''<n>We propose a continual diffusion model that uses gradient projection to achieve stable continual learning.
arXiv Detail & Related papers (2025-02-27T07:47:27Z) - Epistemic Uncertainty for Generated Image Detection [107.62647907393377]
We introduce a novel framework for AI-generated image detection through epistemic uncertainty, aiming to address critical security concerns in the era of generative models.<n>Our key insight stems from the observation that distributional discrepancies between training and testing data manifest distinctively in the epistemic uncertainty space of machine learning models.
arXiv Detail & Related papers (2024-12-08T11:32:25Z) - StealthDiffusion: Towards Evading Diffusion Forensic Detection through Diffusion Model [62.25424831998405]
StealthDiffusion is a framework that modifies AI-generated images into high-quality, imperceptible adversarial examples.
It is effective in both white-box and black-box settings, transforming AI-generated images into high-quality adversarial forgeries.
arXiv Detail & Related papers (2024-08-11T01:22:29Z) - Projection Regret: Reducing Background Bias for Novelty Detection via
Diffusion Models [72.07462371883501]
We propose emphProjection Regret (PR), an efficient novelty detection method that mitigates the bias of non-semantic information.
PR computes the perceptual distance between the test image and its diffusion-based projection to detect abnormality.
Extensive experiments demonstrate that PR outperforms the prior art of generative-model-based novelty detection methods by a significant margin.
arXiv Detail & Related papers (2023-12-05T09:44:47Z) - Exposing the Fake: Effective Diffusion-Generated Images Detection [14.646957596560076]
This paper proposes a novel detection method called Stepwise Error for Diffusion-generated Image Detection (SeDID)
SeDID exploits the unique attributes of diffusion models, namely deterministic reverse and deterministic denoising errors.
Our work makes a pivotal contribution to distinguishing diffusion model-generated images, marking a significant step in the domain of artificial intelligence security.
arXiv Detail & Related papers (2023-07-12T16:16:37Z) - DIRE for Diffusion-Generated Image Detection [128.95822613047298]
We propose a novel representation called DIffusion Reconstruction Error (DIRE)
DIRE measures the error between an input image and its reconstruction counterpart by a pre-trained diffusion model.
It provides a hint that DIRE can serve as a bridge to distinguish generated and real images.
arXiv Detail & Related papers (2023-03-16T13:15:03Z) - Robustness via Uncertainty-aware Cycle Consistency [44.34422859532988]
Unpaired image-to-image translation refers to learning inter-image-domain mapping without corresponding image pairs.
Existing methods learn deterministic mappings without explicitly modelling the robustness to outliers or predictive uncertainty.
We propose a novel probabilistic method based on Uncertainty-aware Generalized Adaptive Cycle Consistency (UGAC)
arXiv Detail & Related papers (2021-10-24T15:33:21Z) - The Hidden Uncertainty in a Neural Networks Activations [105.4223982696279]
The distribution of a neural network's latent representations has been successfully used to detect out-of-distribution (OOD) data.
This work investigates whether this distribution correlates with a model's epistemic uncertainty, thus indicating its ability to generalise to novel inputs.
arXiv Detail & Related papers (2020-12-05T17:30:35Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.