Related papers: DistilDIRE: A Small, Fast, Cheap and Lightweight Diffusion Synthesized Deepfake Detection

DistilDIRE: A Small, Fast, Cheap and Lightweight Diffusion Synthesized Deepfake Detection

URL: http://arxiv.org/abs/2406.00856v1
Date: Sun, 2 Jun 2024 20:22:38 GMT
Title: DistilDIRE: A Small, Fast, Cheap and Lightweight Diffusion Synthesized Deepfake Detection
Authors: Yewon Lim, Changyeon Lee, Aerin Kim, Oren Etzioni,
Abstract summary: diffusion-generated images pose unique challenges to current detection technologies. We propose distilling the knowledge embedded in diffusion models to develop rapid deepfake detection models. Our experimental results indicate an inference speed 3.2 times faster than the existing DIRE framework.
Score: 2.8934833311559816
License: http://creativecommons.org/licenses/by/4.0/
Abstract: A dramatic influx of diffusion-generated images has marked recent years, posing unique challenges to current detection technologies. While the task of identifying these images falls under binary classification, a seemingly straightforward category, the computational load is significant when employing the "reconstruction then compare" technique. This approach, known as DIRE (Diffusion Reconstruction Error), not only identifies diffusion-generated images but also detects those produced by GANs, highlighting the technique's broad applicability. To address the computational challenges and improve efficiency, we propose distilling the knowledge embedded in diffusion models to develop rapid deepfake detection models. Our approach, aimed at creating a small, fast, cheap, and lightweight diffusion synthesized deepfake detector, maintains robust performance while significantly reducing operational demands. Maintaining performance, our experimental results indicate an inference speed 3.2 times faster than the existing DIRE framework. This advance not only enhances the practicality of deploying these systems in real-world settings but also paves the way for future research endeavors that seek to leverage diffusion model knowledge.

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