Model-Agnostic Method: Exposing Deepfake Using Pixel-Wise Spatial and Temporal Fingerprints
Jun Yang, Yaoru Sun, Maoyu Mao, Lizhi Bai, Siyu Zhang, Fang Wang
Abstract
Deepfake poses a serious threat to the reliability of judicial evidence and intellectual property protection. Existing detection methods either blindly utilize deep learning or use biosignal features, but neither considers spatial and temporal relevance of face features. These methods are increasingly unable to resist the growing realism of fake videos and lack generalization. In this paper, we identify a reliable fingerprint through the consistency of AR coefficients and extend the original PPG signal to 3-dimensional fingerprints to effectively detect fake content. Using these reliable fingerprints, we propose a novel model-agnostic method to expose Deepfake by analyzing temporal and spatial faint synthetic signals hidden in portrait videos. Specifically, our method extracts two types of faint information, i.e., PPG features and AR features, which are used as the basis for forensics in temporal and spatial domains, respectively. PPG allows remote estimation of the heart rate in face videos, and irregular heart rate fluctuations expose traces of tampering. AR coefficients reflect pixel-wise correlation and spatial traces of smoothing caused by up-sampling in the process of generating fake faces. Furthermore, we employ two ACBlock-based DenseNets as classifiers. Our method provides state-of-the-art performance on multiple deep forgery datasets and demonstrates better generalization.