Abstract: The increasing photorealism for computer graphics has made computer graphics a convincing form of image forgery. Therefore, classifying photographic images and photorealistic computer graphics has become an important problem for image forgery detection. In this paper, we propose a new geometry-based image model, motivated by the physical image generation process, to tackle the above-mentioned problem. The proposed model reveals certain physical differences between the two image categories, such as the gamma correction in photographic images and the sharp structures in computer graphics. For the problem of image forgery detection, we propose two levels of image authenticity definition, i.e., imaging-process authenticity and scene authenticity, and analyze our technique against these definitions. Such definition is important for making the concept of image authenticity computable. Apart from offering physical insights, our technique with a classification accuracy of 83.5% outperforms those in the prior work, i.e., wavelet features at 80.3% and cartoon features at 71.0%. We also consider a recapturing attack scenario and propose a counter-attack measure. In addition, we constructed a publicly available benchmark dataset with images of diverse content and computer graphics of high photorealism.

@inproceedings{Ng:2005aa,
  publisher    = {ACM Press},
  author       = {Tian-Tsong Ng and Shih-Fu Chang and Jessie Hsu and Lexing Xie and Mao-Pei Tsui},
  url          = {http://portal.acm.org/citation.cfm?id=1101149.1101192},
  year         = {2005},
  booktitle    = {MULTIMEDIA '05: Proceedings of the 13th annual ACM international conference on Multimedia, November 6--11, 2005, Hilton, Singapore},
  address      = {New York, NY, USA},
  title        = {Physics-motivated features for distinguishing photographic images and computer graphics},
  pages        = {239--248},
}