Image Splicing Detection via Camera Response Function Analysis

Recent advances on image manipulation techniques have made image forgery detection increasingly more challenging. An important component in such tools is to fake motion and/or defocus blurs through boundary splicing and copy-move operators, to emulate wide aperture and slow shutter effects. In this paper, we present a new technique based on the analysis of the camera response functions (CRF) for efficient and robust splicing and copy-move forgery detection and localization. We first analyze how non-linear CRFs affect edges in terms of the intensity-gradient bivariable histograms. We show distinguishable shape differences on real vs. forged blurs near edges after a splicing operation. Based on our analysis, we introduce a deep-learning framework to detect and localize forged edges. In particular, we show the problem can be transformed to a handwriting recognition problem an resolved by using a convolutional neural network. We generate a large dataset of forged images produced by splicing followed by retouching and comprehensive experiments show our proposed method outperforms the state-of-the-art techniques in accuracy and robustness.