RFNNS: Robust Fixed Neural Network Steganography with Popular Deep Generative Models
Abstract
Image steganography is a technique that conceals secret information in a cover image to achieve covert communication. Recent research has demonstrated that Fixed Neural Network Steganography (FNNS) exhibits significant practical advantages, as it enables stable and efficient steganographic embedding and extraction without requiring neural network training. However, the stego image generated by existing FNNS methods suffers from considerable distortion and exhibits poor robustness, severely reducing the security and practicality of steganography. To address the aforementioned issues, we propose a Robust Fixed Neural Network Steganography (RFNNS). In RFNNS, we introduce a texture-aware localization technique to add perturbations carrying secret image information to complex texture areas that are less perceptible to the human eye, thereby ensuring the quality of the stego image. To enhance robustness, a robust steganographic perturbation generation (RSPG) strategy is designed, which enables slight perturbations to be accurately decoded even after common image attacks. Subsequently, the generated robust perturbations are combined with the AI-generated cover image to produce the stego image. The receiver only needs to share the secret key and employ the same decoding network structure to accurately extract the secret image from the attacked stego image. Experimental results demonstrate that RFNNS achieves enhanced performance in terms of security, including imperceptibility and anti-steganalysis performance. Furthermore, RFNNS demonstrates superior robustness against common image attacks, such as JPEG compression, Gaussian noise, and contrast adjustment, across diverse embedding capacities, outperforming existing SOTA FNNS methods.