Abstract
Deep learning has brought about a phenomenal paradigm shift in digital steganography. However, there is as yet no consensus on the use of deep neural networks in reversible steganography, a class of steganographic methods that permits the distortion caused by message embedding to be removed. The underdevelopment of the field of reversible steganography with deep learning can be attributed to the perception that perfect reversal of steganographic distortion seems scarcely achievable, due to the lack of transparency and interpretability of neural networks. Rather than employing neural networks in the coding module of a reversible steganographic scheme, we instead apply them to an analytics module that exploits data redundancy to maximise steganographic capacity. State-of-the-art reversible steganographic schemes for digital images are based primarily on a histogram-shifting method in which the analytics module is often modelled as a pixel intensity predictor. In this paper, we propose to refine the prior estimation from a conventional linear predictor through a neural network model. The refinement can be to some extent viewed as a low-level vision task (e.g., noise reduction and super-resolution imaging). In this way, we explore a leading-edge neuroscience-inspired low-level vision model based on long short-term memory with a brief discussion of its biological plausibility. Experimental results demonstrated a significant boost contributed by the neural network model in terms of prediction accuracy and steganographic rate-distortion performance.
Highlights
Steganography is the art and science of concealing a message within a cover object in an imperceptible manner [1]
Accurate and consistent data lay a sound foundation of modern analytics platforms [11], and the ability to reverse steganographic distortion and restore data integrity is of paramount importance
While many deep neural network models may be employed to carry out the refinement, this task seems closest to low-level vision task [47,48,49,50,51,52,53]. erefore, we explore a seminal low-level vision model, the MemNet [54], of which the foundation is long short-term memory (LSTM) [55]
Summary
Steganography is the art and science of concealing a message within a cover object (e.g., image, audio, video, and text) in an imperceptible manner [1]. Contemporary reversible steganographic schemes for digital images are based primarily on the histogram-shifting (HS) method on account of its sterling rate-distortion performance [33,34,35,36,37,38,39,40]. This type of scheme consists of two procedures: histogram generation and histogram modification, linked to the analytics module and the coding module, respectively. E proposed neural analytics module comprises a preprocessing stage that generates a pre-estimated image via a linear predictor and a post-processing stage that refines the prior estimation via an LSTM-based vision model. In order to handle this exception, an overflow map is pre-calculated to flag pixels of which intensity would be off-boundary after
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