Abstract
Currently, the most successful approach to steganography in empirical objects, such as digital media, is to embed the payload while minimizing a suitably defined distortion function. The design of the distortion is essentially the only task left to the steganographer since efficient practical codes exist that embed near the payload-distortion bound. The practitioner’s goal is to design the distortion to obtain a scheme with a high empirical statistical detectability. In this paper, we propose a universal distortion design called universal wavelet relative distortion (UNIWARD) that can be applied for embedding in an arbitrary domain. The embedding distortion is computed as a sum of relative changes of coefficients in a directional filter bank decomposition of the cover image. The directionality forces the embedding changes to such parts of the cover object that are difficult to model in multiple directions, such as textures or noisy regions, while avoiding smooth regions or clean edges. We demonstrate experimentally using rich models as well as targeted attacks that steganographic methods built using UNIWARD match or outperform the current state of the art in the spatial domain, JPEG domain, and side-informed JPEG domain.
Highlights
Designing steganographic algorithms for empirical cover sources [1] is very challenging due to the fundamental lack of accurate models
3 Universal distortion function universal wavelet relative distortion (UNIWARD) we provide a general description of the proposed universal distortion function UNIWARD and explain how it can be used to embed in the JPEG and the side-informed JPEG domains
4 Common core of all experiments Before we move to the experimental part of this paper, which appears in Sections 5 and 6, we introduce the common core of all experiments: the cover source, steganalysis features, the classifier used to build the steganography detectors, and an empirical measure of security
Summary
Designing steganographic algorithms for empirical cover sources [1] is very challenging due to the fundamental lack of accurate models. In the JPEG domain, by far the most successful paradigm is to minimize the rounding distortion with respect to the raw, uncompressed image, if available [8,9,10,11,12]. This ‘side-informed embedding’ can be applied whenever the sender possesses a higher-quality ‘precover’b that is quantized to obtain the coverc. After introducing the basic notation and terminology, we describe the distortion function in its most general form in Section 3 - one suitable for embedding in both the spatial and JPEG domains and the other for side-informed JPEG steganography. This paper is an extended and adjusted version of an article presented at the First ACM Information Hiding and Multimedia Security Workshop in Montpellier in June 2013 [19]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
