Robust JPEG steganography based on the robustness classifier

IF 2.5 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

EURASIP Journal on Information Security Pub Date : 2023-12-11 DOI:10.1186/s13635-023-00148-x

Jimin Zhang, Xianfeng Zhao, Xiaolei He

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引用次数: 0

Abstract

Because the JPEG recompression in social networks changes the DCT coefficients of uploaded images, applying image steganography in popular image-sharing social networks requires robustness. Currently, most robust steganography algorithms rely on the resistance of embedding to the general JPEG recompression process. The operations in a specific compression channel are usually ignored, which reduces the robustness performance. Besides, to acquire the robust cover image, the state-of-the-art robust steganography needs to upload the cover image to social networks several times, which may be insecure regarding behavior security. In this paper, a robust steganography method based on the softmax outputs of a trained classifier and protocol message embedding is proposed. In the proposed method, a deep learning-based robustness classifier is trained to model the specific process of the JPEG recompression channel. The prediction result of the classifier is used to select the robust DCT blocks to form the embedding domain. The selection information is embedded as the protocol messages into the middle-frequency coefficients of DCT blocks. To further improve the recovery possibility of the protocol message, a robustness enhancement method is proposed. It decreases the predicted non-robust possibility of the robustness classifier by modifying low-frequency coefficients of DCT blocks. The experimental results show that the proposed method has better robustness performance compared with state-of-the-art robust steganography and does not have the disadvantage regarding behavior security. The method is universal and can be implemented in different JPEG compression channels after fine-tuning the classifier. Moreover, it has better security performance compared with the state-of-the-art method when embedding large-sized secret messages.

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基于鲁棒性分类器的鲁棒 JPEG 隐写术

由于社交网络中的 JPEG 重压缩会改变上传图像的 DCT 系数，因此在流行的图像共享社交网络中应用图像隐写术需要具备鲁棒性。目前，大多数鲁棒性隐写术算法都依赖于嵌入对一般 JPEG 重压缩过程的抵抗力。特定压缩通道中的操作通常会被忽略，从而降低了鲁棒性能。此外，最先进的鲁棒隐写术在获取鲁棒封面图像时，需要多次将封面图像上传到社交网络，在行为安全性方面可能存在不安全因素。本文提出了一种基于训练分类器软最大输出和协议信息嵌入的鲁棒隐写方法。在所提出的方法中，基于深度学习的鲁棒性分类器经过训练，以模拟 JPEG 重压缩信道的特定过程。分类器的预测结果用于选择稳健的 DCT 块以形成嵌入域。选择信息作为协议信息嵌入到 DCT 块的中频系数中。为了进一步提高协议信息的恢复可能性，提出了一种鲁棒性增强方法。它通过修改 DCT 块的低频系数来降低鲁棒性分类器预测的非鲁棒性可能性。实验结果表明，与最先进的鲁棒隐写术相比，所提出的方法具有更好的鲁棒性能，而且在行为安全性方面没有缺点。该方法具有通用性，在对分类器进行微调后，可在不同的 JPEG 压缩信道中实施。此外，与最先进的方法相比，该方法在嵌入大容量秘密信息时具有更好的安全性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EURASIP Journal on Information Security COMPUTER SCIENCE, INFORMATION SYSTEMS-

CiteScore

8.80

自引率

0.00%

发文量

审稿时长

13 weeks

期刊介绍： The overall goal of the EURASIP Journal on Information Security, sponsored by the European Association for Signal Processing (EURASIP), is to bring together researchers and practitioners dealing with the general field of information security, with a particular emphasis on the use of signal processing tools in adversarial environments. As such, it addresses all works whereby security is achieved through a combination of techniques from cryptography, computer security, machine learning and multimedia signal processing. Application domains lie, for example, in secure storage, retrieval and tracking of multimedia data, secure outsourcing of computations, forgery detection of multimedia data, or secure use of biometrics. The journal also welcomes survey papers that give the reader a gentle introduction to one of the topics covered as well as papers that report large-scale experimental evaluations of existing techniques. Pure cryptographic papers are outside the scope of the journal. Topics relevant to the journal include, but are not limited to: • Multimedia security primitives (such digital watermarking, perceptual hashing, multimedia authentictaion) • Steganography and Steganalysis • Fingerprinting and traitor tracing • Joint signal processing and encryption, signal processing in the encrypted domain, applied cryptography • Biometrics (fusion, multimodal biometrics, protocols, security issues) • Digital forensics • Multimedia signal processing approaches tailored towards adversarial environments • Machine learning in adversarial environments • Digital Rights Management • Network security (such as physical layer security, intrusion detection) • Hardware security, Physical Unclonable Functions • Privacy-Enhancing Technologies for multimedia data • Private data analysis, security in outsourced computations, cloud privacy