A Survey on Reversible Image Data Hiding Using the Hierarchical Block Embedding Technique

The use of graphics for data concealment has significantly advanced the fields of secure communication and identity verification. Reversible data hiding (RDH) involves hiding data within host media, such as images, while allowing for the recovery of the original cover. Various RDH approaches have been developed, including difference expansion, interpolation techniques, prediction, and histogram modification. However, these methods were primarily applied to plain photos. This study introduces a novel reversible image transformation technique called Block Hierarchical Substitution (BHS). BHS enhances the quality of encrypted images and enables lossless restoration of the secret image with a low Peak Signal-to-Noise Ratio (PSNR). The cover image is divided into non-overlapping blocks, and the pixel values within each block are encrypted using the modulo function. This ensures that the linear prediction difference in the block remains consistent before and after encryption, enabling independent data extraction without picture decryption. In order to address the challenges associated with secure multimedia data processing, such as data encryption during transmission and storage, this survey investigates the specific issues related to reversible data hiding in encrypted images (RDHEI). Our proposed solution aims to enhance security (low Mean Squared Error) and improve the PSNR value by applying the method to encrypted images

A Multistage High Capacity Reversible Data Hiding Technique Without Overhead Communication

Reversible Data Hiding(RDH) has been extensively investigated, recently, due to its numerous applications in the field of defence, medical, law enforcement and image authentication. However, most of RDH techniques suffer from low secret data hiding capacity and communication overhead. For this, multistage high-capacity reversible data hiding technique without overhead is proposed in this manuscript. Proposed reversible data hiding approach exploits histogram peaks for embedding the secret data along with overhead bits both in plain and encrypted domain. First, marked image is obtained by embedding secret data in the plain domain which is further processed using affine cipher maintaining correlation among the pixels. In second stage, overhead bits are embedded in the encrypted marked image. High embedding capacity is achieved through exploiting histogram peak for embedding multiple bits of secret data. Proposed approach is experimentally validated on different datasets and results are compared with the state-of-the-art techniques over different images

Histogram-based multilayer reversible data hiding method for securing secret data

In this modern age, data can be easily transferred within networks. This condition has brought the data vulnerable; so they need protection at all times. To minimize this threat, data hiding appears as one of the potential methods to secure data. This protection is done by embedding the secret into various types of data, such as an image. In this case, histogram shifting has been proposed; however, the amount of secret and the respective stego image are still challenging. In this research, we offer a method to improve its performance by performing some steps, for example removing the shifting process and employing multilayer embedding. Here, the embedding is done directly to the peak of the histogram which has been generated by the cover. The experimental results show that this proposed method has a better quality of stego image than existing ones. So, it can be one of possible solutions to protect sensitive data

Novel Frame work for Improving Embedding Capacity of the System using Reversible Data Hiding Technique

Internet communication has become an essential part of infrastructure of today’s world. The secret information communicated in various forms. Security of the secret information has been a challenge when the heavy amount of data is exchanged on the internet. A secure data transfer can be achieved by steganography and Cryptography. Steganography is a process of hiding the information into cover media while cryptography is the technique that encodes the message using encryption key. In this paper described the reversible data hiding concept. This maintains the property that recovered the original cover without loss of data while extracting the embedded message. DOI: 10.17762/ijritcc2321-8169.15072

General Framework of Reversible Watermarking Based on Asymmetric Histogram Shifting of Prediction Error

This paper presents a general framework for the reversible watermarking based on asymmetric histogram shifting of prediction error, which is inspired by reversible watermarking of prediction error. Different from the conventional algorithms using single-prediction scheme to create symmetric histogram, the proposed method employs a multi-prediction scheme, which calculates multiple prediction values for the pixels. Then, the suitable value would be selected by two dual asymmetric selection functions to construct two asymmetric error histograms. Finally, the watermark is embedded in the two error histograms separately utilizing a complementary embedding strategy. The proposed framework provides a new perspective for the research of reversible watermarking, which brings about many benefits for the information security

PENGEMBALIAN PENYEMBUNYIAN DATA DARI GAMBAR ENKRIPSI MENGGUNAKAN PENYEDIAAN RUANG KAPASITAS TAMBAHAN SEBELUM DI ENKRIPSI

Pengembalian data yang disembunyikan pada enkripsi images telah banyak digunakan dan menjamin kerahasiaan untuk medical imagery, military imagery, dan law forensics. Dan banyak kemajuan penelitian mengenai hal ini. Namun penyembunyian data menggunakan image juga memiliki keterbatasan terhadap kualitas dan kapasitas, dimana kedua hal ini selalu berbanding terbalik. Beberapa penelitian sebelumnya hanya terfocus pada salah satu keterbatasan tersebut. Maka dari itu pada penelitian kali ini, kami menggunakan metode reserving room untuk menyembunyikan data sebelum cover image dienkripsi. Metode yang diajukan ialah dengan menambahkan kapasitas sehingga mampu memenuhi permintaan penyembunyian data atau message untuk ukuran yang lebih besar. Sedangkan metode LSB-plane untuk pemilihan blok yang menerima untuk penyembunyian message data dan menggunakan tradisional teknik RDH untuk mengenkripsi dan dekripsi images sehingga cover image maksimal. Hasil eksperiment menunjukkan bahwa metode yang diajukan memberikan kualitas yang unggul untuk menjaga nilai PSNR proses embedding diatas 0.5 bpp sehingga aplikasi ini mampu menyembunyikan data yang lebih besar