What does this research mean for the field?

A dual-layer fragile watermarking framework utilizing 4D-hypercomplex number transformation, hybrid SVD-RSA encoding, and DWT-PCA integration enables high-fidelity image authentication, precise tamper localization, and self-recovery for images with up to 50% distortion, outperforming current methods in perceptual quality and computing efficiency. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to develop a dual-layer watermarking system ensuring image authenticity and recovery post-tampering.

June 5, 2026Open Access

Self-Recovery based Dual Layer Fragile Image Watermarking

Key Points

The aim is to develop a dual-layer watermarking system ensuring image authenticity and recovery post-tampering.
Proposed a dual-layer framework for image authentication, tamper detection, and recovery.
Utilized 4D-hypercomplex number transformation along with various algorithms like FFT, DWT, and PCA.
Implemented a hybrid inpainting technique for restoration after detecting tampering.
Achieved an average PSNR of 52.21 dB and SSIM of 0.9990, indicating exceptional visual quality.
Framework maintained high fidelity recovery even for images with distortion levels up to 50%.
Sustained a payload capacity of 1 bit per pixel with various performance metrics demonstrating efficient image processing.

Abstract

Ensuring the validity and recoverability of digital images is vital in contexts where visual data integrity is paramount. In order to address this need, this work proposed a dual-layer fragile watermarking system for safe image authentication, precise tamper localization, and self-recovery. The proposed framework produces watermark information utilizing a 4D-hypercomplex number transformation (4D-HCNT) grounded on quaternionic algebra, in conjunction with the Fast Fourier Transform (FFT) and logarithmic differencing mapping (LDM). In level-1, authentication bits are encoded utilizing a hybrid singular value decomposition (SVD) method combined with Rivest-Shamir-Adleman (RSA) cryptographic protocol to facilitate dependable integrity verification. In the level-2, recovery bits are integrated by the combination of discrete wavelet transform (DWT) and principal component analysis (PCA), enhancing imperceptibility while preserving robustness against distortions. Tamper detection is accomplished by contrasting retrieved watermark bits with regenerated watermark bits, facilitating accurate identification of altered areas. Following detection of tampering, the compromised areas are restored via a hybrid inpainting technique couples with 255-color range scaling (255-CRS) for adaptive restoration. Experimental findings indicate exceptional visual quality, evidenced by an average peak-signal-to-noise-ration (PSNR) of 52.21 dB, and structural similarity index matrix (SSIM) of 0.9990. Moreover, this framework has also achieved an average MSE, UIQI, AD, NCC, LMSE, and NAE of 0.2961, 0.9931, 0.3586, 0.9843, 0.7698, and 0.0062 respectively. The framework sustains a payload capacity of 1 bit per pixel (bpp) and attains a high-fidelity recovery for images with distortion levels of up to 50%. Overall, the proposed framework delivers efficient image authentication, precise tamper localization, and dependable self-recovery, surpassing current methods in computing efficiency and perceptual quality.

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Cite This Study

Dhar et al. (Mon,) studied this question.

synapsesocial.com/papers/6a22672f763171746d545f99 https://doi.org/https://doi.org/10.1016/j.ibmed.2026.100397

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