A novel blind color image watermarking based on Walsh Hadamard Transform

A new blind color image watermarking based on Walsh Hadamard Transform (WHT) is proposed in this paper which uses Triangular Vertex Transform (TVT) along with WHT. This method introduces a Triangular Vertex Transform (TVT) and Inverse Triangular Vertex Transform (ITVT) as well as applies this transf...

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Published in:Multimedia tools and applications 2020-03, Vol.79 (9-10), p.6845-6869
Main Authors: Prabha, K., Sam, I. Shatheesh
Format: Article
Language:English
Subjects:
Algorithms
Coefficients
Color
Color imagery
Computer Communication Networks
Computer Science
Data Structures and Information Theory
Decomposition
Digital broadcasting
Digital media
Digital watermarks
Embedding
Encryption
Multimedia
Multimedia Information Systems
Signal to noise ratio
Special Purpose and Application-Based Systems
Spread spectrum
Watermarking
Wavelet transforms
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Sam, I. Shatheesh
description A new blind color image watermarking based on Walsh Hadamard Transform (WHT) is proposed in this paper which uses Triangular Vertex Transform (TVT) along with WHT. This method introduces a Triangular Vertex Transform (TVT) and Inverse Triangular Vertex Transform (ITVT) as well as applies this transform for image watermarking. Initially, convert the R, G, B color image to TVT coefficients U, V and W using the proposed TVT transform. Then the W coefficient is subdivided into 4 × 4 non-overlapping blocks, which are then transformed using WHT. The watermark is encrypted with the key K using the 2D-Logistic Sine Coupling Map encryption to obtain the encrypted watermarked image. The bits of the encrypted image is embedded in the first row WHT coefficients since the embedding of watermark bit on the first row provides high robustness to attacks. After embedding the data, the inverse WHT and inverse TVT are applied to obtain the watermarked image. The extraction process is similar to that of the embedding process where TVT is applied on the Watermarked image to construct W′ coefficient. Subdivide the attained W′ coefficient into 4 × 4 sub-block and then the WHT is applied to the 4 × 4 sub-block for extracting the data from the first row of WHT coefficients. The performance of the proposed watermarking algorithm outperforms in terms of Peak Signal to Noise Ratio (PSNR), Structural Similarity Index (SSIM) and Normalized cross-correlation (NC). Experimental results reveal that the proposed watermarking method is highly resistant to different types of attacks.
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Shatheesh</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A novel blind color image watermarking based on Walsh Hadamard Transform</atitle><jtitle>Multimedia tools and applications</jtitle><stitle>Multimed Tools Appl</stitle><date>2020-03-01</date><risdate>2020</risdate><volume>79</volume><issue>9-10</issue><spage>6845</spage><epage>6869</epage><pages>6845-6869</pages><issn>1380-7501</issn><eissn>1573-7721</eissn><abstract>A new blind color image watermarking based on Walsh Hadamard Transform (WHT) is proposed in this paper which uses Triangular Vertex Transform (TVT) along with WHT. This method introduces a Triangular Vertex Transform (TVT) and Inverse Triangular Vertex Transform (ITVT) as well as applies this transform for image watermarking. Initially, convert the R, G, B color image to TVT coefficients U, V and W using the proposed TVT transform. 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subjects Algorithms
Coefficients
Color
Color imagery
Computer Communication Networks
Computer Science
Data Structures and Information Theory
Decomposition
Digital broadcasting
Digital media
Digital watermarks
Embedding
Encryption
Multimedia
Multimedia Information Systems
Signal to noise ratio
Special Purpose and Application-Based Systems
Spread spectrum
Watermarking
Wavelet transforms
title A novel blind color image watermarking based on Walsh Hadamard Transform
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