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Tamper Localization
Review on Self-embedding Fragile Watermarking for Image Authentication and Self-recovery
Chengyou Wang, Heng Zhang and Xiao Zhou
Page: 510~522, Vol. 14, No.2, 2018
10.3745/JIPS.02.0082
Keywords: Image Authentication and Self-recovery, Least Significant Bit (LSB), Peak Signal-to-Noise Ratio (PSNR), Self-embedding Fragile Watermarking
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Secured Telemedicine Using Whole Image as Watermark with Tamper Localization and Recovery Capabilities
Gran Badshah, Siau-Chuin Liew, Jasni Mohamad Zain and Mushtaq Ali
Page: 601~615, Vol. 11, No.4, 2015
10.3745/JIPS.03.0044
Keywords: Lossless Recovery, Tamper Localization, Telemedicine, Watermarking, Whole Image, WITALLOR
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Review on Self-embedding Fragile Watermarking for Image Authentication and Self-recovery
Chengyou Wang, Heng Zhang and Xiao Zhou
Page: 510~522, Vol. 14, No.2, 2018

Keywords: Image Authentication and Self-recovery, Least Significant Bit (LSB), Peak Signal-to-Noise Ratio (PSNR), Self-embedding Fragile Watermarking
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As the major source of information, digital images play an indispensable role in our lives. However, with the development of image processing techniques, people can optionally retouch or even forge an image by using image processing software. Therefore, the authenticity and integrity of digital images are facing severe challenge. To resolve this issue, the fragile watermarking schemes for image authentication have been proposed. According to different purposes, the fragile watermarking can be divided into two categories: fragile watermarking for tamper localization and fragile watermarking with recovery ability. The fragile watermarking for image tamper localization can only identify and locate the tampered regions, but it cannot further restore the modified regions. In some cases, image recovery for tampered regions is very essential. Generally, the fragile watermarking for image authentication and recovery includes three procedures: watermark generation and embedding, tamper localization, and image self-recovery. In this article, we make a review on self-embedding fragile watermarking methods. The basic model and the evaluation indexes of this watermarking scheme are presented in this paper. Some related works proposed in recent years and their advantages and disadvantages are described in detail to help the future research in this field. Based on the analysis, we give the future research prospects and suggestions in the end.
Secured Telemedicine Using Whole Image as Watermark with Tamper Localization and Recovery Capabilities
Gran Badshah, Siau-Chuin Liew, Jasni Mohamad Zain and Mushtaq Ali
Page: 601~615, Vol. 11, No.4, 2015

Keywords: Lossless Recovery, Tamper Localization, Telemedicine, Watermarking, Whole Image, WITALLOR
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Region of interest (ROI) is the most informative part of a medical image and mostly has been used as a major part of watermark. Various shapes ROIs selection have been reported in region-based watermarking techniques. In region-based watermarking schemes an image region of non-interest (RONI) is the second important part of the image and is used mostly for watermark encapsulation. In online healthcare systems the ROI wrong selection by missing some important portions of the image to be part of ROI can create problem at the destination. This paper discusses the complete medical image availability in original at destination using the whole image as a watermark for authentication, tamper localization and lossless recovery (WITALLOR). The WITALLOR watermarking scheme ensures the complete image security without of ROI selection at the source point as compared to the other region-based watermarking techniques. The complete image is compressed using the Lempel-Ziv-Welch (LZW) lossless compression technique to get the watermark in reduced number of bits. Bits reduction occurs to a number that can be completely encapsulated into image. The watermark is randomly encapsulated at the least significant bits (LSBs) of the image without caring of the ROI and RONI to keep the image perceptual degradation negligible. After communication, the watermark is retrieved, decompressed and used for authentication of the whole image, tamper detection, localization and lossless recovery. WITALLOR scheme is capable of any number of tampers detection and recovery at any part of the image. The complete authentic image gives the opportunity to conduct an image based analysis of medical problem without restriction to a fixed ROI.