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Multimedia Tools and Applications

, Volume 77, Issue 24, pp 31737–31762 | Cite as

Publicly verifiable watermarking scheme for intellectual property protection using quantum Chaos and bit plane complexity slicing

  • Gaurav Sharma
  • Shailender Gupta
  • Sangeeta Dhall
  • C. K. Nagpal
Article
  • 23 Downloads

Abstract

Intellectual Property such as music, painting, videos and other similar works being broadcasted on web need to be protected against copyright infringement to ensure the rights of their legitimate owners. Moreover, their users must also be sure of the originality of these artefacts. Both these problems can be solved through proper authentication on behalf of the creator. For this purpose, various publicly verifiable watermarking schemes have been available in literature. Recent proposal, in this domain, is based on chaos theory and Secured Hashing Algorithms SHA-2. Due to tremendous growth in the availability of Intellectual Property on the web and associated breaches it becomes a mandatory requirement to update these authenticating schemes. This paper proposes the usage of some more secure, reliable and efficient components in watermarking schemes than being used at present. Proposed changes include the deployment of encryption scheme based on Quantum Logistic maps instead of current Chaos encryption based on peter de-jong map, in order to optimise randomness, correlation and time complexity. For better security and efficiency in hardware implementation SHA-3 is a better choice than SHA-2. Data embedding can be done in regions where imperceptibility is quite high. The proposed changes can result in the creation of more reliable and efficient system. To test the hypothesis, proposed mechanism has been implemented in MATLAB-16a and various performance metrics such as correlation coefficient, PSNR, UIQI, SSIM have been measured. The results show that proposed scheme outperforms its counterpart in terms of all the performance metrics.

Keywords

BPCS Chaotic maps Hash Quantum chaotic maps Zero knowledge verification protocol 

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Copyright information

© Springer Science+Business Media, LLC, part of Springer Nature 2018

Authors and Affiliations

  • Gaurav Sharma
    • 1
  • Shailender Gupta
    • 1
  • Sangeeta Dhall
    • 1
  • C. K. Nagpal
    • 1
  1. 1.YMCA University of Science and TechnologyFaridabadIndia

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