Collusion-Resistant Video Fingerprinting for Large User Group
Title | Collusion-Resistant Video Fingerprinting for Large User Group |
Publication Type | Journal Articles |
Year of Publication | 2007 |
Authors | He S, M. Wu |
Journal | Information Forensics and Security, IEEE Transactions on |
Volume | 2 |
Issue | 4 |
Pagination | 697 - 709 |
Date Published | 2007/12// |
ISBN Number | 1556-6013 |
Keywords | code, coding-embedding, coding;video, communication;video, complexity;decoding;digital, complexity;digital, computational, content;trimming, demand;watermarking;, DETECTION, distribution;computational, fingerprinting, fingerprinting;decoding, fingerprinting;joint, framework;large, group;multimedia, identification;multimedia, on, signatures;fingerprint, structure;collusion-resistant, technique;video-on-demand, user, video |
Abstract | Digital fingerprinting protects multimedia content from illegal redistribution by uniquely marking copies of the content distributed to users. Most existing multimedia fingerprinting schemes consider a user set on the scale of thousands. However, in such real-world applications as video-on-demand distribution, the number of potential users can be as many as 10-100 million. This large user size demands not only strong collusion resistance but also high efficiency in fingerprint construction, and detection, which makes most existing schemes incapable of being applied to these applications. A recently proposed joint coding and embedding fingerprinting framework provides a promising balance between collusion resistance, efficient construction, and detection, but several issues remain unsolved for applications involving a large group of users. In this paper, we explore how to employ the joint coding and embedding framework and develop practical algorithms to fingerprint video in such challenging settings as to accommodate more than ten million users and resist hundreds of users' collusion. We investigate the proper code structure for large-scale fingerprinting and propose a trimming detection technique that can reduce the decoding computational complexity by more than three orders of magnitude at the cost of less than 0.5% loss in detection probability under moderate to high watermark-to-noise ratios. Both analytic and experimental results show a high potential of joint coding and embedding to meet the needs of real-world large-scale fingerprinting applications. |
DOI | 10.1109/TIFS.2007.908179 |