Optimization-Based Embedding for Wavelet-Domain Audio Watermarking
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- 作者:Huang-Nan Huang (1)
Shuo-Tsung Chen (1) (2)
Muh-Shi Lin (3) (4) (5)
Woon-Man Kung (6) (7)
Chih-Yu Hsu (8)
1. Department of Applied Mathematics ; Tunghai University ; Taichung ; 40704 ; Taiwan ; Republic of China
2. Department of Electronic Engineering ; National Formosa University ; Taiwan ; Republic of China
3. Department of Neurosurgery ; Taipei City Hospital ; Zhong Xiao Branch ; Taipei ; Taiwan ; Republic of China
4. Division of Neurosurgery ; Department of Surgery ; New Taipei City Hospital ; New Taipei City ; Taiwan ; Republic of China
5. Department of Surgery ; Faculty of Medicine ; School of Medicine ; National Yang-Ming University ; Taipei ; Taiwan ; Republic of China
6. Department of Exercise and Health Promotion ; College of Education ; Chinese Culture University (CCU) ; Taipei ; Taiwan ; Republic of China
7. Department of Neurosurgery ; Lo-Hsu Foundation ; Lotung Poh-Ai Hospital ; Luodong ; Yilan ; Taiwan ; Republic of China
8. Department of Information and Communication Engineering ; Chaoyang University of Technology ; Taichung ; 413 ; Taiwan ; Republic of China - 关键词:Audio watermarking ; Optimization ; based ; Discrete wavelet transform (DWT)
- 刊名:The Journal of VLSI Signal Processing
- 出版年:2015
- 出版时间:August 2015
- 年:2015
- 卷:80
- 期:2
- 页码:197-208
- 全文大小:1,067 KB
- 参考文献:1. Gerzon, MA, Graven, PG (1995) A high-rate buried-data channel for audio CD. Journal of the Audio Engineering Society 43: pp. 3-22
2. Bassia, P, Pitas, I, Nikolaidis, N (2001) Robust audio watermarking in the time domain. IEEE Transactions on Multimedia 3: pp. 232-241 CrossRef
3. Gruhl, D. (1996). Echo hiding. In / Proc. 1st Information Hiding Workshop, / LNCS, vol.1174 (pp. 295鈥?15). Berlin, Germany.
4. Zaidi, A, Boyer, R, Duhamel, P (2006) Audio watermarking under desynchronization and additive noise attacks. IEEE Transactions on Signal Processing 54: pp. 570-584 CrossRef
5. Kim, HJ (2003) Audio watermarking techniques, Pacific Rim Workshop on Digital Steganography. Kyushu Institute of Technology, Kitakyushu
6. Alaryani, H., & Youssef, A. (2005). A novel audio watermarking technique based on frequency components. / Proceedings of the Seventh IEEE International Symposium on Multimedia.
7. Boney, L., Tewfik, A. H., & Handy, K. N. (1996). Digital watermarks for audio signals. In / Proc. 3rd IEEE Int. Conf. Multimedia Computing and Systems (pp. 473鈥?80).
8. Ciloglu, T., & Karaaslan, S. U. (2000). An improved all-pass watermarking scheme for speech and audio. In / Proc. 3 rd IEEE Int. Conf. Multimedia Computing and Exposition (ICME) (pp. 1017鈥?020).
9. Kim, H. (2000). Stochastic model based audio watermark whitening filter for improve detection. In / Proc. 3 rd IEEE Int. Conf. Acoustics, Speech and Signal Processing (ICASSP) (pp. 1971鈥?974).
10. Ko, B. S., Nishimura, R., & Suzuki, Y. (2002). Time-spread echo method for digital audio watermarking using PN sequence. In / Proc. IEEE Int. Conf. Acoustics, Speech and Signal processing, vol. II (pp. 2001鈥?004).
11. Lie, WN, Chang, LC (2006) Robust and high-quality time-domain audio watermarking based on low-frequency amplitude modification. IEEE Transactions on Multimedia 8: pp. 46-59 CrossRef
12. Xiang, S, Huang, J (2007) Histogram-based audio watermarking against time-scale modification and cropping attacks. IEEE Transactions on Multimedia 9: pp. 1357-1372 CrossRef
13. Huang, J., Wang, Y., & Shi, Y. Q. (2002). A blind audio watermarking algorithm with self-synchronization. In / Proc. IEEE Int. Symp. Circuits and Systems, vol. 3 (pp. 627鈥?30).
14. Wu, S, Huang, J, Huang, D, Shi, YQ (2005) Efficiently self- synchronized audio watermarking for assure audio data transmission. IEEE Transactions on Broadcasting 51: pp. 69-76 CrossRef
15. Bender, W, Gruhl, D, Morimoto, N (1996) Techniques for data hiding. IBM Systems Journal 35: pp. 131-336
16. Wu, C. P., Su, P.-C., & Kuo, C. C. J. (1999). Robust frequency domain audio watermarking based on audio content analysis. In / Proc. Int. Symp. Multimedia Information Processing, ISMIP (pp. 37鈥?5).
17. Li, X., & Yu, H. H. (2000). Transparent and robust audio data hiding in sub-band domain. In / Proc. IEEE Int. Conf. Information Technique: Coding and Computing (pp. 74鈥?9).
18. Wang, Y. (1998). A new watermarking method of digital audio content for copyright protection. In / Proceedings of the. 4th International Conference on Signal Processing, vol. 2 (pp. 1420鈥?423).
19. Wang, X, Zhao, H (2006) A novel synchronization invariant audio watermarking scheme based on DWT and DCT. IEEE Transactions on Signal Processing 54: pp. 4835-4840 CrossRef
20. Xiang, S., & Huang, J. (2007). Robust audio watermarking against the D/A and A/D conversions, CoRR arXiv:0707.0397v1.
21. He, X., & Scordilis, M. S. (2008). Efficiently synchronized spread-spectrum audio watermarking with improved psychoacoustic model, / Research Letters in Signal Processing, vol. 2008, Article ID 251868, 5 pages.
22. Chen, S-T, Huang, H-N, Chen, C-J, Wu, G-D (2010) Energy-proportion based scheme for audio watermarking. IET Proceedings on Signal Processing 4: pp. 576-587 CrossRef
23. Chen, S-T, Wu, G-D, Huang, H-N (2010) Wavelet-domain audio watermarking scheme using optimization-based quantization. IET Proceedings on Signal Processing 4: pp. 720-727 CrossRef
24. Lewis, FL (1986) Optimal control. John Wiley and Sons, New York
25. Chong, EKP, Zak, SH (2001) An introduction to optimization. John Wiley and Sons, Inc., New York
26. Salovarda, M., Bolkovac, I., & Domitrovic, H. (2005). Estimating perceptual audio system quality using PEAQ algorithm. In / 18 th International Conference on Applied Electromagnetics and Communications (IECCom2005) (pp. 1鈥?). doi:10.1109/ICECOM.2005.205017 .
27. http://www.opticom.de/technology/technology.html: PEAQ information from OPTICOM. - 刊物类别:Engineering
- 刊物主题:Electrical Engineering
Circuits and Systems
Computer Imaging, Vision, Pattern Recognition and Graphics
Computer Systems Organization and Communication Networks
Signal,Image and Speech Processing
Mathematics of Computing - 出版者:Springer New York
- ISSN:1939-8115
文摘
This work proposes a new blind digital audio watermarking system by using optimization-based modification on low-frequency amplitude of discrete wavelet transform (DWT). To modify the low-frequency amplitude under the best signal-to-noise ratio (SNR), the proposed embedding system minimizes the difference between the original and the embedded coefficients. Accordingly, an optimization-based embedding formula connecting the SNR and the embedding system is derived. The formula is then applied to embed the synchronization codes and the watermarks. Based on this formula, the number of DWT coefficients for embedding a binary bit can be increased to enhance the robustness without decreasing the audio quality. Consequently, the embedded audio has good quality and good robustness under high capacity. In addition, the system can extract the hidden data without the knowledge of original audio signal. Finally, the performance of the proposed watermarking method is tested. Experimental results indicate that the performance of proposed system is better than other DWT amplitude modification method.