CFP last date
20 May 2024
Call for Paper
June Edition
IJCA solicits high quality original research papers for the upcoming June edition of the journal. The last date of research paper submission is 20 May 2024

Submit your paper
Know more
The week's pick
Responsive image
Enhancing Privacy Preservation: Multi-Attribute Protection with P-Sensitive K-Anonymity

Twinkle Patel Kiran Amin
Random Articles
Reseach Article

Analysis of Music Signal Compression with Compressive Sensing

by Urvashi P. Shukla, Niteen B. Patel, Amit M. Joshi
journal cover thumbnail

International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
Volume 70 - Number 26
Year of Publication: 2013
Authors: Urvashi P. Shukla, Niteen B. Patel, Amit M. Joshi
10.5120/12229-8341

Urvashi P. Shukla, Niteen B. Patel, Amit M. Joshi . Analysis of Music Signal Compression with Compressive Sensing. International Journal of Computer Applications. 70, 26 ( May 2013), 5-9. DOI=10.5120/12229-8341

@article{ 10.5120/12229-8341,
author = { Urvashi P. Shukla, Niteen B. Patel, Amit M. Joshi },
title = { Analysis of Music Signal Compression with Compressive Sensing },
journal = { International Journal of Computer Applications },
issue_date = { May 2013 },
volume = { 70 },
number = { 26 },
month = { May },
year = { 2013 },
issn = { 0975-8887 },
pages = { 5-9 },
numpages = {9},
url = { https://ijcaonline.org/archives/volume70/number26/12229-8341/ },
doi = { 10.5120/12229-8341 },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Journal Article
%1 2024-02-06T21:33:53.081976+05:30
%A Urvashi P. Shukla
%A Niteen B. Patel
%A Amit M. Joshi
%T Analysis of Music Signal Compression with Compressive Sensing
%J International Journal of Computer Applications
%@ 0975-8887
%V 70
%N 26
%P 5-9
%D 2013
%I Foundation of Computer Science (FCS), NY, USA
Abstract

Music signal processing has matured over the years. Most of the techniques applied to music signal were originally developed for speech signal; the results observed have been quite satisfactory. In music domain, there are lot many challenges faced with respect to the storage and transmission of large data base. In this paper, we try to address the above stated problems with help of growing compressive sensing field. The aim is to extract the features of the signal with aid of the basis which will in turn reduce the number of samples to be stored or transmitted. Also, our goal is to successfully demonstrate the recovery of the signal without hampering the inner characteristics and the melody of the signal.

References
  1. Pertusa, A. , & Inesta, J. M. Efficient methods for joint estimation of multiple fundamental frequencies in music signals. EURASIP Journal on Advances in Signal Processing, 2012(1), pp. 1-13. 2012.
  2. Meinard Müller, Daniel P. W. Ellis, ,Anssi Klapuri and Gaël Richard, Signal Processing for Music Analysis, IEEE Journal Of Selected Topics In Signal Processing, 5(6), pp. 1088-1110, October 2011
  3. Chunghsin Yeh, Axel Roebel and Xavier Rodet,Multiple Fundamental Frequency Estimation and Polyphony Inference of Polyphonic Music Signals, IEEE transactions on audio, speech, and language processing, 18(6), August 2010
  4. Ram K. Nawasalkar, Nilesh M. Shingnapure, Pradeep K. Butey, Extracting Melodic Pattern of 'Mohan Veena' from Polyphonic Audio Signal of North Indian Classical Music, International Journal of Computer Applications ,Recent Trends in Engineering Technology,pp-0975 – 8887, 2013
  5. Naveen Kumar, User Authentication using Musical Password, International Journal of Computer Applications,59(9), pp-0975 – 8887,December 2012
  6. Alamgir Naushad, Tufail Muhammad,Condition Driven Adaptive Music Generation for Computer Games, International Journal of Computer Applications,64( 8),pp-0975 – 8887, February 2013
  7. Zou, Zhenghua, Xinji Liu, and Shu-Tao Xia. "A comparative study of wavelets and adaptively learned dictionary in compressive image sensing. " In Signal Processing (ICSP), 2012 IEEE 11th International Conference on, vol. 2, pp. 811-815, 2012.
  8. G. R. G. Baraniuk, Compressive sensing, IEEE Signal Process. Mag. , 24(4), pp. 118–120, Jul. 2007.
  9. D. Monajemi, Hatef, Sina Jafarpour, Matan Gavish, David L. Donoho, Sivaram Ambikasaran, Sergio Bacallado, Dinesh Bharadia et al. "Deterministic matrices matching the compressed sensing phase transitions of Gaussian random matrices. " Proceedings of the National Academy of Sciences 110, no. 4: 1181-1186,2013.
  10. E. Rauhut, Holger. "Compressive sensing and structured random matrices. " Theoretical foundations and numerical methods for sparse recovery 9 (2010):pp. 1-92. ,2010.
  11. S. Archana, K. A. Narayanankutty, Anand Kumar, Brain Mapping using Compressed Sensing with Graphical Connectivity Maps, International Journal of Computer Applications, pp. 0975 – 8887, 54(11), September 2012
  12. Candès, Oppenheim, J. N. , & Magnasco, M. O. (2013). Human Time-Frequency Acuity Beats the Fourier Uncertainty Principle. Physical Review Letters, 110(4), 044301, 2013.
  13. Sun, G. , Zhou, Y. , Wang, Z. , Dang, W. , & LI, Z. (2012). Sparsity Adaptive Compressive Sampling Matching Pursuit Algorithm Based on Compressive Sensing. Journal of Computational Information Systems, 7(4), pp. 2883-2890,2012.
Index Terms

Computer Science
Information Sciences

Keywords

Basis matrices Discrete Fourier Transform Measurement matrix Music signal Recovery algorithm

Powered by PhDFocusTM