article

Design of Fixed and Adaptive Companding Quantizer with Variable-Length Codeword for Memoryless Gaussian Source

Authors:

Zoran H. Perić,

Jelena R. Nikolić,

Aleksandar V. Mosić,

Marko D. PetkovićAuthors Info & Claims

Informatica, Volume 24, Issue 1

Pages 71 - 86

Published: 01 January 2013 Publication History

Abstract

The problem we address in this paper is the design of a quantizer that in comparison to the classical fixed-rate scalar quantizers provides more sophisticated bit rate reduction while restricting the class of quantizers to be scalar. We propose a switched variable-length code (VLC) optimal companding quantizer composed of two optimal companding scalar quantizers, the inner and the outer one, both designed for the memoryless Gaussian source of unit variance. Quantizers composing the proposed quantizer have a different codebook sizes and a different compressor functions. Particularly, we assume a smaller size of the inner quantizer's codebook in order to provide assignment of the shorter codewords to the high probability low amplitude speech samples belonging to the support region of the inner quantizer. We study the influence of codebook size of the inner and the outer quantizer on the Signal to Quantization Noise Ratio (SQNR). In such a manner the conclusion of the proposed quantizer significance in speech compression is distinctly shown in the paper. For the proposed quantizer model and its forward adaptive version the SQNR robustness analysis in a wide variance range is also presented in the paper. It is shown that our multi-resolution quantizer can satisfy G.712 Recommendation for high-quality quantization at the bit rate of 6.3 bit/sample achieving the compression of 1.7 bit/sample over the G.711 quantizer.

References

[1]

Bennett, W.R. (1948). Spectra of quantized signals. The Bell Systems Technical Journal , 27, 446-472.

[2]

Garofolo, J.S., Lamel, F.L., Fisher, W.M., Fiscus, J.G., Pallett, D.S., Dahlgren, N.L. (1993). The DARPA TIMIT acoustic-phonetic continuous speech corpus. CD-ROM: NTIS .

[3]

Gersho, A., Gray, R.M. (1992). Vector Quantization and Signal Compression . Kluwer, Norwell.

[4]

Hanzo, L., Somerville, C., Woodard, J. (2007). Voice and Audio Compression for Wireless Communications . Wiley/IEEE Press, New York.

[5]

Hiwasaki, Y., Ohmuro, H., Mori, T., Kurihara, S., Kataoka, A. (2006). A G.711 embedded wideband speech coding for VoIP conferences. Transactions on Info and Systems (IEICE) , E89-D(9), 2542-2552.

Digital Library

[6]

Hiwasaki, Y. et al. (2008). G.711: a wideband extension to ITU-T G.711. In: Proceedings of EUSIPCO'08 , Lausanne, Switzerland.

[7]

Hiwasaki, Y., Mori, T., Sasaki, S., Ohmuro, H., Kataoka, A. (2008). A wideband speech and audio coding candidate for ITU-T G.711 WBE standardization. In: ICASSP 2008 .

[8]

ITU-T, Recommendation G.711. (1972). Pulse Code Modulation (PCM) of Voice Frequencies .

[9]

ITU-T, Recommendation G.712. (2001). Transmission Performance Characteristics of Pulse Code Modulation Channels .

[10]

Jayant, N.S., Noll, P. (1984). Digital Coding of Waveforms . Prentice-Hall, New Jersey.

[11]

Judell, N., Scharf, L. (1986). A simple derivation of Lloyd's classical result for the optimum scalar quantizer. IEEE Transactions on Information Theory , 32(2), 326-328.

Digital Library

[12]

Kondoz, A. (2004). Digital Speech Coding for Low Bit Rate Communication Systems . Wiley, New York.

[13]

Max, J., (1960). Quantizing for minimum distortion. In: IRE, Transactions on Information Theory , Vol. IT-6, pp. 7-12.

[14]

Na, S. (2008). Asymptotic formulas for mismatched fixed-rate minimum MSE Laplacian quantizers. Signal Processing Letters (IEEE) , 15, 13-16.

[15]

Na, S. (2011). Asymptotic formulas for variance-mismatched fixed-rate scalar quantization of a Gaussian source. IEEE Transactions on Signal Processing , 59(5), 2437-2441.

[16]

Nikolic, J., Peric, Z. (2008). Lloyd-Max's algorithm implementation in speech coding based on forward adaptive technique. Informatica , 19(2), 255-270.

Digital Library

[17]

Peric, Z., Nikolic, J. (2007). An effective method for initialization of Lloyd-Max's algorithm of optimal scalar quantization for Laplacian source. Informatica , 18(2), 279-288.

Digital Library

[18]

Peric, Z., Petkovic, M., Dincic, M. (2009). Simple compression algorithm for memoryless Laplacian source based on the optimal companding technique. Informatica , 20(1), 99-114.

Digital Library

[19]

Peric, Z., Savic, M., Dincic, M., Denic, D., Prascevic, M. (2010). Forward adaptation of novel semilogarithmic quantizer and lossless coder for speech signals compression. Informatica , 21(3), 375-391.

Digital Library

[20]

Peric, Z., Mosic, A., Panic, S. (2008). Robust and switched nonuniform scalar quantization of Gaussian source in a wide dinamic range of power. Automatic Control and Computer Science , 42(6), 334-341.

[21]

Peric, Z., Nikolic, J., Mosic, A., Panic, S. (2010). A switched-adaptive quantization technique using µ-law quantizers. Information Technology and Control , 39(4), 317-320.

[22]

Sayood, K. (2006). Introduction to Data Compression . Elsevier, Amsterdam.

Cited By

Delić VPerić ZSečujski MJakovljević NNikolić JMišković DSimić NSuzić SDelić T(2019)Speech Technology Progress Based on New Machine Learning ParadigmComputational Intelligence and Neuroscience10.1155/2019/43680362019Online publication date: 25-Jun-2019
https://dl.acm.org/doi/10.1155/2019/4368036
Nikolić JPerić ZJovanović A(2016)Two forward adaptive dual-mode companding scalar quantizers for Gaussian sourceSignal Processing10.1016/j.sigpro.2015.08.016120:C(129-140)Online publication date: 1-Mar-2016
https://dl.acm.org/doi/10.1016/j.sigpro.2015.08.016

Design of Fixed and Adaptive Companding Quantizer with Variable-Length Codeword for Memoryless Gaussian Source
1. Information systems
  1. Data management systems
    1. Data structures
      1. Data layout

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cover image Informatica

Informatica Volume 24, Issue 1

January 2013

168 pages

ISSN:0868-4952

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IOS Press

Netherlands

Publication History

Published: 01 January 2013

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Cited By

Delić VPerić ZSečujski MJakovljević NNikolić JMišković DSimić NSuzić SDelić T(2019)Speech Technology Progress Based on New Machine Learning ParadigmComputational Intelligence and Neuroscience10.1155/2019/43680362019Online publication date: 25-Jun-2019
https://dl.acm.org/doi/10.1155/2019/4368036
Nikolić JPerić ZJovanović A(2016)Two forward adaptive dual-mode companding scalar quantizers for Gaussian sourceSignal Processing10.1016/j.sigpro.2015.08.016120:C(129-140)Online publication date: 1-Mar-2016
https://dl.acm.org/doi/10.1016/j.sigpro.2015.08.016

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