Matching pursuits sinusoidal speech coding

Matching pursuits sinusoidal speech coding

This paper introduces a sinusoidal modeling technique for low bit rate speech coding wherein the parameters for each sinusoidal component are sequentially extracted by a closed-loop analysis. The sinusoidal modeling of the speech linear prediction (LP) residual is performed within the general framew...

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Bibliographic Details
Published in:IEEE transactions on speech and audio processing Vol. 11; no. 5; pp. 413 - 424
Main Authors: Etemoglu, C.O., Cuperman, V.
Format: Journal Article
Language:English
Published: New York, NY IEEE 01-09-2003
Institute of Electrical and Electronics Engineers
Subjects:
Applied sciences
Bit rate
Coders
Coding
Cutoff frequency
Data mining
Dictionaries
Exact sciences and technology
Frames
Frequency estimation
Functional analysis
Information, signal and communications theory
Matching
Matching pursuit algorithms
Mathematical analysis
Mathematical models
Predictive models
Signal processing
Speech
Speech analysis
Speech coding
Speech processing
Telecommunications and information theory
Vectors (mathematics)
Speech coding
Vector quantization
Matching pursuits
Signal synthesis
Signal analysis
Speech processing
Subjective evaluation
sinusoidal speech coding
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Summary:This paper introduces a sinusoidal modeling technique for low bit rate speech coding wherein the parameters for each sinusoidal component are sequentially extracted by a closed-loop analysis. The sinusoidal modeling of the speech linear prediction (LP) residual is performed within the general framework of matching pursuits with a dictionary of sinusoids. The frequency space of sinusoids is restricted to sets of frequency intervals or bins, which in conjunction with the closed-loop analysis allow us to map the frequencies of the sinusoids into a frequency vector that is efficiently quantized. In voiced frames, two sets of frequency vectors are generated: one of them represents harmonically related and the other one nonharmonically related components of the voiced segment. This approach eliminates the need for voicing dependent cutoff frequency that is difficult to estimate correctly and to quantize at low bit rates. In transition frames, to efficiently extract and quantize the set of frequencies needed for the sinusoidal representation of the LP residual, we introduce frequency bin vector quantization (FBVQ). FBVQ selects a vector of nonuniformly spaced frequencies from a frequency codebook in order to represent the frequency domain information in transition regions. Our use of FBVQ with closed-loop searching contribute to an improvement of speech quality in transition frames. The effectiveness of the coding scheme is enhanced by exploiting the critical band concept of auditory perception in defining the frequency bins. To demonstrate the viability and the advantages of the new models studied, we designed a 4 kbps matching pursuits sinusoidal speech coder. Subjective results indicate that the proposed coder at 4 kbps has quality exceeding the 6.3 kbps G.723.1 coder.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:1063-6676
1558-2353
DOI:10.1109/TSA.2003.815520