Gaussian Source Coding using a Simple Switched Quantization Algorithm and Variable Length Codewords

Gaussian Source Coding using a Simple Switched Quantization Algorithm and Variable Length Codewords

This paper introduces an algorithm based on switched scalar quantization utilizing a novel μ-law quantization model (optimized in terms of minimal distortion) and variable length codewords, for high-quality encoding of the signals modeled by Gaussian distribution. The implemented μ-law quantizer rep...

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Bibliographic Details
Published in:Advances in electrical and computer engineering Vol. 20; no. 4; pp. 11 - 18
Main Authors: PERIC, Z., PETKOVIC, G., DENIC, B., STANIMIROVIC, A., DESPOTOVIC, V., STOIMENOV, L.
Format: Journal Article
Language:English
Published: Suceava Stefan cel Mare University of Suceava 01-11-2020
Subjects:
Algorithms
Codes
Gaussian distribution
Measurement
Normal distribution
quantization
Signal processing
signal processing algorithms
Signal quality
signal to noise ratio
source coding
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Summary:This paper introduces an algorithm based on switched scalar quantization utilizing a novel μ-law quantization model (optimized in terms of minimal distortion) and variable length codewords, for high-quality encoding of the signals modeled by Gaussian distribution. The implemented μ-law quantizer represents an improvement of the standard μ-law quantizer in terms of bit rate, at the same time providing the equal signal quality. The main concept of the algorithm is to divide the range of the input signal variances into a certain number of sub-ranges, and to design the optimal quantizer for each sub-range. The signal is processed frame-by-frame, and for each frame the best performing quantizer is chosen, where the estimated frame variance is used as the switching criterion. Theoretical results indicate that the proposed algorithm achieves performance comparable to the standard μ-law quantizer, enabling the compression of about 0.5 bit/sample. The simulation results are provided to confirm the correctness of the proposed model.
ISSN:1582-7445
1844-7600
DOI:10.4316/AECE.2020.04002