Asymptotic Optimal Quantizer Design for Distributed Bayesian Estimation

Xia Li; Jun Guo; Uri Rogers; Hao Chen

doi:10.1109/ICASSP.2016.7472370

Asymptotic Optimal Quantizer Design for Distributed Bayesian Estimation

Xia Li, Jun Guo, Uri Rogers, Hao Chen

Electrical Engineering Department

Research output: Chapter in Book/Report/Conference proceeding › Chapter

3 Scopus citations

Abstract

In this paper, we address the optimal quantizer design problem for distributed Bayesian parameter estimation with one-bit quantization at local sensors. A performance limit obtained for any distributed parameter estimator with a known prior is adopted as a guidance for quantizer design. Aided by the performance limit, the optimal quantizer and a set of noisy observation models that achieve the performance limit are derived. Further, when the performance limit may not be achievable for some applications, we develop a nearoptimal estimator which consists of a dithered noise and a single threshold quantizer. In the scenario where the parameter is Gaussian and signal-to-noise ratio is greater than −1.138 dB, we show that one can construct such an estimator that achieves approximately 99.65% of the performance limit.

Original language	American English
Title of host publication	2016 IEEE International Conference on Acoustics, Speech, and Signal Processing: Proceedings
DOIs	https://doi.org/10.1109/ICASSP.2016.7472370
State	Published - 1 Jan 2016

Keywords

Cramer-Rao lower bound
asymptotic performance limit
distributed Bayesian estimation
one-bit quantization
quantizer design

EGS Disciplines

Electrical and Computer Engineering

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10.1109/ICASSP.2016.7472370License: Unspecified

http://dx.doi.org/10.1109/ICASSP.2016.7472370

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title = "Asymptotic Optimal Quantizer Design for Distributed Bayesian Estimation",

abstract = " In this paper, we address the optimal quantizer design problem for distributed Bayesian parameter estimation with one-bit quantization at local sensors. A performance limit obtained for any distributed parameter estimator with a known prior is adopted as a guidance for quantizer design. Aided by the performance limit, the optimal quantizer and a set of noisy observation models that achieve the performance limit are derived. Further, when the performance limit may not be achievable for some applications, we develop a nearoptimal estimator which consists of a dithered noise and a single threshold quantizer. In the scenario where the parameter is Gaussian and signal-to-noise ratio is greater than −1.138 dB, we show that one can construct such an estimator that achieves approximately 99.65% of the performance limit.",

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AU - Rogers, Uri

AU - Chen, Hao

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N2 - In this paper, we address the optimal quantizer design problem for distributed Bayesian parameter estimation with one-bit quantization at local sensors. A performance limit obtained for any distributed parameter estimator with a known prior is adopted as a guidance for quantizer design. Aided by the performance limit, the optimal quantizer and a set of noisy observation models that achieve the performance limit are derived. Further, when the performance limit may not be achievable for some applications, we develop a nearoptimal estimator which consists of a dithered noise and a single threshold quantizer. In the scenario where the parameter is Gaussian and signal-to-noise ratio is greater than −1.138 dB, we show that one can construct such an estimator that achieves approximately 99.65% of the performance limit.

AB - In this paper, we address the optimal quantizer design problem for distributed Bayesian parameter estimation with one-bit quantization at local sensors. A performance limit obtained for any distributed parameter estimator with a known prior is adopted as a guidance for quantizer design. Aided by the performance limit, the optimal quantizer and a set of noisy observation models that achieve the performance limit are derived. Further, when the performance limit may not be achievable for some applications, we develop a nearoptimal estimator which consists of a dithered noise and a single threshold quantizer. In the scenario where the parameter is Gaussian and signal-to-noise ratio is greater than −1.138 dB, we show that one can construct such an estimator that achieves approximately 99.65% of the performance limit.

KW - Cramer-Rao lower bound

KW - asymptotic performance limit

KW - distributed Bayesian estimation

KW - one-bit quantization

KW - quantizer design

UR - https://scholarworks.boisestate.edu/electrical_facpubs/333

UR - http://dx.doi.org/10.1109/ICASSP.2016.7472370

U2 - 10.1109/ICASSP.2016.7472370

DO - 10.1109/ICASSP.2016.7472370

M3 - Chapter

BT - 2016 IEEE International Conference on Acoustics, Speech, and Signal Processing: Proceedings

ER -

Asymptotic Optimal Quantizer Design for Distributed Bayesian Estimation

Abstract

Keywords

EGS Disciplines

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