Linear and non-linear montecarlo approximations of analog joint source-channel coding under generic probability distributions

Author

Davoli, Franco ; Mongelli, Maurizio

Author_Institution

Dept. of Electr., Electron. & Telecommun. Eng., & Naval Archit., Univ. of Genova, Genoa, Italy

fYear

2014

fDate

12-15 Nov. 2014

Firstpage

1

Lastpage

6

Abstract

A distributed estimation setting is considered, where a number of sensors transmit their observations of a physical phenomenon, described by one or more random variables, to a sink over noisy communication channels. The goal is to minimize a quadratic distortion measure (Minimum Mean Square Error - MMSE) under a global power constraint on the sensors´ transmissions. Both linear MMSE encoders and decoders, parametrically optimized in encoders´ gains, and non-linear parametric functional approximators (neural networks) are investigated and numerically compared, highlighting subtle differences in sensitivity and achievable performance.

Keywords

Monte Carlo methods; combined source-channel coding; decoding; least mean squares methods; statistical distributions; wireless channels; wireless sensor networks; MMSE decoder; analog joint source-channel coding; generic probability distribution; global power constraint; linear MMSE encoder; linear Monte Carlo approximation; linear parametric functional approximator; minimum mean square error; noisy communication channel; nonlinear Monte Carlo approximation; quadratic distortion measure minimization; wireless sensor network; Approximation methods; Decoding; Encoding; Minimization; Nonlinear distortion; Optimization; Sensors;

fLanguage

English

Publisher

ieee

Conference_Titel

Euro Med Telco Conference (EMTC), 2014

Conference_Location

Naples

Print_ISBN

978-8-8872-3721-4

Type

conf

DOI

10.1109/EMTC.2014.6996642

Filename

6996642