A Unified Carnot Thermodynamic and Shannon Channel Capacity Information-Theoretic Energy Efficiency Analysis

Author

Parker, Michael C. ; Walker, Stuart D.

Author_Institution

Sch. of Comput. Sci. & Electron. Eng., Univ. of Essex, Colchester, UK

Volume

62

Issue

10

fYear

2014

fDate

Oct. 2014

Firstpage

3552

Lastpage

3559

Abstract

In this paper we employ the Shannon channel capacity theorem and classical thermodynamic Carnot´s Law to derive the kT ln 2 minimum energy dissipation per bit for a communications channel. We then extend the analysis, incorporating forward error correction (FEC) to show an asymptotic energy efficiency approach to the Carnot/Shannon limit. For the first time, we derive a generalized version of the Shannon channel capacity theorem which embraces non-Gaussian noise statistics. Finally, we apply the theory to different telecommunications technologies, thus offering commonality of absolute energy efficiency assessment.

Keywords

Carnot cycle; Gaussian noise; channel capacity; energy conservation; forward error correction; statistical analysis; FEC; Shannon channel capacity information-theoretic energy efficiency analysis; asymptotic energy efficiency approach; communication channel; forward error correction; minimum energy dissipation; nonGaussian noise statistics; telecommunication technology; thermodynamic Carnot´s Law; unified carnot thermodynamic; Channel capacity; Energy efficiency; Engines; Entropy; Noise; Reservoirs; Thermodynamics; Carnot law; Energy efficiency; Shannon capacity theorem; communications; noise; thermodynamics;

fLanguage

English

Journal_Title

Communications, IEEE Transactions on

Publisher

ieee

ISSN

0090-6778

Type

jour

DOI

10.1109/TCOMM.2014.2351412

Filename

6882211