Title :
The Shannon channel capacity of dispersion-free nonlinear optical fiber transmission
Author_Institution :
Bell. Labs. Lucent Technol., Holmdel, NJ, USA
fDate :
8/1/2001 12:00:00 AM
Abstract :
We extend the Shannon information theory to a nonlinear system and present a model for calculating the channel capacity of an optical-fiber transmission system using dispersion-free fiber. For this particular fiber, a closed-form solution for the nonlinear Schroedinger equation exists. This allows us to derive an analytical result for the channel capacity that is exact and valid for arbitrary input power. We will study the single-span case and examine the dependence of the capacity on operating input power, the number of channels (Nc), the noise power (PW), etc. The maximum capacity is shown to follow a simple scaling law with log2(1+CNc-2/3P W-2/3) dependence, multiplexing (WDM) systems
Keywords :
Schrodinger equation; channel capacity; information theory; nonlinear optics; optical fibre communication; optical noise; wavelength division multiplexing; Shannon channel capacity; Shannon information theory; WDM systems; arbitrary input power; channel capacity; closed-form solution; dispersion-free fiber; dispersion-free nonlinear optical fiber transmission; maximum capacity; multiplexing systems; noise power; nonlinear Schroedinger equation; nonlinear system; operating input power; optical-fiber transmission system; scaling law; Channel capacity; Closed-form solution; Fiber nonlinear optics; Information theory; Nonlinear equations; Nonlinear optics; Nonlinear systems; Optical fiber theory; Power system modeling; Wavelength division multiplexing;
Journal_Title :
Lightwave Technology, Journal of
