An advanced split-step method is employed for the digital backward-propagation (DBP) method using the coupled nonlinear Schrodinger equations for the compensation of inter-channel nonlinearities. Compared to the conventional DBP, cross-phase modulation (XPM) can be efficiently compensated by including the effect of the inter-channel walk-off in the nonlinear step of the split-step method (SSM). While self-phase modulation (SPM) compensation is inefficient in WDM systems, XPM compensation is able to increase the transmission reach by a factor of 2.5 for 16-QAM-modulated signals. The advanced SSM significantly relaxes the step size requirements resulting in a factor of 4 reduction in computational load
We demonstrate nonlinearity compensation of 37.5-GHz-spaced 128-Gb/s PDM-QPSK signals using dispersi...
Distributed compensation for cross-phase modulation (XPM) by solving the coupled nonlinear Schro di...
This chapter describes a universal postcompensation scheme to compensate all deterministic impairmen...
Interchannel nonlinear impairments are one of the major limitations to the channel capacity and tran...
A comprehensive treatment of digital backward propagation (DBP) accounting for the vectorial nature ...
An improved digital backward propagation (DBP) is proposed to compensate inter-nonlinear effects and...
Enhanced coupled-nonlinear equations are introduced for full compensation of cross-phase modulation ...
Enhanced coupled-nonlinear equations are introduced for full compensation of cross-phase modulation ...
An improved split-step method (SSM) for digital backward propagation (DBP) applicable to wavelength-...
We review the latest advances on digital backward-propagation for the compensation of inter-channel ...
We present results of nonlinear compensation achieved by digital backward-propagation (DBP) for next...
A computationally efficient dispersion-folded (D-folded) digital backward propagation (DBP) method f...
Distributed compensation for cross-phase modulation (XPM) by solving the coupled nonlinear Schröding...
We investigate a digital back-propagation simplification method to enable computationally-efficient ...
Using digital backpropagation (DBP) based on the split step Fourier method (SSFM) aided by a memory ...
We demonstrate nonlinearity compensation of 37.5-GHz-spaced 128-Gb/s PDM-QPSK signals using dispersi...
Distributed compensation for cross-phase modulation (XPM) by solving the coupled nonlinear Schro di...
This chapter describes a universal postcompensation scheme to compensate all deterministic impairmen...
Interchannel nonlinear impairments are one of the major limitations to the channel capacity and tran...
A comprehensive treatment of digital backward propagation (DBP) accounting for the vectorial nature ...
An improved digital backward propagation (DBP) is proposed to compensate inter-nonlinear effects and...
Enhanced coupled-nonlinear equations are introduced for full compensation of cross-phase modulation ...
Enhanced coupled-nonlinear equations are introduced for full compensation of cross-phase modulation ...
An improved split-step method (SSM) for digital backward propagation (DBP) applicable to wavelength-...
We review the latest advances on digital backward-propagation for the compensation of inter-channel ...
We present results of nonlinear compensation achieved by digital backward-propagation (DBP) for next...
A computationally efficient dispersion-folded (D-folded) digital backward propagation (DBP) method f...
Distributed compensation for cross-phase modulation (XPM) by solving the coupled nonlinear Schröding...
We investigate a digital back-propagation simplification method to enable computationally-efficient ...
Using digital backpropagation (DBP) based on the split step Fourier method (SSFM) aided by a memory ...
We demonstrate nonlinearity compensation of 37.5-GHz-spaced 128-Gb/s PDM-QPSK signals using dispersi...
Distributed compensation for cross-phase modulation (XPM) by solving the coupled nonlinear Schro di...
This chapter describes a universal postcompensation scheme to compensate all deterministic impairmen...