Title :
Mitigation of EEPN in Coherent Optical Systems With Low-Speed Digital Coherence Enhancement
Author :
Kakkar, Aditya ; Navarro, Jaime Rodrigo ; Schatz, Richard ; Xiaodan Pang ; Ozolins, Oskars ; Louchet, Hadrien ; Jacobsen, Gunnar ; Popov, Sergei
Author_Institution :
Opt. & Photonics Div., R. Inst. of Technol., Stockholm, Sweden
Abstract :
A method for mitigating local oscillator (LO) phase noise-induced impairment, also known as equalization-enhanced phase noise, in coherent optical systems is discussed. The method is suitable for real-time implementation and requires hardware with a bandwidth much lower than the signal baud rate, even for a system utilizing conventional semiconductor laser as LO. We evaluate the required parameters like interpolation technique, electrical signal-to-noise ratio at digital coherence enhancement (DCE) front end, for long haul transmission links having quadrature phase shift keying and 16-quadrature amplitude modulation formats. We show that the method can be implemented using a low-speed DCE front end and a simple digital linear interpolator with small (<;1 dB) implementation penalty even in cases that would otherwise result in error floor.
Keywords :
interpolation; light coherence; optical communication equipment; optical elements; optical links; optical modulation; optical noise; phase noise; quadrature amplitude modulation; quadrature phase shift keying; 16-quadrature amplitude modulation formats; EEPN mitigation; coherent optical systems; digital coherence enhancement front end; digital linear interpolator; electrical signal-to-noise ratio; equalization-enhanced phase noise; local oscillator phase noise-induced impairment mitigation; long haul transmission links; low-speed digital coherence enhancement; quadrature phase shift keying; semiconductor laser; Bandwidth; Dispersion; Hardware; Interpolation; Optical noise; Phase noise; Coherent receivers; coherent receivers; equalization-enhanced phase noise; laser linewidth; optical communication; quadrature amplitude modulation (QAM);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2015.2447839
