Title :
10-GHz clock recovery using an optoelectronic phase-locked loop based on three-wave mixing in periodically poled lithium niobate
Author :
Agis, Fausto Gómez ; Ware, Cédric ; Erasme, Didier ; Ricken, Raimund ; Quiring, Viktor ; Sohler, Wolfgang
fDate :
7/1/2006 12:00:00 AM
Abstract :
Clock recovery is a critical function of any digital communications system. To replace the classical electronic phase-locked loops (PLLs) at higher bit rates, several all-optical or optoelectronic clock recovery methods are being studied. This letter presents an optoelectronic PLL where three-wave mixing in a periodically poled lithium niobate (PPLN) device provides the phase comparator. Since PPLN is passive, it generates no amplified spontaneous emission noise; also, the error signal is in the visible (763 nm), therefore easily separated from infrared input signals. Clock recovery is performed on a 10-GHz sinusoidal optical signal. Being based on ultrafast nonlinear effects, this scheme should be able to reach still higher bit rates, on the order of several hundred gigahertz. Also, subclock extraction (e.g., 40-to-10 GHz) should be possible without modifications.
Keywords :
high-speed optical techniques; lithium compounds; multiwave mixing; optical fibre communication; optical materials; optical phase locked loops; synchronisation; 10 GHz; 763 nm; LiNbO3; amplified spontaneous emission noise; clock recovery; optoelectronic phase-locked loop; periodically poled lithium niobate; phase comparator; subclock extraction; three-wave mixing; ultrafast nonlinear effects; Bit rate; Clocks; Digital communication; Lithium niobate; Noise generators; Nonlinear optical devices; Optical noise; Phase locked loops; Signal generators; Spontaneous emission; Clock recovery; optical signal processing; periodically poled lithium niobate (PPLN); phase-locked loops (PLLs); three-wave mixing (TWM);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.877586
