Title :
10-GHz 1.3-ps pulse generation using chirped soliton compression in a Raman gain medium
Author_Institution :
Lincoln Lab., MIT, Lexington, MA, USA
Abstract :
The authors demonstrate a novel pulse compression technique that is capable of producing high-quality 1.3-ps pulses at a repetition rate of 10 GHz. The technique begins with 20-ps pulses carved by a commercially available external modulator and achieves up to 15-fold compression using a combination of phase modulation and distributed Raman amplification. Unlike adiabatic soliton compression, the scheme takes advantage of an exact solution to the nonlinear Schrodinger equation for chirped soliton evolution. As such, high-quality low-pedestal compressed pulses can be produced in a shorter span of fiber than would be needed for adiabatic compression. Because the system uses external modulation, the source is inherently tunable. Furthermore, the degree of pulse compression can be adjusted by varying the amount of Raman gain and phase modulation.
Keywords :
Raman lasers; Schrodinger equation; chirp modulation; electro-optical modulation; optical fibre amplifiers; optical pulse compression; optical pulse generation; optical solitons; phase modulation; 1.3 ps; 15-fold compression; 20 ps; 20-ps pulses; Raman gain; Raman gain medium; adiabatic compression; chirped soliton compression; chirped soliton evolution; distributed Raman amplification; electroabsorption modulator; exact solution; external modulation; external modulator; high-quality 1.3-ps pulses; high-quality low-pedestal compressed pulses; inherently tunable source; nonlinear Schrodinger equation; phase modulation; pulse compression technique; pulse generation; repetition rate; shorter fiber span; Chirp; Nonlinear equations; Optical pulse compression; Optical pulses; Pulse amplifiers; Pulse compression methods; Pulse generation; Pulse modulation; Solitons; Space vector pulse width modulation;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2002.801828
