The development of ultrashort optical pulse sources, exhibiting excellent temporal and spectral profiles, will play a crucial role in the performance of future optical time division multiplexed (OTDM) systems. In this paper, we demonstrate the difference in performance in 40- and 80-Gb/s OTDM systems between optical pulse sources based on a gain-switched laser whose pulses are compressed by a nonlinearly and linearly chirped fiber Bragg grating. The results achieved show that nonlinear chirp in the wings of the pulse leads to temporal pedestals formed on either side of the pulse when using the linearly chirped grating, whereas with the nonlinearly chirped grating, pedestals are essentially eliminated. In an OTDM system, these pedestals cause coherent interaction between neighboring channels, resulting in intensity fluctuations that lead to a power penalty of 1.5 dB (40 Gb/s) and 3.5 dB (80 Gb/s) in comparison to the case where the nonlinearly chirped grating is used. Simulations carried out with the aid of Virtual Photonics Inc. verify the results achieved

Anandarajah, Prince M.

Barry, Liam P.

Bramerie, Laurent

Clarke, Aisling M.

Guignard, Celine

Harvey, John D.

Simon, Jean Claude

English

DCU Online Research Access Service

(M’98) received the B.E. degree in electronic engineering and the M.Eng.Sc. degree in optical communications from the University College

[19] M.C.Gross,M.Hanna,K.M.Patel,andS.E.Ralph,“Reductionofpower ﬂuctuations in ultrafast optically time-division-multiplexed pulse trainsby use of a nonlinear amplifying loop mirror,”

[29] J.SkaarandO.H.Waagaard,“Design andcharacterization ofﬁnite-length ﬁber gratings,”

160 Gb/s OTDM signal source with 3R function utilizing ultrafast mode-locked laser diodes and modiﬁed

40 Gb/s directly modulated InGaAsP passive feedback DFB laser,” in

A highspeed optical star network using TDMA and all-optical demultiplexing techniques,”

All-optical signal processing for terabit/second optical transmission,”

Anandarajah (S’00–M’04) received the B.Eng. degree in electronic engineering from the

Bramerie received the optoelectronic engineering degree from ENSSAT,UniversityofRennesI,Rennes,France,in1999,andthePh.D.degree in

Clarke (S’03) received the B.Eng. degree in electronic engineering in 2002 from

Compact and fully packaged ﬁbre grating laser-based RZ pulse source for 40 Gb/s OTDM transmission systems,” in

Complete characterization of terahertz pulse trains generated from nonlinear process in optical ﬁbers,”

Complete characterization of ultrashort pulse sources at 1550 nm,”

Experimental demonstration of compression of dispersed optical pulses by reﬂection from self-chirped optical ﬁbre Bragg gratings,”

Extinction ratio improvement by strong external light injection and SPM in an SOA for OTDM pulse source using a DBR laser diode,”

Fibre grating laserbased RZ pulse source for 40 Gb/s OTDM transmission systems,”

Gainswitched DFB laser diode pulse source using continuous wave light injection for Jitter suppression and an electroabsorption modulator for pedestal suppression,”

Generation of transform limited gain-switched DFB-LD pulses < 6 ps with linear ﬁbre compression and spectral window,”

Generation of widely tunable picosecond pulses with large SMSR by externally injecting a gain switched dual laser source,”

Harvey (M’76) received the B.Sc. and M.Sc. degrees from the

he joined France Telecom’s Research Laboratories (CNET), Lannion, France, which is the Research Center of the French PTT (now France Telecom), for his thesis work. In

he was a Research Engineer with the Optical Systems Department, France Telecom’s Research Laboratories,

He worked in France as a Technical Expert on ultralong haul 40-Gb/s dense-wavelength-division-multiplexing systems for two years with the Corvis Algety,

Inverse scattering algorithm for reconstructing strongly reﬂecting ﬁber Bragg gratings,”

Measuring ultrashort laser pulses in the time-frequency domain using frequency-resolved optical gating,”

Method of generating nearly transform-limited pulses from gain-switched distributed-feedback laser diodesanditsapplicationtosoliton transmission,”

Optical time division multiplexing: Systems and networks,”

Optimized pulse source for 40-Gb/s systems based on a gain switched-laser diode in conjunction with a nonlinearly chirped grating,”

Picosecond and nanosecond sources generation of a 2.5 ps pedestal-free optical pulse using a 10 GHz gain-switched laser and a compressing nonlinear amplifying loop mirror,” in

received the Eng. degree in optronics in 2001, the Masters degree in sciences and techniques of communications (D.E.A.) in optics communications,

she has been a Postdoctoral Researcher with the Radio and Optical

Simon received the Ph.D. degree from the University d’Orsay,

Solitons for breaking barriers to terabit/second WDM and OTDM transmission in the next millennium,”

Subpicosecond pulse generation using an electroabsorption modulator and a double-stage pulse compressor,”

The effects of pedestal suppression on gain-switched laser sources for 40 Gb/s OTDM transmission,” in

Timing jitter reduction of gainswitched DFB laser by external injection seeding,”

to 1997, he was an Instructor/ Maintenance Engineer with the Aeronautical Telecommunications Department, Nigerian College of Aviation Technology,

Tunable transform limited pulse generation using self-injection locking of an

System-performance analysis of optimized gain-switched pulse source employed in 40-and 80-Gb/s OTDM systems

Name not available

Prince M. Anandarajah

Aisling M. Clarke

Celine Guignard

Laurent Bramerie

Liam P. Barry

John D. Harvey

Jean Claude Simon

Crossref

System-Performance Analysis of Optimized Gain-Switched Pulse Source Employed in 40- and 80-Gb/s OTDM Systems

International audienceThe development of ultrashort optical pulse sources, exhibiting excellent temporal and spectral profiles, will play a crucial role in the performance of future optical time division multiplexed (OTDM) systems. In this paper, we demonstrate the difference in performance in 40- and 80-Gb/s OTDM systems between optical pulse sources based on a gain-switched laser whose pulses are compressed by a nonlinearly and linearly chirped fiber Bragg grating. The results achieved show that nonlinear chirp in the wings of the pulse leads to temporal pedestals formed on either side of the pulse when using the linearly chirped grating, whereas with the nonlinearly chirped grating, pedestals are essentially eliminated. In an OTDM system, these pedestals cause coherent interaction between neighboring channels, resulting in intensity fluctuations that lead to a power penalty of 1.5 dB (40 Gb/s) and 3.5 dB (80 Gb/s) in comparison to the case where the nonlinearly chirped grating is used. Simulations carried out with the aid of Virtual Photonics Inc. verify the results achieved

System-performance analysis of optimized gain-switched pulse source employed in 40-and 80-Gb/s OTDM systems

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