Title :
Highly reliable and high-yield 1300-nm InGaAlAs directly modulated ridge fabry-Perot lasers, operating at 10-gb/s, up to 110°C, with constant current swing
Author :
Paoletti, Roberto ; Agresti, Michele ; Bertone, Daniele ; Bianco, L. ; Bruschi, C. ; Buccieri, A. ; Campi, Roberta ; Dorigoni, C. ; Gotta, Paola ; Liotti, Manuela ; Magnetti, Gloria ; Montangero, P. ; Morello, G. ; Rigo, C. ; Riva, E. ; Rossi, G. ; Soders
Author_Institution :
TTC-Agilent Technol., Turin, Italy
Abstract :
Transceivers for 300-m multimode links, based on a serial 10-Gb/s laser source and incorporating a receiver based on electronic dispersion compensation (EDC), are creating the first high-volume application for a 10-Gb Fabry-Perot (FP). A highly reliable and high-yield uncooled ridge FP laser is presented. The device shows excellent power characteristics in the 25÷150°C temperature range with very high T0 (95 K in the temperature range 0÷85°C and still 78 K at 150°C). Outstanding dynamic performances are also shown: 6 dB of extinction ratio can be achieved up to 110°C by using a constant current swing of 50 mA. Because of their enhanced performances, these devices have enabled single temperature setting of the optical module, leading to a significant test cost reduction.
Keywords :
III-V semiconductors; aluminium compounds; gallium arsenide; gallium compounds; indium compounds; optical communication equipment; optical fibre communication; optical fibre dispersion; optical modulation; semiconductor device reliability; semiconductor lasers; thermo-optical effects; transceivers; 0 to 150 degC; 10 Gbit/s; 1300 nm; 300 m; 50 mA; Fabry-Perot lasers; InGaAlAs; InGaAlAs lasers; constant current swing; directly modulated lasers; electronic dispersion compensation; extinction ratio; high-volume application; high-yield lasers; highly reliable lasers; multimode links; optical module; ridge lasers; serial laser source; test cost reduction; transceivers; uncooled laser; Consumer electronics; Costs; Extinction ratio; Fiber lasers; Optical devices; Optical receivers; Optical transmitters; Semiconductor lasers; Temperature distribution; Transceivers; Quantum well lasers; semiconductor device manufacture; semiconductor device reliability; semiconductor lasers;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2005.861128
