Author_Institution :
Nortel Networks, Ottawa, Ont., Canada
Abstract :
10 Gb/s data transmission over 80 km of standard fiber, or 2.5 Gb/s over 1000 km, can best be accomplished with an external Mach-Zehnder modulator and a high power DFB laser operating CW. Co-packaging those devices, and including dense WDM wavelength locking plus variable optical attenuation, provides an extremely compact, cost-effective, yet highly sophisticated module. Co-packaging discrete DFB and InP MZ chips has also paved the way for introducing cost-reducing integrated DFB/MZ devices with minimal impact at the system level. Nortel has been manufacturing, and using in its state-of-the-art transmission systems, evolving versions of these modules since 1995. We describe the optics train which couples laser light into the MZ chip. Because of the extreme alignment sensitivity, the design must provide both high coupling efficiency and stability. Because production volumes of these modules were initially low, with costs dominated by the laser and modulator chips themselves, the design is based on skilled manual alignment techniques. As volumes have increased the design has had to adapt to manufacturability issues such as operator training, quality, and productivity limits
Keywords :
data communication equipment; digital communication; distributed feedback lasers; electro-optical modulation; electronic equipment manufacture; integrated optoelectronics; microassembling; modules; optical communication equipment; packaging; semiconductor lasers; wavelength division multiplexing; 10 Gbit/s; 2.5 Gbit/s; 80 to 100 km; CW operation; DWDM wavelength locking; InP; InP MZ modulator chips; Mach-Zehnder modulator; Nortel; alignment sensitivity; co-packaged DFB/MZ module; compact cost-effective module; data transmission; dense WDM wavelength locking; high coupling efficiency; high coupling stability; high power DFB laser; manufacturability issues; standard fiber; variable optical attenuation; Data communication; Fiber lasers; Manufacturing; Optical attenuators; Optical design; Optical fiber devices; Optical modulation; Optical sensors; Power lasers; Ultraviolet sources;
