Title :
Simulation and design for a tunable dispersion compensator package
Author :
Zhu, Weidong ; Barbarossa, Giovanni ; Yang, Di ; Lin, Christopher
Author_Institution :
R&D Div., Avanex Corp., Fremont, CA, USA
Abstract :
A novel optical model for a tunable dispersion compensator is realized by a deliberate packaging scheme ensuing from intensive interactions of mechanical design, materials science and numerical simulation techniques including computational fluid dynamics and finite element analysis. The compensator is comprised of multiple cascaded single cavity Gires-Tournois etalons, each under independent temperature control. Three critical issues are addressed: etalon temperature uniformity, thermal insulation and optical surface deformation of the etalons. With etalon optical surface deformation minimized and etalon temperature uniformity successfully controlled within a range of ±0.1°C, this small (232 × 139 × 16 mm) compensator achieves extremely low group delay ripple (<2.0 ps), low insertion loss ripple (<0.5 dB, insertion loss <6.3 dB), low polarization dependent loss [(PDL),<0.15 dB] and low polarization mode dispersion [(PMD),<0.7 ps]. The dispersion tuning range is from -700 ps/nm to +700 ps/nm in a dispersion passband of 0.2 nm which is sufficient for 10-Gb/s transmission. Thermal insulation design makes the tuning process take effect within 1 min at maximum power consumption 5 W.
Keywords :
compensation; computational fluid dynamics; electronics packaging; finite element analysis; light interferometers; optical communication equipment; optical fibre dispersion; optical tuning; temperature control; thermal insulation; 1 min; 10 Gbit/s; 5 W; chromatic dispersion; computational fluid dynamics; deliberate packaging scheme; etalon temperature uniformity; finite element analysis; group delay; independent temperature control; insertion loss; intensive interactions; materials science; mechanical design; multiple cascaded Gires-Tournois etalons; numerical simulation; optical fiber; optical model; optical surface deformation; polarization dependent loss; polarization mode dispersion; single cavity Gires-Tournois etalons; thermal insulation; tunable dispersion compensator package; tuning process; Computational modeling; Insertion loss; Insulation; Materials science and technology; Optical design; Optical design techniques; Optical losses; Packaging; Polarization mode dispersion; Temperature control; CFD; Chromatic dispersion; FEA; Gires–Tournois etalon; computational fluid dynamics; dispersion compensator; finite element analysis; numerical simulation; optical fiber; temperature control; thermally tunable;
Journal_Title :
Components and Packaging Technologies, IEEE Transactions on
DOI :
10.1109/TCAPT.2004.831785
