The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Un circuit intégré de pilote de modulateur monolithique basé sur des HBT InP avec une nouvelle topologie de circuit - appelée circuit distribué fonctionnel (FDC) - pour les systèmes de transmission optique supérieurs à 80 Gbit/s a été développé. La topologie FDC comprend un amplificateur large bande conçu à l'aide d'un circuit distribué, une fonction numérique conçue à l'aide d'un circuit localisé et une adaptation d'impédance à large bande entre le circuit localisé et le circuit distribué pour permettre à la fois une bande passante plus large et des fonctions numériques. Le circuit intégré de pilote intégré à une fonction de multiplexage 2:1 produit 2.6 Vpp (sortie différentielle : 5.2 Vpp) et 2.4-Vpp (sortie différentielle : 4.8 Vpp) la tension de sortie oscille avec une gigue efficace inférieure à 450 fs et 530 fs à 80 Gb/s et 90 Gb/s, respectivement. Au meilleur de nos connaissances, cela équivaut au fonctionnement au débit de données le plus élevé jamais signalé pour les pilotes de modulateurs monolithiques. Lorsqu'il a été monté dans un module, le circuit intégré pilote a réussi à réaliser une modulation électro-optique à l'aide d'un LiNbO à double entraînement.3 Modulateur Mach-Zehnder jusqu'à 90 Gb/s. Ces résultats indiquent que le FDC a le potentiel de réaliser des circuits intégrés fonctionnels et à haut débit pour les systèmes de transmission supérieurs à 80 Gbit/s.
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Yasuyuki SUZUKI, Zin YAMAZAKI, Masayuki MAMADA, "A 90-Gb/s Modulator Driver IC Based on Functional Distributed Circuits for Optical Transmission Systems" in IEICE TRANSACTIONS on Electronics,
vol. E93-C, no. 8, pp. 1266-1272, August 2010, doi: 10.1587/transele.E93.C.1266.
Abstract: A monolithic modulator driver IC based on InP HBTs with a new circuit topology -- called a functional distributed circuit (FDC) -- for over 80-Gb/s optical transmission systems has been developed. The FDC topology includes a wide-band amplifier designed using a distributed circuit, a digital function designed using a lumped circuit, and broadband impedance matching between the lumped circuit and distributed circuit to enable both wider bandwidth and digital functions. The driver IC integrated with a 2:1 multiplexing function produces 2.6-Vp-p (differential output: 5.2 Vp-p) and 2.4- Vp-p (differential output: 4.8 Vp-p) output-voltage swings with less than 450-fs and 530-fs rms jitter at 80 Gb/s and 90 Gb/s, respectively. To the best of our knowledge, this is equivalent to the highest data rate operation yet reported for monolithic modulator drivers. When it was mounted in a module, the driver IC successfully achieved electro-optical modulation using a dual-drive LiNbO3 Mach-Zehnder modulator up to 90 Gb/s. These results indicate that the FDC has the potential to realize high-speed and functional ICs for over-80-Gb/s transmission systems.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/transele.E93.C.1266/_p
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@ARTICLE{e93-c_8_1266,
author={Yasuyuki SUZUKI, Zin YAMAZAKI, Masayuki MAMADA, },
journal={IEICE TRANSACTIONS on Electronics},
title={A 90-Gb/s Modulator Driver IC Based on Functional Distributed Circuits for Optical Transmission Systems},
year={2010},
volume={E93-C},
number={8},
pages={1266-1272},
abstract={A monolithic modulator driver IC based on InP HBTs with a new circuit topology -- called a functional distributed circuit (FDC) -- for over 80-Gb/s optical transmission systems has been developed. The FDC topology includes a wide-band amplifier designed using a distributed circuit, a digital function designed using a lumped circuit, and broadband impedance matching between the lumped circuit and distributed circuit to enable both wider bandwidth and digital functions. The driver IC integrated with a 2:1 multiplexing function produces 2.6-Vp-p (differential output: 5.2 Vp-p) and 2.4- Vp-p (differential output: 4.8 Vp-p) output-voltage swings with less than 450-fs and 530-fs rms jitter at 80 Gb/s and 90 Gb/s, respectively. To the best of our knowledge, this is equivalent to the highest data rate operation yet reported for monolithic modulator drivers. When it was mounted in a module, the driver IC successfully achieved electro-optical modulation using a dual-drive LiNbO3 Mach-Zehnder modulator up to 90 Gb/s. These results indicate that the FDC has the potential to realize high-speed and functional ICs for over-80-Gb/s transmission systems.},
keywords={},
doi={10.1587/transele.E93.C.1266},
ISSN={1745-1353},
month={August},}
Copier
TY - JOUR
TI - A 90-Gb/s Modulator Driver IC Based on Functional Distributed Circuits for Optical Transmission Systems
T2 - IEICE TRANSACTIONS on Electronics
SP - 1266
EP - 1272
AU - Yasuyuki SUZUKI
AU - Zin YAMAZAKI
AU - Masayuki MAMADA
PY - 2010
DO - 10.1587/transele.E93.C.1266
JO - IEICE TRANSACTIONS on Electronics
SN - 1745-1353
VL - E93-C
IS - 8
JA - IEICE TRANSACTIONS on Electronics
Y1 - August 2010
AB - A monolithic modulator driver IC based on InP HBTs with a new circuit topology -- called a functional distributed circuit (FDC) -- for over 80-Gb/s optical transmission systems has been developed. The FDC topology includes a wide-band amplifier designed using a distributed circuit, a digital function designed using a lumped circuit, and broadband impedance matching between the lumped circuit and distributed circuit to enable both wider bandwidth and digital functions. The driver IC integrated with a 2:1 multiplexing function produces 2.6-Vp-p (differential output: 5.2 Vp-p) and 2.4- Vp-p (differential output: 4.8 Vp-p) output-voltage swings with less than 450-fs and 530-fs rms jitter at 80 Gb/s and 90 Gb/s, respectively. To the best of our knowledge, this is equivalent to the highest data rate operation yet reported for monolithic modulator drivers. When it was mounted in a module, the driver IC successfully achieved electro-optical modulation using a dual-drive LiNbO3 Mach-Zehnder modulator up to 90 Gb/s. These results indicate that the FDC has the potential to realize high-speed and functional ICs for over-80-Gb/s transmission systems.
ER -