The European BOOM project :silicon photonics for high-capacity optical packet routers

L. Stampoulidis; K. Vyrsokinos; K. Voigt; L. Zimmermann; F. Gomez-Agis; H.J.S. Dorren; Z. Sheng; D. Thourhout, Van; L. Moerl; J. Kreissl; B. Sedighi; J.C. Scheytt; A. Pagano; E. Riccardi

doi:10.1109/JSTQE.2009.2038238

The European BOOM project :silicon photonics for high-capacity optical packet routers

L. Stampoulidis, K. Vyrsokinos, K. Voigt, L. Zimmermann, F. Gomez-Agis, H.J.S. Dorren, Z. Sheng, D. Thourhout, Van, L. Moerl, J. Kreissl, B. Sedighi, J.C. Scheytt, A. Pagano, E. Riccardi

Electro-Optical Communication

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Abstract

During the past years, monolithic integration in InP has been the driving force for the realization of integrated photonic routing systems. The advent of silicon as a basis for cost-effective integration and its potential blend with III–V material is now opening exciting opportunities for the development of new, high-performance switching and routing equipment. Following this rationale, BOOM—as a European research initiative—aims to develop compact, cost-effective, and power-efficient silicon photonic components to enable optical Tb/s routers for current and new generation broadband core networks. This "siliconization" of photonic routers is expected to enable ultrahigh bit rates as well as higher levels of integration and power efficiency. The BOOM "device portfolio" includes all-optical wavelength converters, ultradense wave-division multiplexing (UDWDM) photodetectors, and high-speed transmitters; all based on silicon waveguide substrates. Here, we present the device concepts, the fabrication of photonic building blocks and the experiments carried out as the initial steps toward the realization of the first high-capacity silicon photonic router.

Original language	English
Pages (from-to)	1422-1433
Number of pages	12
Journal	IEEE Journal of Selected Topics in Quantum Electronics
Volume	16
Issue number	5
DOIs	https://doi.org/10.1109/JSTQE.2009.2038238
Publication status	Published - 2010

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Stampoulidis, L., Vyrsokinos, K., Voigt, K., Zimmermann, L., Gomez-Agis, F., Dorren, H. J. S., Sheng, Z., Thourhout, Van, D., Moerl, L., Kreissl, J., Sedighi, B., Scheytt, J. C., Pagano, A., & Riccardi, E. (2010). The European BOOM project :silicon photonics for high-capacity optical packet routers. IEEE Journal of Selected Topics in Quantum Electronics, 16(5), 1422-1433. https://doi.org/10.1109/JSTQE.2009.2038238

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title = "The European BOOM project :silicon photonics for high-capacity optical packet routers",

abstract = "During the past years, monolithic integration in InP has been the driving force for the realization of integrated photonic routing systems. The advent of silicon as a basis for cost-effective integration and its potential blend with III–V material is now opening exciting opportunities for the development of new, high-performance switching and routing equipment. Following this rationale, BOOM—as a European research initiative—aims to develop compact, cost-effective, and power-efficient silicon photonic components to enable optical Tb/s routers for current and new generation broadband core networks. This {"}siliconization{"} of photonic routers is expected to enable ultrahigh bit rates as well as higher levels of integration and power efficiency. The BOOM {"}device portfolio{"} includes all-optical wavelength converters, ultradense wave-division multiplexing (UDWDM) photodetectors, and high-speed transmitters; all based on silicon waveguide substrates. Here, we present the device concepts, the fabrication of photonic building blocks and the experiments carried out as the initial steps toward the realization of the first high-capacity silicon photonic router.",

author = "L. Stampoulidis and K. Vyrsokinos and K. Voigt and L. Zimmermann and F. Gomez-Agis and H.J.S. Dorren and Z. Sheng and {Thourhout, Van}, D. and L. Moerl and J. Kreissl and B. Sedighi and J.C. Scheytt and A. Pagano and E. Riccardi",

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doi = "10.1109/JSTQE.2009.2038238",

language = "English",

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Stampoulidis, L, Vyrsokinos, K, Voigt, K, Zimmermann, L, Gomez-Agis, F, Dorren, HJS, Sheng, Z, Thourhout, Van, D, Moerl, L, Kreissl, J, Sedighi, B, Scheytt, JC, Pagano, A & Riccardi, E 2010, 'The European BOOM project :silicon photonics for high-capacity optical packet routers', IEEE Journal of Selected Topics in Quantum Electronics, vol. 16, no. 5, pp. 1422-1433. https://doi.org/10.1109/JSTQE.2009.2038238

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AU - Stampoulidis, L.

AU - Vyrsokinos, K.

AU - Voigt, K.

AU - Zimmermann, L.

AU - Gomez-Agis, F.

AU - Dorren, H.J.S.

AU - Sheng, Z.

AU - Thourhout, Van, D.

AU - Moerl, L.

AU - Kreissl, J.

AU - Sedighi, B.

AU - Scheytt, J.C.

AU - Pagano, A.

AU - Riccardi, E.

PY - 2010

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AB - During the past years, monolithic integration in InP has been the driving force for the realization of integrated photonic routing systems. The advent of silicon as a basis for cost-effective integration and its potential blend with III–V material is now opening exciting opportunities for the development of new, high-performance switching and routing equipment. Following this rationale, BOOM—as a European research initiative—aims to develop compact, cost-effective, and power-efficient silicon photonic components to enable optical Tb/s routers for current and new generation broadband core networks. This "siliconization" of photonic routers is expected to enable ultrahigh bit rates as well as higher levels of integration and power efficiency. The BOOM "device portfolio" includes all-optical wavelength converters, ultradense wave-division multiplexing (UDWDM) photodetectors, and high-speed transmitters; all based on silicon waveguide substrates. Here, we present the device concepts, the fabrication of photonic building blocks and the experiments carried out as the initial steps toward the realization of the first high-capacity silicon photonic router.

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DO - 10.1109/JSTQE.2009.2038238

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JO - IEEE Journal of Selected Topics in Quantum Electronics

JF - IEEE Journal of Selected Topics in Quantum Electronics

IS - 5

ER -

The European BOOM project :silicon photonics for high-capacity optical packet routers

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