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Operating wavelength range of 25.8-Gb/s 1.3-µm DML extended to 30 nm | IEEE Conference Publication | IEEE Xplore
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Operating wavelength range of 25.8-Gb/s 1.3-µm DML extended to 30 nm

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W. Kobayashi; K. Tsuzuki; T. Fujisawa; Y. Ohiso; Y. Ogiso; T. Ito
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Abstract:

A 30-nm operating wavelength range was realized for a 1.3-μm InGaAlAs DML with a 25.8-Gb/s push-pull driving configuration. Clear eye openings, an 8.0-dBm output power, a...Show More

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Abstract:

A 30-nm operating wavelength range was realized for a 1.3-μm InGaAlAs DML with a 25.8-Gb/s push-pull driving configuration. Clear eye openings, an 8.0-dBm output power, and a 4.0-dB dynamic extinction ratio were obtained.
Published in: 2013 18th OptoElectronics and Communications Conference held jointly with 2013 International Conference on Photonics in Switching (OECC/PS)
Date of Conference: 30 June 2013 - 04 July 2013
Date Added to IEEE Xplore: 16 September 2013
Electronic ISBN:978-4-88552-271-0

ISSN Information:

Conference Location: Kyoto, Japan
References is not available for this document.
Contents

I. Introduction

The recent explosive increase in data traffic due to the spread of such technologies as the internet and the smart phone, has led to the need for a higher speed optical network system. At datacenters, there is an increasing demand for a high-speed light source with an ultra high capacity of up to 1 Tb/s. For this application, the light source must offer both a large capacity and a low power consumption.

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1.
T. Shimoyama et al., Proc. ECOC2012, P2.11 (2012).
Google Scholar
2.
W. Kobayashi et al., IEEE JSTQE, accepted for publication (2013).
Google Scholar
3.
P. Bernasconi et al., Proc. ECOC2012, Tu.4.E.3 (2013).
Google Scholar
4.
K. Adachi et al., Proc. ISLC2012, TuB5 (2012).
Google Scholar
5.
G. Sakaino et al., Proc. OFC2012, OTh3F.3 (2012).
Google Scholar
6.
Y. Yamasaki et al., Proc. ISLC2012, TuB2 (2012).
Google Scholar
7.
T. Shimoyama et al., Proc. ISLC2012, TuB3 (2013).
Google Scholar
8.
http://www.ieee802.org/3/ba/
9.
S. G. Mao et al., IEEE Trans. Microw. Theory Tech, 48, p23 (2000).
Google Scholar
10.
D. E. Anagnostou et al., IEEE Trans. Microw. Theory Tech, 56, p1 (2008).
Google Scholar
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