Sep 19, 2018 11:20 JST

Source: Fujitsu Ltd

Fujitsu Develops Novel Technology to Massively Boost Optical Data Transfer Throughput Using Existing Equipment
Enables the use of multiple wavelength bands to support expanded transmission capacity between datacenters

TOKYO, Sep 19, 2018 - (JCN Newswire) - Fujitsu Laboratories Ltd. has developed an ultra-high capacity wavelength-division multiplexing system that considerably expands the transmission capacity of optical fibers in optical networks connecting datacenters. The new technology achieves this without the deployment of new transceivers dedicated to new wavelength. Previously, in order to expand transmission capacity between datacenters, operators had to either increase the number of optical fibers being used, or they needed receivers supporting each band of wavelengths. Now, Fujitsu Laboratories has developed the world's first broadband wavelength conversion technology that can batch convert C-band(1) optical signals to new wavelength bands, including L-band and S-band, reconverting them back to the original C-band when received. Upon development of a system that converts optical signals in C-band to L- and S-bands before multiplexing and transmitting them utilizing this innovative technology, Fujitsu Laboratories successfully demonstrated in principle that transmission capacity could be tripled. This allows datacenter operators to use existing equipment as-is to raise the efficiency of optical fiber utilization and thereby expand transmission capacity. This promises to eliminate the kind of network bottlenecks that could pose challenges for high-volume users that need to store, back up, or perform parallel analysis on large volumes of data distributed between multiple datacenters. This includes cases that many expect to increase dramatically in the near future, such as transfers of unstructured data including 8K video material and device log information connected through 5G networks.

Figure 1: Diagram and example use of optical networks connecting datacenters
 

Figure 2: Wavelength bands used in transmissions through optical fibers
 

Figure 3: Method using transceivers for different wavelength bands simultaneousy
 

Figure 4: Proposed new wavelength conversion technology
 

Figure 5: Method for expanding band usage through wavelength conversion using this technology
 


Development Background

In recent years, the use of social networks and streaming video has contributed to exponential increases in the volumes of data handled by datacenters. Moreover, many predict that data circulation will grow dramatically in the future with the spread of 5G communications and 8K video technologies. Though datacenter operators have already connected multiple datacenters with optical networks and use distributed storage for disaster recovery and distributed processing for high-speed processing, they need to expand transmission capacity even further to effectively prepare for the increases in data volume anticipated in the immediate future.

http://www.acnnewswire.com/topimg/Low_FujitsuOpticalDataFig1.jpg
Figure 1: Diagram and example use of optical networks connecting datacenters

Issues

Expanding transmission capacities between datacenters can be accomplished by increasing the number of optical fibers, however, additional fees would be assessed based on the number of optical fibers used, presenting a significant cost burden for operators. On the other hand, what could also be considered is the simultaneous use of new wavelength bands outside the C-band. Optical networks generally use the C-band for its good transmission performance, but for medium-distance transmissions of several dozen kilometers between datacenters, the impact of transmission loss with the use of other wavelength bands, such as the L-band or the S-band, is seen as quite small, and consideration may also be given to using these wavelength bands. However, this method would necessitate the separate development of transceivers that could support each band.

http://www.acnnewswire.com/topimg/Low_FujitsuOpticalDataFig2.jpg
Figure 2: Wavelength bands used in transmissions through optical fibers

http://www.acnnewswire.com/topimg/Low_FujitsuOpticalDataFig3.jpg
Figure 3: Method using transceivers for different wavelength bands simultaneously

About the Newly Developed Technology

To address these challenges, Fujitsu Laboratories developed an ultra-large transmission capacity optical wavelength-division multiplexing system (a patent application was filed) that batch converts C-band optical signals output by a transmitter into new wavelengths for transmission, and then converts them back to the original wavelength band before sending them to the receiver. First, the C-band optical signal is combined with two pump lights(2), generating a signal with mixed wavelength. The pump lights change the signal's refractive index of a nonlinear optical medium which the signal passes through and outputs converted signals at a different wavelength. A similar principle is used on the receiver side to return the transmitted optical signal to the C-band. With this newly developed technology, it becomes possible to convert an optical signal to an arbitrary wavelength band efficiently by choosing the wavelengths of two pump lights, based on the chromatic dispersion characteristics of various nonlinear optical media. Additionally, this technology can reduce the noise superimposed on the signal after wavelength conversion by synchronously controlling the pump lights. This means it can simultaneously convert the signal's wavelength efficiently while maximizing the quality of the optical signal.

http://www.acnnewswire.com/topimg/Low_FujitsuOpticalDataFig4.jpg
Figure 4: Proposed new wavelength conversion technology

http://www.acnnewswire.com/topimg/Low_FujitsuOpticalDataFig5.jpg
Figure 5: Method for expanding band usage through wavelength conversion using this technology

Effects

Using this technology, Fujitsu Laboratories created a prototype system to convert an optical signal in C-band to L- and S-bands, and then multiplexed them for transmission, successfully confirming in principle that this technology could triple available wavelength without the use of transceivers for each new wavelength band. Using this technology, transmissions using an even greater variety of different bands become possible, allowing for the expansion of transmission capacity from two to 10 times, as needed. In addition to this technology, datacenter operators can immediately make use of new C-band transceivers that will be developed going forward in wavelength bands outside the C-band.

Future Plans

Fujitsu Laboratories aims to incorporate this technology into a new lineup of the Fujitsu Network 1FINITY series of optical transmission systems, in fiscal 2019. In addition, Fujitsu Laboratories is considering extending this technology to datacenter operators, contributing to the creation of new business for its customers.

(1) C-band A wavelength band used for optical transmissions defined by ITU-T, the Telecommunication Standardization Sector of the International Telecommunication Union. The C-band refers to wavelengths of 1,530-1,565 nm, while the L-band covers 1,565-1,625 nm and the S-band covers 1,460-1,530 nm.
(2) Pump light A light that induce modulation on optical signal through refractive index change in nonlinear optical media.

About Fujitsu Laboratories

Founded in 1968 as a wholly owned subsidiary of Fujitsu Limited, Fujitsu Laboratories Ltd. is one of the premier research centers in the world. With a global network of laboratories in Japan, China, the United States and Europe, the organization conducts a wide range of basic and applied research in the areas of Next-generation Services, Computer Servers, Networks, Electronic Devices and Advanced Materials. For more information, please see: http://www.fujitsu.com/jp/group/labs/en/.

Contact:
Fujitsu Laboratories Ltd.
Photonics Research Center
Photonics Innovation Project
E-mail: wlconv@ml.labs.fujitsu.com

Fujitsu Limited
Public and Investor Relations
Tel: +81-3-3215-5259
URL: www.fujitsu.com/global/news/contacts/
Source: Fujitsu Ltd
Sectors: Electronics, Cloud & Enterprise

Copyright ©2024 JCN Newswire. All rights reserved. A division of Japan Corporate News Network.

Related Press Release


Fujitsu Selected as CDP Supplier Engagement Leader
March 29 2024 09:28 JST
 
Fujitsu Tech Leverages AI and Underwater Drone Data for 'Ocean Digital Twin'
March 26 2024 09:24 JST
 
Fujitsu Limited announces recruitment plans
March 19 2024 09:34 JST
 
Fujitsu and AWS will launch a new Modernization Acceleration Joint Initiative to enable customers across industries to drive digital transformation with fast and secure legacy modernization
March 18 2024 15:12 JST
 
Japanese joint research group win Prime Minister's Award with ultra high-performance computing platform using jointly developed 64-qubit quantum computer
March 15 2024 09:19 JST
 
Fujitsu and Tokai National Higher Education and Research System collaborate on AI-based space weather research
March 14 2024 09:21 JST
 
GMO Research Activity Support & Technology launches brain MRI analysis tool developed on world class supercomputer Fugaku with Fujitsu Computing as a Service (CaaS)
March 12 2024 09:20 JST
 
Fujitsu and Carnegie Mellon University develop AI-powered social digital twin technology with traffic data from Pittsburgh
March 07 2024 09:25 JST
 
Fujitsu and Celonis Expand Strategic Global Partnership
February 26 2024 14:40 JST
 
Fujitsu introduces "Uvance Wayfinders", expanded and strengthened consulting capabilities to deliver cross-industry business value
February 22 2024 11:05 JST
 
More Press release >>

Latest Press Release


More Latest Release >>