News Article
Fujitsu SiGe Optical Switch Cuts Power Consumption by Half
The firm sees its latest SiGe product as a solution for ever-increasing network equipment power consumption.
Fujitsu Laboratories has halved the power consumption of an optical waveguide switch by using what it claims to be the world's first use of fine-patterned silicon germanium (SiGe) over conventional silicon (Si).
The prototype optical switch devices developed by the firm operate on 1.5 mW of power, approximately half the power required for conventional fine-patterned Si optical switching elements.
This, says Fujitsu, represents the lowest power requirement in the world for an optical switching element capable of high-speed operation across a wide range of wavelengths.
The newly-developed technology will help contain power consumption while supporting large-volume network traffic, thus enabling high-end services linking multiple cloud networks and ultra-high-definition videoconferencing, among other applications.
Details of this technology will be presented at the 23rd Annual Meeting of the IEEE Photonics Society (PHO 2010), being held from November 7-11 in Denver, Colorado, U.S.
Parts of this research were undertaken as part of the work of the Vertically Integrated Center for Technologies of Optical Routing toward Ideal Energy Savings (VICTORIES) project.
With the spread of data-intensive network services, such as cloud computing and ultra-high-definition video distribution, the volume of data being transmitted over networks looks set to rise continuously.
According to the Japanese Ministry of Economy, Trade and Industry's "Green IT Initiative" report (December 2007), the amount of electricity consumed by networking equipment in the year 2025 is predicted to be 13 times the 2006 figure if no energy-saving measures are taken.
Conventionally, switching between optical network paths requires that signals be converted from light to electricity and back again to light in order to be processed - these conversions are problematic because of the considerable power they require.
An optical switch that processes optical signals as they are - without the need for conversion to electricity - would greatly reduce its power requirements. This issue has spurred ongoing research and development efforts for next-generation networks.
An optical switch is a device that can connect the paths of optical signals, and switch between them. A waveguide optical switch is a design that arrays multiple optical switching elements in series, between an optical-signal input point and output point. By combining the operations of each optical switching element, a desired optical signal path can be created (Figure 1).
An optical waveguide switch employing silicon photonics uses well-established silicon fabrication technology, which allows for inexpensive mass production. Furthermore, optical switch devices based on nanometer-scale waveguides and control electronic circuits can be lined up in large numbers on the same substrate, large-scale optical switches can be fabricated compactly, measuring a mere few centimeters squared.
Large-scale optical-waveguide switches operate multiple optical switching elements simultaneously. The heat that this generates can degrade device performance, which necessitates the lowest possible power consumption for each optical switching element.
With optical switching elements, the application of an electrical current to the refractive-index modulator causes electrons to accumulate in fine waveguides, which modulates the refractive index and switches the output port (Figure 2). With conventional optical switching elements made using fine-patterned Si, the electron-accumulation efficiency in fine Si waveguides is low, necessitating more current to achieve sufficient electron-accumulation, thereby increasing power consumption.
Fujitsu’s optical switching element uses fine-patterned SiGe in the refractive-index modulator (Figure 3). Forming fine-patterned SiGe, which has a narrower band-gap than Si, on top of Si allows for more efficient electron accumulation, and therefore less power is required for switching.
Fujitsu's newly-developed low-power technologies for optical switch devices represent a significant step forward toward next-generation networking and pave the way for new services, such as high-speed services linking multiple cloud networks and ultra-high-definition videoconferencing.
The company will proceed with development of large-scale integration technology and integration technology for control electronic circuits, for the realization of large-scale optical switches to enable next-generation networks.