Posted on 02/07/2008 12:48:44 PM PST by Red Badger
Three years ago a team from Bell Labs took on a very daunting challenge put an optical networking system on a commercially manufactured silicon chip, load it with a smorgasbord of sophisticated opto-electronic devices in a combination thats never been done before, and make it easy to mass produce.
The project is part of a U.S. DARPA-funded program (Defense Advanced Research Project Agency) to develop technologies and design tools necessary to fabricate an application specific, electronic-photonic integrated circuit (EPIC). This program is led by BAE Systems in partnership with MIT, Applied Wave Research, and Bell Labs, through Alcatel-Lucents LGS subsidiary.
Free White Paper
Free Information Technology white papers, downloads and podcasts Modern communication systems are built using both photonic and electronic components, each with their own technology platforms based on different materials. The vision is to put photonics and electronics on a tiny silicon chip where the strengths of both technologies can be realized on a high volume, low cost manufacturing platform, explained Sanjay Patel, Bell Labs Integrated Photonics.
CMOS (complementary metal oxide semiconductor), fabrication is the platform on which todays electronics industry is based. Recently, CMOS fabrication passed a feature-size milestone where the level of control in integrated circuit manufacturing is precise enough to support the demanding requirements of photonics. The timing is right to take advantage of the commercial mass production infrastructure and put optical networking onto silicon. The EPIC project achieved the critical first step in building the foundation for this new breed of devices, said Alice White, vice president, Enabling Physical Technologies Research at Alcatel-Lucents Bell Labs. Weve applied our core competency in optics and expertise in chip design and telecommunications technology towards realizing the full potential of silicon-based optical networking by not only creating circuits that can carry optical signals, but providing the control to modify those signals, which is a much more sophisticated process.
This research will enable telecom providers to move from using specialized and large optical networking devices to a new generation of low cost, mass produced silicon chips that combine electronics and photonics in a single chip - opening the door to new optical networking architectures that could usher in new sorts of broadband deployments and applications. Possible new applications include low-cost, mass deployment of fiber to the home; truly meshed optical networks that cleanly switch optical signals between different transmission formats; and the deployment of optical networking into places unapproachable by todays optical networking devices such as over short-runs or in confined spaces.
A wide variety of photonic components are being developed on the silicon platform under the EPIC program to complement the existing suite of electronic components already available in the marketplace. These include all the basic building blocks of any modern optical communication system: optical filters to provide signal processing in the optical domain; electro-optic modulators to convert electrical signals to the optical domain; optical filters to provide signal processing in the optical domain; and detectors to convert optical signals back to the electrical domain.
One of the first achievements of the EPIC project is a highly versatile guided-wave (tunable) optical filter made entirely in a standard CMOS manufacturing line, upon which was demonstrated a novel optical equalizer. This achievement, announced at the 2007 OFC/NFOEC conference, is a critical first step toward the ultimate goal of seamless integration of photonics and electronics on the CMOS platform.
The tunable optical equalizer uses a novel architecture to correct distortion from bandwidth limitations in the signal, allowing for superior performance with minimal control requirements. It also counteracts another form of distortion in a signal, called dispersion. Self-correction of distortion could significantly improve the speed, cost and performance of next-generation optical and high-speed data networks.
The success we have achieved thus far bodes well for the full EPIC capability envisioned by DARPA as well as for novel and potentially lower cost components for commercial optical systems, said Patel.
Source: Bell Labs
Ping!...............
The Clintons already preparing the sale of the technology to China to finance her next campaign.
She won’t need another campaign. She’ll abolish the 20th Amendment.
This achievement, announced at the 2007 OFC/NFOEC conference, is a critical first step toward the ultimate goal of seamless integration of photonics and electronics on the CMOS platform.
CMOS= Classified Maritime Operational Support platform, or to the unititiated, a photon torpedo! ;^)
See Moss.......
They are probably two years away from delivering the brick cell phone equivalent to the commercial market. Thats OK. The first real gains will be the lower power consumption. The transistor initially resolved the heat and speed hurdles of the vacuum tube. The Power consumption were resolved and then the focus was on silicon component reduction (Integrated circuit). Now with the intense concentration of the IC we are presented with reduced power consumption (heat) in the form of Optical processing. The cycle begins anew.
For those of us who don’t have EE degrees what is the potential practical non-defence applications for this technology ?
Smaller, lighter, more efficient stuff like laptops, cell phones, video displays, etc. Anything that runs on batteries will last longer and be “lighter”.............
Does this also mean you could build a computer/other electronic system that would be immune to a nuclear electro-magnetic pulse ?
Does this also mean you could build a computer/other electronic system that would be immune to a nuclear electro-magnetic pulse ?
"...mass produced silicon chips that combine electronics and photonics in a single chip..."
I want glow-in-the-dark contact lenses so I can read in low light conditions, also would be nice to have wireless transmit capabilities to take snapshots to a pocket device.
It’s already possible to shield small systems from EMP with a faraday cage (which also protects you somewhat from EM eavesdropping). No one is going to pay the price tag for it for the most part as the commercial electrical grid is not EMP shielded, and I’m not sure it’s effectively possible to shield equipment that is plugged into the grid at time of EMP.
Where on-chip optical components will probably really excel is cheaper optical fiber networking (Internet backbone routers), and interconnects like system busses, next generation Hi-Def video connections, network attached storage devices, and successors to firewire.
We can do that now, albeit expensively. There are many semiconductors/ics available in pkgs that are different than their commercial equivalent, that are "rad hardened" and much more expensive. The only fundamental electronic device I know of that is "immune" to EMP is the vacuum tube. These opto devices may be also, but their interfaces to the electron devices would not be unless made of the aforementioned special materials........
Disclaimer: Opinions posted on Free Republic are those of the individual posters and do not necessarily represent the opinion of Free Republic or its management. All materials posted herein are protected by copyright law and the exemption for fair use of copyrighted works.