Light it up: The silver-colored rectangular chip in the middle of the copper-colored holder is Intel’s latest advance in silicon photonics. The chip contains eight modulators that encode data onto light that enters and exits from the side via optical fibers (not pictured). This chip can process 200 gigabits of data per second and is used to test designs that could ultimately process a terabit of data per second.
Intel
Intel researchers have built a superfast silicon chip for optical networking.
The road to a faster Internet, data center, and personal computer is paved with silicon. Or so believe researchers at Intel who have unveiled a test chip--made entirely from silicon--that can encode 200 gigabits of data per second on a beam of light. In contrast, the most advanced chips used in today's fastest optical networks operate at speeds of 100 gigabits per second. And these 100-gigabit chips, which are made from nonsilicon materials, have limitations that Intel's chip doesn't: they can't scale to faster speeds as inexpensively as can those made from silicon.
While silicon is the material of choice in the electronics industry, it has been overlooked in the photonics industry because its optical properties are inferior to those of other semiconductors. Silicon doesn't produce, detect, and manipulate photons as well as materials such as indium phosphide and gallium arsenide. But within the past few years, optical engineers have been giving silicon a second look and cleverly engineering around some of its natural limitations.
The new Intel test chip splits an incoming beam of light into eight channels. Within each channel is a modulator, a device that encodes data onto light. After the beams are encoded with data, they are recombined. In the tests, each modulator ran at a rate of 25 gigabits per second, and each performed nearly identically, says Mario Paniccia, director of the company's silicon-photonics lab. He notes that only one modulator was tested at a time but says that in a future paper his team will publish the results from running multiple channels simultaneously. The multiple channels could produce cross talk, electrical or optical activity that could hinder performance. However, preliminary results, Paniccia says, show that due to the design, cross talk is limited.
In 2004, Intel researchers, led by Paniccia, proved that silicon could be used to build a one-gigabit-per-second modulator; in 2005, the team boosted the speed to 10 gigabits per second. Also in 2005, the researchers built a remarkably good all-silicon laser, and in 2006, they introduced a hybrid laser that combines indium phosphide with silicon, allowing a practical telecom laser to be fabricated on a silicon wafer. Most recently, they have sped up the modulator to 40 gigabits and built a silicon detector.
Replacing metal wiring with fiber optics could change everything from supercomputers to laptops.
A silicon nanobeam uses optical force to do mechanical work in an integrated circuit.
Details emerge of a chip design that will make computers faster without draining more power.
uuuuhhhhmmmmm! Global Warming!!
Are we talking about global warming here??
If not, I have nothin to say
Manufacturing in the United States is in trouble. That's bad news not just for the country's economy but for the future of innovation.
This document is part of the “How-To Guide for Most Common Measurements” centralized resource portal. This tutorial provides a detailed guide for measurement and device considerations to take temperature measurements using thermocouples. Get an introduction to thermocouples, which are inexpensive sensing devices widely used with PC-based data acquisition systems. Also review some specific thermocouple examples and learn how thermocouples work and ways to integrate them into a data acquisition measurement system.
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knarfyrreb
1 Comment
Moving to Terrabyes
Great,...how is this going to solve Global Warming; will we need terrabyte speed to regulate the climate controls in our geodesic domes in 100 years?
Come on you geniuses out there at MIT,...work on real problems. We need to survive as a species, not make the CEO's of Intel richer.
All the Best,
Reply
olegalexandrov
1 Comment
Re: Moving to Terrabyes
In order to solve the problem of global warming, as well as such problems as poverty and environment destruction, you need new technology. You can't predict in advance which technology will help solve the problems we have.
Superfast optical computers could pave the way towards more efficient manufacturing, better use of resources, and breakthroughs in nanotechnology/biotechnology, which could ultimately solve many of today's problems.
Reply
no1kilo
1 Comment
Re: Moving to Terrabyes
Here's your answer to how will this new technology help solve global warming.
Power consuption reduction.
Optical transmission of data requires less power over distance than standard copper wire.
I don't know the exact numbers but the amount of power required to send a data packet from California to New York is more than ten times that of fiber optic. This is due to the losses of electrical energy over wires. Less energy is lost over optical channels and therefore reuires less energy to transimtt the same distance.
So the help is in the amount of fuel (Coal) required to transmit the same data, hence, reduced global warming.
Al T
Reply
briang1621
173 Comments
What Global Warming??
Hun? Where did this Global Warming thing come from, did you even read the article, this is a monumental achievement in silicon chip optics.
You probably didn't even read the article, just put your post up. If you want to solve global warming go to this website.
www.GlobalWarmingIsChina&IndiaFault.com
Then write them an email, don't post randomly on articles that have nothing to do with global warming.
Reply
gsweeney
7 Comments
Re: What Global Warming??
In your anger, you have provided an incorrect address.
www.GlobalWarmingIsChina&IndiaFault.com
Reply