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A visual representation of a CPU using nanophotonic switches to direct light speed traffic between cores on a chip.  (Source: IBM)
IBM continues push towards light speed computing

In 2005 International Business Machines demonstrated silicon nanophotonic devices that slowed down light via clever reflecting methods.  Then in 2006 it showed how a similar device could be used to buffer a full byte of information in stored optical pulses, a necessity for optical computing. 

In December 2007, researchers demonstrated a silicon device that transformed energy from electronic impulses from a processor into light pulses -- the pulses in the 2005 and 2006 developments were manually triggered.

Now, IBM has made another significant research breakthrough in its quest to achieve optical computing.  Researchers at IBM have announced that they have developed the world's smallest nanophotonic switch.  The tiny silicon device, measuring a mere hundredth of the size of a human hair, is an essential step towards creating "light transistors," that allow chips to process at the speed of light.  Such chips could greatly outclass today's chips in performance and speed, as today's chips rely on slower electrical communication through copper wires.

Before such chips, though, an important stepping stone IBM sees is the use of its optical technologies in on chip networks.  The optical devices could be put to use as a bus between cores in IBM's next generation Cell processors or other multicore systems.  Yurii Vlasov, manager of silicon nanophotonics at IBM’s TJ Watson Research Center states, "This new development is a critical addition in the quest to build an on-chip optical network."

IBM's partially DARPA-funded research is published in the April 2008 journal
Nature Photonics, titled "High-throughput silicon nanophotonic wavelength-insensitive switch for on-chip optical networks."  The switch takes light converted by IBM's other devices from electrical signals and can direct it along multiple routes.  This will eventually allow on-chip optical interconnects.  IBM states that the device fulfills several key criteria making it ideal for use on-chip.  First, they state, it is extremely compact.  Secondly, it can process multiple wavelengths of light (known as colors in the visible spectra).  This means that with each wavelength transmitting data at up to 40 Gb/s, the aggregated bandwidth can exceed 1 Tb/s. 

IBM has shown the device is tolerant to heat.  This is an essential characteristic for successful on-chip deployment as modern processors develop "hot spots" which migrate around, based on changing loading conditions.

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RE: Technically ...
By geddarkstorm on 3/18/2008 3:48:21 PM , Rating: 3
Correct me if I'm wrong:

Electrons can never travel at the speed of light under current theory, that's impossible due to the theory of relativity . Electrons have mass, therefore they'd require infinite energy to reach c in a vacuum.

Light itself is a self propagating electric field with a perpendicular magnetic field. So indeed light and electrons are affected differently by different materials. Changes in the movement speed of electrons creates light, or low wavelengths like infrared, aka heat (in a synchrotron, or particle accelerator, changing the speed of an electron can create much higher wavelengths like X-rays due to the electron's immense speed, and therefore is useful in X-ray crystallography). Whereas changes in the speed of light is usually due to the different densities and refractive qualities of materials and so doesn't really create heat unless absorbed by atoms; and then the heat produced will be proportional to the amplitude of the light. So as long as you can detect it, you can have almost no heat production by transmitting and receiving light by using very small amplitudes and pulse lengths.

Light can move faster, but far more importantly, light can carry a near infinite range of information via wavelength and phase differences. You're limited only by how much you can detect and decipher reliably. So, a light transistor could do many of calculations at once theoretically by having many separate wavelength/phase channels, as long as said channels didn't interact of course.

RE: Technically ...
By rangerdavid on 3/18/08, Rating: 0
RE: Technically ...
By Regs on 3/21/2008 12:04:01 PM , Rating: 2
It's very interesting in what you say in your 2nd paragraph. Which makes more disappointed in what IBM has has in mind for the application of optical computing.

"The optical devices could be put to use as a bus between cores in IBM's next generation Cell processors". This to me seems like a waste of innovation if we were only to implicate it as a bus between two processing cores. Now to have information transfer inside the data execution units of the processor core itself using optics would be truly remarkable.

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