FRANKFURT, Dec 6: IBM says it has made a breakthrough in converting electrical signals into light pulses that brings closer the day when supercomputing, which now requires huge machines, will be done on a single chip.
In research published on Thursday in the journal Optics Express, IBM said it had produced electro-optic modulators 100 to 1,000 times smaller than comparable silicon photonics modulators and small enough to fit on a processor chip.
By connecting processing cores on a chip by light instead of with wires, the problems of high energy consumption and heat generated by multi-core chips could be bypassed, enabling leaps in computing power.
The firm said it had reached a “milestone” in the quest to connect hundreds or thousands of processing cores on a tiny chip. By comparison there are nine cores on the sophisticated chips that power the Sony PlayStation 3 games console.
“Just like fibre optic networks have enabled the rapid expansion of the Internet by enabling users to exchange huge amounts of data from anywhere in the world, the technology is bringing similar capabilities to the computer chip,” said Will Green, IBM’s lead scientist on the project.
He said using light instead of wires to send information between the cores could be as much as 100 times faster and use 10 times less power than wires.
CHALLENGES AHEAD: That gave the research team confidence the process could be replicated commercially, although it would likely take at least a decade for that stage to be reached.“We’re looking at much more real-world applications in the timeframe of 10 to 15 years or something like that. There’s a lot of pieces to come together. There are many challenges ahead,” Green said in an interview.
He said in future tiny supercomputers on a chip could expend as little energy as a lightbulb, paving the way for enormous reductions in cost, energy, heat and space required while increasing communications bandwidth.
Drastically shrinking the size and energy requirements of supercomputing could open up possibilities of powerful data analysis in remote locations or high-resolution three-dimensional image rendering in real time, Green said.
“You immediately can envision the mobile applications that that would allow you to do,” he said. “Remote laboratory instruments for medical applications, screening for diseases or even complicated DNA analysis.”
The team has been working on the project, partly funded by a US government defence research agency, for about five years. Green declined to comment on the project’s budget.—Reuters
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