Caroline Humer
NEW YORK: Researchers at International Business Machines Corp. said on
Wednesday they have demonstrated a calculation that could be used to break
complicated codes, marking a small step in the advance of quantum computing, a
technology based on quantum mechanics.
IBM scientists will publish details in the scientific journal Nature on
Thursday of the demonstration of "Shor's Algorithm," a method of
factoring numbers that was developed in 1994 by AT&T scientist Peter Shor.
It was that algorithm, and the promise it holds for its ability to break
large encryption codes, that spurred interest in quantum computing in the 1990s.
Quantum computing is one of several paths that researchers are taking as they
strive to make smaller and smaller microchips. Under Moore's Law, which was set
forth by Intel Corp. co-founder Gordon Moore, the number of transistors on a
chip doubles, or alternatively, data density doubles, every 18 months.
IBM said it has built a quantum computer based on seven atoms which, because
of the physical properties of those atoms, are able to work together as both the
computer's processor and memory. Previously the largest computer IBM had built
was based on five atoms.
IBM scientists said that they were able to use the computer to show that
Shor's algorithm works by correctly identifying 3 and 5 as the factors of 15.
"Although the answer may appear to be trivial, the unprecedented control
required ... during the calculation made this the most complex quantum
computation performed to date," Nabil Amer, manager of IBM Research's
physics of information group said. A quantum computer is based on the spin of an
electron or atomic nucleus.
In addition to encryption, other applications for quantum computing include
data mining, or searching large databases for particular pieces of information.
Amer said it is still unclear when quantum computers could become commercially
available.
John Preskill, professor of theoretical physics and director of the Institute
of Quantum Information at CalTech in Pasadena, California, said that the
experiment brought quantum computing a baby step forward by revealing errors in
the process.
"Part of the challenge of building large scale quantum computers is that
they are very susceptible to error and we need to understand the types of errors
that occur, as well, in order to know what's the most promising way of building
quantum computers," Preskill said.
To put the size of the computer into perspective, Preskill explained that
currently the fastest computers in existence, or supercomputers, could factor --
or find the smallest indivisible factors of -- a number that is 130 digits long
in about a month. But they wouldn't be able to factor a 200-digit number.
A quantum computer could tackle that task, he said, but it would need to
include thousands of quantum bits, or atoms. IBM scientists used the computer
based on seven atoms to factor a two-digit number.
(C) Reuters Limited.