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D-Wave's quantum computer overcomes key math challenge, doesn't silence skeptics
D-Wave has long wanted to show that its quantum computing technology is the real deal, and it may have just come closer to proving its case. The company now says that its computer has calculated Ramsey numbers, or solutions to optimization-based math problems that are sometimes difficult to find using traditional systems. The computation represented one of the biggest-ever implementations of an algorithm, according to researchers. However, the feat isn't necessarily proof of quantum computing at work. As Wired explains, we've seen all of these numbers in previous experiments; the challenge wasn't difficult enough to require the involvement of a quantum computer. However, D-Wave may have better evidence in the future. Its third-generation system, due in 2015, should have enough power to find Ramsay numbers that are theoretically impossible to calculate today.
World's first "commercial" quantum computer solves Sudoku
As expected, Canada's D-Wave Systems has announced "the world's first commercially viable quantum computer," and they seem to be pretty stoked about it. The achievement is notable, since they've managed to build a whole 16 qubit computer that actually does some simple computations, even if it's far less powerful than even the most basic of home computers. Qubits are quantum bits that can be in an "on," "off" or "both" state due to fuzzy physics at the atomic level, and up until now the best anyone had done was get three qubits together for computing. This 16-bit version can solve Sudoku, create a complicated seating plan and search for molecular structures, but quantum computers will need to be in the range of thousands of qubits to be able to solve puzzles -- such as encryption -- that current computers cannot. D-Wave is planning to have a 1,000 qubit version ready by the end of next year, but scientists in the field are skeptical. The adiabatic method used by D-Wave, which cools electronic circuits into a superconducting state, with the resulting qubits being slowly varied in a magnetic field, might not be able to keep its speed when on that large of a scale. "It probably won't work but it's not quixotic," says Seth Lloyd of MIT. "If it works then they can solve really hard problems and they'll be very much in demand," he says. But it's a long shot: "It's certainly not the kind of company I'd invest my money in." To raise awareness, D-Wave will be opening the computer up to computational problems over the internet after the results of the project are peer-reviewed. More pics after the break.[Via Digg]
