IBM Builds A Limited Quantum Computer

phr1 writes "IBM has announced and Yahoo has noted that the first working implementation of Shor's factoring algorithm. Using NMR techniques they built a seven-qubit quantum computer and factored the number 15 into the factors 3 and 5. This is by far the most complicated quantum computation ever done. It's quite an amazing feat--many people thought quantum computing was just a theoretical curiosity and Shor's algorithm could never be implemented in practice."

An Introduction...

[GFish4]

My brother found this for me not too long ago. The math involved can get rather intense, but I think it 's worth pointing out:

An Introduction to to Quantum Computing for Non-Physicists - Available in PDF, PostScript, and others.

If you do a google search, you probably can find it elsewhere, also.

--GFish4

Re:Frightening implications

[internic]

While I have also often heard stories of the NSA having much more advanced equipment and techniques than the private sector, or at least than the non-classified private sector, in the case of quantum computing this is unlikely. First, it's a relatively new subject. Shore's algorithm, for example, was only discovered in the 80's. There really hasn't been enough time for them to get so far ahead. Second, the NSA is full mostly of mathematicians and computer scientsts, not physicists, so they really don't have the right staff for that. Third, most of the academic research is funded by the NSA.

Finally, though it's hard to say exactly how far this technology is from being useful (or alternately the probability that it will EVER be useful), it is probably safe to say it will be quite a while from now. Moreover, it is probably also safe to say that it only gets harder from here. Larger computations will involve the same problems as these only on larger scales plus a whole new, tougher, slew of problems that these avoid. These are chiefly quantum decoherence and entangling large numbers of quantum states.

Quantum decoherence is the loss of the special quantum information (quantum phase relations) that allows quantum computers to do their funky magic. This happens over time in any system that has any interaction with the outside world. I think these small calculations largely avoid this problem because they are reasonably fast. Larger ones involve more steps and thus will run up against these problems. Some error correcting quantum codes have been developed, but these involve even more qubits, which exaserbates the other problems, and are still largely in the formative stages.

The other big hurdle is entangling much larger numbers of particles in one state. These take advantage of the interactions between different nuclei in the same molecule. Once you need many more qubits, you will need to come up with a more general scheme for entangling the quantum states, because it's unlikely that you'll be able to engineer a molicule for the purpose. Also, the bigger you make your system, the more strongly it interacts with the outside world and the worse decoherence becomes....Life's a bitch, ain't it?

So, I think this is really exciting and quantum computers have great promise, but I don't expect to have a quantum co-processor in my PC any time soon, nor do I really think it's likely that the NSA has a quantum supercomputer sitting in the back room decrypting my credit card information.