Creeping Toward 10 Qbits: Atomic Computing 113
RetroGeek points to this "New York Times article about a computer using atoms as switches. Give me twenty atoms and I'll break the RC5 contest." Going from 7 atoms to 10 is the order of the year, and if this keeps up maybe soon we'll need some slightly longer encryption keys, thanks.
Best Atomic Encryption Prize (Score:1)
I had too many atomic quantitities of C2H4Oh so do not blast me as a troll
Later
Can somebody explain this? (Score:1)
who cares about crypto... (Score:1)
Codebreakers are finally catching up... (Score:2)
Bill Gates is ahead of his time (Score:4)
Re:Best Atomic Encryption Prize (Score:3)
user slashdot2000
pword slashdot2000
parallel processing (Score:1)
i'm gettin wet. i should go.
Run, Mr. Freeman! (Score:1)
Might wanna warn Gordon about the possibility of a resonance cascade.
The One,
The Only,
--The Kid
thougths (Score:4)
I'm sure the Czech crew [i.cz] who released the PGP advisory this week would love the same kind of computing. (more historical [antioffline.com] codebreaking)
Seems entirely over my head (the level of computing obviously) but here would be some nice uses for this level of computing.
I wonder how old I'll be before a computer like this is something like what a c64 is in nowadays. Just think scientists where developing this starting in 1994 (from what I saw on NYTimes), imagine when the level of computing in 20 years, or would it all come crashing down. Scary thought. Anyone care to reply with links to basic quantum computing information you care to share?
Privacy Links [antioffline.com]
Re:Run, Mr. Freeman! (Score:1)
Yes, but... (Score:1)
I wonder how this will affect Moore's Law... (Score:1)
Also, will the software industry be able to keep pace, writing bloated code to run on these things?
-Scott
Re:Yes, but... (Score:1)
VB bugs caused by "third state" (Score:2)
1) up
2) down
3) dead kitten AND live kitten (superposition)
Does this mean that we'll use a new, post-boolean algebra on trinary computers, or will we be running a binary system which gets internally compiled down into operations involving QBITS?
Maybe the third state will be soaked up by the error correction mentioned in the article...
I actually think it would be cooler to have a binary computer, but the third state really did represent an unknown and mysterious simultaneously true and false state...
dim x as boolean
x=MyComplexMethod("goat",45,"all your base")
if x=true then
print "Yes- true"
else
if x=false then
print "No- false"
else
print "WTF is up with this?"
endif
endif
other Quantum *info* (Score:2)
here are some good introductory articles, and btw (Score:3)
Introductory articles on quantum computation> [qubit.org]
Quantum cryptography (Score:2)
Re:I wonder how this will affect Moore's Law... (Score:1)
Hey, I've got an idea! Let's use gluon fields with the gluons as the transistors in thequantum computer - that way, when we need another gluon, we just increase the field size! Just another interesting quantum effect tidbit you really wouldn't care to know: by increasing the distance between two gluons, you can make more between them - which is why the strong force increases in strength with distance, to a point.
Yet I digress.
-Leo
Re:Can somebody explain this? (Score:1)
Re:Bill Gates is ahead of his time (Score:2)
Re:VB bugs caused by "third state" (Score:2)
Re:thougths (Score:1)
A great Scientific American article on the subject ("Quantum Computing with Molecules") can be found at http://www.sciam.com/1998/0698issue/0698gershenfe
High Hopes, Big Lasers... (Score:4)
And no one has EVER gotten an Ion-Trap quantum computer to do ANYTHING. Not add two numbers. Not factor a number. Not multiply two numbers. The potential is there - the qubits - its just no one has ever tapped it in a feasible way.
I'm sure people said the same things about transistor based computer back in the day, but I really, really feel that the Ion Trapping method is not going to be the type of QC we'll see in practical use anytime down the road.
Moore's law again (Score:1)
Just when we we getting worried about Moore's law failing, here comes someone getting ready to take the acceleration curve and golf it into warp drive.
Damn!
Re:not a qbit (Score:1)
Consequences of solving NP probs in P time? (Score:2)
Remember that a lot of the problems that are in NP can be approximated pretty well. If you were actually routing travelling salesmen around the US, you might not mind a solution that's off by a few percent (particularly when there are going to be a whole pile of other sources of error; your salesmen getting stuck in traffic jams or dallying with housewives, etc.).
Can anyone offer some problem domains where quantum computing would offer more than an incremental improvement (discounting crypto, which seems to be a case of gain a little, lose a little)? I'm not claiming that such domains don't exist, btw. I'd be delighted if someone could point out a few.
Re:Don't (Score:1)
Quantum Computing Basics (Score:2)
It's a bit dated (from 1998) but the principles are the same.
Re:Consequences of solving NP probs in P time? (Score:3)
Second, I believe an algorithm is known that can do lookups in unsorted, unindexed lists in O(log(n)) time. That is certainly an interesting proposition.
Third, encryption *is* a big deal. You or I are not necessarily worried about someone developing a QC to read our email, but governments are.
Finally, there are a number of protocols in quantum cryptography and quantum information that are not general purpose quantum computers, but might be very useful. Also, we don't really know what a quantum computer might be capable of, and won't until we have one built.
Right now, the reason people are building bigger quantum computers is because they want to study them, not because their computing power (even for "easy" quantum problems like finding large prime factors) is going to be usable any time soon.
Even Microsoft.... (Score:1)
A bit about Quantum Computing. (Score:1)
"The good thing about Alzheimer's is that you can hide your own Easter eggs."
practically every combinatorial optimization prob (Score:3)
For more info on P vs. NP, see the classic Computers and Intractability: A Guide to the Theory of NP-Completeness by Garey and Johnson.
Note, by the way, that quantum computers are not generally thought able to solve NP-hard problems in P-time. They can solve in P-time a class of problems called QBP, which is believed to sit between P and NP in difficulty. Quantum computing suddenly got a lot of press when Peter Shor discovered that factoring is in QBP. However, factoring is probably not NP-hard.
Re:VB bugs caused by "third state" (Score:1)
Re:Can somebody explain this? (Score:2)
Each bit is always a 1 or a 0. In a quantum computer they are represented by an elections spin, so if it is spinning clockwise it is a one, counter-clockwise is a zero. Because of all sorts of wierd arsed quantum stuff an electon can have multiple states, so it can represent a 1 and a 0 at once which is why in the article it says the quantum computer can perform multiple instructions at once. The electrons state is then manipulated using lasers, or radio waves.
The main problem which this article is saying they are closer to solving is that the state of an electron is very unstable and can be easily corrupted by all sorts of things, another passing electron for example.
I may be wrong about all of this, so if I am wrong please tell me, but this is how I think they are working.
Re:Can somebody explain this? (Score:2)
this will be reall interesting soon... (Score:1)
This will get really interesting when we have computing at a molecular level, but we can grow huge clusters of them like fruit or vines. Now that'll rock. Welcome to the next universe, baby!
Is this my idea or has anyone read about this organic computer idea somewhere before?
http://www.hyperpoem.net
NMR is dificult to scale (Score:1)
This work is impressive, but NMR-based quantum computers have some special scaling problems. The net spin polarization of these liquids at room temperature is very small- about one part in a thousand roughly. This means that the quantum computation is done with only the slightest of distinction between 0 and 1. That can be handled for small computations, but the signal to noise problem becomes severe for larger systems.
The current quantum error correction codes impose a large bit overhead (factor of three or so), which compounds the signal/noise difficulty of the NMR technique.
The nice thing about this method is that the nuclei are well-isolated inside the electron clouds and decohere slowly. However, my guess is that NMR-based quantum computing will be first out of the gates, but will lag behind other implementations before reaching the finish line.
Still catching up to the ancient Egyptians. (Score:2)
--
Re:VB bugs caused by "third state" (Score:1)
Re:Can somebody explain this? (Score:1)
Re:not a qbit (Score:1)
Re:High Hopes, Big Lasers... (Score:1)
Re:Can somebody explain this? (Score:1)
Re:Consequences of solving NP probs in P time? (Score:1)
In any case, whether quantum computing can solve NP-complete problems in polynomial time is an open question.
really? (Score:1)
Grover's algorithm is O(n^0.5).
Title (Score:1)
Re:Bill Gates is ahead of his time (Score:1)
matt
progress and foreseeing (Score:1)
2. We all know that the NSA is de facto "a little bit" ahead in this subject, due to their obfuscation of their existance and all the matter of cryptology during the 70s.
3. The US government decided to "open up" to allow the use of "strong" encryption to the rest of the world.
1+2+3=> I'm seriously thinking that the NSA itself could have gained enough computing power (quantum computing? does it look less impossible now?) at the time they started opening the key-size barrier.
time will prove me wrong, hopefully.
And don't forget JVM (Score:1)
Re:High Hopes, Big Lasers... (Score:2)
It's about NMR based QC, using multiple 13C atoms in a molecule as multiple q-bits.
Re:High Hopes, Big Lasers... (Score:1)
Seriously, there are two sides to the story, or in this case the research. Your side, with big fat equipment which hits the news every now and then when it breaks another barrier, and the side looking at how nature et al implements quantum computers. AFAIK, there is still ongoing investigation into whether and how every one of our cells utilises the quantum nature of particles in DNA manipulation - and if it is possible under the conditions in a human cell, it should certainly be possible in a home PC.
Going back to your analogy of the transistor, I would disagree slightly. I would say that quantum computing is still in its 'valve' era or even before that. Noone has yet made the 'quantum transistor' that will help it take the leap from the theoretical and laboratories into first business and then the home.
Of course, it may yet just not work ;-)
Beg:
Anyone care to put a timescale on this? (Score:1)
Personally, I think the major advances will happen once companies such as Intel begin to hit fundemental barriers in creating silicone chips. Then we'll see some real money being thrown at optical and quantum computing, by companies who work by results rather than by scientific interest.
This is kind of an informed guess, but:
- 7 to 10 years: Silicone begins to run out of steam
- 15 years: First useful optical computers
- 20 to 25 years: Silicone is gone, optical is mainstream
- 50 years: Quantum computers do something useful for the first time
- 75 years: Quantum computers begin to be used by large companies
- 100 years: Quantum computing is mainstream
Hopefully, I'll be around to see all of the above!
Anyone else care to reply with their own timescale?
Beg:
Link not requiring registration (Score:1)
Practical NP complete proofs (Score:1)
If QC is achieved these transformation algorithms will have practical importance. Yet another thing I learnt in school that seemed useless at the time but maybe isn't
Re:High Hopes, Big Lasers... (Score:1)
Re:Practical NP complete proofs (Score:1)
Re:Yes, but for 2 atoms, you get a bigger superpos (Score:1)
The only reason you get superpositions is because you haven't measured the state yet, as when you have a kitten and a puppy (in separate sound proof boxes of course.)
Without looking in the boxes you can't tell whether the kitten or the puppy are dead or alive.
(obviously if you forgot to put holes in the box so they could breathe, they'd both be dead.)
By opening the box the kitten decides whether it is alive or dead and the same with the puppy.
Which asks the questions.
Can you use animals for quantum computing, or are the costs of feeding them too high?
and
If a tree is in a wood, and no one is around, is it still standing or is it falling down or is it in a supositioned state, until someone goes to look at it?
And of course then you have to ask if you don't know nothing about anything does anything exist?
Re:High Hopes, Big Lasers... (Score:2)
I admit that this is no more than gut feeling, though, I am neither a chemist nor a physicist.
Re:VB bugs caused by "third state" (Score:2)
heh, the problem being that by virtue of VB programs' tendancy to allocate memory extremely poorly, VB:QE (quantum edition) might inadvertantly be running out of control one day and by virtue Heisenberg (et al.) end up running on (and screwing up) every atom in the known universe. Maybe this is MS's secret plot for world domination by atomic subjugation[1]?
[1] Bill. Boris. Natasha. Lordy, do I need sleep.
--
News for geeks in Austin: www.geekaustin.org [geekaustin.org]
Re:Best Atomic Encryption Prize (Score:1)
http://channel.nytimes.com/2001/03/27/science/2
Re:WARNING: GOATSEX LINK (Score:1)
you need 64 qubits to break rc5-64 ... (Score:1)
Re:Run, Mr. Freeman! (Score:1)
Oh dear, I do appear to have been seriously wounded.
C'mon, a crowbar? You're kidding, surely man! I scarcely touched you! But my, what a nasty cut.
Re:I wonder how this will affect Moore's Law... (Score:2)
Moore's Law is _not_ to do with computing power, but with gate size/density.
e.g. here is the first thing a web search provided:
http://www.webopedia.com/TERM/M/Moores_Law.html
THL
--
Re:here are some good introductory articles, and b (Score:1)
I've got a nasty feeling I haven't got a clue what I'm asking... Ooops!
THL
--
Re:VB bugs caused by "third state" (Score:1)
Elliptic curve cryptology (Score:1)
Can anything be proven about the possibility of such a "quantum algorithm" existing if not?
Re:High Hopes, Big Lasers... (Score:1)
Surfing the net and other cliches...
The Emporer's New Car (Score:1)
Wow, I never knew Roger Penrose was an expert in DNA as well as neurology.
I've heard he's working on a theory that motor cars operate at the quantum level also.
Windows already uses quantum effects (Score:3)
Windows already uses quantum effects. Just looking at it will make it crash....
</Humor>
Hot Qubits (Score:2)
need clarification (Score:1)
I'm confused; what sort of quantum system ran Shor's system or the basic quantum search algorithm?
Biometric Security (Score:2)
They'll also need 64-bit hardware. Goodbye 32-bits and that other unportable OS won't make it there will it?
an article for you (Score:2)
So how many atoms .... (Score:2)
Hybrids (Score:1)
Or are they completely incompatible?
Re:I wonder how this will affect Moore's Law... (Score:1)
ie. Finding a 2048 bit encryption key with a 2048 qubit quantum computer would take no more than ONE calculation.
So, by adding more qubits, you're not 'doubling' the processing speed because a 2049 qubit quantum computer will still solve things as fase as a 2048 qubit computer
The only difference is now the 2049 qubit quantum computer can solve a bigger problem.
Factoring "probably" not NP-hard? (Score:3)
That's as opposed to Travelling Salesman where even if you have a proposed path, you'd have to check all possible paths to decide if yours was the minimum.
--
Re:Yes, but... (Score:1)
--Bill Gates, The Road Ahead, Viking Penguin (1995), p. 265.
You may want a new key anyhow... (Score:1)
The uber-paranoid may want to revoke their old private keys and issue new ones anyhow... According to this report [cryptome.org] on cryptome.org [cryptome.org], a serious flaw was found in OpenPGP and its derivatives which leaves your private key vulnerable to attack.
Moore's Law... (Score:2)
10 atoms this year
20 atoms by early 2003
40 atoms by late 2004...
By the 22nd century, the entire universe will be a computer. Or is it already?
Re:Uhh, no (Score:1)
Re:Bill Gates is ahead of his time (Score:2)
--
Re:Hot Qubits (Score:1)
Re:The Emporer's New Car (Score:1)
New meaning to "Nobody will ever need" (Score:2)
"Nobody will ever need more than 640KB RAM." -- Bill Gates.
Maybe he meant 'more than 640 atoms' or 'more than 640KB RSA'?
SQUIDs (Score:1)
These devices have excellent magnetic sensitivity. And when two of these thingies are coupled, you have your information travelling between one another through insulators at awesome speed (in these, even the superconducting electrons tunnel through).
Incidentally, I'm also working on SQUIDs, although on a theoretical basis. Getting to make a SQUID is, well, a little tough... So we are trying to find guys who'd give us Liquid Helium for free
Another interesting thing to do would be to quantumly couple 2 SQUIDs!!! And imagine building a Beowulf cluster of *those* !!!
"...Fear the people who fear your computer"
Re:need clarification (Score:1)
It's like when you write programs for PRAMs in your parallel algorithms class. The algorithms are fine and all, but PRAMs don't exist.
--
Re:Factoring "probably" not NP-hard? (Score:1)
Your definition of NP-hard is way off. A problem being NP-hard means that all problems in NP are reducible to that problem. In plain english, it means that a quick solution to an NP-hard problem would yield a quick solution to all problems in NP. A problem that is both NP-hard and in the set NP is called NP-complete.
Satisfiability is NP-hard (as it is NP-complete), and it can be verified in polynomial time (just verify that the formula evaluates to true given the binding). In fact, any NP-complete problem can be verified in polynomial time as having this property is one way to define the set NP (languages with polynomial time verification proofs).
Verifying a factorization answer is easy: just multiply. That's polynomial time, therefore factoring isn't NP-hard.
Again, this is way off. Most problems in NP are known to be either NP-complete or in the set P. Factoring is one of the few that is not known to be in either category. I believe graph isomorphism is another. You can't just say factoring "isn't" NP-hard. It hasn't been proven that it is not. Researchers don't think it is, but until it is proven to be in P, this is just a hunch.
That's as opposed to Travelling Salesman where even if you have a proposed path, you'd have to check all possible paths to decide if yours was the minimum.
Here you are confusing problems and languages. Technically, when I mentioned 'problem' earlier, I should have said 'language'. Problems must be phrased as languages to apply complexity theory to them. When you frame Travelling Salesman as a language, it looks something like: "Does this graph have a salesman path of length less than x?" Languages must have yes/no answers, unlike the open-ended Travelling Salesman problem. Phrased as a language, even Travelling Salesman has polynomial time verification (as it should as it is NP-complete).
Re:High Hopes, Big Lasers... (Score:1)
Ions are not magic, they're just electrically charged atoms. I've got four tubes of ions right over my head; I use them to light my office. Electric arc are visible because of the ionization of the air and the recombination of the ions with the free electrons. The Sun is a ball of ionized gas.
Here at work we have desk-top ionizers to reduce the chance of ESD damage to electronic components. They emit a spray of charged particles that are good at slowly, safely dissapating static charges on nearby objects.
Ions are not dangerous. Beta-particle radiation, which is of course merely helium nuclei, are +2 ions. They don't penetrate the human body past the first few layers of skin. A piece of paper is an adequate shield against beta radiation.
Oh-- how many of you drink Gatoraid or other salt-containing drinks? In what form does one find NaCl dissolved in water? Here's a hint: NaCl contains an ionic bond between the atoms. In water, the sodium and the chlorine atoms disassociate and become free ions.
I'm going to go now and drink my ion-laden sports drink ;)
Re:Anyone care to put a timescale on this? (Score:1)
Perhaps you meant Silicon, without the "e."
Remember, there are other semiconductors other than Silicon. Gallium Arsenide (GaAs), for instance, is used extensively in MMIC (Microwave Monolithic Integrated Circut) chips, where Silicon would not perform as well.
Vintermann's Nightmare (Score:1)
Yet. Quantum computers. There's one technology I hope never comes real in my lifetime. Looks like I'll be disappointed, I had no idea they had come this far.
Why? Because it will mean an end to public-key cryptography forever. Even if we manage to restore secure communication through quantum cryptography, digital signature technology will be lost.
I had great hopes for digital signatures. Here was a technology that gave the truth an edge over lies. Imagine a digital videocamera with a tamper-resistant chip wired into it that signs the video data regularly. Then connect it to a UMTS mobile or a satelite phone, give it to a brave man and send him to say Palestine. Make it so that it can't easily be turned on and off. You have a pretty damn good witness.
The loss for crypto is also sad. Today if I e-mail with a teacher at Birzeit, we can use crypto to aid in his safety. If the adversary, in this case Israel, gets a QC they can easily intercept this mail, kill him and create credible faked reports supporting their case. And if QC's become a reality, states will get it first, and possibly the public will never get it.
Public-key cryptography seemed to provide an antidote to big-brother type scenarios. But in a world where states have QC's we will be back were we was most of the 20th century: where you can never know very much about what's truth and what's propaganda, and the best you can do is support "your side". The best I can think of is praying.
Better suggestions are welcome.
Big Iron May Win In The End (Score:1)
If it works out that Q-Comps are both *incredibly* more powerful in raw capacity (likely) and require special facilities (also likely), then we'll see a return to the architectures of the 70's and 80's, when Iron was Big and the Glass House was king.
In such an architecture, distributed platforms would be used to handle UI and interpretation, and the processor time to brute-force the calculations would be rented. A lot of the paradigm we've come to take for granted is very recent, and would have to be rethought in such an environment. Just as an example: Q-Comps could have the raw power to accurately simulate the physics of an FPS with hundreds of simulataneous players down to a microscopic level. Then an abstract of that could be transmitted to the players. Welcome to the Holodeck, boys.
--Dave Rickey
Re:Vintermann's Nightmare (Score:1)
Why? Because it will mean an end to public-key cryptography forever.
What?! This just is absolutely FALSE!
(1) Public key cryptography is secure because of the difficulty of a particular computational task. For example, in RSA, that task can be mapped onto factoring numbers
(2) Quantum computers provide algorithmic speedup of some algorithmic tasks. For example, quantum computers can factor numbers efficiently.
Now (1) plus (2) does NOT imply all public key cryptography schemes are insecure because not all public key cryptography schemes are built on problems that quantum computers are known to be able to handle efficiently. For example, it is possible (though encoding and decoding times are ugly, I've been told) to use an NP-complete problem as the computational roadblock in codebreaking. As of today, we do now know how to solve NP-complete problems efficiently on either a classical or a quantum computer.
And remember, the security of public key cryptography like RSA is not "proven": it relies on the "difficulty" of a computational task. People really believe it is difficult to factor numbers classically. Why? Because they have been banging their heads up against the problem for quite a few years. But proof by exhaustion is no proof at all: just evidence.
So the main jist is: public key cryptography as a whole will NOT be destroyed by building quantum computers. Certain schemes which you bought into because you believed that factoring is hard WILL be broken, however.
Finally I would like to point out that quantum cryptography is a way to establish a secure key distribution. The security of this scheme is based not on some conjectured hardness of a problem, but instead on the belief that quantum mechanics governs the physics of the universe.
Dave Bacon
Re:Consequences of solving NP probs in P time? (Score:1)
Solving something faster doesn't mean that it's not in polynomial time...you just did it faster. Hell, the P problems will be even faster too...doesn't meant that they're now done instantly...they're just done faster.
Now, if someone can reduce a NP-Complete problem to P...that would be pretty friggin cool...that and it would destroy all modern mathematics theory as we know it.
Re:Moore's Law... (Score:1)
Rick
p.s. Bob Sewell is a friend of mine, known far and wide for the level of cynicism expressed in this quote. OTOH, he's good enough to earn being cynical.
Re:Vintermann's Nightmare (Score:1)
There is to my knowledge no PK system today that uses an NP-complete problem. I believe Diffie and Hellman experimented with a knapsack-based system which was NP-complete (or it's possible it was just proven to be NP-hard), but it turned out you didn't need to solve the underlying problem after all. So they used a discrete log based system instead.
I admit I don't know so much about this as I wish I did, if you can reassure me there's no need to worry then that's great
As to elliptic curve problems, I've read that the main objection is that although NFS won't work, there's nothing mathematically that says that elliptic curve problems will be harder to solve in polynomial time than the others; it just hasn't been worked on so long.
If you know of a working public-key system that uses an NP-complete problem, please give me a link!
Re:Best Atomic Encryption Prize (Score:1)
Re:New meaning to "Nobody will ever need" (Score:1)
it worked! (Score:1)