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Looking around a bit I have found that most solutions for generating a true random number involves inspecting natural phenomenon.
But is it really necessary?
I mean, assuming that Pi has random infinite sequence of digits as far any system could tell, couldn't we just build an algorithm which will look something like this (assuming 64 bits architecture):

  1. Take the first 64 bits.
  2. Cast the bits into double
  3. Take next 64 bits
  4. Cast the bits into double
  5. etc...

Of course this could be enhanced (involving seeds, casting to Integers and so on...)

Does this sounds right or am I missing something?

Note:
About the assumption about pi, according to Wikipedia it is widely believed that Pi is a Normal number. Shouldn't this be enough? If it can't be disproved, Shouldn't it be enough for any practical system?

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    @AviTurner: But it's always the same series of random numbers, which destroys the purpose of an RNG. So let's say I wanted to use an RNG to generate a private key for my encryption. I generate a random number using the digits of pi, and get a key. Someone else generates a random number using the digits of pi, they get their key. Our keys are exactly the same- not a very good encryption. (As for Spurs #50, I think my profile picture leaves little room for doubt) Oct 23, 2013 at 6:14
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    @AviTurner: So you do agree that you need to decide how many steps to perform (unless you meant something else by "inserting a seed"). Now you're competing with other pseudorandom number generators such as a Mersenne twister: it takes a seed and it spits out a number pseudorandomly. The question is then whether pi is a good pseudorandom number generator, and it's not, for reasons rici discusses: it's just much slower than other pseudorandom approaches. (And slower often means fewer cycles, which means less secure). Oct 23, 2013 at 6:30
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    Unrelated: MAC address is not a very good seed: if someone discovered your MAC address (by hacking the router, for example), they could discover the seed. Better would be something like the least significant digits of your current computer time. Oct 23, 2013 at 6:33
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    Another note: there are 10 trillion known digits of pi. These take up 9TB of hard drive space and took almost a year of running on specialized systems (see here), but let's say you could use all of them in your RNG. There are 2^64=1.8*10^19 possible 64-bit integers, so the chance of a given integer appearing more than once in the series is < 1/10 million. That means that if you have an integer from the generator, you could find out the seed and predict the next one (and all future/past ones) just by searching for it in the series. Oct 23, 2013 at 6:46
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    @AviTurner: As some of the answers below state, it depends on what you mean by true randomness. Here you're really asking if pi offers "true pseudorandomness": randomness depending on a starting seed, which has to itself be generated in some random way. That's still not getting at the kind of randomness for which people turn to natural phenomena such as radioactive decay, which tries to avoid relying on that starting seed at all. Oct 23, 2013 at 7:04

3 Answers 3

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No, it's absolutely not possible!

On a deterministic machine, you can compute deterministic sequences. There is no randomness to be found. Even chaotic systems are just deterministic sequences.

You can indeed generate a deterministic sequence which appears to have the same distribution of digits as one would expect from a randomly generated one. But it's still deterministic.

Pi is completely deterministic: If you and I both generate the sequence of digits in Pi, we both get the same numbers.

I believe you are right in saying the distribution of digits seems to be uniform: but this raises the obvious question: where do we start? We need to choose a random place to start in the sequence to make it 'truly random': thus we are back to square one.

In practice we use sources of what seems to be randomness: Linux will look at times between disc accesses, and keystrokes, and the exact time. But with a little work we can predict all of these more and more accurately, or alter them by fixing our environment.

Hardware random number generators use quantum processes which are believed to be truly random. For example, performing a quantum measurement is believed to be a perfectly random process: no 'better' knowledge of the initial state can help predict the output state (as with chaotic systems).

A paper absolutely worth reading on this subject is "On random and hard to describe numbers" by Bennett, it's quite easy to find with a quick Google.

And here's a nice related XKCD :)

This reminds me of an XKCD...

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  • Look at the discussion I had with @DavidRobinson about entrance point. I agree that given an input, the same output will be given from the algorithm, but isn't it enough for any practical system? The numbers in a given system will be random. You are arguing that there is no randomness between a collection of series.
    – Avi Turner
    Oct 23, 2013 at 7:04
  • @AviTurner: In a comment on a different answer you said you weren't interested in practicality! Now you're saying "it's enough for practical purposes?" :-) Oct 23, 2013 at 7:05
  • @DavidRobinson You are correct. The discussion is just to interesting!
    – Avi Turner
    Oct 23, 2013 at 7:07
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    It's a different question: If you want 'true randomness'. This is not the way to go. If you want a pseudo-random sequence of digits with the correct distribution of digits. You could maybe use Pi. But there are much more efficient to compute sequences of digits out there that do the same thing. Plus, others have said it's not 'constant time per digit', so if you want to start at a random position, you are quite limited: an attacker 'knows' that you started early on in the sequence! - Also, you may have to compute all the way to the seed before you can continue generating? Oct 23, 2013 at 7:09
  • Also: say I use my random number to generate a random angle: using digits of Pi might not be such a good idea in this case! :) Oct 23, 2013 at 7:12
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Sure. But why go to all that trouble? Computing π is a complicated task, and it is hard to reason about the results. Also, as far as I know there is no algorithm which will produce digits of π in constant time.

On the other hand, pseudo random generators like the Mersenne twister are designed to be fast to compute, are easily seeded, and allow some amount of analysis (in the case of the twister, the cycle length, for example).

However you compute pseudo-random number sequences, you leave yourself open to prediction attacks if the algorithm is known. (That would be particularly easy in the case of mathematical constants like π.) If you're using the random number as part of a security system, the suspicion that the bad guys could predict the sequence would be an obvious vulnerability.

So for such purposes, "natural" phenomena can have their uses.

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  • Actually the question is just out of curiosity, no practical implementation for now...
    – Avi Turner
    Oct 23, 2013 at 6:27
  • In case your curiosity gets more acute: experimentalmath.info/bbp-codes/bbp-alg.pdf Note, however, that the algorithm described there is not linear; it slows down as you get further from the decimal point (another reason not to use π as a source of random digits.)
    – rici
    Oct 23, 2013 at 6:42
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Isn't Pi a natural phenomenon as well?

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  • True, but unlike the suggestion I have seen so far it does not require additional hardware for inspecting. This actually is a really good comment. Do you think than that the algorithm should work?
    – Avi Turner
    Oct 23, 2013 at 6:16
  • If you could at will subsample any piece of pi the infinite series, then sure. It doesn't seem like the best approach for random numbers though since the known sequence is well, known. See rici's answer.
    – sarwar
    Oct 23, 2013 at 6:23
  • Although, If I am not looking for it for security reasons, being known is not an issue...
    – Avi Turner
    Oct 23, 2013 at 6:31
  • Secure or not if someone can guess correctly better than 10% over infinite iterations guessing between 1-10 then either the sequence isn't random, or they're from the future!
    – sarwar
    Oct 23, 2013 at 6:35

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