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Are there any problems, for which all known algorithms require more than double exponential time?

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It's not terribly interesting, but you can get any arbitarty O(f(N)) for any function f(x). Simply by creating a storing a list of all the numbers from 0 to f(N). –  Nuclearman Mar 25 '14 at 15:25
    
So, for any given O(f(n)) we can construct a problem. –  Somnium Mar 25 '14 at 15:45
    
That is correct, at least in big O terms. Finding interesting problems with uncommon big O's can be a bit harder though. –  Nuclearman Mar 25 '14 at 18:12

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up vote 3 down vote accepted

The time hierarchy theorem ensures that problems of this sort exist. As a very contrived example that's used by the theorem, consider the following problem:

Given a Turing machine M and a string x, does M accept x within 222n steps?

This problem provably cannot be solved by a TM in under 222n steps, and since a TM can simulate a computer with only an n6 slowdown, this means that no computer can solve this problem in time o(222n).

Granted, this isn't really an interesting problem (I can't see why you'd want to solve this except in very contrived situations), but it's known that this problem requires triple exponential time to solve.

Hope this helps!

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Yeah, thanks! Interesting, is there any upperbound, than no problem exist, for which fastest algorithm is faster than that upperbound? –  Somnium Mar 24 '14 at 19:08
    
@user2992539 I'm not sure I understand what you mean - any algorithm gives an upper bound on the runtime needed, so the fastest algorithm can't be faster than the upper bound. –  templatetypedef Mar 24 '14 at 19:12
    
I was thinking about universal upperbound, that all problems can be solved faster. Maybe something like (n!)^(n!)^(n!) –  Somnium Mar 24 '14 at 19:18
    
@user2992539 All problems that can be solved have runtimes that are computable functions. Any function that grows faster than all computable functions will upper bound the runtimes of all problems that can be solved. For example, the Busy Beaver function will upper bound all runtimes. However, by definition, these functions can't be computed and we barely know anything about their runtimes, so it's hard to see if this is useful. –  templatetypedef Mar 24 '14 at 19:25

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