# Algorithm for Interpreting For Uniform Bernoulli Sequence as Non-Uniform

I have a large, uniformly distributed sequence of binary digits (P(1) = P(0)) and I need to interpret this sequence of random bits as an EQUAL sized sequence of binary digits whose distribution is not uniform (i.e. P(1) != P(0)).

Specifically, I am looking for either of the following:

1.) an INVERTIBLE function F whose domain is equal to its range = the set of N bit binary sequences (i.e. a function whose domain = range = {0,1}^N for some fixed N) AND with the property that the function maps sequences of high entropy to ones of low entropy and vice versa as well as possible

Ideas?

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Shannon proved that it's impossible to compress a uniform random binary string. Compression algorithms exploit non-uniformity in the input distribution.

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Is this on AVERAGE or for any PARTICULAR such sequence. I am not trying to come up with magic compression; I am trying to create a completely worthless program that simply compresses a large, random, uniformly distributed binary sequence to win a prize. – user562688 Apr 4 '11 at 15:05
I assume you're talking about this challenge: marknelson.us/2006/06/20/million-digit-challenge . The relevant definition of compression is Kolmogorov compression, and almost all strings are not Kolmogorov compressible. – qrqwe Apr 4 '11 at 22:14
I doubt the unavoidability of it becoming an unreadable mess. You just need to structure your code in a way that suits the language. That is of course true in every language, but Java is singled out for it, usually by people unwilling or unable to adapt. – user562688 Jun 14 '11 at 19:15

There are a whole lot more high entropy sequences than low ones. If the function is both invertible and has domain equal to range, there's no way to do that mapping.

``````A = YourLargeSequence