Shannon's Theorem is defined in terms of random data and probabilities. Similarly, the *entropy* of a string is only defined for random strings -- the entropy is a property of the distribution, not of the strings themselves. So, we can restate Shannon's Theorem informally as:

If you randomly select a string from a given probability distribution, then the best average compression ratio we can get for the string is given by the entropy rate of the probability distribution.

Given any random string, I can easily write a compression algorithm which will compress that string down into 1 bit, but my algorithm will necessarily increase the length of some other strings. My compression algorithm works as follows:

- If the input string equals
*some pre-chosen random string*, the output is the 1-bit string "0"
- Otherwise, the output is the N+1-bit string of "1" followed by the input string

The corresponding decompression algorithm is:

- If the input is "0", the output is
*our previous pre-chosen random string*
- Otherwise, the output is everything except for the first input bit

The key here is that we can't write down *one* algorithm which, for all strings from a given distribution, compresses them *all* at a high rate on average. There's just too many strings.

If we have a given probability distribution of strings, we can calculate the entropy rate of the distribution, and then if randomly pick a string *according to the distribution* and attempt to compress it using **any** algorithm, the relative size of the compressed string will, on average, never be less than the entropy rate. This is what Shannon's Theorem says.