# Is there an algorithm to find the Shannon entropy for text?

I know the Shannon entropy for English is 1.0 to 1.5 bits per letter and some say as low as 0.6 to 1.3 bits per letter but I was was wondering is there a way to run an algorithm that looks at a large volume of text and then determine the expected value of the collective text is say .08 bits per letter of the collective text?

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It's difficult to measure that in a completely meaningful way, as entropy is by definition a probabilistic measure. I can compress any given text down to a single bit, using a compression scheme that maps that bit back to the original text. And that's absolutely fine, if I only ever need to represent two different texts. So in that context, the information content of your text is 1 bit. –  Oli Charlesworth Apr 8 '12 at 21:09
Thanks for the response. Is there a way to measure the redundancy of different text? So say you have two sets of text with 1000 words, could you measure if one text is more or less redundant than the other text? –  Polo Montana Apr 8 '12 at 21:26
Not without some context. It's possible that one of the texts was generated by a pseudo-random number generator, in which case it's completely redundant (other than the value that was used to seed the generator). All you can say is that in the context of certain rules (e.g. predicting current letter from previous two letters), you can compress the text by a certain ratio. But choose different rules, and the results will be different. –  Oli Charlesworth Apr 8 '12 at 21:28
The basic problem is that you must figure out how "predictable" the next bit in a bit stream is, given what's gone before. Though there are many different compression algorithms that make use of known predictable features, there is no way to quantify all the ways that something might be predictable. Just think -- some friends you can predict word-for-word what they will say in a given situation, and some friends will use the same phrases over and over but in a different sequence, while other friends are totally unpredictable. –  Hot Licks Sep 15 '13 at 14:20
You'll get a reasonable estimate by compressing the text (eg: gzip) and look at the compression ratio. A "standard" text can probably be compressed downto 10...20 % of its original size. –  wildplasser Dec 10 '13 at 1:19

The mathematical definition of the entropy rate of a language is, if you have a source that generates strings in that language, the limit of the entropy of the nth symbol, conditioned on the n-1 previous ones (assuming that the source is stationary).

A good enough approximation of such a source is a large corpus of English text. The Open national american corpus is pretty nice (100M characters, covers all types of written texts). Then the basic algorithm to approximate the limit above is to look, for a given n, at all n-grams that appear in the text, and build a statistical estimate of the various probabilities that occur in the definition of the conditional entropies involved in the calculation of the entropy rate.

The full source code to do it is short and simple (~40 lines of python code). I've done a blog post about estimating the entropy rate of English recently that goes into much more details, including mathematical definitions and a full implementation. It also includes references to various relevant papers, including Shannon's original article.

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N-grams are not as powerful as general data compression. N-grams will therefore overestimate the Shannon entropy. Compressors like PAQ hold the world record for compression and are the best Shannon estimator known to mankind at the moment. –  usr Dec 17 '13 at 9:10

The Shannon entropy value for text is estimated. It is beyond human power to ever find out exactly. You can estimate it by running efficient compression algorithms over it (PAQ) or use humans to predict the next letter of a given string. Humans will do a good job because they apply semantic knowledge, not just statistical knowledge or syntactic knowledge.

Short answer: Try to compress the data/text you have as well as possible and calculate, how many bits you empirically needed.

It depends on the concrete algorithm what you can get the number down to. This will always just be an upper bound on the Shannon entropy (remember that the exact value will never be known).

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Thanks for the response. Do you know of any software downloads that compress data/text and gives you the data compression ratio? –  Polo Montana Apr 8 '12 at 21:43
The compression ratio in "bits/character" is (compressedSizeInBytes / originalSizeInBytes * 8). –  usr Apr 8 '12 at 21:46
@PoloMontana: Just use your favourite compression tool, and compare the file size before and after. –  Oli Charlesworth Apr 8 '12 at 21:46
Thank for the responses. I know exactly what I need to do now. –  Polo Montana Apr 8 '12 at 21:48
@usr I'm not positive that what you suggest would be a good measure (though I agree it's on the right track). First off - we should stress that this is an upper bound to the Shannon Entropy (SE). Second, we should compare the compressed size to the same text but randomly permuted. One could imagine that there is some compression that is encoding specific, this should not be counted as part of the SE. Presumably the permuted text can not be compressed as much as the original, and that difference is the crucial measure. –  Hooked Apr 9 '12 at 13:43