# How do I compute the approximate entropy of a bit string?

Is there a standard way to do this?

Googling -- "approximate entropy" bits -- uncovers multiple academic papers but I'd like to just find a chunk of pseudocode defining the approximate entropy for a given bit string of arbitrary length.

(In case this is easier said than done and it depends on the application, my application involves 16,320 bits of encrypted data (cyphertext). But encrypted as a puzzle and not meant to be impossible to crack. I thought I'd first check the entropy but couldn't easily find a good definition of such. So it seemed like a question that ought to be on StackOverflow! Ideas for where to begin with de-cyphering 16k random-seeming bits are also welcome...)

What is the computer science definition of entropy?

Entropy is not a property of the string you got, but of the strings you could have obtained instead. In other words, it qualifies the process by which the string was generated.

In the simple case, you get one string among a set of N possible strings, where each string has the same probability of being chosen than every other, i.e. 1/N. In the situation, the string is said to have an entropy of N. The entropy is often expressed in bits, which is a logarithmic scale: an entropy of "n bits" is an entropy equal to 2n.

For instance: I like to generate my passwords as two lowercase letters, then two digits, then two lowercase letters, and finally two digits (e.g. va85mw24). Letters and digits are chosen randomly, uniformly, and independently of each other. This process may produce 26*26*10*10*26*26*10*10 = 4569760000 distinct passwords, and all these passwords have equal chances to be selected. The entropy of such a password is then 4569760000, which means about 32.1 bits.

• This is correct but I may not have asked the question correctly. See the answer I gave which perhaps indicates the question I meant to ask. But I think it may in fact be standard to refer to the "approximate entropy" of a bitstring. Regardless, this answer is useful and relevant; thanks! Jun 8, 2010 at 18:18
• @specializt The answer has constraints for the characters, so the available alphabet is not 36 characters for every character in the password. For unconstrained 8-character passwords from an alphabet of 36 characters, your calculation is correct; but with the explanation in the answer, the added constraints actually make it more interesting, and somewhat more illustrative. Aug 27, 2015 at 9:34
• @tripleee the constraint in this answer is exactly "36" -- a-z and 0-9. Also : you are contradicting yourself - at first you acknowledge that i calculated that very constraint and immediately after that you claim its "unconstrained". Are you confused, perhaps? Aug 27, 2015 at 9:56
• The constraints are that the first two are lowercase alphabetics (alphabet is 26 characters), the next two are numbers (alphabet is 10 characters), etc. I don't see how I can make this any clearer than it already is. Aug 27, 2015 at 10:04
• Sheesh. Under those constraints. 00000000 violates the constraints. Within the group of first two alphabetics, they are chosen randomly, uniformly, and independently. Then two digits are pulled out of the digit pool, randomly, uniformly, and independently. Aug 27, 2015 at 10:13

Shannon's entropy equation is the standard method of calculation. Here is a simple implementation in Python, shamelessly copied from the Revelation codebase, and thus GPL licensed:

import math

def entropy(string):
"Calculates the Shannon entropy of a string"

# get probability of chars in string
prob = [ float(string.count(c)) / len(string) for c in dict.fromkeys(list(string)) ]

# calculate the entropy
entropy = - sum([ p * math.log(p) / math.log(2.0) for p in prob ])

return entropy

def entropy_ideal(length):
"Calculates the ideal Shannon entropy of a string with given length"

prob = 1.0 / length

return -1.0 * length * prob * math.log(prob) / math.log(2.0)

Note that this implementation assumes that your input bit-stream is best represented as bytes. This may or may not be the case for your problem domain. What you really want is your bitstream converted into a string of numbers. Just how you decide on what those numbers are is domain specific. If your numbers really are just one and zeros, then convert your bitstream into an array of ones and zeros. The conversion method you choose will affect the results you get, however.

• Ah, thank you! But this requires you to know the word length in your bit string? For example, I could apply this to my string of 16,320 bits if I assume that those are really 2040 bytes. Jun 5, 2010 at 4:56
• If you convert to just ones and zeros then won't this algorithm treat "0101010101..." as having the maximum possible entropy? Jun 5, 2010 at 5:25
• As per cypherpunks answer, this assumes a model where every character is equally likely at every position. Jun 5, 2010 at 12:34
• @fmark @dreeves The information entropy depends on the number of states available. As binary strings only have 2 possible states the maximum entropy is always 1. Nov 10, 2010 at 11:32

I believe the answer is the Kolmogorov Complexity of the string. Not only is this not answerable with a chunk of pseudocode, Kolmogorov complexity is not a computable function!

One thing you can do in practice is compress the bit string with the best available data compression algorithm. The more it compresses the lower the entropy.

• A small correction, low compression indicates low entropy since low entropy equal low disorder. Entropy, Compression, and Information Content Mar 15, 2013 at 18:43
• "Drawing on these intuitions, Shannon developed a measure of entropy for language that assigns high entropy to the disordered, random first sentence, and low entropy to the ordered, patterned second sentence"... from your cited paper @isalamon
– VP.
Jul 5, 2013 at 9:59
• @lsalamon, link is broken. Dec 9, 2016 at 16:46
• @ValmikyArquissandas, here another paper about Entropy Dec 13, 2016 at 11:55
• @lsalamon High compression => low entropy. Low compression => high entropy. Mar 3, 2018 at 21:04

The NIST Random Number Generator evaluation toolkit has a way of calculating "Approximate Entropy." Here's the short description:

Approximate Entropy Test Description: The focus of this test is the frequency of each and every overlapping m-bit pattern. The purpose of the test is to compare the frequency of overlapping blocks of two consecutive/adjacent lengths (m and m+1) against the expected result for a random sequence.

And a more thorough explanation is available from the PDF on this page:

http://csrc.nist.gov/groups/ST/toolkit/rng/documentation_software.html

There is no single answer. Entropy is always relative to some model. When someone talks about a password having limited entropy, they mean "relative to the ability of an intelligent attacker to predict", and it's always an upper bound.

Your problem is, you're trying to measure entropy in order to help you find a model, and that's impossible; what an entropy measurement can tell you is how good a model is.

Having said that, there are some fairly generic models that you can try; they're called compression algorithms. If gzip can compress your data well, you have found at least one model that can predict it well. And gzip is, for example, mostly insensitive to simple substitution. It can handle "wkh" frequently in the text as easily as it can handle "the".

• I'm not sure I understand your second paragraph. Jun 5, 2010 at 6:58

Using Shannon entropy of a word with this formula : https://i.sstatic.net/GBBJG.jpg

Here's a O(n) algorithm that calculates it :

import math
from collections import Counter

def entropy(s):
l = float(len(s))
return -sum(map(lambda a: (a/l)*math.log2(a/l), Counter(s).values()))

Here's an implementation in Python (I also added it to the Wiki page):

import numpy as np

def ApEn(U, m, r):

def _maxdist(x_i, x_j):
return max([abs(ua - va) for ua, va in zip(x_i, x_j)])

def _phi(m):
x = [[U[j] for j in range(i, i + m - 1 + 1)] for i in range(N - m + 1)]
C = [len([1 for x_j in x if _maxdist(x_i, x_j) <= r]) / (N - m + 1.0) for x_i in x]
return -(N - m + 1.0)**(-1) * sum(np.log(C))

N = len(U)

return _phi(m) - _phi(m + 1)

Example:

>>> U = np.array([85, 80, 89] * 17)
>>> ApEn(U, 2, 3)
-1.0996541105257052e-05

The above example is consistent with the example given on Wikipedia.

• what are m and r? Jan 29, 2019 at 21:21
• I also have another question. Using this function, I'll get 0 for randU = np.random.choice([0, 1], size=17 * 3), m = 2, r = 3. Is this normal? Jan 31, 2019 at 4:10
• @Shabnam I honestly can't remember, I haven't used this for a while. But I tested my implementation pretty thoroughly when I wrote it. If you check out the wikipedia article I'm sure you can understand. Feb 1, 2019 at 10:15