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Let std::vector<int> counts be a vector of positive integers and let N:=counts[0]+...+counts[counts.length()-1] be the the sum of vector components. Setting pi:=counts[i]/N, I compute the entropy using the classic formula H=p0*log2(p0)+...+pn*log2(pn).

The counts vector is changing --- counts are incremented --- and every 200 changes I recompute the entropy. After a quick google and stackoverflow search I couldn't find any method for incremental entropy computation. So the question: Is there an incremental method, like the ones for variance, for entropy computation?

EDIT: Motivation for this question was usage of such formulas for incremental information gain estimation in VFDT-like learners.

Resolved: See this mathoverflow post.

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1  
You might want to try heading over to math.stackexchange to get a more detailed mathematical treatment of your question. –  Shaktal Jun 14 '13 at 9:01
    
Shaktal, I posted the question on the mathoverflow, where they pointed out the following paper: hal.inria.fr/docs/00/60/90/65/PDF/RR-7663.pdf –  blazs Jun 18 '13 at 11:03

3 Answers 3

up vote 1 down vote accepted

I derived update formulas and algorithms for entropy and Gini index and made the note available on arXiv. (The working version of the note is available here.) Also see this mathoverflow answer.

For the sake of convenience I am including simple Python code, demonstrating the derived formulas:

from math import log
from random import randint

# maps x to -x*log2(x) for x>0, and to 0 otherwise 
h = lambda p: -p*log(p, 2) if p > 0 else 0

# update entropy if new example x comes in 
def update(H, S, x):
    new_S = S+x
    return 1.0*H*S/new_S+h(1.0*x/new_S)+h(1.0*S/new_S)

# entropy of union of two samples with entropies H1 and H2
def update(H1, S1, H2, S2):
    S = S1+S2
    return 1.0*H1*S1/S+h(1.0*S1/S)+1.0*H2*S2/S+h(1.0*S2/S)

# compute entropy(L) using only `update' function 
def test(L):
    S = 0.0 # sum of the sample elements
    H = 0.0 # sample entropy 
    for x in L:
        H = update(H, S, x)
        S = S+x
    return H

# compute entropy using the classic equation 
def entropy(L):
    n = 1.0*sum(L)
    return sum([h(x/n) for x in L])

# entry point 
if __name__ == "__main__":
    L = [randint(1,100) for k in range(100)]
    M = [randint(100,1000) for k in range(100)]

    L_ent = entropy(L)
    L_sum = sum(L)

    M_ent = entropy(M)
    M_sum = sum(M)

    T = L+M

    print "Full = ", entropy(T)
    print "Update = ", update(L_ent, L_sum, M_ent, M_sum)

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I suppose by count vector is changing you mean that new elements are getting added to the vector and even values of existing elements i changing.

 1.varibles
   You can declare a new vector p[](probability) and a variable 'L' meaning total number
   of elements in count and a variable 'H' meaning total entropy.Also a variable N 
   meaning sum of elements in count vector.

 2.Method
   Initially with the given count vector initialise 'L' , 'H' and vector 'p[]'
   a.If a new element 'x' is added to count vector
     increment L
     store that element in count
     N=N+x
     increment size of p[]
     store x/N in p[]
     Now H becomes H+p[L-1]*log2(p[l-1])
  b.If an existing element in count is changed suppose the element at index 'i' is 
    changed from value 'a' to value 'b'
    old=count[i]
    count[i]=b
    N=N-old+count[i]
    p_old=p[i]
    p[i]=count[i]/N
    H=H+p[i]*log2(p[i])-p_old

In either case you don't need to compute entropy again, only O(1) changes have to be made.

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@Blaz but still could you elaborate what is the meaning that vector count changes if my assumptions above are wrong. –  migdal Jun 14 '13 at 9:18
    
Migdal thanks for the answer and sorry for the late response regarding your assumptions: By `vector count changes' I mean that existing elements are changing --- what's more, they are increasing, never decreasing --- but no new elements are added (counts vector size is constant). –  blazs Jun 17 '13 at 16:44
    
Yes, your answer works for me; I only need the 2.b step of the method. :-) –  blazs Jun 17 '13 at 16:51
    
Also, a word of warning: Above approach is okay for small changes, but if most of the entries change it essentially completely recomputes the entropy and takes more space than the naive recomputation. –  blazs Jun 17 '13 at 17:19
    
WARNING: After looking into it in detail, I found the above answer is incorrect. When new element gets added, all the probabilities change as they are estimated using relative frequency, so the ``whole'' old H changes. See this post for possible solution to the incremental entropy copmutation problem. –  blazs Jun 19 '13 at 15:43

You could re-compute the entropy by re-computing the counts and using some simple mathematical identity to simplify the entropy formula

K = count.size();
N = count[0] + ... + count[K - 1];
H = count[0]/N * log2(count[0]/N) + ... + count[K - 1]/N * log2(count[K - 1]/N)
  = F * h
h = (count[0] * log2(count[0]) + ... + count[K - 1] * log2(count[K - 1]))
F = -1/(N * log2(N)) 

which holds because of log2(a / b) == log2(a) - log2(b)

Now given an old vector count of observations so far and another vector of new 200 observations called batch, you can do in C++11

void update_H(double& H, std::vector<int>& count, int& N, std::vector<int> const& batch)
{
    N += batch.size();
    auto F = -1/(N * log2(N));
    for (auto b: batch)
       ++count[b];
    H = F * std::accumulate(count.begin(), count.end(), 0.0, [](int elem) { 
        return elem * log2(elem);
    });
}

Here I assume that you have encoded your observations as int. If you have some kind of symbol, you would need a symbol table std::map<Symbol, int>, and do a lookup for each symbol in batch before you update the count.

This seems the quickest way of writing some code for a general update. If you know that in every batch only few counts actually change, you can do as @migdal does and keep track of the changing counts, subtract their old contribution to the entropy and add the new contribution.

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