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I've been thinking about information entropy in terms of the Markov equation:

H = -SUM(p(i)lg(p(i)), where lg is the base 2 logarithm.

This assumes that all selections i have equal probability. But what if the probability in the given set of choices is unequal? For example, let's say that StackExchange has 20 sites, and that the probability of a user visiting any StackExchange site except StackOverflow is p(i). But, the probability of a user visiting StackExchange is 5 times p(i).

Would the Markov equation not apply in this case? Or is there an advanced Markov variation that I'm unaware of?

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Have you considered posting at the Theoretical Computer Science SE? That would probably cater for this question better! –  Yuki Izumi May 24 '12 at 12:47
    
Or Even link? –  Totero May 24 '12 at 13:05
    
@Totero: I'm not sure this is a DSP question … –  Yuki Izumi May 27 '12 at 6:14
    
@Len: I suggested DSP because I know Markov is extensively used and studied in that field. –  Totero May 27 '12 at 9:20
    
@Totero: fair enough! It seemed peculiar when I read the site description, that's all, but if they do know, all the better! –  Yuki Izumi May 27 '12 at 9:35

2 Answers 2

up vote 1 down vote accepted

I believe you are mixing up 2 concepts: entropy and the Markov equation. Entropy measures the "disorder" of a distribution on states, using the equation you gave: H = -SUM(p(i)lg(p(i)), where p(i) is the probability of observing each state i.

The Markov property does not imply that every state has the same probability. Roughly, a system is said to exhibit the Markov property if the probability to observe a state depends only on observing a few previous states - after a certain limit, the extra states you observe add no information to predicting the next state.

The prototypical Markov model is known as a Markov chain. It says that from each state i, you can move to any state with another probability, represented as a probability matrix:

0 1 2
0 0.2 0.5 0.3
1 0.8 0.1 0.1
2 0.3 0.3 0.4

In this example, the probability of moving from state 0 to 1 is 0.5, and depends only on being in state 0 (knowing more about the previous states would not change that probability).

As long as all states can be visited starting from any state, no matter what the initial distribution, the probability of being in each state converges to a stable, long-term distribution, and on a "long series" you'll observe each state with a stable probability, which is not necessarily equal for each states.

In our example, we would end up having probabilities p(0), p(1) and p(2), and you could then compute the entropy of that chain using your formula.

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From your example are you thinking of Markov Chains?

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Seems strange to me that this didn't get accepted as the answer. It was the first answer which made reference to Markov Chains. Poor etiquette from the the op really. –  daveL May 28 '12 at 9:32

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