Entropy of a probability distribution: Difference between revisions
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#Given a [[continuous probability distribution]] function f, the entropy H of the distribution is given by <math>H=-\int_{i=-Inf}^{i=Inf} f(x_{i}) log_{2} f(x_{i} ) dx</math> | #Given a [[continuous probability distribution]] function f, the entropy H of the distribution is given by <math>H=-\int_{i=-Inf}^{i=Inf} f(x_{i}) log_{2} f(x_{i} ) dx</math> | ||
Note that some authors prefer to use the natural logarithm rather than base two. | |||
== See also == | == See also == | ||
Revision as of 11:11, 27 June 2007
The entropy of a probability distribution is a number that describes the degree of uncertainty or disorder the distribution represents.
Examples
Assume we have a set of two mutually exclusive propositions (or equivalently, a random experiment with two possible outcomes). Assume all two possiblities are equally likely.
Then our advance uncertainty about the eventual outcome is rather small - we know in advance it will be one of exactly two known alternatives.
Assume now we have a set of a million alternatives - all of them equally likely - rather than two.
It seems clear that our uncertainty now about the eventual outcome will be much bigger.
Formal definitions
- Given a discrete probability distribution function f, the entropy H of the distribution is given by
- Given a continuous probability distribution function f, the entropy H of the distribution is given by
Note that some authors prefer to use the natural logarithm rather than base two.