In information theory, the conditional entropy quantifies the amount of information needed to describe the outcome of a random variable given that the value of another random variable is known. Here, information is measured in shannons, nats, or hartleys. The entropy of conditioned on is written as .

Venn diagram showing additive and subtractive relationships various information measures associated with correlated variables and . The area contained by both circles is the joint entropy . The circle on the left (red and violet) is the individual entropy , with the red being the conditional entropy . The circle on the right (blue and violet) is , with the blue being . The violet is the mutual information .

Definition

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The conditional entropy of   given   is defined as

  (Eq.1)

where   and   denote the support sets of   and  .

Note: Here, the convention is that the expression   should be treated as being equal to zero. This is because  .[1]

Intuitively, notice that by definition of expected value and of conditional probability,   can be written as  , where   is defined as  . One can think of   as associating each pair   with a quantity measuring the information content of   given  . This quantity is directly related to the amount of information needed to describe the event   given  . Hence by computing the expected value of   over all pairs of values  , the conditional entropy   measures how much information, on average, the variable   encodes about  .

Motivation

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Let   be the entropy of the discrete random variable   conditioned on the discrete random variable   taking a certain value  . Denote the support sets of   and   by   and  . Let   have probability mass function  . The unconditional entropy of   is calculated as  , i.e.

 

where   is the information content of the outcome of   taking the value  . The entropy of   conditioned on   taking the value   is defined by:

 

Note that   is the result of averaging   over all possible values   that   may take. Also, if the above sum is taken over a sample  , the expected value   is known in some domains as equivocation.[2]

Given discrete random variables   with image   and   with image  , the conditional entropy of   given   is defined as the weighted sum of   for each possible value of  , using   as the weights:[3]: 15 

 

Properties

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Conditional entropy equals zero

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  if and only if the value of   is completely determined by the value of  .

Conditional entropy of independent random variables

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Conversely,   if and only if   and   are independent random variables.

Chain rule

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Assume that the combined system determined by two random variables   and   has joint entropy  , that is, we need   bits of information on average to describe its exact state. Now if we first learn the value of  , we have gained   bits of information. Once   is known, we only need   bits to describe the state of the whole system. This quantity is exactly  , which gives the chain rule of conditional entropy:

 [3]: 17 

The chain rule follows from the above definition of conditional entropy:

 

In general, a chain rule for multiple random variables holds:

 [3]: 22 

It has a similar form to chain rule in probability theory, except that addition instead of multiplication is used.

Bayes' rule

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Bayes' rule for conditional entropy states

 

Proof.   and  . Symmetry entails  . Subtracting the two equations implies Bayes' rule.

If   is conditionally independent of   given   we have:

 

Other properties

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For any   and  :

 

where   is the mutual information between   and  .

For independent   and  :

  and  

Although the specific-conditional entropy   can be either less or greater than   for a given random variate   of  ,   can never exceed  .

Conditional differential entropy

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Definition

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The above definition is for discrete random variables. The continuous version of discrete conditional entropy is called conditional differential (or continuous) entropy. Let   and   be a continuous random variables with a joint probability density function  . The differential conditional entropy   is defined as[3]: 249 

  (Eq.2)

Properties

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In contrast to the conditional entropy for discrete random variables, the conditional differential entropy may be negative.

As in the discrete case there is a chain rule for differential entropy:

 [3]: 253 

Notice however that this rule may not be true if the involved differential entropies do not exist or are infinite.

Joint differential entropy is also used in the definition of the mutual information between continuous random variables:

 

  with equality if and only if   and   are independent.[3]: 253 

Relation to estimator error

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The conditional differential entropy yields a lower bound on the expected squared error of an estimator. For any random variable  , observation   and estimator   the following holds:[3]: 255 

 

This is related to the uncertainty principle from quantum mechanics.

Generalization to quantum theory

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In quantum information theory, the conditional entropy is generalized to the conditional quantum entropy. The latter can take negative values, unlike its classical counterpart.

See also

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References

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  1. ^ "David MacKay: Information Theory, Pattern Recognition and Neural Networks: The Book". www.inference.org.uk. Retrieved 2019-10-25.
  2. ^ Hellman, M.; Raviv, J. (1970). "Probability of error, equivocation, and the Chernoff bound". IEEE Transactions on Information Theory. 16 (4): 368–372. CiteSeerX 10.1.1.131.2865. doi:10.1109/TIT.1970.1054466.
  3. ^ a b c d e f g T. Cover; J. Thomas (1991). Elements of Information Theory. Wiley. ISBN 0-471-06259-6.