Difference between revisions of "Entropy, Relative Entropy, Mutual Information"

Definitions

Entropy

• a measure of the uncertainty of a random variable
• The entropy of a random variable is a measure of the uncertainty of the random variable
  • it is a measure of the amount of information required on the average to describe the random variable

Relative Entropy

• a measure of the distance between two distributions
• a measure of the inefficiency of assuming that the distribution is ${\displaystyle q}$ when the true distribution is ${\displaystyle p}$.

Mutual Information

• a measure of the amount of information that one random variable contains about another random variable

Entropy

Definitions:

• a measure of the uncertainty of a random variable
• The entropy of a random variable is a measure of the uncertainty of the random variable
  • it is a measure of the amount of information required on the average to describe the random variable

The entropy of a discrete random variable, ${\displaystyle X}$, is

${\displaystyle H\left(X\right)=-\sum _{x\in {\mathcal {X}}}p\left(x\right)\cdot \log _{2}p\left(x\right)}$

(1)

where ${\displaystyle X}$ has a probability mass function (pmf), ${\displaystyle p\left(x\right)}$, and an alphabet ${\displaystyle {\mathcal {X}}}$.

Expected Value

For a discrete random variable, ${\displaystyle X}$, with probability mass function, ${\displaystyle p\left(x\right)}$, the expected value of ${\displaystyle X}$ is

${\displaystyle E\left[X\right]=\sum _{x\in {\mathcal {X}}}x\cdot p\left(x\right)}$

(2)

For a discrete random variable, ${\displaystyle X}$, with probability mass function, ${\displaystyle p\left(x\right)}$, the expected value of ${\displaystyle g\left(X\right)}$ is

${\displaystyle E\left[g\left(X\right)\right]=\sum _{x\in {\mathcal {X}}}g\left(x\right)\cdot p\left(x\right)}$

(3)

Consider the case where ${\displaystyle g\left(x\right)=\log _{2}\left({\tfrac {1}{p\left(x\right)}}\right)}$. We get

${\displaystyle E\left[\log _{2}\left({\tfrac {1}{p\left(x\right)}}\right)\right]=\sum _{x\in {\mathcal {X}}}\log _{2}\left({\tfrac {1}{p\left(x\right)}}\right)\cdot p\left(x\right)=-\sum _{x\in {\mathcal {X}}}p\left(x\right)\cdot \log _{2}p\left(x\right)=H\left(X\right)}$

(4)

Lemma 1: Entropy is greater than or equal to zero

${\displaystyle H\left(X\right)\geq 0}$

(5)

Proof: Since ${\displaystyle 0\leq p\left(x\right)\leq 1}$, then ${\displaystyle \log _{2}\left({\tfrac {1}{p\left(x\right)}}\right)\geq 0}$, and subsequently, ${\displaystyle E\left[\log _{2}\left({\tfrac {1}{p\left(x\right)}}\right)\right]\geq 0}$. Thus from Eq. (4) we get ${\displaystyle H\left(X\right)\geq 0}$.

Lemma 2: Changing the logarithm base

${\displaystyle H_{b}\left(X\right)=\left(\log _{b}a\right)\cdot H_{a}\left(X\right)}$

(6)

Proof:

• Given that
  • ${\displaystyle H_{b}\left(X\right)=-\sum _{x\in {\mathcal {X}}}p\left(x\right)\cdot \log _{b}p\left(x\right)}$
  • ${\displaystyle H_{a}\left(X\right)=-\sum _{x\in {\mathcal {X}}}p\left(x\right)\cdot \log _{a}p\left(x\right)}$
• And since ${\displaystyle \log _{b}p=\log _{b}a\cdot log_{a}p}$
• We get ${\displaystyle H_{b}\left(X\right)=\left(\log _{b}a\right)\cdot H_{a}\left(X\right)}$

Note that the entropy, ${\displaystyle H_{b}\left(X\right)}$, has units of bits for ${\displaystyle b=2}$, or nats (natural units) for ${\displaystyle b=e}$, or dits (decimal digits) for ${\displaystyle b=10}$.

Joint Entropy