The Data Processing Inequality

Markovity

A Markov Chain is a random process that describes a sequence of possible events where the probability of each event depends only on the outcome of the previous event. Thus, we say that ${\displaystyle X,Y,Z}$ is a Markov chain in this order, denoted as:

${\displaystyle X\rightarrow Y\rightarrow Z}$

(1)

If we can write:

${\displaystyle P\left(X=x,Y=y,Z=z\right)=P\left(Z=z\mid Y=y\right)\cdot P\left(Y=y\mid X=x\right)\cdot P\left(X=x\right)}$

(2)

Or in a more compact form:

${\displaystyle P\left(x,y,z\right)=P\left(z\mid y\right)\cdot P\left(y\mid x\right)\cdot P\left(x\right)}$

(3)

We can use Markov chains to model how a signal is corrupted when passed through noisy channels. For example, if ${\displaystyle X}$ is a binary signal, it can change with a certain probability, ${\displaystyle p}$, to ${\displaystyle Y}$, and it can again be corrupted to produce ${\displaystyle Z}$.

Consider the joint probability ${\displaystyle P\left(x,z\mid y\right)}$. We can express this as:

${\displaystyle P\left(x,z\mid y\right)={\frac {P\left(x,y,z\right)}{P\left(y\right)}}}$

(4)

And if ${\displaystyle X\rightarrow Y\rightarrow Z}$, we get:

${\displaystyle P\left(x,z\mid y\right)={\frac {P\left(z\mid y\right)\cdot P\left(y\mid x\right)\cdot P\left(x\right)}{P\left(y\right)}}}$

(5)

Since ${\displaystyle P\left(y,x\right)=P\left(y\mid x\right)\cdot P\left(x\right)=P\left(x\mid y\right)\cdot P\left(y\right)}$, we can write:

${\displaystyle P\left(x,z\mid y\right)={\frac {P\left(z\mid y\right)\cdot P\left(y,x\right)}{P\left(y\right)}}=P\left(z\mid y\right)\cdot P\left(x\mid y\right)}$

(6)

Thus, we can say that ${\displaystyle X}$ and ${\displaystyle Z}$ are conditionally independent given ${\displaystyle Y}$. If we think of ${\displaystyle X}$ as some past event, and ${\displaystyle Z}$ as some future event, then the past and future events are independent if we know the present event ${\displaystyle Y}$. Note that this property is good definition of, as well as a useful tool for checking Markovity.

We can rewrite the joint probability ${\displaystyle P\left(x,y,z\right)}$ as:

${\displaystyle {\begin{aligned}P\left(x,y,z\right)&=P\left(z\mid y\right)\cdot P\left(y\mid x\right)\cdot P\left(x\right)\\&={\frac {P\left(z,y\right)}{P\left(y\right)}}\cdot P\left(y,x\right)\\&={\frac {P\left(z,y\right)}{P\left(y\right)}}\cdot P\left(x\mid y\right)\cdot P\left(y\right)\\&=P\left(z,y\right)\cdot P\left(x\mid y\right)\\&=P\left(x\mid y\right)\cdot P\left(y\mid z\right)\cdot P\left(z\right)\\\end{aligned}}}$

(7)

Therefore, if ${\displaystyle X\rightarrow Y\rightarrow Z}$, then it follows that ${\displaystyle Z\rightarrow Y\rightarrow X}$.

Conditional Mutual Information

Conditional mutual information is defined as the expected value of the mutual information of two random variables given the value of a third random variable.

The Data Processing Inequality

Sufficient Statistics

Fano's Inequality