Difference between revisions of "The Data Processing Inequality"
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{{NumBlk|::|<math>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)}</math>|{{EquationRef|5}}}} | {{NumBlk|::|<math>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)}</math>|{{EquationRef|5}}}} | ||
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| + | Since <math>P\left(y,x\right)=P\left(y\mid x\right)\cdot P\left(x\right)</math>, we can write: | ||
| + | |||
| + | {{NumBlk|::|<math>P\left(x, z\mid y\right) = \frac{P\left(z\mid y\right)\cdot P\left(y, x\right)}{P\left(y\right)}</math>|{{EquationRef|6}}}} | ||
== The Data Processing Inequality == | == The Data Processing Inequality == | ||
Revision as of 10:29, 23 October 2020
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 is a Markov chain in this order, denoted as:
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(1)
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If we can write:
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(2)
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Or in a more compact form:
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(3)
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We can use Markov chains to model how a signal is corrupted when passed through noisy channels. For example, if is a binary signal, it can change with a certain probability, to , and it can again be corrupted to produce .
Consider the joint probability . We can express this as:
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(4)
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And if , we get:
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(5)
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Since , we can write:
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(6)
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