Multivariate discrete distributions and independence
Bivariate discrete distributions
- Definition : If
and are discrete random variables on , the joint (probability) mass function of and is the function defined by usually abbreviated to . - It is clear that:
and - the marginal mass functions of
and :
Expectation in the multivariate case
- If
and are discrete random variables on and , it is easy to check that is a discrete random variable on also, defined formally by for . The expectation of may be calculated directly from the joint mass function , as the following theorem indicates: - Theorem:We have that
whenever this sum converges absolutely - The expectation operator
acts linearly on the set of discrete random variables:
Independence of discrete random variables
- Definition Two discrete random variables
and are independent if the pair of events and are independent for all , and we normally write this condition as May be expressed as: Random variables which are not independent are called dependent - This latter condition may be simplified as indicated by the following theorem:
- Theorem:Discrete random variables
and are independent if and only if there exist functions such that the joint mass function of and satisfies: - Theorem If
and are independent discrete random variables with expectations and , then: - Theorem:Discrete random variables
and on (?, F , P) are independent if and only if: for all functions for which the last two expectations exist. - Families
of random variables with . For example, the family is called independent if: or, equivalently: Furthermore, if are independent, then Finally, the family is called pairwise independent if and are independent whenever
Sums of random variables
If
Indicator functions
- Definition : The indicator function of an event
is the random variable denoted and given by - The function
indicates whether or not occurs.It is a discrete random variable with expectation given by - Indicator functions have two basic properties, namely:
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