Variance and Covariance

A mean does not give adequate description of the shape of a random variable (probability distribution).
We need to characterize the variability (or dispersion) of the random variable in the distribution.

Figure 1: Distributions with equal means and unequal dispersions.

$\includegraphics[scale=0.5,angle=1]{figures/04-01}$
Definition 4.3:
$\fbox{\parbox{5in}{ Let $X$\ be a random variable with probability distribution ... ...aymath}\end{small}$\sigma$\ is called the \textbf{standard deviation} of $X$. }}$

**Figure 1:** Distributions with equal means and unequal dispersions.
$\includegraphics[scale=0.5,angle=1]{figures/04-01}$

Example 4.8:Let the random variable represent the number of automobiles that are used for official business purposes on any given workday.
The probability distribution for company A and B is as follows.

1 2 3

0.3 0.4 0.3

0 1 2 3 4

0.2 0.1 0.3 0.3 0.1
Show that the variance of the probability distribution for company B is greater than that of company A.
Solution:

$\displaystyle \mu_A=E(X)=1*0.3+2*0.4+3*0.3=2.0$

$\displaystyle \sigma_A^2=\sum_{x=1}^3 (x-2.0)^2f(x)=(1-2)^2*0.3+(2-2)^2*0.4+(3-2)^2*0.3=0.6$

$\displaystyle \mu_B=2.0~ \&~ \sigma_B^2=1.6$

Theorem 4.2:
$\fbox{\parbox{5in}{ The \textbf{variance} of a random variable $X$\ is \begin{displaymath} \sigma^2=E(X^2)-\mu^2 \end{displaymath}}}$
Example 4.9: Let the random variable represent the number of defective parts for a machine when 3 parts are sampled from a production line and tested.
Calculate $\sigma^2$ using the following probability distribution.

0 1 2 3

0.51 0.38 0.10 0.01
Solution:

$\displaystyle \mu=E(X)=0*0.51+\ldots=0.61$

$\displaystyle E(X^2)=\sum_{x=0}^3 x^2f(x)=0^2*0.51+\ldots=0.87$

$\displaystyle \sigma^2=E(X^2)-\mu^2=0.87-0.61^2=0.4979$

Theorem 4.3:
$\fbox{\parbox{5in}{ Let $X$\ be a random variable with probability distribution ... ...if~ X~is~continuous \\ \end{array}\right\rbrace \end{displaymath}\end{small}}}$
Example 4.11: Calculate the variance of , where is a random variable with probability distribution.

0 1 2 3

1/4 1/8 1/2 1/8
Solution:

$\displaystyle \mu_{2X+3}=E(2X+3)=\sum_{x=0}^3 (2X+3)f(x)= 6$

$\displaystyle \sigma^2_{2X+3}=E\left\lbrace [2X+3-\mu_{2X+3}]^2 \right\rbrace =E\left\lbrace [2X+3-6]^2 \right\rbrace$

$\displaystyle =E(4X^2-12X+9)=\sum_{x=0}^3 (4X^2-12X+9)f(x)=4$

Definition 4.4:
$\fbox{\parbox{5in}{ Let $X$\ and $Y$\ be random variables with joint probability... ...continuous \\ \end{array}\right\rbrace \end{displaymath}\ \end{footnotesize}}}$
The covariance between two random variables is a measurement of the nature of the association between the two.
The sign of the covariance indicates whether the relationship between two dependent random variables is positive or negative.
When and are statistically independent, it can be shown that the covariance is zero.
The converse, however, is not generally true. Two variables may have zero covariance and still not be statistically independent.

The covariance only describe the linear relationship between two random variables.
If a covariance between and is zero, and may have a nonlinear relationship, which means that they are not necessarily independent.
Theorem 4.4:
$\fbox{\parbox{5in}{ The covariance of two random variables $X$\ and $Y$\ with me... ...iven by \begin{displaymath} \sigma_{XY}=E(XY)- \mu_X\mu_Y \end{displaymath} }}$

Definition 4.5:
$\fbox{\parbox{5in}{ Let $X$\ and $Y$\ be random variables with covariance $\sigm... ...\sigma_{XY}}{\sigma_{X}\sigma_{Y}},~-1 \leq \rho_{XY} \leq 1 \end{displaymath}}}$
Exact linear dependency:

$\displaystyle \rho_{XY} =1, ~ if~ b> 0 ~~;~~ \rho_{XY} =-1, ~ if~ b< 0$

Cem Ozdogan 2010-03-25

	1	2	3
	0.3	0.4	0.3

	0	1	2	3	4
	0.2	0.1	0.3	0.3	0.1

	0	1	2	3
	0.51	0.38	0.10	0.01

	0	1	2	3
	1/4	1/8	1/2	1/8