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Recall that, in the previous readings, we defined the conditional distribution function of \(X\), given that \(\text{Y}=\text{y}\) as:
$$
\text{g}(\text{x} \mid \text{y})=\frac{\text{f}(\text{x}, \text{y})}{\text{f}_{\text{Y}}(\text{y})}, \quad \text { provided that } \text{f}_{\text{Y}}(\text{y})>0
$$
Similarly, the conditional distribution function of \(Y\), given that \(X=\text{x}\) is defined by:
$$
\text{h}(\text{y} \mid \text{x})=\frac{\text{f(x, y)}}{\text{f}_{\text X}(\text x)}, \quad \text { provided that } \text{f}_{\text X}(\text x)>0
$$
Now, if we have the above conditional distributions, we can go ahead to calculate conditional variance as well as the conditional standard deviation.
The conditional variance of \(X\), given that \(Y=y\), is defined by:
$$
\operatorname{Var}(\text X \mid \text Y=\text y)=\text E\left(\text X^{2} \mid \text Y=\text y\right)-[\text E(\text X \mid \text Y=\text y)]^{2}
$$
Where
$$
\text E\left(\text X^{2} \mid \text Y= \text y\right)=\sum_{\text x} \text x^{2} \cdot \text g(\text x \mid \text Y=\text y)
$$
and
$$
\text{E}(\text{X} \mid \text{Y}=\text{y})=\sum_{\text{x}} \text{x} \cdot \text{g}(\text{x} \mid \text{Y}=\text{y})
$$
Note that this is analogous to the variance of a single random variable.
We know that standard deviation is defined simply as the square root of variance.
This implies that the conditional standard deviation of \(\text{X}\), given that \(\text{Y}=\text{y}\) is defined by:
$$
\sigma_{\text{X} \mid \text{Y}=\text{y}}=\sqrt{\text{Var}(\text{X} \mid \text{Y}=\text{y})}
$$
Now, the conditional variance of \(\text{Y}\) given \(\text{X}=\text{x}\) is defined by:
$$
\text{Var}(\text{Y} \mid \text{X}=\text{x})=\text{E}\left(\text{Y}^{2} \mid \text{X}=\text{x}\right)-[\text{E}(\text{Y} \mid \text{X}=\text{x})]^{2}
$$
Where
$$
\text{E}\left(\text {Y}^{2} \mid \text{X}=\text{x}\right)=\sum_{\text{y}} \text{y}^{2} * \text h(\text{y}\mid \text {X}=\text {x})
$$
and
$$
\text{E}(\text{Y} \mid \text{X}=\text{x})=\sum_{\text{x}} \text{y} \cdot \text{h}(\text{y} \mid \text{X}=\text{x})
$$
The number of days of hospitalization for two individuals, \(\text{P}\), and \(Q\), is jointly distributed as:
$$
\text{f(x, y)}=\frac{\text{x}+\text{y}}{21}, \text {x=1,2,3} \quad \text{y=1,2}
$$
Find \(\operatorname{Var}(\text{X} \mid \text{Y}=1)\)
Since we wish to find \(\operatorname{Var}(\text{X} \mid \text{Y}=1)\), we first need to determine the conditional distribution of \(\mathrm{X}\) given \(\mathrm{Y}=1\), namely,
$$
\text{g}(\text{x} \mid \text{y})=\frac{\text{f(x, y)}}{\text{f}_{\text{Y}}(\text{y})}
$$
Where,
$$
\begin{align}
\text{f}_{\text{Y}}(\text{y})=& \sum_{\text {all } x} \text{P}(\text{x}, \text{y})=\text{P}(\text{Y}=\text{y}), \quad \text{y in S}_{\text{y}} \\
\Rightarrow & \text{f}_{\text{Y}}(\text{y})=\frac{(1)+\text{y}}{21}+\frac{(2)+\text{y}}{21}+\frac{(3)+\text{y}}{21}=\frac{6+3 \text{y}}{21}\end{align}
$$
Therefore, we have,
$$
\text {g}(\text{x} \mid\text{y} )=\frac{\text{f}\text{(x, y)}}{\text{f}_{\text{Y}}(\text{y})}=\frac{\frac{\text{x}+\text{y}}{21}}{\frac{6+3 y}{21}}=\frac{\text{x}+\text{y}}{\text{3y}+6}
$$
We can now go ahead to find the conditional variance:
$$
\operatorname{Var}(\text{X} \mid \text{Y}=\text{y})=\sigma_{\text{X} \mid \text{Y}=\text{y}}^{2}=\text{E}\left(\text{X}^{2} \mid \text{Y}=\text{y}\right)-[\text{E}(\text{X} \mid \text{Y}=\text{y})]^{2}
$$
We need:
$$
\operatorname{Var}(\text{X} \mid \text{Y}=1)=\text{E}\left(\text{X}^{2} \mid \text{Y}=1\right)-[\text{E}(\text{X} \mid \text{Y}=1)]^{2}
$$
Now,
$$
\begin{align}
\text{E}(\text{X} \mid \text{Y}&=1)=\sum_{\text{x}=1}^{3} \text{x} \cdot \text{g}(\text{x} \mid \text{y}=1) \\
&=\sum_{\text{x}=1}^{3} \text{x} \frac{(\text{x}+(1))}{3(1)+6} \\
&=(1) \frac{(1+(1))}{3(1)+6}+2 \frac{(2+(1))}{3(1)+6}+3 \frac{(3+(1))}{3(1)+6} \\ &=1\left(\frac{2}{9}\right)+2\left(\frac{1}{3}\right)+3\left(\frac{4}{9}\right)=\frac{20}{9} \end{align}
$$
We also need,
$$
\begin{align}\text{E}\left(\text{X}^{2} \mid \text{Y}=\text{y}\right)&=\sum_{\text{x}=1}^{3} \text{x}^2*\text{g}(\text{x} \mid \text{y}=1) \\&=\sum_{\text{x}=1}^{3} \text{x}^{2} \frac{(\text{x}+(1))}{3(1)+6} \\&
=\left(1^{2}\right) \frac{(1+(1))}{3(1)+6}+2^{2} \frac{(2+(1))}{3(1)+6}+3^{2} \frac{(3+}{3(1)} \\&
=1\left(\frac{2}{9}\right)+4\left(\frac{1}{3}\right)+9\left(\frac{4}{9}\right)=\frac{50}{9} \\&
\Rightarrow \operatorname{Var}(\text{X} \mid \text{Y}=1)=\text{E}\left(\text{X}^{2} \mid \text{Y}=1\right)-[ \text{E}(\text{X} \mid \text{Y}=1)]^{2} \\&
=\frac{50}{9}-\left(\frac{20}{9}\right)^{2}=\frac{50}{81}
\end{align}$$
Using the output from Example 1 above, find \(\text{SD}(\text{X} \mid \text{Y}=1)\)
From Example 1, we have
$$
\text{V}(\text{X} \mid \text{Y}=1)=\frac{50}{81}
$$
Thus,
$$
\text{SD}(\text{X} \mid \text{Y}=1)=\sqrt{\text{V}(\text{X} \mid \text{Y}=1)}=\sqrt{\frac{50}{81}}=0.7856
$$
Recall that if \(\text{X}\) and \(\text{Y}\) are discrete random variables with joint probability mass function \(\text{f}(\text{x}, \text{y})\) defined on the space \(S\), then the marginal distribution functions of \(X\) and \(Y\) are given by:
$$
\text{f}_{\text{X}}(\text{x})=\sum_{\text{y}} \text{f}(\text{x}, \text{y})=\text{P}(\text{X}=\text{x}), \quad \text{x} \in \text{S}_{\text{x}}
$$
and,
$$
\text{f}_{\text{Y}}(\text{y})=\sum_{\text{x}} \text{f(x, y)}=\text{P}(\text{Y}=\text{y}), \quad \text{y in S}_{\text{y}}
$$
Once we have the marginal distribution functions of \(X\) and \(Y\), we can now go ahead to find individual variances and standard deviations for \(X\) and \(Y\).
The variance for the random variable \(\text{X}\) is given by:
$$
\operatorname{Var}(\text{X})=\text{E}\left(\text{X}^{2}\right)-[\text{E}(\text{X})]^{2}
$$
Where
$$
\text{E}\left(\text{X}^{2}\right)=\sum_{\text{x}} \text{x}^{2} * \text{P}(\text{X}=\text{x})
$$
and
$$
\text{E}(\text{X})=\sum_{\text{X}} \text{x} * \text{P}(\text{X}=\text{x})
$$
Similarly, the variance of the random variable \(Y\) is given by:
$$
\operatorname{Var}(\text{Y})=\text{E}\left(\text{Y}^{2}\right)-[\text{E}(\text{Y})]^{2}
$$
Where
$$
\text{E}\left(\text{Y}^{2}\right)=\sum_{\text{x}} \text{y}^{2} * \text{P}(\text{Y}=\text{y})
$$
and
$$
\text{E(Y)}=\sum_{\text{x}} \text{y} * \text{P(Y=y)}
$$
The standard deviation for \(\text{X}\) and \(\text{Y}\) is the square root of their respective variances.
$$
\text{SD}(\text{X})=\sqrt{\text{E}\left(\text{X}^{2}\right)-[\text{E}(\text{X})]^{2}}
$$
and,
$$
\text{SD}(\text{Y})=\sqrt{\text{E}\left(\text{Y}^{2}\right)-[\text{E}(\text{Y})]^{2}}
$$
Let \(\text{X}\) and \(\text{Y}\) be the number of days of sickness for two individuals, \(\text{A}\) and \(\text{B}\).
$$
\text{f(x, y)}=\frac{\text{x}+\text{y}}{21}, \text{x=1,2,3} \quad \text{y=1,2}
$$
Calculate the variance and the standard deviation of \(X\).
We know that,
$$
\operatorname{Var}(\text{X})=\text{E}\left(\text{X}^{2}\right)-[\text{E}(\text{X})]^{2}
$$
First, we find the marginal probability mass function of \(\text{X}\), which is given by:
$$
\begin{align}
\text{f}_{\text{X}}(\text{x}) &=\sum_{\text {all } \text{y}} \text{f}(\text{x}, \text{y}) \text{x in S}_{\text{x}} \\
&=\frac{\text{x}+(1)}{21}+\frac{\text{x}+(2)}{21}=\frac{2 \text{x}+3}{21}, \quad \text { for } \text{x}=1,2,3
\end{align}
$$
Then,
$$\begin{align}
\text{E(X)} &=\sum_{\text{x}=1}^{3}\text{x} \text{P}_{\text{X}}(\text{x})=\sum_{\text{x}=1}^{3} \text{x} \frac{2 x+3}{21} \\
&=(1) \frac{2(1)+3}{21}+(2) \frac{2(2)+3}{21}+(3) \frac{2(3)+3}{21}\\&=1\left(\frac{5}{21}\right)+2\left(\frac{7}{21}\right)+3\left(\frac{9}{21}\right)=\frac{46}{21}
\end{align}
$$
and
$$
\begin{align}
\text{E}\left(\text{X}^{2}\right) &=\sum_{\text {all }\text{x}} \text{x}^{2} \text{P}_{\text{X}}(\text{x}) \\
&=(1)^{2}\left(\frac{5}{21}\right)+(2)^{2}\left(\frac{7}{21}\right)+(3)^{2}\left(\frac{9}{21}\right)-\left(\frac{46}{21}\right)^{2}=\frac{38}{7}
\end{align}
$$
Thus,
$$
\operatorname{Var(X)}=\frac{38}{7}-\left(\frac{46}{21}\right)^{2}=\frac{278}{441} \approx 0.6304
$$
We know that the standard deviation of \(\text{X}\) is the square root of its variance.
Therefore,
$$
\sigma_{\text{X}}=\sqrt{\text{Var}(\text{X})}=\sqrt{0.6304}=0.7940
$$
A laptop dealer specializes in two brands of laptops, HP and Lenovo. Let \({X}\) be the number of HP laptops sold in a day, and let \(Y\) be the number of Lenovo laptops sold in a day. The dealer has determined that the number of mobile phones sold in a day is jointly distributed as in the table below:
$$ \begin{array}{c|c|c|c} {\quad \text X }& {1} & {2} & {3} \\ {\Huge \diagdown } & & & \\ {\text Y \quad} & & & \\ \hline {0} & {\cfrac{1}{6}} & {\cfrac{1}{8}} & {\cfrac{1}{6}} \\ \hline {1} & {\cfrac{1}{3}} & {\cfrac{1}{12}} & {\cfrac{1}{8}} \\ \end{array} $$
Calculate the variance of \(\text{X}\)
We need to find the marginal distribution function of \(X\) first:
We know that,
$$
\text{f}_{\text{X}}(\text{x})=\sum_{\text{y}} \text{f(x, y)}=\text{P(X=x)}, \quad \text{x in S}_{\text{x}}
$$
Now,
$$
\
$$
$$
\begin{align}&\text{P(X=1)}=\frac{1}{6}+\frac{1}{3}=\frac{1}{2}\\ \\
&\text{P}(\text{X}=2)=\frac{1}{8}+\frac{1}{12}=\frac{5}{24} \\ \\
&\text{P}(\text{X}=3)=\frac{1}{6}+\frac{1}{8}=\frac{7}{24}
\end{align}
$$
Therefore,
$$
\text{E}(\text{X})=\sum_{\text{x}=1}^{3} x P_{\text{X}}(\text{x})=1 * \frac{1}{2}+2 * \frac{5}{24}+3 * \frac{7}{24}=\frac{43}{24}
$$
and,
$$
\text{E}\left(\text{X}^{2}\right)=\sum_{\text{x}=1}^{3} \text{x}^{2}(\text{x})=1^{2} * \frac{1}{2}+2^{2} * \frac{5}{24}+3^{2} * \frac{7}{24}=\frac{95}{24}
$$
Thus,
$$
\begin{aligned}
\operatorname{Var}(\text{X}) &=\text{E}\left(\text{X}^{2}\right)-[\text{E}(\text{X})]^{2} \\
&=\frac{95}{24}-\left(\frac{43}{95}\right)^{2}=3.992
\end{aligned}
$$
Note:
We can calculate the variance and the standard deviation of \(\text{Y}\) in a similar manner.
Let \(\alpha\) and \(\beta\) be non-zero constants. Then, it can be proven that:
i) \(\operatorname{Var}(\alpha)=0\)
ii) \(\operatorname{Var}(\alpha \text{X})=\alpha^{2} * \operatorname{Var}(\text{X})\)
iii) \(\operatorname{Var}(\alpha \text{X}+\beta)=\alpha^{2} * \operatorname{Var}(\text{X})\)
Learning Outcome
Topic 3. d: Multivariate Random Variables – Calculate variance and standard deviation for conditional and marginal http://www.gulfportpharmacy.com/ probability distributions for discrete random variables only.