0.5 Ch. 5: continuous random variables

Let $X$ = the amount of time (in minutes) a student waits in line at the college cafeteria. The notation for the distribution is $X$ ~ $U(a,b)$ where $a=0$ and $b=5$ . The function is $f\left(x\right)=\frac{1}{5}$ where $0<x<5$ . The pattern is $\text{f(x)}=\frac{1}{b-a}$ where $a<x<b$ .

In this example $a=0$ and $b=5$ . The function $f\left(x\right)$ where $0<x<5$ graphs as a horizontal line segment.

The function is where $f(x)={\text{me}}_{-\text{mx}}$ $m\ge 0$ AND $x\ge 0$ . Find the probability that the amount of change one person has is less then $.50. Draw the graph.

The formula is $P(X<x)=1-e^{\text{mx}}P(X<.50)=$ _________. The authors use technology to solve the probability problems. If you use the TI-83/84 calculator series, enter on the home-screen, $1-e^{-m\cdot .50}$ . Fill in the $m$ with whatever the data produces ( $m=\frac{1}{\mu }$ ; replace $\mu$ with the sample mean).

Ask the question, "Ninety percent of you have less than what amount?" and have them find the 90th percentile.

Draw the picture and let $k$ = the 90th percentile. $P(X<k)=0.90$ . Solve the equation $1-e^{\mathrm{mk}}=0.90$ for $k$ . On the home-screen of the TI-83/TI-84, enter $\frac{\ln (1-.90)}{(-m)}$ .

On average, a student would expect to have _________ . The word "expect" implies the mean. Ten students together would expect to have _________. (the mean multiplied by 10)