Respuesta :
Answer:
About "95% of the attendance around the average is between" 22722 and 60482.
Step-by-step explanation:
The key to answering this question is the application of the 68-95-99.7 rule. It is a rule that "tells us" that data that follow a normal distribution approximately:
- 68% (68.27% to be more precise) of the observations are one standard deviation above and below the mean. We can express this mathematically as:
[tex] \\ P(\mu - 1\sigma \leq X \leq \mu + 1\sigma) = 0.6827 \approx 0.68[/tex] [1].
- 95% (95.45%) of the data are two standard deviations above and below the mean.
[tex] \\ P(\mu - 2\sigma \leq X \leq \mu + 2\sigma) = 0.9545 \approx 0.95[/tex] [2].
- 99.7% (99.73%) of the data are three standard deviations above and below the mean.
[tex] \\ P(\mu - 3\sigma \leq X \leq \mu + 3\sigma) = 0.9973 \approx 99.7 [/tex] [3].
The two parameters that characterized the normal distribution are the mean, [tex] \\ \mu[/tex], and the standard deviation, [tex] \\ \sigma[/tex].
In this case, we have:
- [tex] \\ \mu = 41602[/tex].
- [tex] \\ \sigma = 9440[/tex].
According to the 68-95-99.7 rule above explained, we know that the "95% of the attendance around the average" is two standard deviations, [tex] \\ \sigma[/tex], above and below the mean, [tex] \\ \mu[/tex].
Then, using [2], we have:
[tex] \\ P(\mu - 2\sigma \leq X \leq \mu + 2\sigma) = 0.9545 \approx 0.95[/tex] [2].
[tex] \\ P(41602 - 2*9440 \leq X \leq 41602 + 2*9440) = 0.9545 \approx 0.95[/tex].
[tex] \\ P(41602 - 18880 \leq X \leq 41602 + 18880) = 0.9545 \approx 0.95[/tex].
[tex] \\ P(22722 \leq X \leq 60482) = 0.9545 \approx 0.95[/tex].
Therefore, about "95% of the attendance around the average is between" 22722 and 60482.
Notice that we approximate the values using the 68-95-99.7 rule, which is a good approximation and sufficient for practical uses. However, if we want to know exactly the 95% of the attendance around the average, we can calculate it using the formula for z-score (which, roughly speaking, "tell us" the distance from the mean in standard deviations units of a normally distributed value):
[tex] \\ z = \frac{x - \mu}{\sigma}[/tex] [4]
A positive value of z indicates that x is above the mean and a negative that x is below the mean.
Since the normal distribution is symmetrical around the mean, we can divide the 95% of probability in two equal parts. One above the mean, [tex] \\ \frac{0.95}{2} = 0.475[/tex], and the other below the mean [tex] \\ \frac{0.95}{2} = 0.475[/tex]
If we consult the cumulative standard normal table from the mean (0 to Z), the value for z, in this case, is [tex] \\ z = 1.96[/tex], because for a probability of 0.475, the value of z = 1.96. Remember that the standard normal normal distribution has a [tex] \\ \mu = 0[/tex] and [tex] \\ \sigma = 1[/tex]. That is why the interval is from 0 (mean) to the value of Z.
Therefore, solving [4] for x, for an exactly value of 95% of the attendance around the average is between:
Upper value
The value is above the mean:
[tex] \\ 1.96 = \frac{x - 41602}{9440}[/tex]
[tex] \\ (1.96 * 9440) + 41602 = x[/tex]
[tex] \\ x = (1.96 * 9440) + 41602[/tex]
[tex] \\ x = 60104.40 \approx 60104[/tex]
Lower value
The value is below the mean:
[tex] \\ -1.96 = \frac{x - 41602}{9440}[/tex]
[tex] \\ x = (-1.96 * 9440) + 41602[/tex]
[tex] \\ x = 23099.60 \approx 23100[/tex]
Or an exactly value of 95% of the attendance around the average is between 23100 and 60104. Notice that the question gives us options using the 68-95-99.7 rule, that is, 22722 and 60482, which are also valid (with less precision).
The below graphic shows the previous result (which is very similar to that obtained using the 68-95-99.7 rule.)
