Respuesta :
Answer: 0.098525
Step-by-step explanation:
According to the given description, we have
[tex]\mu=98.20[/tex]
[tex]\sigma=0.62[/tex]
Let x be a random variable that represents the body temperatures.
Also,Healthy people have body temperatures that are normally distributed.
Then , the z-score corresponds to x= 98.9 on normal curve ,
[tex]z=\dfrac{98.9-98.20}{0.62}[/tex] ([tex]z=\dfrac{x-\mu}{\sigma}[/tex])
[tex]=1.12903225806\approx1.129[/tex]
P-value = P(x> 98.9)= P(z>1.129)=1-P(z≤1.129)
=1-0.901475=0.098525 ≈ 0.098525 (using z-value table)
Hence, the probability that he or she has a temperature above 98.9°F = 0.098525
Answer:
The probability that a healthy person has a temperature above 98.9 Fahrenheit degrees is about P(x>98.9) = 0.1292 or 12.92%.
Step-by-step explanation:
This is a question of finding the probability of a normally distributed variable, and for this, we have to know that the normal distribution is determined by two parameters: the population mean and the population standard deviation. In this case, they are, respectively, [tex] \\ \mu = 98.20[/tex] Fahrenheit degrees and [tex] \\ \sigma = 0.62[/tex] Fahrenheit degrees.
To find probabilities, we can "transform" these "raw" scores into z-scores, or standardized values, using the z-score formula. After this, we can consult the cumulative standard normal table (available in Statistics books or on the Internet) using this z-score (e.g., z = a), for which we have the corresponding cumulative probability, that is, P(z<a). Of course, we can also use statistical software, or even a spreadsheet, to find such probabilities.
A z-score tells us the distance from the mean in standard deviations units for the standardized value of the raw score. A positive value indicates that the value is above the mean. Conversely, a negative value tells us that the value is below the mean.
The formula for this z-score is as follows
z = [tex] \\ \frac{x - \mu}{\sigma}[/tex] [1]
Where x is the raw score (x = 98.9 Fahrenheit degrees, in this case).
With this information at hand, we can solve the question.
The probability that a healthy person has a temperature above 98.9 Fahrenheit degrees
We need to find P(x>98.9).
Using formula [1], the z-score for x = 98.9 is
z = [tex] \\ \frac{x - \mu}{\sigma}[/tex]
z = [tex] \\ \frac{98.9 - 98.20}{0.62}[/tex]
z = [tex] \\ \frac{0.70}{0.62}[/tex]
z = [tex] \\ 1.12903 \approx 1.13[/tex]
With this value for z (z = 1.13), we can consult the cumulative standard normal table to find the probability for z = 1.13 or P(z<1.13), for which we have a value of P(z<1.13) = 0.8708.
However, we are asked for P(x>98.9) = P(z>1.13), which is the complement probability for P(z<1.13) or
[tex] \\ P(x>98.9) = P(z>1.13) = 1 - P(z<1.13)[/tex]
[tex] \\ P(x>98.9) = P(z>1.13) = 1 - 0.8708[/tex]
[tex] \\ P(x>98.9) = P(z>1.13) = 0.1292[/tex]
Remember that z is the standardized value for x, so P(x>98.9) = P(z>1.13).
Therefore, the probability that a healthy person has a temperature above 98.9 Fahrenheit degrees is about [tex] \\ P(x>98.9) = P(z>1.13) = 0.1292[/tex] or 12.92%.
We can see this area in the graph below.
