Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Math 1125-Introductory Statistics — Lecture 17 10/11/06 1. Normally Distributed Populations We left off last time saying that normally distributed populations are populations whose z-scores are distributed like the Standard Normal. If we have a population that is normally distributed, and we also know its mean and standard deviation, then we can use the Standard Normal to compute probabilities. For a population with variable x, mean µ, and standard deviation σ, we can convert x’s to z-scores using (1) z= x−µ , σ and we’ll assume that these z-scores belong to the standard normal distribution. 2. Computing probabilities We computed one probability last time. Let’s do a few more. Let’s say that we have a population of male lab rats whose weights are normally distributed with mean µ = 3.2 ounces and standard deviation σ = 0.5 ounces. If we were to take one of these rats at random, what is the probability that it weighs more than 4.0 ounces? We’ll use x for the weights of these rats. First of all, let’s convert these x-scores into z-scores. One relevant x-score is the number x = 3.2. This is the mean weight. Plugging into the formula (2) z= x−µ 3.2 − 3.2 0 = = = 0. σ 0.5 .5 This shouldn’t be too surprising. The mean will always convert to a z-score of z = 0. Equivalently, the mean will always lie at the center of the normal curve. We’re interested in x’s that lie above x = 4.0, so we need to convert this to a z-score as well. (3) z= x−µ 4.0 − 3.2 0.8 = = = 1.60. σ 0.5 0.5 This x-score, x = 4.0 is larger than the mean, so it will have a positive z-score, and it will lie to the right on the normal curve. As always, you should draw a picture, and the picture for this problem looks like Figure 1. We’re interested in the probability of x-scores to the right of x = 4.0. The weights of our rats surely do not go to infinity, but a true normal distribution does. The probabilities 1 2 0 3.2 1.60 4.0 z x Figure 1. The area corresponding to P (4.0 ≤ x < ∞). beyond about three or four standard deviations is practically zero, however, so computing the probability out to infinity is convenient and reasonable. Here’s the probability. (4) P (4.0 ≤ x < ∞) = P (1.60 ≤ z < ∞) = 0.5000 − 0.4452 = 0.0548 We can interpret this probability as saying that about 5.48% of this population of rats weighs more than 4.0 ounces. Using this same population, we can ask for the probability that one of these rats weighs between 2.5 and 3.5 ounces. Since x = 2.5 is below the mean, we know that we’ll get a negative z-score for it, and it will lie on the left side of the graph. The x = 3.5 is above the mean, so it will lie to the right. We can compute the z-scores as we did before. 2.5 − 3.2 −0.7 x−µ = = = −1.40 σ 0.5 0.5 (5) x−µ 3.5 − 3.2 0.3 z= = = = 0.60 σ 0.5 0.5 The picture, therefore, looks like Figure 2. z= −1.40 2.5 0 3.2 0.60 3.5 z x Figure 2. The area corresponding to P (2.5 ≤ z ≤ 3.5). Here, the computation goes like this. The picture tells us to add, so (6) P (2.5 ≤ z ≤ 3.5) = P (−1.40 ≤ z ≤ 0.60) = 0.4192 + 0.2257 = 0.6449 It looks like almost two-thirds of the population lies between these two weights. 3. Some statistical reasoning Suppose Chemical X is known to be present in the hair of men. It is also in women’s hair, but usually in much smaller quantities. If the concentration of Chemical X in men 3 is normally distributed with mean 12.3 ppm (parts per million) and standard deviation 2.1 ppm, would it be reasonable to conclude that a hair sample with a Chemical X concentration of 4.1 ppm came from a woman? In statistics, a standard quantity to look at would be the probability that a man would have concentration this low or lower. In other words, what is P (x ≤ 4.1)? We need to convert x = 4.1 to a z-score. (7) z= 4.1 − 12.3 = −3.90 2.1 This z-score is not in our table. Our table runs out at P (0 ≤ z ≤ 3.19) = 0.4993, and we’re well beyond that. We can’t find the precise probability, but we know that (8) P (x ≤ 4.1) = P (z ≤ −3.90) < P (z ≤ −3.19) = 0.5000 − 0.4993 = 0.0007 That is, the probability that this is a man’s hair sample with concentration this low is less than 0.07%. This is so unlikely, that we should conclude that this sample came from a woman. 4. Quiz 17 Suppose that we have a dexterity test, and the completion times are normally distributed with µ = 5.3 seconds and σ = 0.7 seconds. Find the probability of a random person getting a time . . . 1. Faster than 3.5 seconds. 2. Faster than 6.2 seconds. 3. Slower than 6.2 seconds. 4. Between 5.0 and 6.0 seconds. 5. Slower than 7.0 seconds. 4 5. Homework 17 For all problems, write z-scores out to two decimal places, and probabilities out to four. For problems 1-4, consider any population. 1. The mean of a population (that is, an x-score of x = µ) will convert to a z-score of . 2. x-scores above the mean will lie on the side of the normal curve. 3. x-scores below the mean will lie on the side of the normal curve. 4. True or False, negative z-scores correspond to negative probabilities. For problems 5-9, consider the population of male lab rats discussed in these lecture notes (µ = 3.2 ounces and σ = 0.5 ounces). 5. Find the z-score for a rat that weighs x = 2.0 ounces. 6. Find the probability that a rat taken at random weighs less than 2.0 ounces. 7. Find the probability that one of these rats weighs between 2.0 ounces and 3.2 ounces. 8. Find the probability that one of these rats weighs between 2.0 ounces and 4.4 ounces. 9. Find the probability that one of these rats weighs more than 4.4 ounces. For problems 10-15, suppose we have a particular standardized test whose scores are normally distributed with mean µ = 800 and standard deviation σ = 100. We’ll use x for the scores on the test. 10. Find the z-score for x = 800. Remember to give z-scores out to two decimal places. 11. Find the z-score for x = 600. 12. Find the probability that a test taker chosen at random will score below 600. Remember that I want probabilities taken out to four decimal places. 13. Find the probability that a random test taker will score above 1100. 14. Find the probability that a random test taker will score between 600 and 1000. 15. Find the probability that a random test taker will score between 900 and 1000. 5 For problems 16-20, suppose that the times to complete a particular dexterity test are normally distributed with mean µ = 12.0 seconds and standard deviation σ = 2.8 seconds. 16. What side of the normal curve will times faster than 12 seconds lie on? 17. Find the z-score for x = 10.5 seconds. 18. Find the probability that a person taken at random will complete the test faster than 10.5 seconds. 19. Find the probability that a person taken at random will complete the test slower than 15.0 seconds. 20. Find the probability that a person taken at random will complete the test faster than 15.0 seconds. (Be careful, and be sure to look at a correct picture. It should be an easy problem, however.) Bye.