Statistical Practice Questions: Two-Sample Hypothesis Testing & Confidence Intervals, Exams of Statistics

Download Statistical Practice Questions: Two-Sample Hypothesis Testing & Confidence Intervals and more Exams Statistics in PDF only on Docsity! Stat 20 Fall 06 A. Adhikari ANSWERS TO PRACTICE QUESTIONS FOR THE FINAL 1. The box has 155 tickets. Each ticket has two parts: the left side shows the 1/0 that will be the result if the patient gets assigned to the treatment group, and the right side shows the 1/0 that will be the result if the patient gets assigned to the control group. We see a simple random sample of 78 of the left sides, and the remaining 77 right sides. The null hypothesis states that the proportion of 1’s on the left side of all 155 tickets is equal to the proportion of 1’s on the right side of all 155 tickets (that is, the treatment has no effect). 2. z = 3.46. This is the usual “two sample” calculation in the context of the randomized experiment. The SE for difference = 7.21% 3. (ii) 4. (100 30 ) 0.3300.770 5. 7.97%. Expect 30 blue tickets, SE 4.58, z = 0.11. 6. (i). The chance of hitting the theoretical probability exactly will decrease. 7. (ii) At least 79. This is the 80th percentile of the midterm distribution. 8. 85.8. 9. 78.82%. The rms error is 8.43. 10. (ii) There’s a perfectly good random sample but the two sets of responses are dependent because they are obtained from the same people. There is no information about the nature of the dependence. 11. The box has 15,000 tickets, one for each patient. Each ticket shows blood pressure. The average and SD of the box are unknown. The null hypothesis says that the average of the box is equal to 120. 12. The average of the box is less than 120. 13. t (degrees of freedom = 5) = −1.2. 14. The data support the investigators’ belief. (Or, the data do not support the conclusion that the population average is lower than 120.) 15. 94.21%. Binomial n = 5, p = 0.2, k = 0, 1, 2. Add the three terms. 16. 8.075%. I expect to lose $0 give or take $35.36. 17. 69. Expect 80 hits with an SE of 8, and z = −1.3. You get 69.6, and should use the continuity correction to see that 69 is a better answer than 70. 18. (ii) is approximately 25%. This is an “Are you awake?” question. With hundreds of throws, the distribution of the number of hits is roughly normal and centered at 20%. Therefore on a single day the chance of “more than 20% hits” is about 50%. The throws are independent, so the answer is 0.5× 0.5 = 0.25. 19. (ii) equal to 15.5%. It’s the center of the interval; recall the method of construction. This is another “Are you awake?” question. 20. (ii) goes from 12.25% to 18.75%. The z is 2.6. The SE for the percent is 1.25%, because the 1 distance between the center and each end of the 95%-CI must be 2 times the SE for the percent. [See if you can find the sample size (at least to a pretty good approximation) and the number of senior citizens in the sample. Those numbers are not necessary for the problems here, but it’s instructive to find them.] 21. 180 through 220. In 400 tosses of a fair coin you expect 200 heads give or take 10. It’s a two-sided test so the critical values of z are ±2.05. 22. 288. It’s 96% of 300. 23. 293. According to our earlier calculation, the students who will conclude that the coin is fair will be those who get 180 to 220 heads inclusive. In 400 tosses of a coin which lands heads with chance 0.6, the expected number of heads is 240 with an SE of √ 400× 0.6× 0.4 = 9.8. Convert 179.5 and 220.5 to standard units to get z = −6.17 and −1.99 respectively. The area in that region is essentially equal to the area to the left of −2, which is 2.275%. We have shown that 2.275% of the students will conclude that the coin is fair, which is the wrong conclusion for this coin. But the remaining 100% − 2.275% = 97.725% of the students will conclude, correctly, that the coin is not fair. If you used 95% instead of 95.45% as the area in the range ±2, that’s OK. You should still get 293 as your answer. 24. 15.56%. You can draw a chart (which is pretty big; there are 90 possibilities because you remove the diagonal from a 10×10 grid). Or you can find the chances of SS, TT, II separately and add up. 25. 30%. The easiest way is to reason by symmetry, as you do for “What’s the chance that the second card dealt from a standard deck is an ace?” Or you can use the chart to see that the fraction is 27/90. 26. 33.33%. Given that a vowel gets used up on the second draw, only 9 tickets are possibilities for the first. Of these, 3 are T’s. 27. (ii) 28. (iii). The distribution of the sample is clearly non-normal. 29. (iii). It’s the histogram of all possible sample averages and all their probabilities. 30. I’ll accept anything in the range 24% to 26%. There 120 draws with replacement from a box which contains one ticket marked $1, four marked −$1.5, and one marked $6. The expected sum of the draws is $20 with an SE of $30.23 (use the old formula from Chapter 4 to find the SD of the box). So z is just around −0.67. 31. 97.98%. This is about the number of bets my friend wins, so the box has 4 tickets marked 1 and 2 tickets marked 0. My friend has to win at least 70 bets (if he wins 70 then I win 50, so he wins 20 more). His expected number of wins is 80 with an SE of 5.16. Convert 69.5 to standard units to get z = −2.03. 32. 88.87%. This is 1 minus the chance that we both win the same number of bets, that is, 1 minus the chance that my friend wins 6 bets. Use the binomial formula with n = 12, p = 4/6 and k = 6. Yes, that’s exactly the same as using the binomial formula with n = 12, p = 2/6, and k = 6. 33. (ii), because the sample sizes are equal. If you want to calculate anything, compute the SE 2