Answers to Selected Exercises

The Central Limit Theorem for Sample Means (Averages) — Practice

1. mean = 4 hours; standard deviation = 1.2 hours; sample size = 16

3.

a. Check student’s solution.

b.  3.5, 4.25, 0.2441

5. The fact that the two distributions are different accounts for the different probabilities.

The Central Limit Theorem for Sums — Practice

7. 0.3345

9. 7,833.92

11. 0.0089

13. 7,326.49

15. 77.45%

17. 0.4207

19. 3,888.5

21. 0.8186

23. 5

25. 0.9772

27. The sample size, n, gets larger.

29. 49

31. 26.00

33. 0.1587

35. 1,000

Using the Central Limit Theorem — Practice

37.

 

  1. U(24, 26), 25, 0.5774
  2. N(25, 0.0577)
  3. 0.0416

 

39. 0.0003

41. 25.07

43.

  1. N(2,500, 5.7735)
  2. 0

45. 2,507.40

47.

a. 10

b. [latex]\frac{1}{10}[/latex]

49. N[latex]\left(10,\frac{{10}}{{8}}\right)[/latex]

51. 0.7799

53. 1.69

55. 0.0072

57. 391.54

59. 405.51

The Central Limit Theorem for Sample Means (Averages) – Homework

61.

  1. Χ = amount of change students carry
  2. Χ ~ E(0.88, 0.88)
  3. X⎯⎯⎯ = average amount of change carried by a sample of 25 students.
  4. X⎯⎯⎯ ~ N(0.88, 0.176)
  5. 0.0819
  6. 0.1882
  7. The distributions are different. Part a is exponential and part b is normal.

63.

  1. length of time for an individual to complete IRS form 1040, in hours.
  2. mean length of time for a sample of 36 taxpayers to complete IRS form 1040, in hours.
  3. N(10.53, 13)
  4. Yes. I would be surprised, because the probability is almost 0.
  5. No. I would not be totally surprised because the probability is 0.2312

65.

  1. the length of a song, in minutes, in the collection
  2. U(2, 3.5)
  3. the average length, in minutes, of the songs from a sample of five albums from the collection
  4. N(2.75, 0.0220)
  5. 2.74 minutes
  6. 0.03 minutes

67.

  1. True. The mean of a sampling distribution of the means is approximately the mean of the data distribution.
  2. True. According to the Central Limit Theorem, the larger the sample, the closer the sampling distribution of the means becomes normal.
  3. The standard deviation of the sampling distribution of the means will decrease making it approximately the same as the standard deviation of X as the sample size increases.

69.

  1. X = the yearly income of someone in a third world country
  2. the average salary from samples of 1,000 residents of a third world country
  3. [latex]\overline{X}[/latex] ∼ N[latex]\left(2000,\frac{{8000}}{{\sqrt{1000}}}\right)[/latex]
  4. Very wide differences in data values can have averages smaller than standard deviations.
  5. The distribution of the sample mean will have higher probabilities closer to the population mean.
    P(2000 < [latex]\overline{X}[/latex]< 2100) = 0.1537
    P(2100 < [latex]\overline{X}[/latex]< 2200) = 0.1317

71. [latex]\displaystyle\overline{{X}}[/latex] ~ N(4.59, [latex]\frac{{0.10}}{{\sqrt{16}}}[/latex])

The Central Limit Theorem for Sums – Homework

73.

  1. the total length of time for nine criminal trials
  2. N(189, 21)
  3. 0.0432
  4. 162.09; ninety percent of the total nine trials of this type will last 162 days or more.

75.

  1. X = the salary of one elementary school teacher in the district
  2. X ~ N(44,000, 6,500)
  3. ΣX ~ sum of the salaries of ten elementary school teachers in the sample
  4. ΣX ~ N(44000, 20554.80)
  5. 0.9742
  6. $52,330.09
  7. 466,342.04
  8. Sampling 70 teachers instead of ten would cause the distribution to be more spread out. It would be a more symmetrical normal curve.
  9. If every teacher received a $3,000 raise, the distribution of X would shift to the right by $3,000. In other words, it would have a mean of $47,000.

Using the Central Limit Theorem – Homework

77.

  1. X = the closing stock prices for U.S. semiconductor manufacturers
  2. i. $20.71; ii. $17.31; iii. 35
  3. Check student’s solution
  4. Exponential distribution, Χ ~ Exp[latex]\left(\frac{{1}}{{20.71}}\right)[/latex]
  5. Answers will vary.
  6. i. $20.71; ii. $11.14
  7. Answers will vary.
  8. Answers will vary.
  9. Answers will vary.
  10. N[latex]\overline{X}~\left(60,\frac{{9}}{{\sqrt{25}}}\right)[/latex]
  11. 0.5000
  12. 59.06
  13. 0.8536
  14. 0.1333
  15. N(1500, 45)
  16. 1530.35
  17. 0.6877

89.

  1. $52,330
  2. $46,634

91. We have

  • μ = 17, σ = 0.8, [latex]\overline{x}[/latex]= 16.7, and n = 30. To calculate the probability, we use normalcdf (lower, upper, [latex]\mu,\frac{{\sigma}}{{\sqrt{n}}}[/latex]) = normalcdf [latex]\left(E-99,16.7,17,\frac{{0.8}}{{\sqrt{30}}}\right)[/latex] = 20
  • If the process is working properly, then the probability that a sample of 30 batteries would have at most 16.7 lifetime hours is only 2%. Therefore, the class was justified to question the claim.

93.

  1. For the sample, we have n = 100, [latex]\overline{x}[/latex]= 0.862, s = 0.05
  2. [latex]\overline{x}[/latex]= 85.65, Σs = 5.18
  3. normalcdf(396.9,E99,(465)(0.8565),(0.05)([latex]\sqrt{465}[/latex])) ≈ 1
  4. Since the probability of a sample of size 465 having at least a mean sum of 396.9 is appproximately 1, we can conclude that Mars is correctly labeling their M&M packages.

95. Use normalcdf

[latex]\left(E-99,1.1,1\frac{{1}}{{\sqrt{70}}}\right)[/latex]

= 0.7986. This means that there is an 80% chance that the service time will be less than 1.1 hours. It could be wise to schedule more time since there is an associated 20% chance that the maintenance time will be greater than 1.1 hours.

97.  We assume that the weights of coins are normally distributed in the population. Since we have 

normalcdf(5.11, 5.291, 5.201, [latex]\frac{0.065}{\sqrt{280}}[/latex] ) ≈ 0.8338, we expect (1 – 0.8338)280 ≈ 47 coins to be rejected.