1. Inference about Two Populations
Chapter 13
Inference about Two Populations

2. 12.1 Introduction
Variety of techniques are presented whose objective is to compare two populations.
We are interested in:
The difference between two means.
The ratio of two variances.
The difference between two proportions.

3. 13.2 Inference about the Difference between Two Means: Independent Samples
Two random samples are drawn from the two populations of interest.
Because we compare two population means, we use the statistic

4. The Sampling Distribution of
is normally distributed if the (original) population distributions are normal .
is approximately normally distributed if the (original) population is not normal, but the samples’ size is sufficiently large (greater than 30).
The expected value of is m1 - m2
The variance of is s12/n1 + s22/n2

5. Making an inference about m1 – m2
If the sampling distribution of is normal or approximately normal we can write:
Z can be used to build a test statistic or a confidence interval for m1 - m2

6. Making an inference about m1 – m2
Practically, the “Z” statistic is hardly used, because the population variances are not known. t
S12 ?
S22 ?
Instead, we construct a t statistic using the
sample “variances” (S12 and S22).

7. Making an inference about m1 – m2
Two cases are considered when producing the t-statistic.
The two unknown population variances are equal.
The two unknown population variances are not equal.

8. Inference about m1 – m2: Equal variances
Calculate the pooled variance estimate by:
The pooled
variance
estimator
n2 = 15
n1 = 10
Example: s12 = 25; s22 = 30; n1 = 10; n2 = 15. Then,

9. Inference about m1 – m2: Equal variances
Calculate the pooled variance estimate by:
The pooled
Variance
estimator
n2 = 15
n1 = 10
Example: s12 = 25; s22 = 30; n1 = 10; n2 = 15. Then,

10. Inference about m1 – m2: Equal variances
Construct the t-statistic as follows:
Perform a hypothesis test
H0: m1 - m2 = 0
H1: m1 - m2 > 0
Build a confidence interval
or < 0
or 0

11. Inference about m1 – m2: Unequal variances

12. Inference about m1 – m2: Unequal variances
Conduct a hypothesis test
as needed, or,
build a confidence interval

13. Which case to use: Equal variance or unequal variance?
Whenever there is insufficient evidence that the variances are unequal, it is preferable to perform the equal variances t-test.
This is so, because for any two given samples
The number of degrees
of freedom for the equal
variances case
The number of degrees
of freedom for the unequal
variances case

15. Example: Making an inference about m1 – m2
Do people who eat high-fiber cereal for breakfast consume, on average, fewer calories for lunch than people who do not eat high-fiber cereal for breakfast?
A sample of 150 people was randomly drawn. Each person was identified as a consumer or a non-consumer of high-fiber cereal.
For each person the number of calories consumed at lunch was recorded.

16. Example: Making an inference about m1 – m2
Solution:
The data are interval.
The parameter to be tested is
the difference between two means.
The claim to be tested is:
The mean caloric intake of consumers (m1)
is less than that of non-consumers (m2).

17. Example: Making an inference about m1 – m2
The hypotheses are:
H0: (m1 - m2) = 0
H1: (m1 - m2) < 0
To check the whether the population variances are equal, we use (Xm13-01) computer output to find the sample variances We have s12= 4103, and s22 = 10,670.
It appears that the variances are unequal.

18. Example: Making an inference about m1 – m2
Compute: Manually
From the data we have:

19. Example: Making an inference about m1 – m2
Compute: Manually
The rejection region is t < -ta,n =

20. Example: Making an inference about m1 – m2
Xm13-01
At the 5% significance level there is sufficient
evidence to reject the
null hypothesis.
-2.09 <
.0193 < .05

21. Example: Making an inference about m1 – m2
Compute: Manually
The confidence interval estimator for the difference between two means is

23. Example: Making an inference about m1 – m2
An ergonomic chair can be assembled using two different sets of operations (Method A and Method B)
The operations manager would like to know whether the assembly time under the two methods differ.

24. Example: Making an inference about m1 – m2
Two samples are randomly and independently selected
A sample of 25 workers assembled the chair using method A.
A sample of 25 workers assembled the chair using method B.
The assembly times were recorded
Do the assembly times of the two methods differs?

25. Example: Making an inference about m1 – m2
Assembly times in Minutes
Solution
The data are interval.
The parameter of interest is the difference
between two population means.
The claim to be tested is whether a difference
between the two methods exists.

26. Example: Making an inference about m1 – m2
Compute: Manually
The hypotheses test is:
H0: (m1 - m2) = H1: (m1 - m2) ¹ 0
To check whether the two unknown population variances are equal we calculate S12 and S22 (Xm13-02).
We have s12= , and s22 =
The two population variances appear to be equal.

27. Example: Making an inference about m1 – m2
Compute: Manually
To calculate the t-statistic we have:

28. Example: Making an inference about m1 – m2
The rejection region is t < -ta/2,n =-t.025,48 = or t > ta/2,n = t.025,48 = 2.009
The test: Since t= < 0.93 < 2.009, there is insufficient evidence to reject the null hypothesis.
For a = 0.05
Rejection region
-2.009
.093
2.009

29. Example: Making an inference about m1 – m2
Xm13-02
< .93 <
.3584 > .05

30. Example: Making an inference about m1 – m2
Conclusion: There is no evidence to infer at the 5% significance level that the two assembly methods are different in terms of assembly time

31. Example: Making an inference about m1 – m2
A 95% confidence interval for m1 - m2 is calculated as follows:
Thus, at 95% confidence level < m1 - m2 <
Notice: “Zero” is included in the confidence interval

32. Checking the required Conditions for the equal variances case (Example 13.2)
Design A
The data appear to be
approximately normal
Design B

33. 13.4 Matched Pairs Experiment
What is a matched pair experiment?
Why matched pairs experiments are needed?
How do we deal with data produced in this way?
The following example demonstrates a situation
where a matched pair experiment is the correct
approach to testing the difference between two
population means.

35. 13.4 Matched Pairs Experiment
Example 13.3
To investigate the job offers obtained by MBA graduates, a study focusing on salaries was conducted.
Particularly, the salaries offered to finance majors were compared to those offered to marketing majors.
Two random samples of 25 graduates in each discipline were selected, and the highest salary offer was recorded for each one. The data are stored in file Xm13-03.
Can we infer that finance majors obtain higher salary offers than do marketing majors among MBAs?.

36. 13.4 Matched Pairs Experiment
Solution
Compare two populations of interval data.
The parameter tested is m1 - m2 m1
The mean of the highest salary offered to Finance MBAs
H0: (m1 - m2) = H1: (m1 - m2) > 0 m2
The mean of the highest salary offered to Marketing MBAs

37. 13.4 Matched Pairs Experiment
Solution – continued
From the data we have:
Let us assume equal variances
There is insufficient evidence to conclude that Finance MBAs are offered higher salaries than marketing MBAs.

38. The effect of a large sample variability
Question
The difference between the sample means is – = 5,201.
So, why could we not reject H0 and favor H1 where (m1 – m2 > 0)?

39. The effect of a large sample variability
Answer:
Sp2 is large (because the sample variances are large) Sp2 = 311,330,926.
A large variance reduces the value of the t statistic and it becomes more difficult to reject H0.

40. Reducing the variability
The range of observations
sample A
The values each sample consists of might markedly vary...
The range of observations
sample B

41. Reducing the variability
Differences
...but the differences between pairs of observations
might be quite close to one another, resulting in a small
variability of the differences.
The range of the
differences

42. The matched pairs experiment
Since the difference of the means is equal to the mean of the differences we can rewrite the hypotheses in terms of mD (the mean of the differences) rather than in terms of m1 – m2.
This formulation has the benefit of a smaller variability.
Group Group Difference
Mean1 =12.5 Mean2 =11.5
Mean1 – Mean2 = Mean Differences = 1

43. The matched pairs experiment
Example 13.4
It was suspected that salary offers were affected by students’ GPA, (which caused S12 and S22 to increase).
To reduce this variability, the following procedure was used:
25 ranges of GPAs were predetermined.
Students from each major were randomly selected, one from each GPA range.
The highest salary offer for each student was recorded.
From the data presented can we conclude that Finance majors are offered higher salaries?

44. The matched pairs hypothesis test
Solution (by hand)
The parameter tested is mD (=m1 – m2)
The hypotheses: H0: mD = 0 H1: mD > 0
The t statistic:
Finance Marketing
The rejection region is
t > t.05,25-1 = 1.711
Degrees of freedom = nD – 1

45. The matched pairs hypothesis test
Solution
From the data (Xm13-04) calculate:

46. The matched pairs hypothesis test
Solution
Calculate t

47. The matched pairs hypothesis test
Xm13-04
3.81 >
.0004 < .05

48. The matched pairs hypothesis test
Conclusion:
There is sufficient evidence to infer at 5%
significance level that the Finance MBAs’ highest
salary offer is, on the average, higher than that of
the Marketing MBAs.

49. The matched pairs mean difference estimation

50. The matched pairs mean difference estimation
Using Data Analysis Plus
Xm13-04
First calculate the differences,
then run the confidence interval
procedure in Data Analysis Plus.

51. Checking the required conditions for the paired observations case
The validity of the results depends on the normality of the differences.

52. 13.5 Inference about the ratio of two variances
In this section we draw inference about the ratio of two population variances.
This question is interesting because:
Variances can be used to evaluate the consistency of processes.
The relationship between population variances determines which of the equal-variances or unequal-variances t-test and estimator of the difference between means should be applied

53. Parameter and Statistic
Parameter to be tested is s12/s22
Statistic used is
Sampling distribution of s12/s22
The statistic [s12/s12] / [s22/s22] follows the F distribution with n1 = n1 – 1, and n2 = n2 – 1.

54. Parameter and Statistic
Our null hypothesis is always
H0: s12 / s22 = 1
Under this null hypothesis the F statistic becomes
F =
S12/s12
S22/s22

56. Testing the ratio of two population variances
Example 13.6 (revisiting Example 13.1)
(see Xm13-01)
In order to perform a test regarding average consumption of calories at people’s lunch in relation to the inclusion of high-fiber cereal in their breakfast, the variance ratio of two samples has to be tested first.
Calories intake at lunch
The hypotheses are:
H0:
H1:

57. Testing the ratio of two population variances
Solving by hand
The rejection region is F>Fa/2,n1,n2 or F<1/Fa/2,n2,n1
The F statistic value is F=S12/S22 = .3845
Conclusion: Because .3845<.58 we reject the null hypothesis in favor of the alternative hypothesis, and conclude that there is sufficient evidence at the 5% significance level that the population variances differ.

58. Testing the ratio of two population variances
Example 13.6 (revisiting Example 13.1)
(see Xm13-01)
In order to perform a test regarding average consumption of calories at people’s lunch in relation to the inclusion of high-fiber cereal in their breakfast, the variance ratio of two samples has to be tested first.
The hypotheses are:
H0:
H1:

59. Estimating the Ratio of Two Population Variances
From the statistic F = [s12/s12] / [s22/s22] we can isolate s12/s22 and build the following confidence interval:

60. Estimating the Ratio of Two Population Variances
Example 13.7
Determine the 95% confidence interval estimate of the ratio of the two population variances in Example 13.1
Solution
We find Fa/2,v1,v2 = F.025,40,120 = 1.61 (approximately) Fa/2,v2,v1 = F.025,120,40 = 1.72 (approximately)
LCL = (s12/s22)[1/ Fa/2,v1,v2 ] = ( /10,669.77)[1/1.61]= .2388
UCL = (s12/s22)[ Fa/2,v2,v1 ] = ( /10,669.77)[1.72]= .6614

61. 13.6 Inference about the difference between two population proportions
In this section we deal with two populations whose data are nominal.
For nominal data we compare the population proportions of the occurrence of a certain event.
Examples
Comparing the effectiveness of new drug versus older one
Comparing market share before and after advertising campaign
Comparing defective rates between two machines

62. Parameter and Statistic
When the data are nominal, we can only count the occurrences of a certain event in the two populations, and calculate proportions.
The parameter is therefore p1 – p2.
Statistic
An unbiased estimator of p1 – p2 is (the difference between the sample proportions).

63. Sampling Distribution of
Two random samples are drawn from two populations.
The number of successes in each sample is recorded.
The sample proportions are computed.
Sample 1
Sample size n1
Number of successes x1
Sample proportion
Sample 2
Sample size n2
Number of successes x2
Sample proportion x n 1 ˆ = p

64. Sampling distribution of
The statistic is approximately normally distributed if n1p1, n1(1 - p1), n2p2, n2(1 - p2) are all greater than or equal to 5.
The mean of is p1 - p2.
The variance of is (p1(1-p1) /n1)+ (p2(1-p2)/n2)

65. The z-statistic Because and are unknown the standard error
must be estimated using the sample proportions.
The method depends on the null hypothesis

66. Testing the p1 – p2 There are two cases to consider: Then Then Case 1:
H0: p1-p2 =0
Calculate the pooled proportion
Case 2:
H0: p1-p2 =D (D is not equal to 0)
Do not pool the data
Then
Then

67. Testing p1 – p2 (Case 1) Example 13.8
The marketing manager needs to decide which of two new packaging designs to adopt, to help improve sales of his company’s soap.
A study is performed in two supermarkets:
Brightly-colored packaging is distributed in supermarket 1.
Simple packaging is distributed in supermarket 2.
First design is more expensive, therefore,to be financially viable it has to outsell the second design.

68. Testing p1 – p2 (Case 1) Summary of the experiment results
Supermarket purchasers of Johnson Brothers soap out of a total of 904
Supermarket purchasers of Johnson Brothers soap out of a total of 1,038
Use 5% significance level and perform a test to find which type of packaging to use.

69. Testing p1 – p2 (Case 1) Solution
The problem objective is to compare the population of sales of the two packaging designs.
The data are nominal (Johnson Brothers or other soap)
The hypotheses are H0: p1 - p2 = 0 H1: p1 - p2 > 0
We identify this application as case 1
Population 1: purchases at supermarket 1
Population 2: purchases at supermarket 2

70. Testing p1 – p2 (Case 1) Compute: Manually
For a 5% significance level the rejection region is z > za = z.05 = 1.645

71. Testing p1 – p2 (Case 1)
Excel (Data Analysis Plus)
Xm13-08
Conclusion: There is sufficient evidence to conclude at the 5% significance level, that brightly-colored design will outsell the simple design.

72. Testing p1 – p2 (Case 2) Example 13.9 (Revisit Example 13.8)
Management needs to decide which of two new packaging designs to adopt, to help improve sales of a certain soap.
A study is performed in two supermarkets:
For the brightly-colored design to be financially viable it has to outsell the simple design by at least 3%.

73. Testing p1 – p2 (Case 2) Summary of the experiment results
Supermarket purchasers of Johnson Brothers’ soap out of a total of 904
Supermarket purchasers of Johnson Brothers’ soap out of a total of 1,038
Use 5% significance level and perform a test to find which type of packaging to use.

74. Testing p1 – p2 (Case 2) Solution
The hypotheses to test are H0: p1 - p2 = .03 H1: p1 - p2 > .03
We identify this application as case 2 (the hypothesized difference is not equal to zero).

75. Testing p1 – p2 (Case 2) Compute: Manually15 . 1
038 , )
1493 (
904
1991 03
155
180 ˆ 2 = - + ÷ ø ö ç è æ n p D Z
The rejection region is z > za = z.05 =
Conclusion: Since 1.15 < do not reject the null hypothesis. There is insufficient evidence to infer that the brightly-colored design will outsell the simple design by 3% or more.

76. Testing p1 – p2 (Case 2)
Using Excel (Data Analysis Plus)
Xm13-08

77. Estimating p1 – p2 Estimating the cost of life saved
Two drugs are used to treat heart attack victims:
Streptokinase (available since 1959, costs $460)
t-PA (genetically engineered, costs $2900).
The maker of t-PA claims that its drug outperforms Streptokinase.
An experiment was conducted in 15 countries.
20,500 patients were given t-PA
20,500 patients were given Streptokinase
The number of deaths by heart attacks was recorded.

78. Estimating p1 – p2 Experiment results
A total of 1497 patients treated with Streptokinase died.
A total of 1292 patients treated with t-PA died.
Estimate the cost per life saved by using t-PA instead of Streptokinase.

79. Estimating p1 – p2 Solution
The problem objective: Compare the outcomes of two treatments.
The data are nominal (a patient lived or died)
The parameter to be estimated is p1 – p2.
p1 = death rate with t-PA
p2 = death rate with Streptokinase

80. Estimating p1 – p2 Compute: Manually Sample proportions:
The 95% confidence interval estimate is

81. Estimating p1 – p2 Interpretation
We estimate that between .51% and 1.49% more heart attack victims will survive because of the use of t-PA.
The difference in cost per life saved is = $2440.
The total cost saved by switching to t-PA is estimated to be between 2440/.0149 = $163,758 and 2440/.0051 = $478,431